epidemiological investigation of risk factors of …
TRANSCRIPT
EPIDEMIOLOGICAL INVESTIGATION OF RISK FACTORS OF MASTITIS IN DAIRY BUFFALO AND ANTIBIOTIC
RESISTANCE OF STAPHYLOCOCCUS AUREUS
ABID HUSSAIN 2010-VA-261
A THESIS SUBMITTED IN PARTIAL FULFILLMENT OF REQUIREMENTS FOR THE DEGREE
OF
DOCTOR OF PHILOSOPHY
IN
EPIDEMIOLOGY AND PUBLIC HEALTH
UNIVERSITY OF VETERINARY AND ANIMAL SCIENCES, LAHORE
2015
The Controller of Examinations, University of Veterinary and Animal Sciences, Lahore.
We, the supervisory committee, certify that the contents and form of the thesis,
submitted by Mr. Abid Hussain, Regd. No. 2010-VA-261 have been found satisfactory and
recommend that it be processed for the evaluation by the External Examiner(s) for the award of
the degree.
SUPERVISOR ____________________________ Prof. Dr. Mansur-ud-Din Ahmad MEMBER _____________________________ Dr. Muhammad Hassan Mushtaq MEMBER ______________________________ Prof. Dr. Muhammad Sarwar Khan
DEDICATED
To
My Teachers, Parents and Family
i
ACKNOWLEDGEMENTS
All praises to “ALLAH”, the Almighty, Most Gracious, the most Merciful and the Sustainer
of the worlds, Who created the jinn and humankind only for His worship and raised among the
inhabitants of Makkah the Holy Prophet “Muhammad” (peace be upon him.) from among
themselves, who recited to them His revelations and purified them, and taught them the Book (Holy
Quran) and the Wisdom. Foremost, thanks to Almighty Allah Who blessed me with good health
and valued teachers to accomplish my Ph.D studies. I feel great pleasure in expressing my
heartiest gratitude and a deep sense of obligation to my distinguished supervisor, Prof. Dr.
Mansur ud Din Ahmad, Department of Epidemiology and Public Health, for his able guidance,
keen interest, skilled advice, constructive criticism, constant encouragement, valuable suggestions
and kind supervision throughout the course of my study and research work. In addition, I owe my
thanks to my committee members, Dr. Muhammad Hassan Mushtaq Assistant Professor,
Department of Epidemiology and Public Health, and Prof. Dr. Muhammad Sarwar Khan,
Department of Clinical Medicine and Surgery, for their time and insights into this study. All these
respected teachers have contributed their thoughts, perspectives, insights, and experiences, which
have positively impacted the quality of my thesis. Special thanks to Prof. Dr. Michael Philipp
Reichel and Dr. Tanveer Hussain who helped me a lot during my research work. Many thanks go
to the labs of Epidemiology and Public Health. In the end, I could not envisage the endeavors that
my parents, made for my comfortable stay at the campus No acknowledgement could ever
adequately express my obligation to my affectionate parents for leading their children into
intellectual pursuits. “May Allah give them a long, prosperous and happy life” (Aa’meen). I also
extend my heartiest compliments to Dr. Noshaba Fakhar-ud-Din, Fatima Abid, Meerub Abid,
brother and sisters whose love and support made it possible to reach this position.
Abid Hussain
ii
TABLE OF CONTENTS
DEDICATION ………………………………………………………….. (i)
ACKNOWLEDGEMENTS ……………………………………………. (ii)
TABLE OF CONTENTS………………………………………………. (iii)
LIST OF TABLES ……………………………………………………… (iv)
LIST OF FIGURES …………………………………………………….. (v)
S. NO. CHAPTERS PAGE NO.
1 INTRODUCTION 1
2 REVIEW OF LITERATURE 6
3 EXPERIMENT-1 53
4 EXPERIMENT-2 105
5 EXPERIMENT-3 120
6 SUMMARY 154
iii
LIST OF TABLES
TABLE NO.
TITLE PAGE NO.
3.1 Prevalence of Clinical and Subclinical Mastitis in Lactating Buffaloes 73 3.2 Prevalence of Mastitis on basis of Herd size in Lactating Buffaloes 74 3.3 Prevalence of Mastitis on basis of Age wise in Lactating Buffaloes 75 3.4 Prevalence of mastitis on basis of breed in Lactating Buffaloes 76 3.5 Prevalence of mastitis on basis of parity in lactating buffaloes 77
3.6 Prevalence of mastitis on basis of stage of lactation in lactating buffaloes 78
3.7 Quarter wise prevalence of mastitis in lactating buffaloes 79
3.8 Prevalence of mastitis in lactating buffaloes having mastitis in 1, 2, 3 and 4 quarters 80
3.9 Univariable Analysis for Association of different Risk Factors with Mastitis
81
3.10 Univariable Analysis for Association of different Risk Factors with Mastitis
82
3.11 Univariable Analysis for Association of different Risk Factors with Mastitis 83
3.12 Multivariable Analysis of Potential Risk Factors with Prevalence of Mastitis
84
4.1 Isolation and identification of Staphylococcus aureus 110
4.2 Percentage (%) and number of Staphylococcus aureus resistant, intermediate and sensitivity to antibiotics (n=236) 110
5.1 Coagulase gene pairwise genetic distance among all Pakistani strains 136 5.2 FnbA Pairwise genetic distance between all Pakistani strains 137
5.3 The pairwise genetic distance relationship between isolated strains and some reference strains based on coagulase gene sequence 138
5.4 The pairwise genetic distance relationship between isolated strains and some reference strains based on fibronectin binding protein A 139
iv
LIST OF FIGURES FIGURE
NO. TITLE PAGE NO.
2.1 Anatomy of the Bovine Udder 09
4 .1 Pattern of resistance of Staphylococcus aureus against Antibiotics 111
4.2 Pattern of sensitivity of Staphylococcus aureus against Antibiotics 112
5.1 Agarose gel electrophoresis of coa gene PCR amplification products. 100 bp DNA ladder, lane 1-2: 540 bp, lane 3,6: 550 bp, lane 4-5,10: 525 bp, lane 7: 430 bp and lane 9: 840bp
128
5.2 Agarose gel electrophoresis of FnbA gene PCR amplification products. 100 bp plus DNA ladder, lane 1-10: 1150 bp. 129
5.3 Coa Phylogenetic tree (MEGA6.1, NJ method with 1000 bootstrap value) showing evolutionary relationship among all Pakistani strains 132
5.4
Phylogenetic tree (MEGA6.1, NJ method with 1000 bootstrap value), based on coagulase gene sequences, showing evolutionary relationship of Pakistani strains/isolates with selected reference strains from different geographical locations. Pakistani strains/isolates have been indicated by closed triangles
133
5.5 Fibronectin Binding Protein A, Phylogenetic tree (MEGA6.1, NJ method with 1000 bootstrap value) showing evolutionary relationship among all Pakistani strains
134
5.6
Phylogenetic tree (MEGA6.1, NJ method with 1000 bootstrap value), based on FnbA gene sequences, showing evolutionary relationship of Pakistani strains/isolates with selected reference strains from different geographical locations. Pakistani strains/isolates have been indicated by closed triangles
135
v
CHAPTER 1 INTRODUCTION
Pakistan is an agricultural country where livestock farming is its integral part and
considered to be the backbone of the rural economy. The livestock contribution in national GDP
is 11.8% while its share in agricultural value added stands at 55.9%. The agriculture sector involves
43.7% of the labour force in the country. As many as 8.4 million farming families are directly
engaged in livestock rearing nationwide that shows the critical dependence of nearly 40 million
rural people on the livestock sector for their livelihoods. Milk is by far single most commodity of
the livestock sector and the value of milk alone exceeds than the combined value of cash crops
such as wheat, rice, maize and sugarcane. Pakistan is third largest milk producing country in the
world with an annual production of 50.9 million tons. Milk production in Pakistan is mainly
dominated by 34.6 million buffaloes (Anonymous, 2014) having a share 75% of the total milk
produced in the country (Jamil et al. 2011; Hussain et al. 2012).
Dairy farming in Pakistan is primarily fragmented into traditional rural, progressive/semi-
commercial rural, peri-urban and commercial/corporate farming. However, the traditional rural
farming is the largest segment among all. The majority of dairy farmers are smallholders with
substantial number of landless farmers. The 61% of the farmers owned only 1-2 animals, 30% of
their owned 3-6 animals and the reaming 9% farmers have more than 6 animals herd size. A
number of notable livestock diseases, both infectious and non-infectious, are quite common in
Pakistan. These diseases are not only life threatening but also have substantial impact on the
production of dairy animals towards economic distress for the farmers. Among the infectious
diseases mastitis has been ranked on top for economic losses because of decreased milk production
1
INTRODUCTION
(Hussain et al. 2013; Farooq et al. 2008). It results not only in milk losses but also deteriorate its
quality.
Mastitis is a complex and multi factorial disease and prevalent around the globe in herds.
It is an inflammation of the parenchyma of the udder characterized by physical, chemical and
pathological changes in the milk and udder. Mastitis mostly occurs in two forms i.e. clinical and
subclinical. The clinical mastitis can easily be identified with abnormal milk, udder swelling and
disorder of the affected animal, while subclinical mastitis, mostly gone unnoticed by farmers
because of non-apparent milk changes (Radostits et al. 2000). For every case of clinical mastitis,
there are 20-40 times as many cases of subclinical mastitis and this subclinical mastitis causes
losses in the dairy industry (Erskine et al. 2002; Schultz et al. 1978).
Mastitis can be divided in the environmental and contagious form on the basis of its
etiological agents. The environmental mastitis is derived from the environment in which the animal
lives. Contagious mastitis can be transmitted from one buffalo to another during milking from
infected to healthy animal. The contagious pathogens are Streptococcus agalactiae,
Staphylococcus aureus and mycoplasma spp. Among the contagious mastitis pathogens,
Staphylococcus aureus is most frequently responsible for this disease. Staphylococcus aureus
produce toxins that destroy cell membranes and can directly damage milk producing tissue. The
leukocytes are attracted to the area of inflammation, where they attempt to fight the infection.
Initially, the bacteria damage the tissues lining the teats and gland cisterns within the quarter,
which eventually leads to formation of scar tissue. The bacteria then move up into the duct system
and establish deep-seated pockets of infection in the milk alveoli. This is followed by the formation
of abscesses that wall-off the bacteria to prevent spread but allow the bacteria to avoid detection
by the immune system. The abscesses prevent antibiotics from reaching the bacteria and are the
2
INTRODUCTION
primary reason (Petersson et al. 2010). S. aureus is modified to survive in the mammary gland and
usually causes a subclinical mastitis and can be shed in the milk, facilitating transmission to healthy
animals during the milking process (Radostits et al. 2007). The main reasons for the failure of any
of the antibiotic therapy in most cases of Staphylococcal mastitis are inadequate concentration of
antibiotics reaching at the site of infection, bacterial antibiotic resistance, L-forms of bacteria
(sensitive to beta-lactam antibiotics), bacterial dormancy and tissue barriers, as this organism lies
in deep seated foci. It causes pockets in the depth of udder surrounded by fibrous tissue where
antibiotics cannot gain access (Sandholm et al. 1991).
In principle, antibiotic sensitivity against the available chemotherapeutic agents in a region
or locality should be done from time to time to enable the veterinarians to prescribe the most
suitable antibiotics against the prevailing diseases.
The present study was planned with the following aims and objectives:
• To assess the prevalence of mastitis in buffaloes.
• To identify the epidemiological risk factors of mastitis.
• To assess the resistance of Staphylococcus aureus against commonly used
antibiotics.
• Molecular characterization of virulent gene of indigenous strains of Staphylococcus
aureus.
3
INTRODUCTION
REFERENCES
Anonymous. 2014. Agriculture Corner, Livestock. Pakistan Economic Survey. Government of
Pakistan, Finance division, Economic Advisor’s Wing Islamabad. 27-29.
Erskine R, Walker R, Bolin C, Bartlett P, White D. 2002. Trends in antibacterial susceptibility of
mastitis pathogens during a seven-year period. J Dairy Sci. 85: 1111-1118.
Farooq A, Inayat S, Akhtar M, Mushtaq M. 2008. Prevalence of mastitis and antibiotic sensitivity
of bacterial isolates recovered from Nili-Ravi buffaloes. J Anim Plan Sci. 18: 76-77.
Hussain R, Javed MT, Khan A, Mahmood F, Kausar R. 2012. Mastitis and associated histo-
pathological consequences in the context of udder morphology. Int J Agric Biol. 14: 947-
952.
Hussain R, Javed MT, Khan A, Muhammad G. 2013. Risk factors associated with subclinical
mastitis in water buffaloes in Pakistan. Trop anim health prod. 45(8): 1723-1729.
Jamil H, Samad H, Rehman N, Qureshi Z, Lodhi L. 2011. Effect of somatic cell types and culture
medium on in vitro maturation, fertilization and early development capability of buffalo
oocytes. Pak Vet J. 31: 105-108.
Petersson-Wolfe, CS, Mullarky IK, Jones GM. 2010. Staphylococcus aureus mastitis: cause,
detection, and control.
Radostits OM, Gay CC, Blood DC, Hincheliff KW. 2000. Mastitis In: Veterinary Medicine: A text
book of diseases of cattle, sheep, pig, goat and horses. Vol, Edition. W.B. Saunders,
London, 603-700.
Radostits OM, Gray CC, Hinchcliff KW, Constable PD. 2007. Mastitis. In: Veterinary Medicine.
A text book of the disease of Cattle, Horse, Sheep, Pigs and Goats.Vol, Edition. Sounder,
Spain, 673-749.
4
INTRODUCTION
Sandholm M, Louhi M, Espinasse. J. 1991. Bovine Mastitis: why does antibiotic therapy fail?
Mammites, desvaches, laitieres. 9: 88-106.
Schultz LH, Brown RW, Jesper DE, Berger MW, Natzke RP, Philpot WN, Smith JW, Thompson
PD. 1978. Current concept of bovine mastitis. 2nd ed. The Natl. Mastitis Council, Inc.
Washington D. C., USA. P. 6-9.
5
CHAPTER 2 REVIEW OF LITERATURE
2.1 Buffalo
In South Asia, the water buffalo is reared as a primary dairy animal. The water buffalo
(Bubalus bubalis) is also called as the ‘Black Gold’. Water buffalo plays a vital role in Asia and
Far-Eastern countries where 96.0% of its total population exists. At present, Pakistan has a buffalo
population of 34.6 million (Anonymous 2014). Buffalo is recognized as the world’s second most
important milk producing species. In buffalo milk production, it has been estimated that 95.0% of
world’s buffalo milk is produced in Asia (FAO, 2010). Pakistan is the fifth largest milk producer
in the world (FAO, 2010). In Pakistan, the increasing interest in buffalo breeding during recent
years owes to the increased demand of buffalo milk with more butterfat, protein and lactose, which
is essential for buffalo mozzarella cheese and makes it more valuable than bovine milk (Moroni et
al. 2006).
2.2 Mastitis
Mastitis is a complex and multifactorial disease and it is an important dairy health problem
with physical, chemical and pathological alterations in milk and udder. It is an inflammation of
the parenchyma of the udder and is characterized by physical, chemical and pathological changes
in the milk and udder. Udder inflammation may be caused by any injurious agent, including
physical trauma, chemical irritants, infectious agents and their toxins. Mastitis occurs worldwide
among dairy animals and it has an extreme zoonotic and economic impact (Radostits et al. 2007).
Mastitis mostly occurs in two forms i.e. clinical and subclinical. The clinical mastitis can
be easily identified with abnormal milk, udder swelling and the disorder of the affected animal
while in case of subclinical mastitis, there only increases in somatic cell count with no apparent
milk changes (Radostits et al. 2000). In subclinical mastitis, milk production may decrease and
6
REVIEW OF LITERATURE
bacteria are present in the milk. It has been reported from previous studies that annual losses due
to mastitis in dairy industry are approximately $2 billion and $526 million in the USA and India,
respectively (Varshney and Naresh 2004; Donovan et al. 2005). For every case of clinical mastitis,
there are 20-40 times as many cases of subclinical mastitis and this subclinical mastitis causes the
losses in the dairy industry (Erskine, 2002: Schultz et al. 1978). Mastitis can be divided in the
contagious and environmental form on the basis of its etiological agents. Among the etiological
agents, bacteria are the most common ones, the greatest share of which resides widely distributed
in the environment of dairy cows, and hence pose a common threat to the mammary glands
(Bradley, 2002). The cost of milk production increases due to the cost of treatment along with the
loss of milk due to reduced volumes and its poor quality (Radostits et al. 2007). Mastitis severely
affects milk quality and production of infected animals and has a tendency to spread rapidly within
the herds and to other animals. Compositional changes in the milk of infected animals with mastitis
depend upon the inflammatory response of mammary gland, extent and pathogenicity of infectious
agent along with amount of infected tissue, leakage of blood, various enzymes, proteins, salts,
decreased concentration of lactose and fat in milk (Osteras, 2000).
2.2.1 Anatomy of Udder
The glands and teats of domestic animals are collectively known as udder. A buffalo udder is
composed of two halves, each of which has two teats and each teat drains a separate gland (quarter).
The quarters are separated by connective tissue and each has a separate milk collecting system.
The two halves of the bovine udder are separated by the median suspensory ligament, which is
formed by two lamellae of elastic connective tissue originated from the abdominal tunic. The
posterior extremity of its ligament is attached to the prepubic tendon. The lateral suspensory
ligaments are composed largely of fibrous, non-elastic strands given rise to numerous lamellae that
7
REVIEW OF LITERATURE
penetrate the gland and become continuous with the interstitial tissue of the udder. The lateral
suspensory ligaments are attached to the prepubic and subpubic tendons, which in turn are attached
to the pelvic symphysis. The lateral and median suspensory ligaments are the primary structure
supporting the bovine udder. The bovine teat has a small cistern terminating at its distal extremity
in the streak canal, which is the opening to the exterior of the teat. Radiating downward from its
internal opening into the streak canal is a structure known as Furstenberg’s rosette, which is
composed of about seven or eight loose folds of double layered epithelium and underlying
connective tissue; each fold has a number of secondary folds. The primary structure responsible
for the retention of milk is a sphincter muscle surrounding the streak canal. Large ducts empty into
a gland cistern located above each teat. These ducts branch profusely, ultimately ending in
secretory units called alveoli. Alveoli are generally recognized as the basic functional units of the
lactating mammary gland (Husveth, 2011).
Milk is formed in the epithelial cells of the alveolus. The alveolus are approximately 100
to 300 µm in diameter. The size of the alveolus is affected by many factors, primarily the amount
of milk in the lumen. The alveoli are grouped together in units known as lobules, which are
surrounded by more extensive connective septa. The alveoli are surrounded by contractile
myoepithelial cells that are involved in the milk-ejection. Myoepithelial cells are also located along
the ducts (Husveth, 2011).
8
REVIEW OF LITERATURE
Figure: 2.1 Anatomy of the Bovine Udder.
9
REVIEW OF LITERATURE
2.3 Mastitis and its Pathogens
The major pathogens responsible for mastitis include Staphylococcus aureus,
Streptococcus uberis, Streptococcus agalactiae, Streptococcus dysgalactiae and Escherichia coli.
Staphylococcus aureus and Streptococcus agalactiae serve as contagious pathogens while
Escherichia coli, Streptococcus uberis, and Streptococcus dysgalactiaeact as environmental
pathogens (Waller et al. 2009). Among a very large number of pathogens causing mastitis in
buffalo and cow, Staphylococcus aureus and Streptococcus agalactiae are the most frequent
etiological agents and induce an extensive and wide variety of pathologies in lactating animals
(Marjan et al. 2009; Cheng et al. 2010). Intramammary infections with Staphylococcus aureus are
associated usually with increased somatic cell count. Staphylococcus aureus is contagious and
spreads easily within dairy herds (Barkema et al. 2006; Marjan et al. 2009). Prevalence of mastitis
pathogens varies from one dairy herd to other dairy herd, but bacterial pathogens are most
prominent and act as a first line of infection throughout the world (Bradley, 2002; Unnerstad et al.
2009). Mastitis causing bacteria are divided into two groups contagious and non-contagious, which
include gram positive bacteria, whose cell wall consists of peptidoglycan layers that withhold
crystal violet stain and gram negative that lack peptidoglycan layers and teichoic acid incorporated
within the peptidoglycan. The major gram positive bacteria include Staphylococcus aureus,
Streptococcus dysgalactiae, Streptococcus uberis and Streptococcus agalactiae (Piepers et al.
2009). In gram negative mastitis pathogens, Escherichia coli acts as the primary pathogen
(Unnerstad et al. 2009). Mastitis is mostly caused by a wide range of bacteria mainly
Staphylococcus aureus followed by Streptococcus agalactiae, Staphylococcus hyicus,
Staphylococcus epidermidis, Bacillus spp., Staphylococcus hominis, Escherichia coli,
Staphylococcus xylosus, Streptococcus dysgalactiae and Corynebacterial spp. (Ali et al. 2008;
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REVIEW OF LITERATURE
Unnerstad et al. 2009; Waller et al. 2009). In spite of growth inhibitory properties of keratin,
bacteria are able to survive in teat canal causing inflammation (Trinidad et al. 1990). Milk is sterile
and free from pathogens when it is secreted by the mammary gland and it is infected with different
micro-organisms when flows out of the udder. Generally, various pathogenic and non-pathogenic
microorganisms excluding mastitis dairy animals cause changes in color, taste, aromas of milk and
certain pathogens result in food borne diseases. Pathogenic organisms which are responsible for
the deterioration of milk and its product quality, mainly enter into milk through improper milking,
handling, storage and finally unhygienic conditions of workers.
Staphylococcus aureus produce toxins that destroy cell membranes and can directly
damage milk producing tissue. The leukocytes are attracted to the area of inflammation, where
they attempt to fight the infection. Initially, the bacteria damage the tissues lining the teats and
gland cisterns within the quarter, which eventually leads to formation of scar tissue. The bacteria
then move up into the duct system and establish deep-seated pockets of infection in the milk alveoli.
This is followed by the formation of abscesses that wall-off the bacteria to prevent spread but allow
the bacteria to avoid detection by the immune system. The abscesses prevent antibiotics from
reaching the bacteria and are the primary reason (Petersson et al. 2010).
2.4 Economic Importance and Characterization of Mastitis
In Pakistan, economic losses due to mastitis have serious concerns (Farooq et al. 2008).
The importance of domestic animals may be realized from the fact that the rural population is
generating, 30-40% of their income from livestock and almost 35-40 million populations are
involved in the livestock industry (Anonymous 2013). Various expenses like decreasing in milk
production, treatment cost, increased labor charges are compound conditions where culling
becomes necessary. The improved management practices can reduce the prevalence of mastitis.
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REVIEW OF LITERATURE
While investigating the total expenses that are involved in mastitis prevention and its treatment,
scientists have determined some strategies based on the direct impacts of disease. Miller et al.
(1993), determined cost of mastitis prevention was $14.50 per animal per year. Economic losses
due to mastitis may be divided into: 70.0% lower milk production, 8.0% discarded milk due to
veterinary medication, 8.0% treatment and veterinary charges and 14.0% premature culling
(Barkema et al. 2006; Halasa et al. 2007). Mastitis results in premature removal of herd, alters
reproduction, increases culling thus causing serious economic loss to farmers (Parker et al. 2008).
According to Wells et al. (1998), worldwide losses due to mastitis were estimated to be
approximately $35 billion annually. In the US, overall costs of mastitis were estimated to be $1.5–
2.0 billion per year, while losses from reduced milk production and higher replacement costs
associated with high somatic cell counts (SCC), due to subclinical mastitis were estimated at $960
million (Wells et al. 1998). In 2007, the USDA reported that mastitis was considered to be one of
the most costly diseases of the dairy industry (USDA, 2008). The average cost of generic clinical
mastitis (CM) per cow and year in high-yielding dairy cows, based on collecting data from 5 large
herds since 2004 to 2006 in New York State was $71, with an incidence of 39.7 CM cases per 100
cows per year and the average cost of a CM case was $179. This cost comprised of $115 due to
milk yield losses, $14 due to increased mortality, and $50 due to treatment-associated costs
(Barkema et al. 2006). In Africa, according to Mungube et al. (2005), production losses associated
with subclinical mastitis were estimated 5.6% of the Addis Ababa Milk Shed. Losses were highest
(9.3%) for urban dairy farms and small-scale farms (6.3%). The estimates of the financial losses
ranged from $29.1, for dairy herds in secondary towns, to $66.6 for urban dairy farms. A total loss
of $38 was estimated for each cow per lactation (Mungube et al. 2005).
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REVIEW OF LITERATURE
2.5 Prevalence of Mastitis
According to a study conducted by Ali (2009), the overall prevalence of subclinical mastitis
was 23.9%. Sharma et al. (2007) reported the overall prevalence of subclinical mastitis (SCM) by
quarter was 42.0% in Chhattisgarh State, India by the Modified California Mastitis Test (MCMT).
Elbers et al. (1998), conducted a study in Southern part of Netherland and reported the incidence
rate was 12.7 quarter/year per. Hameed et al. (2012) conducted a study in Burewala Pakistan, and
reported a total of 673 animals (n=291 cattle, n=382 buffaloes) from 300 livestock farmers and
tested using the Surf Filed Mastitis Test (SFMT) for the presence of mastitis. A prevalence of
clinical and subclinical mastitis was 24.6 and 36.4% in buffaloes, respectively, and subclinical
mastitis was more vital in varying from 10–50%, 5–20% in cow and buffaloes respectively than
clinical mastitis (Joshi and Gokhale 2006) in India. Anwar et al. (2013) reported that
Staphylococcus aureus prevalence was highest and the most frequently bacterial species such as
in Nili Ravi and Kundhi 40.4% and 34.9%, while in the study by Hussain et al. (2013) the
subclinical mastitis prevalence was recorded to be 15.2% in Lahore, Pakistan. According to
Megersa et al. (2010), subclinical mastitis and clinical mastitis were 11.2%, 4.3% respectively in
Southern Ethiopia, while mastitis overall prevalence was 15.5%. Busato et al. (2000) described
the quarter wise subclinical mastitis prevalence was 21.2% and overall prevalence of subclinical
mastitis (SCM) was 36.5% in Switzerland while Buchaya et al. (2005) the quarter wise overall
prevalence of mastitis as 58.7% and the animal wise was 78.0% in Bangladesh.
2.6 Quarter wise prevalence
According to Bansal et al. (1995), subclinical mastitis was present in 23.9% of buffaloes
and 11.3% of buffalo’s udder quarters while Prabhakar et al. 1995 stated that the overall monthly
incidence was 4.1 percent and Khan et al. (2004), by using the Surf field mastitis test, recorded
13
REVIEW OF LITERATURE
27.0, 4.0 and 10.0 % prevalence for subclinical mastitis, clinical mastitis and blind quarters,
respectively. Lalrinthuanga et al. (2003) revealed that 37.5% and 11.6% for mastitis by animal
and quarter, respectively while Ahmad et al. (1991) described the subclinical mastitis prevalence
was 7.0%. Physical examination of udders revealed (7.2%) blind teats. Islam, et al. (2011)
showed the overall clinical mastitis prevalence and subclinical mastitis as 4.5% and 37.2%,
respectively while another study by Islam et al. (2012) showed the overall prevalence of
subclinical mastitis (SCM) 29.0%. Zeryehun et al. (2013) revealed abnormalities of the udder as
evidence of mastitis 74.7% in cows and 9.6% clinical and 55.1% were subclinical mastitis while
the incidence of clinical mastitis was 22.8% (Peeler et al. 2000). Sargeant et al. (1998) mentioned
a prevalence of 19.8% of cows experiencing one or more cases of clinical mastitis during lactation
and the bacteria isolated was Staphylococcus aureus (6.7%). Oezencet al. (2008) investigated the
mastitis per quarter and animal 36.5%, 69.1%, respectively. Bachaya et al. (2011) investigated
Staphylococcus aureus was a predominant bacterial species recovered from mastitis and it shows
dominancy 48.6% and following bacterial species were isolated such as Staphylococcus aureus
(48.6%), Bacillus cereus (2.9%), Escherichia coli (10.0%), Micrococcus luteus (15.7%), Proteus
vulgaris (4.3%), Pseudomonas aeruginosa (1.4%), Streptococcus dysgalactiae (11.4%),
Streptococcus uberis (4.3%) and Citrobacter species (1.4%). Ali et al. (2011) stated the overall
prevalence of subclinical mastitis was 44.0% and it was the highest (58.0%) in dairy buffaloes.
The lowest prevalence was in organized farms with reasonable good management conditions
(32.0%). The overall prevalence of SCM was 36.5% of a CMT Test (Islam et al. 2012b). Khan
and Muhammad (2005) studied the overall subclinical mastitis prevalence 27.0%, clinical mastitis
4.0% and prevalence in buffaloes was 29.0%. Ahemd et al. (2012) studied the overall prevalence
of mastitis (clinical and subclinical) and found it in 60.3% buffaloes. The clinical mastitis
14
REVIEW OF LITERATURE
prevalence was higher in peri-urban 25.1% than rural 9.7% and incidence was highest during 4
to 6 months after calving both in peri-urban 45.8% and rural areas 45.1%. Mastitis was maximum
during third lactation both in peri-urban 19.0% and rural (23.0%) localities. In the folded thumb
milking method, prevalence was higher than suckling calves. Stage of lactation and lactation
number, source of milk let down, method of milking and floor condition have their effect on
mastitis (Bilal et al. 2004).
The clinical mastitis prevalence of individual quarter in buffaloes was 8.0%, while quarter-
based prevalence of subclinical mastitis was 16.0% in buffaloes (Hameed et al. 2012). The overall
quarter wise prevalence was 58.7% in buffaloes (Bachaya et al. 2005). According to Memon et
al. (2012), the prevalence of subclinical and clinical mastitis at quarters 20.2% and cow level 52.3%
was recorded, respectively. Occurrence of subclinical mastitis in the left rear quarter was high
26.7%, while Sharif et al. (2007) investigated that the overall quarter-wise prevalence was 37.7%
quarters and mastitic quarters maximum prevalence was found in right rear (30.4%) followed by
left front, right front and left rear with values of 24.5, 23.8 and 21.2%, respectively. Bilal et al.
(2004) observed the incidence of mastitis was higher in hindquarters 73.3 and 63.1% than in
forequarters 26.6 and 36.8% in peri-urban and rural areas, respectively while Sharma et al. (2007)
mentioned the overall quarter-wise prevalence of SCM was 39.0% by Modified Wide side Test,
42.0% of Modified California Mastitis Test and 45.0% of SCC, 1.9%. Oezenc et al. (2008)
investigated that mastitis was higher per quarter 36.5% and animal 69.1% while (Joshi and
Gokhale 2006) the prevalence was increased with lactation number and animals in 4th to 5th month
of lactation were more susceptible (59.5%) while hind quarters were more affected (56.5%) than
fore quarters (43.5%. The maximum quarter wise prevalence was in Nili Ravi and Kundhi 60.1%
and 77.3%, respectively, (Anwar et al. 2013). The incidence of mastitis in cows was higher in the
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hind quarters than in the forequarters (Prem and chand et al. 1995) as well as in buffaloes hind
quarters the incidence of mastitis was higher than fore quarter, similarly, left quarters prevalence
(44.0%) was higher than right quarters (33.3%) (Shukla et al. 1997) while mastitis prevalence
was highest in the left fore quarters (29.3%) then left hind (28.0%), right hind (22.0%) and the
right fore (20.7%) quarters. Due to the common practice of milkmen milking the prevalence was
higher (Ramachandraiah et al. (1998). Lalrintluanga et al. (2003) screened the lactating cows an
quarter infections was 63.44%, more frequently than any other combination of quarters and left
hind quarters (30.2%) were more frequent and single factor as compared to the other three quarters
same as Bilal et al. (2004) mastitis incidence was higher in hind quarters (73.3 and 63.1%) than
in forequarters (26.6 and 36.8%).
2.7 Animal related risk factor of mastitis:
2.7.1 Age
Rahman et al. (2009) identified the risk factors about dairy farms and management and age
and lactation wise distribution of mastitis cases varied in different age groups, being highest in 6-
8 years of age group (40.5%) while according to Bilal (1999) the relative risk of clinical mastitis
increased with the age and it was maximum in buffaloes 10-11 years as well as Ahmed et al. (2012)
significantly associated (p<0.05) of age with the prevalence of mastitis and the prevalence (33.4%)
of mastitis of 5–7 years of age were low, while the animals aged between 14 to 16 mastitis was
highest (80.0%). According to Waage at el. (1998), mastitis increased as age of animal increased.
Hameed et al. (2012) described that age is considered as a risk factor of mastitis as well as by
Zeryehun et al. (2013) age was also considered as major intrinsic risk factors that influenced the
prevalence of mastitis resembles with Rady and Sayed (2009) who investigated that age is an
intrinsic risk factor of mastitis. According to Sharma et al. (2007) the prevalence was highest at 3
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to 9 years of age. While Islam et al. (2012b) the prevalence of subclinical mastitis (SCM) was
significantly (p<0.01) higher (47.6%) in age group more than 13 years than others. Bilal (1999)
mentioned the relative risk for clinical mastitis increased with the age increase and it was
maximum in buffaloes 10-11 years while Lalrintluanga et al. (2003) screened the lactating cows
and higher number of cases were in 4-6 years age group (51.1%) while, Feroze (1992) noted that
age wise mastitis varied in different age group and mastitis was highest in 6-8 years age group
(40.5%).
2.7.2 Breed
The dairy buffalo breeds popular for milk production in Pakistan are Nili Ravi and Kundhi.
The breed characteristics of Nili Ravi buffaloes are as massive animals having curled horns with an
average weight 350-450 kg. The whole of the body skin is black in colour with five white marks on
the body (on forehead and all the four hooves). This striking feature of the breed is locally
pronounced as “Panj Kalyan” in native language. Males attain their maturity at the age of 30 months
and females at 36 months. The first calving has been recorded at 46 months of age with an average
milk yield of 1800-2500 liters per lactation with 6.5% butter fat. (Bilal et al. 2006; Shah et al. 1994).
Kundhi breed buffaloes are also massive animals having jet-black colour with an average
weight 300-400 kg. The have broader horns at the base and taper upward and inward, giving them
a fishhook shape. The average age of maturity of these animals is 30 months in males and 36
months in females. The milk yield per lactation is 1700-2200 liters with over 6.5% butter fat (Bilal
et al. 2006: Shah et al. 1994).
2.7.3 Parity
According to Ahmed et al. (2012) lactation number (parity) is significantly associated
(p<0.05) with the mastitis prevalence as well as Bilal et al. (2004) investigated that lactation
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number has a significant effect on mastitis and during third lactation both in peri-urban (19.0%)
and in rural areas (23.0%) maximum cases of mastitis were seen. Lactation number was
considered as an intrinsic risk factor of mastitis (Hameed et al. 2012) same as parity was
considered as major intrinsic risk factor of mastitis (Zeryehun et al. 2013). According to Busato et
al. (2000) quarter level 21.2% for lactation period 7–100 days and 34.5% for 101 to 305 days post-
partum subclinical mastitis prevalence was increased while Oezenc et al. (2008) studied that during
the first 4 months of lactation after the 5th lactation prevalence was higher. According to Prem and
chand et al. (1995), incidence of mastitis increased as the lactation number increased while
according to study in Nepal by Joshi and Shrestha (1995), the prevalence of bovine clinical mastitis
was the highest (17.6%) during first lactation, declining in successive lactations. Ramachandraiah
et al. (1998) investigated that the subclinical mastitis was increased with the increase in lactation
number same as during third lactation mastitis increased (Bilal et al. 2004). Similarly,
Thirunvukkarasu and Prabaharan (1998) concluded that, lactation number has significantly
associated with mastitis (P<0.05).
2.7.4 Stage of lactation
Stage of lactation was investigated by Ahmed et al. (2012) that has significant association
(p<0.05) with the prevalence of mastitis and it was associated with the prevalence highest (54.5%)
during the initial stage of lactation (0 to 1 month) than by last 2 months (10–12 months) as 54.17%
and mid-stages (1–3 and 3–10 months) of lactation as 28.6% and 37.5%. Hameed et al. (2012)
concluded that the stage of lactation is a significant risk factor of mastitis and Sharma, et al. (2007)
described that the stage of lactation has an influence on infection rate and it was higher during the
late lactation followed by early and mid-stage of lactation. According to Bilal et al. (2004) stage
of lactation is a physiological factor and it has its effect on clinical mastitis in buffalo same as
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Zadoks et al. (2001) lactation stage has a significant effect on mastitis and rate of S.
aureus infection. Megersa et al. (2010) investigated that late stage of lactation has an effect on
mastitis (OR = 4.3, 1.8, 10.4) of udder have a high risk than early lactation same as Kavitha et al.
(2009) who also reported that the first stage of lactation and the last part of dry period were more
prone to mastitis in buffaloes. Zeryehun et al. (2013) studied the prevalence of mastitis at the stage
of lactation was 87.2%, 65.9% and 73.1% in early, mid and late lactation, respectively, and this
variation was statistically significant (P<0.05) as Islam et al. (2012b) described the prevalence of
SCM was the highest in late lactation (72.4%) followed by early (40%) and mid lactation (27.6%).
Hussain et al. (2013) revealed the significant difference between lactation stage (P<0.001) same
as Lalrintluanga et al. (2003), who screened the lactating cows and incidence of mastitis was higher
in the early stage of third lactation (30.6%). Stage of lactation was found significantly associated
with mastitis (P<0.05) (Thirunvukkarasu and Prabaharan 1998). The mastitis cases were a higher
number (53.6%) during early stage of lactation than in middle and late stages and affected animals
showed a 20.6 % decrease in milk yield (Pyroala et al. 1991). Morin et al. (1998) examined the
cows for clinical parameters including various udder and milk characteristics, lactation number
and stage of lactation showed significant effect on clinical mastitis.
2.7.5 Udder and Teat injury
Hussain et al. (2013) revealed the significant difference between various groups, including
teat/udder pathology, teat (P<0.001) have a significant positive association with mastitis. Ahmed
et al. (2012) stated lesion on udder/teat were significantly associated (p<0.05) with mastitis.
According to Hameed et al. (2012), udder and teat injury is significant risk factors of mastitis same
as Biffa et al. (2005) revealed that the udder/teat injuries by ticks were the main risk factors of
mastitis while Zadoks et al. (2001) teat end callosity and infection with was not significant as risk
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factors. Udder abnormalities and milking hygiene have significant association with mastitis
(P<0.05) (Thirunvukkarasu and Prabaharan 1998) while according to the Oltenacu et al. (1990),
the incidence rates of trampled teats, udder injuries and clinical mastitis as well as the inter
relationship between the 4 disorders depend upon the stall length, manure system, type of bedding
and calving disorders and cows in herds with liquid manure system were at higher risk of udder
injuries and mastitis. Lower risk of both udder injuries and mastitis was found for cows in herds
with short stall size (180 cm) as compared to herds with large stall size (205- 219 cm) length.
2.7.6 Udder and Teat edema
In a case-control study by Waage et al. (1998), udder edema, teat edema and milk leakage
were the significant risk factors and teat edema at calving as risk factors for clinical mastitis caused
by Staphylococcus aureus. Hussain et al. (2012b) used the univariate and bivariate logistic
regression including teat shape and udder shape with the occurrence of mastitis and determined
the association of some morphometric characteristics of the udder with mastitis in dairy cattle same
as Hussain et al. (2013) revealed significant difference between various groups, including teat
shape, and udder shape (P<0.001). Shukla et al. (1997) investigated the relationship of teat type,
teat length and quarters effect on the mastitis and the teat tips were categorized into four types viz.,
funnel, round, flat and plate shaped. Mastitis prevalence was maximum in case of funnel shaped
teat tip.
2.8 Management, Housing and Environmental Risk Factors related to Mastitis
2.8.1 Management and Farm Hygienic
According to investigation by Fadlelmoula et al. (2007), the management and hygienic risk
factors of mastitis were associated with mastitis prevalence and the results show that the
probability of mastitis was higher, in tie-stall housed cows, and with the use of the pipe milking
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unit. In a Swedish study (Ekman et al. 2004), management practices like, use of wood shavings of
any kind reduced the risk of finding Staphylococcus aureus, but increased the probability of
Klebsiella spp., four times as compared to straw or peat. The correlation between sawdust and
acute cases of clinical mastitis caused by Klebsiella spp. was well known (Oz et al. 1985). Neaveet
al. (1969) evaluated the value of hygiene systems in the control of mastitis and how this control
can be improved by changes in hygiene and milking machines and by better use of therapy and
hygiene systems designed to prevent the transfer of pathogens and more particularly to eliminate
residual contamination at the completion of milking have been shown to reduce the number of new
infections. Furthermore, the combination of such hygiene systems with effective antibiotic therapy,
which reduces the duration of infection, generally resulted in a decrease of more than 50.0% in the
incidence of infection within a year. It is probable that further reduction in the incidence of
infection can be made by improving management techniques and it can be achieved by improving
methods of mechanical milking designed to prevent infection occurring during milking and by the
use of better teat dips than by the development of more comprehensive hygiene systems. Ahmed
et al. (2012) described the hygiene of milking process has significant association (p<0.05) with the
mastitis prevalence and it was concluded by Zaki et al. (2010) who described that both
environmental and hygienic measures surrounded the animals are major risk factors of mastitis.
Zeryehun et al. (2013) described the prevalence of mastitis in cows that were managed in poor
hygienic condition was 82.6%, while those managed in good hygienic condition showed an
infection rate of 59.6% and this prevalence were significantly different (P<0.05). Erskine et al.
(2002) performed milking hygiene and management practices of each herd and milking-machine
function was evaluated and it was concluded that management practices have a significant effect
on the control of mastitis.
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2.8.2 Condition of floor
Hameed et al. (2012) revealed that bricks floor, uneven floor, poor drainage system are risk
factors of mastitis while Bilal et al. (2004) investigated the management factors like method of
milking and floor condition have their effect on clinical mastitis in buffalo and bricks and cemented
floor were more mastitis as compare to Kacha floors. Hameed et al. (2012) analyzed that poor
drainage system and low frequency of dung removal are a risk factor of mastitis.
2.8.3 Teat Dipping
An investigation by Kavitha et al. (2009) depicted that teat dipping has a significant effect
on mastitis furthermore, farmers’ education regarding the risk factors and about teat dipping is
essential as Peeler et al. (2000) described the teat dipping can reduce 50.0% of mastitis occurrence.
According to Neave et al. (1969), improved methods of mechanical milking designed to prevent
infection occurring during milking and by the use of better teat dips than by the development of
more comprehensive hygiene systems. Teat dipping treatments reduced occurrence of mastitis
(Galton et al. 2004; Philpot and Pankey 1978). Mastitis control practices like post milking
antiseptic teat dipping, prompt detection and treatment of clinical cases and dry therapy can
reduced the mastitis (Oliver, 1975).
2.8.4 Milker hands
Larsen et al. (2000) investigated the transmission of infection for bovine mastitis by
milkers with Staphylococcus aureus and Ali (2009) considered hand milking as a source of risk
factor of mastitis used as a lubricant during milking and milker’s hands is often heavily soiled with
milk during this process while in developing countries like Pakistan dairy animals are mostly hand
milked used as a lubricant during milking and milker’s hands are often soiled with milk during
this process.. Gonzalez et al. (1990) investigated that the milkers are the reservoir of source of
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infection and its transmission to susceptible cows may be in direct contact with the milkers or by
mechanical transfer from cow to cow via the teat cups. Hand-milked dairy animals have higher
prevalence of mastitis than machine milked-animals (Lafi et al. 1994; Motie et al. 1985).
2.8.5 Methods for milk letdown
Mastitis prevalence was higher in animals milked with folded thumb pressure as compared
to milk let down through suckling calves (Bilal et al. 2004) as Hameed et al. (2012) mentioned
that hard milking, calf suckling, folded thumb milking techniques are risk factors of mastitis. In
Pakistan, Oxytocin injection is used commonly for the letdown of milk particularly in buffaloes.
At the time of milking by hand the calf is used in most of the animals. Newbould (1970)
recommended that the stimulus for these phenomena also affects the smooth muscles around the
proximal part of the teat duct near Furstenberg’ Rosette resulting in its dilation. Thus, instead of
keeping the duct closed, the smooth muscles around the duct under stimulation, open the proximal
end, and allow direct access for micro-organisms to the cistern. In theory at least, animals milked
by exogenous oxytocin are at a greater risk to develop mastitis than animals not receiving this milk
let down (Allen, 1990). On hand-milked animals, the technique of milking is also important in
relation to prevalence of mastitis and factors affecting the mastitis prevalence of clinical in
buffaloes by Bilal et al. (2004) encountered 4.2 magnitudes higher prevalence (39.2%) in buffaloes
milked by folded-thumb method (thumb-knuckle and finger method) than those milked by full-
hand method (9.0%). The relatively higher prevalence was ascribed to relatively larger herd size,
use of hired labor for milking (who cannot be desirably careful in milking) and more common
housing of animals on the brick floor. Kavitha et al. (2009) evaluated the milking method and the
incidence of clinical and subclinical mastitis was high when knuckling was practiced as compared
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to stripping with the full-hand milking. An association between risk factor and mastitis were higher
infection rates when dairy animals are milked by milking machine (Oezenc et al. (2008).
2.9 Some other Determinants Related to Mastitis
2.9.1 Foot and mouth Disease, Pox and Reproductive disorders
Diseases like foot and mouth disease and pox are particularly known to predispose mastitis
in cattle and buffaloes. According to a study in Pakistan by Muhammad et al. (1998), an
investigation of an outbreak of pox in 6 small holder dairy farm (buffalo = 185; cattle = 7) a
cumulative incidence rate of 55.3% was recorded over a one month period. Milk from nearly 47.0%
of the affected teats and 23.0% of the adjacent unaffected ones reacted positive to California
mastitis test (CMT). According to Radostits et al. (2000) observation, foot and mouth disease,
vesicles may appear on the teat as to the involvement of the teat orifice the severe mastitis. Cows
with the retained placenta were three times more likely to develop mastitis during hospitalization
than animals without retained placenta. Ali (2009) investigated on the outbreak of pox in 6 small
holder dairy farms and a cumulative incidence rate of 55.3% was recorded over a one month period
and milk from nearly 47.0% of the affected teats and 23.0% of the adjacent unaffected ones reacted
positive to California mastitis test. According to Bilal (1999) dairy buffaloes having retained
placenta, metritis, vaginal prolapses and dystocia at calving are risk factors of mastitis and by
Barker (1998) clinical mastitis during the first 45 days of lactation shows 2.7 times higher risk of
abortion. Esmat and Badr (1996) studied lactation failure and purulent uterine discharge (metritis)
in 127 dairy cows from 3 dairy farms in relation to mastitis. Eighty seven cows (68.5%) had acute
mastitis and 23 (18.1%) subclinical one and bacteriological examination of the udder and uterine
secretion of cows showed mastitis-metritis syndrome.
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2.9.2 Previous exposure to mastitis
Vaarst and Enevoldsen (1997) studied previous udder infections, which showed two-third
of the clinical mastitis cases, severe local inflammations were found in 21.0% of the cases and
some indications of generalized signs. Enevoldsea and Sorensen (1992) stated that previous
mastitis statuses are considered to be much more important predisposing factors as same as
Karimuribo et al. (2006) conducted a cross-sectional study and 4.0% of cows had clinical mastitis
during the previous year.
2.10 Diagnosis, Isolation and Identification of Staphylococcus aureus Mastitis
2.10.1 Mastitis diagnosis methods
Clinical and subclinical mastitis were diagnosed by using the California Mastitis Test
(CMT) and Surf Field Mastitis Test (SFMT) by Islam et al. (2009). According to Ali et al. (2008),
the diagnosis of subclinical mastitis was based on the results of the Surf Field Mastitis Test (SFMT).
Sharif et al. (2007) screened milk samples by SFMT for the presence of subclinical mastitis as well
as Sharif and Muhammad (2009) mentioned the most common mastitis pathogens are contagious
and environmental pathogens and most common causes of udder disease include Staphylococci
(Staphylococcus aureus & S. epidermidis). Soomro et al. (1997) used three chemical tests viz.,
Bromothymol blue test, chloride test and Whiteside test on milk for screening of subclinical
mastitis and revealed that 19.7%, 15.9% and 13.8% quarters were affected with subclinical mastitis.
Ali et al. (2011) identified the bacterial isolates of mastitis and found the highest prevalence was
of Staphylococci (28.3%). Chavoshi and Husaini (2012) determined the major causes of buffalo’s
subclinical mastitis are teat skin opportunistic bacteria.
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2.10.2 Physical examination of udder
Clinical and subclinical mastitis prevalence in buffalo in Hyderabad, Pakistan was
investigated by Soomro et al. (1997) and the physical examination of the udder of these animals
revealed 6.0% clinical (chronic) and 1.0% congenital abnormalities of udder while Milne et al.
(2003) correlated the clinical signs with the bacteriological findings and reduced milk yield,
swollen or hard udders, watery milk and being systemically sick. Falkenberg et al. (2004)
evaluated clinical examination and the appearance of teat lesions and the status of the teat duct
especially the existence of hyperceratosis were defined and prevalence of Staphylococcus aureus
mastitis was high. Klass et al. (2004) conducted a study to evaluate the disease characteristics of
Staphylococcus aureus mastitis in buffaloes and visual inspection and palpation of udder and teat.
Sargeant et al. (1998) described the abnormal milk with a hard or swollen udder and milk plus
systemic signs of illness related to mastitis.
2.10.3 Isolation of Staphylococcus aureus
Rahman and Rahman (1985) examined the milk samples derived from apparently healthy
udders in Bangladesh and 350 representatives isolates showed distribution to be 42.0%
Staphylococci, 12.6% Streptococci, 22.0% Coliforms, 20.0% Gram-positive aerobic sporeformers,
1.4% Pseudomonads and 2% Corynebacteria, while Smith (2000) isolated Staphylococcus aureus
13.3% from mastitis cases. In Istanbul, Firat and Uysal (1986) collected milk samples and
examined the nature of mastitogens and found that 34.0% were coagulase-positive Staphylococci,
16.0% coagulase-negative Staphylococci, 51 (13.0%) gram-negative bacteria, 28 Streptococcus
agalactiae, 27 Streptococcus uberis, 22 Streptococcus faecalis, and 21 Streptococcus dysgalactiae.
Trinidad et al. (1990) reported that most common bacterial pathogen were Staphylococcus aureus
as it was from isolated from teat canal (31.0%) and from quarters (12.3%). Prabhakar et al. (1995)
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described that Staphylococci were the major causative organisms (34.2% Staphylococcus aureus
and 13.2% coagulase-negative Staphylococci), followed by Str. agalactiae (14.7%), E. coli
(10.5%), Pseudomonas spp (7.9%), Str. pyogenes (3.9%), Klebsiella spp. (3.9%), Str. dysgalactiae
(2.6%), Proteus spp. (2.6%), Str. uberis, Diptheroids and mixed infections (1.3% each). No
organism could be isolated from 2.6% quarters. Gonalez et al. (1990) isolated Staphylococcus
aureus (43.0% of samples) S. epidermidis (21.0%), Str. Uberis (19.0%), Str. Agalactiae (13.0%),
Str. Dysgalactiae (9.0%), Corynebacterium pyogenes (1.3%), Corynebacterium bovis (7.0%) and
coliform (1.7%) from subclinical cases of mastitis in cows. Rady and Sayed (2009) recovered
Staphylococcus aureus from milk samples and prevalence was 52.5%. Hameed et al. (2008) also
reported that prevalence of Staphylococcus aureus was the highest 53.9% by a study conducted on
lactating buffaloes in Pakistan. According to investigation of Hussain et al. (2012a), the disease
characteristics of Staphylococcus aureus mastitis in buffaloes and isolates of Staphylococcus
aureus were obtained on the basis of growth on a Staph-110 medium, colony morphology and
hemolytic pattern on 5% sheep blood agar plates and isolates were identified by slide coagulase
test, tube coagulase test and Staphytect plus test. Ali et al. (2008) recovered the isolates of
Staphylococcus aureus and it was the most frequently bacterial species accounting for 49.5% of
all the isolates while Ericsson et al. (2009) the most frequently isolated bacterial species
were Staphylococcus aureus constituting 21.3% of the diagnoses.
2.11 Antibiotic Resistance Profiles of Staphylococcus aureus strains isolated from Mastitis:
The antibiotic resistance of Staphylococcus aureus strains isolated from mastitic milk is
well known around the globe. It may vary from country to country and depends on various factors.
Some of the resistant reports are as under. In Argentina, the antibiotic resistance of Staphylococcus
aureus was reported as 40.3%, 11.6% and 3.4% to penicillin, erythromycin and gentamycin,
respectively Gentilini et al. (2000). In India, Sharma et al. (2007) also reported the resistance
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against ampicillin most. Sharma et al. (2007) revealed the antimicrobial susceptibility test for the
bacterial strains isolated from subclinical mastitis milk samples were sensitive to oxytetracycline
17.4% and resistant to streptomycin. In Brazil, Pianta and Fallavena (1980) observed 40.0%
resistance of S. aureus against oxytetracycline. A study was conducted in China (Sun et al.
(2013) and reported Staphylococcus aureus resistant to gentamycin, tetracycline and erythromycin.
2.12 Emergence of Antimicrobial Resistance
There are several factors responsible for the emergence of antimicrobial resistance. Some
of these include misuse of antibiotics, lack of access to appropriate treatment and failure to
complete treatment courses etc. In Staphylococci the resistance to multiple antimicrobial agents is
driven by the acquisition of distinct hereditary elements comprising plasmids, transposable genetic
elements and genomic islands. These elements incorporate resistance genes and are exchanged via
horizontal gene transfer between interrelated bacterial strains and even between different species
and genera (Chambers, 2001; Schito, 2006).
2.13 Staphylococcus aureus Genome
The Staphylococcus aureus genome consists of a single circular chromosome of about 2.7
to 2.9 Mbp containing about 2600 genes composed of core and auxiliary (accessory) genes. It has
a G+C content of 33.0%. In silico analysis, core genome makes up about 75.0% of the
Staphylococcus aureus genome and it is highly conserved between isolates. These genes are
associated with common species functions and are not essential for growth and survival, including
virulence genes. It included, binding proteins, exoenzymes, toxins, and capsule biosynthetic
cluster (Lindsay and Holden, 2004). The accessory genome accounts for about 25.0% of any
Staphylococcus aureus genome, and mostly consist of mobile genetic elements that transfer
horizontally between strains. These elements include bacteriophages, pathogenicity islands,
chromosomal cassettes, genomic islands, plasmids and transposons. Accessory genes typically
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have a different G + C content than those in the core genome, often because they are obtained from
other species of bacteria. Many of these genetic elements are known to carry genes associated with
virulence, drug and metal resistance, with substrate utilization and miscellaneous metabolism.
Therefore, the distribution and horizontal spread of these elements can have important clinical
implications. The identification and characterization of these elements provide insights into how
Staphylococcus aureus causes disease, and their diversity (Shittu et al. 2007). Bacteria obtain
genetic information from other cells or the surrounding environment in three ways: (1) uptake of
free DNA from the environment (transformation), (2) bacteriophage transduction, and (3) direct
contact between bacterial cells (conjugation). Bacteriophages or bacterial viruses seem to have the
greatest impact on staphylococcal diversity and evolution. They are known to transfer genes such
as lukF-PV and lukS-PV that encode the Panton- Valentine leukocidin (PVL) components which
is strongly associated with severe forms of pneumonia (necrotic pneumonia) in human caused by
community-acquired S. aureus strains; the staphylokinase gene (sak) gene, which is a potent
plasminogen activator that could facilitate bacterial spreading through its fibrin-specific blood
clotting activities and the enterotoxin genes (Shittu et al. 2007; Malachowa and DeLeo, 2010). S.
aureus pathogenicity islands (SaPIs) often carry super antigen genes, such as toxic shock
syndrome (tst) and enterotoxins B and C, implicated in toxic shock and food poisoning. Three
families of genomic islands have been discovered in sequenced strains of Staphylococcus aureus
strains. They carry exotoxin and lipoprotein genes (Shittu et al. 2007). All the sequenced
Staphylococcus aureus strains are known to carry one or more free or integrated plasmids. All
types of Staphylococcus aureus plasmids frequently carry antibiotic resistance genes, or resistance
to heavy metals or antiseptics. Some virulence genes are also known to be carried on plasmids,
such as exfoliative toxin B and some super antigens (Lindsay and Holden, 2004). Other mobile
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genetic elements found in the Staphylococcus aureus chromosome include Staphylococcal cassette
chromosomes (SCCs). They encode antibiotic resistance and/or virulence determinants. SCCs
encode the methicillin resistance gene (mecA) (Shittu et al. 2007; Malachowa and DeLeo, 2010).
2.14 Molecular optimization of Coagulase and Fibronectin binding protein A of
Staphylococcus aureus
New molecular techniques have emerged which are very helpful for detection,
identification and characterization of milk borne pathogens, e.g. PCR, RT-PCR, Microarray,
Multilocus Typing which are rapid, sensitive and specific and give a better differentiation among
species, serotypes or strains. Various molecular techniques have been used for identification of
Staphylococcus aureus. Among them, Polymerase Chain Reaction (PCR) is most currently used
for identification of Staphylococcus aureus. With the help of PCR, we will be able to detect a
single genome of Staphylococcus aureus with accuracy and sensitivity. Many infectious agents
that are missed by microbiological, serological tests and DNA probe are detected by PCR.
Therefore, now-a-days PCR based tests are mostly used for the clinical and epidemiological
investigation of pathogenic bacteria (Ahmadi et al. 2010; Firyal et al. 2009; Kalorey et al. 2007).
According to Sun et al. 2013, in china Staphylococcus isolates were electrophoresis (PFGE)
analysis, spa typing and minimal inhibitory concentration determination while Kumar et al. (2011)
studied in India that the Staphylococcus aureus recovered from the buffaloes distribution of
virulent genes such as Coagulase and Fibronectin binding protein A and genetic form of
Staphylococcus aureus isolates were further used for segregation or culling of infected animals
from harmful strains to reduce the dissemination of pathogenic microorganisms.
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2.15 Staphylococcus aureus Virulence Determinants
Exoproteins of Staphylococcus aureus contribute to its facility to colonize and cause
disease in hosts. These virulent factors cause colonization through the damaged mucosa and skin,
propagation to the body, and evasion of host defense mechanisms. Approximately, 50 potential
virulence factors in S. aureus with a wide range of biologic activities have been reported.
Staphylococcal infections occur in a stepwise manner, each step involving one or several specific
virulence factors (Ferry et al. 2005). Nearly all strains secrete a group of enzymes and cytotoxins
include four hemolysins (alpha, beta, gamma, and delta), nucleases, proteases, lipases,
hyaluronidase, and collagenase. The main function of these proteins may be to convert local host
tissues into nutrients required for bacterial growth. Each of these toxins is known to have potent
effects on cells of the immune system, but many of them have other biological effects as well.
Their primary function in vivo may be to inhibit host immune responses to Staphylococcus aureus
(Dinges et al. 2000). The orchestrated expression of multiple virulence factors is the key to the
success of staphylococcal pathogenesis. Staphylococcus virulence factors are located either on the
chromosome or on mobile elements such as plasmids, transposons and bacteriophages. Acquisition
of genes mediating antibiotic resistance, such as the mecA gene conferring resistance to methicillin,
can further favor epidemic spread by promoting the acquisition of additional virulence factors.
Expression of most virulence factors in Staphylococcus aureus is controlled by the accessory gene
regulator (agr) locus, which encodes a two-component signaling pathway whose activating ligand
is a bacterial-density sensing peptide (auto inducing peptide) also encoded by agr (Lina et al. 2003).
A polymorphism in the amino acid sequence of the auto inducing peptide and of its corresponding
receptor (AgrC) has been described. Staphylococcus aureus strains can be divided into four major
groups on this basis: within a given group, each strain produces a peptide that can activate the agr
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response in the other member strains, whereas the auto inducing peptides produced by the different
groups are usually mutually inhibitory (Ji et al. 1997). Links between a peculiar agr type and a
specific staphylococcal syndrome have been shown for toxic shock syndrome (TSS) and
staphylococcal scalded skin syndrome (SSSS). TSST-1- producing isolates belong to agr
specificity group III and mostly belong to a single clone, as shown by multilocus enzyme
electrophoresis (MLEE) (Musser et al. 1990; Ji et al. 1997). Most exfoliating-producing strains
responsible for SSSS belong to agr group IV, but these strains have not been investigated (Jarraud
et al. 2002). Staphylococcus aureus virulence factors include surface proteins that promote
colonization of host tissues, invasion factors that promote bacterial spread in tissues (leukocidin,
hyaluronidase), surface factors that inhibit phagocytic engulfment (capsule), biochemical
properties that enhance their survival in phagocytes (catalase production), and membrane
damaging toxins that lyse eukaryotic cell membranes (hemolysins, leukotoxin) (Turkyilmaz and
Kaya, 2006).
2.16 Transmission of Staphylococcus aureus
Staphylococcus aureus is transmitted from an infected to an uninfected mammary gland
during the milking process. Shared equipment, udder cloths, and even milkers’ hands can transmit
Staphylococcus aureus between cows, if good hygienic practices are not followed. Environmental
factors, such as bedding, housing, and foodstuffs can also be contaminated and play a role in
spreading Staphylococcus aureus infections. Thorne et al. (1960) isolated Staphylococcus aureus
from the floor of dairy barns. Also, Spencer et al. (1952) were able to maintain Staphylococcus
aureus in vitro on sterile straw for at least 49 days, which raises the possibility that bedding may
be a source of the organisms. However, in low Staphylococcus aureus prevalence herds, 0 of 183
bedding samples were positive for S. aureus, and 4 of 208 bedding samples from high
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Staphylococcus aureus prevalence herds were positive for Staphylococcus aureus (Roberson et al.
1994). These findings suggest that bedding may play a limited role in spreading infection
(Roberson et al. 1999). To cause mastitis, Staphylococcus aureus must enter the mammary gland
through the teat sphincter. Contaminated wash cloths or milking equipment may bring the bacteria
to the teat canal. After bacteria gain access to teat ducts and grows in milk producing tissue,
mastitis occurs. After Staphylococcus aureus enters the teat canal, neutrophils respond to the
infection. If the leukocytes succeed, there will only be mild signs. If Staphylococcus aureus growth
continues and leukocytes are not able to prevent bacterial growth, swelling of the mammary gland
and changes in the milk will occur resulting in clinical mastitis. Infections caused by
Staphylococcus aureus strains that produce α-toxin can cause gangrenous mastitis, which can lead
to death due to toxemia or culling of the infected cow. In addition to the mammary glands,
Staphylococcus aureus has been found on other body sites of animals and humans. Haveri et al.
(2008) reported that the Staphylococcus aureus strains causing bovine intramammary infection
(IMI) were not different from those isolated from extra mammary sites. Teat skin and especially
teat canals were important potential reservoirs of Staphylococcus aureus causing IMI. Heifers that
had Staphylococcus aureus on their skin were at a higher risk to develop Staphylococcus aureus
mastitis than heifers without skin colonization (Sears et al., 2003). Roberson et al. (1994) reported
that milk from heifers that have Staphylococcus aureus on their teat skin could be another source
of S. aureus. Although some authors (Haveri et al. 2008; Thorne et al. 1960) have reported that
Staphylococcus aureus on the udder skin were genetically similar to Staphylococcus aureus
isolates from milk samples, it has also been reported that teat skin is not an important reservoir for
Staphylococcus aureus mastitis because less than 4% of cows had the same type of Staphylococcus
aureus on teat skin as the type that causes Staphylococcus aureus mastitis (Fox et al. 1992).
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2.17 Control of Staphylococcus aureus
Correct milking procedures play a significant role in reducing new intramammary
infections. Washing the udder with water or sanitizing solution and drying with individual towels,
preferably disposable towels are recommended for preventing the spread of infection among dairy
animals (National Mastitis Council, 2003; Sears et al. 2003). To prevent spread, milkers should
wear disposable gloves and sanitize the equipment for each use (Roberson et al. 1999). Germicidal
teat dip after each milking is an effective method in preventing spread of infection from cow to
cow (National Mastitis Council, 2003). Both pre and post milking teat disinfection have significant
impacts on reducing new infections by Staphylococcus aureus and Streptococci (Vestweber et al.
1994). Quarters which were dipped before and after milking showed a lower rate of new infections
than quarters, which were dipped only post-milking (Vestweber et al. 1994). Back flushing, which
is an automated way of washing milking clusters with water and rinsing them with disinfectant
after the removal of milking uniform teats, may also decrease the spread of infection. However,
back flushing may be less beneficial in herds that follow effective post milking teat dipping.
Intramammary dry cow antibiotic therapy is one component of mastitis control programs. One of
the goals of dry cow therapy is to prevent new mastitis infections from occurring during the dry
period, as cows are susceptible to infection during this time and it may also cure existing infections.
Intramammary antibiotic dry cow therapy cure rates are higher than those achieved during lactation
because udders have less volume and antibiotic is present for a greater length of time. In some
countries, including the USA, it is recommended that all quarters should be routinely treated at
drying off (Robert et al. 2006), while other countries, such as Finland, Norway, and Switzerland
typically use selective treatment based on identification of udder infection (Pitkala et al. 2004;
Osteras et al. 2006). Cows with Staphylococcus aureus should be segregated and milked last to
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prevent uninfected cows from getting infected (Vestweber et al. 1994; Roberson et al. 1994).
Culling is considered the most effective way to lower the prevalence of Staphylococcus aureus in
dairy herds (Radostits et al. 2000). Staphylococcus aureus may reside inside the udder and on teat
skin, and they provide the most important source of infection to other cows in the herd. With the
limited success of dry cow treatment of chronic infections, culling is the most reliable way to
remove the organism and reduce exposure to other cows and heifers. However, culling is primarily
recommended for chronically infected cases.
2.18. Statement of Problem
Mastitis is a complex and multi factorial disease and it is an important dairy health problem
with physical, chemical and pathological alterations in milk and udder. Mastitis mostly occurs in
two forms i.e. clinical and subclinical. Mastitis can be divided in the contagious and environmental
form on the basis of its etiological agents. Various microorganisms are responsible for mastitis,
including bacteria, Mycoplasma, yeast and fungi etc. Among all, bacteria are most frequently
responsible for this disease. Staphylococcus aureus is held accountable for 50.0% of cases of
mastitis in buffaloes (Shakoor, 2006). The main reasons for the failure of any of the antibiotic
therapy in most cases of Staphylococcus aureus mastitis are inadequate concentration of
antibiotics reaching at the site of infection, bacterial antibiotic resistance, L-forms of bacteria
(sensitive to beta-lactic antibiotics), bacterial dormancy and tissue barrier as this organism lies in
deep seated foci. It causes pockets in the depth of udder surrounded by fibrous tissue where
antibiotics cannot gain access (Sandholm et al. 1991). In principle, antibiotic sensitivity against
the available chemotherapeutic agents in a region or locality should be done from time to time to
enable the veterinarians to prescribe the most suitable antibiotics against the prevailing diseases.
In Pakistan mastitis losses might be higher, because prevention practices of mastitis are not
35
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adopted by dairy farmers. The present study was planned with the following aims and objectives:
Assess the prevalence of mastitis in buffaloes and identify the epidemiological risk factors of
mastitis. To assess the resistance of Staphylococcus aureus against commonly used antibiotics.
Molecular characterization of virulent gene of indigenous strains of Staphylococcus aureus.
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RISK FACTORS ASSOCIATED WITH MASTITIS IN DAIRY BUFFALOES
ABSTRACT
The cross sectional study was carried out between January to December 2012 to investigate the
prevalence of mastitis in dairy buffaloes and risk factors. Total sample size for this survey consists
of 1,036 lactating buffaloes. The farms were categorized as small scale 5-10, medium scale 11-30
and large scale having more than 30 dairy animals. The overall prevalence of mastitis was recorded
as 49%. Among mastitis cases the prevalence of clinical mastitis was 10.2% as a whole. The
overall prevalence of subclinical mastitis was 38.8% as diagnosed with a California mastitis test.
In a univariable analysis: area, herd size, age, breed, parity, stage of lactation, reproductive
disorders, udder shape, previous exposure to mastitis, ease of milking, udder edema, lesion on
udder/teat, swelling on udder/teat, condition of floor, frequency of dung removal, exposure to
FMD, udder wash, teat dipping, milking techniques and tick infestation were significantly
associated (𝑃𝑃< 0.25) with a prevalence of mastitis. These 20 significant variables were further
selected for multivariable analysis to estimate the independence of the effect of the variables. The
final model identified area, age, breed, parity, stage of lactation, udder shape, ease of milking,
previous exposure to mastitis, udder edema, lesion on udder/teat, exposure to FMD, teat dipping
and tick infestation were significantly associated with the prevalence of mastitis in buffaloes (p<
0.05). Mastitis can be minimized by improving management and animal related potential risk
factors.
Keywords: Mastitis, Buffaloes, Prevalence, Risk factors, Age, Breed, Parity
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INTRODUCTION
Milk produced from dairy animals provides an important dietary source of rural as well as
urban population. However, milk production often does not fulfil the country’s requirements due
to various factors. Mastitis is reported to be one of the common problem of dairy industry all over
the world. The economic losses due to mastitis occur because discarded milk, reduction in the
quality of milk and the cost of treatment (Radostits et al. 2007; Fekadu, 1995). In Pakistan mastitis
has also been reported as top ranking disease responsible for economic losses (Hussain et al. 2005).
It has been reported that annual losses due to mastitis in USA are approximately $2 billion while
in India $526 million (Donovan et al. 2005; Varshney and Naresh 2004). Mastitis can affect any
herd at any time, therefore all herds are potentially susceptible.
Mastitis can be caused by a number of pathogens. Broadly mastitis can be defined as two
categories i.e contagious and environmental. The contagious mastitis is caused by S. aureus, Str.
agalactiae, etc. It can spread from the infected quarters to other quarters or animals during milking
(milker hands or machines). The environmental mastitis can be caused by many other organisms
such as Str. uberis, Str. dysgalactiae, coliforms, etc. which are commonly present in the
environment (bedding, flooring, droppings). It can infect the glands between milking as well as
during the dry period (Radostits et al. 2007). Mastitis is a multifactorial disease, closely related to
the production system and environment in which the dairy animals are kept (Mekibib et al. 2010).
That’s why monitoring udder health performance is impossible without reliable and affordable
diagnostic methods (Zadoks and Schukken, 2006). Furthermore, it can be divided into two group
clinical, subclinical mastitis. Mustafa (2003) reported that only a small proportion of udder
infection results in "clinical mastitis" whereby there are changes in udder condition and milk
quality. The vast majority of cases exists as subclinical; with estimated 20-40 cases for every
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clinical mastitis case within the herd. Therefore mastitis problems may be present within a herd
despite no visible presence within the animal or the milk. Subclinical mastitis is responsible for
the greatest financial losses associated with mastitis. It is estimated to cause 70% of the total losses.
These losses however, are difficult to demonstrate producers since they are associated with
decreased milk production caused by the effects of chronic inflammation of the mammary gland.
Bovine mastitis can be caused by physical or chemical agents but the majority of cases are
infectious and usually caused by bacteria. The disease has been reported by several authors on the
prevalence and mastitis in different parts of the world (Biffa et al. 2005; Hussain et al. 2013;
Chishty et al. 2007). Several of these studies have shown mastitis is caused by a range of bacteria
and Staphylococcus aureus is major pathogenic. Moreover, there are no proper control measures
in order to contain the disease because of its multifactorial nature. Milk contaminated from
affected dairy animals with bacteria may render it inappropriate for human consumption. Zoonotic
diseases potentially transmitted by raw milk include brucellosis, caseous lymphadenitis,
leptospirosis, listeriosis, melioidosis, Q-fever, staphylococcal food poisoning, toxoplasmosis and
tuberculosis (Mungube et al. 2005; Radostits et al. 2007). These conditions are associated with
public health risks brought about by contaminated raw milk and antibiotic residues as a
consequence of drug therapy (Andrew et al. 2009).
Mastitis in dairy herds occurs as a complex interaction between the host, the environment
and agent. The most common risk factors for mastitis in dairy herds can be divided in two groups:
animal related risk factors and environmental and management risk factors. Animal related risk
factors include: breed, age, parity/lactation number, stage of lactation, lesions on udder/teat,
swelling on udder/teat, udder shape Teat shape, udder edema, treat edema, and ease of milking.
Management, environmental and housing related risk factors included: stimulus for milk letdown,
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number of animals milked by the same milker, udder washing, milking technique, dairy husbandry
system, condition of floor, tick infestation, the source of drinking water, frequency of dung
removal per day, farm hygiene and husbandry practices. Other risk factors associated with mastitis
included: previous exposure to mastitis, reproductive disorders, History of exposure to foot and
mouth disease and pox lesions on udder and teat (Nigo et al. 2013; Sarker et al. 2013; Elbaby et
al. 2013). Many studies report risk factors for mastitis are associated with farm management,
hygiene management, the breeding environment, milking technology, feeding, the calving, season
and preventive health management (Bludau et al. 2014). In an individual herd, animal related
factors are breed, parity, period of lactation, udder and teat morphology, age at calving, milk
leakage, udder edema, milk production, number of milk somatic cells and reproductive disorders
(Nyman et al. 2007). Moreover, the stage of lactation, lactation number, trauma to udder, teat and
teat canal, loose teat sphincters, lesions on teat skin, immunological status of each mammary gland,
bulk of infection in the environment and managemental conditions are amongst the determinants
which dictate the level of mastitis incidence (Radostits et al. 2007).
In developing countries like Pakistan owing to small herd sizes, dairy animals are mostly
hand milked. Mastitis in hand milked animals were nearly twice as frequent as in machine-milked
ones (25.1 VS 14.6%) Motie et al. (1985). Infectious agents of mastitis may be transmitted from
infected to healthy animals through the milker's hand (Oliver, 1975) especially because milk is
often used as a lubricant for milking. The infection originates either from the infected udder or the
contaminated environments and the major sources of pathogens and means of transmission include
infected quarters and soiled udder, contaminated milking machines, teat cups, milker’s hands,
washing clothes, flies and surgical instruments. Several studies have investigated various risk
factors for mastitis (Barnouin et al. 2005; O’Reilly et al. 2006). The results of these studies differ,
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but some risk factors are in concordance. However, these studies were conducted in different
countries under varying conditions, which may explain different results, and no specific studies on
risk factors for mastitis have been performed under the climatic, housing and dairy breed
conditions.
Mastitis prevalence was found to be significantly influenced by stage of lactation, parity,
breed, milk yield, anatomical abnormality of the udder, and some management aspects including
nutrition (Almaw et al. 2008). There are numerous risk factors identified by many researchers that
influence the occurrence of mastitis such as age, parity, lactation stage, milk yield, breed, previous
mastitis record, floor type, disinfection of fingers and teat dipping, etc. (Karimuribo et al. 2006;
Madut et al. 2009). There are some reports on the magnitude of the disease, but information
relating to its risk factors is insufficient (Kahir et al. 2008). Such information is important to
envisage when designing appropriate strategies that would help to reduce its prevalence and effects.
However, virtually all of the published information about the risk factors for mastitis refers to dairy
breeds of cattle, and little information available for water buffaloes. Though a high probability
exists that these identified risk factors may also be observed among these species, the degree of
influence by these factors is still unknown.
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MATERIALS AND METHODS
Study Area
The present study was conducted in two districts Lahore and Bhimber of Pakistan. Lahore
is a capital of Punjab province and it lies between longitudes 74° 20' 37 east and latitude 31° 32'
59 north and the altitude is 209 meters above the sea level. The Lahore features hot, semi-arid
climate with an average of temperature 1100F in summer and 350F in winter and average annual
rainfall is from 470.1 to 738 millimeters. While, Bhimber is a district of Azad Kashmir and lies
74° 4' 0 east and latitude 32° 58' 60 north and average altitude is 314 meters from sea level.
Bhimber is semi-hilly and mountainous area with some stretches of plains. The weather of
Bhimber is an arid climate with average temperature 1020F in summer and 22 0F in winter. It has
a very diverse climate; ranging from sub-humid subtropical, to moist temperate, dry cold temperate,
very cold temperate. The mean annual rainfall varies from 800 to 1100 millimeters. Buffalo
population in Lahore and Bhimber was 403128 and 147539, respectively (Anonymous, 2006).
Study Population and Design
The present cross sectional study was carried out between January to December 2012 to
investigate the mastitis prevalence in dairy buffaloes and epidemiological investigation of risk
factors. The study area was consist of two district i,e Lahore and Bhimber. The total buffalo
population in Pakistan is 34.6 million Buffalo. There is no registration of dairy farmers to kept
small dairy herds at their premises. Unfortunately, list of herds was not available due to this reason
convenience sampling was adopted. From the study area the population of district Lahore was
higher as compared to district Bhimber. But due to limited sources total 50 dairy herds from two
district, 25 from each were selected. The total sample size for this study was consisted of 1,036
lactating buffaloes.
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Inclusion and exclusion criteria
All the lactating buffaloes were included. Dry buffaloes and heifers were excluded from
the study.
Questionnaire and data collection
The questionnaire was designed with the guideline of Nigo et al. (2013), Ali (2009), Biffa
et al. (2005), Sarker et al. (2013), Mustafa et al. (2013), Elbaby et al. (2013) and Kiveria et al.
(2006). A questionnaire was designed for collection of data farm demography, climate and
management practices. It was having some dichotomous, polychotomous questions and farmer’s
interviewing and farm records were used for collection of data. The related data were obtained
from farm owners’ interviews and farm records. All the risk factors were arranged into categories
in three groups, i.e. Animal related risk factors, management (environmental and housing) related
risk factors and others associated risk factors of mastitis. Animal related risk factors include: breed,
age, parity/lactation number, stage of lactation, lesion on udder/teat, swelling on udder/teat, udder
shape Teat shape, udder edema, treat edema, and ease of milking. Management, environmental
and housing related risk factors included: stimulus for milk letdown, number of animals milked by
the same milker, udder washing, milking technique, condition of floor, tick infestation, the source
of drinking water, frequency of dung removal per day. Other risk factors associated with mastitis
included: previous exposure to mastitis, reproductive disorders, history of exposure to foot and
mouth disease and pox lesions on udder and teat.
Physical Examination of the Udder and Teat in Clinical Mastitis
In case of clinical mastitis udder and teats were examined visually and thoroughly palpated
for detecting any possible fibrosis, visible injury, cardinal signs, tick infestation and viscosity. The
size and consistency of the udder and quarters were inspected for the presence of any anatomical
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malformation, such as disproportional symmetry, swelling, firmness and blindness. Information
regarding previous history of mastitis and quarters effected were obtained and recorded on the
questionnaire by interviewing farm owners. Information or the presence of clots, flakes, watery,
any bloody secretions and physical appearance of milk secretion were examined from each quarter
according to guidelines of Mekibib et al. (2010), Kivaria et al. (2007) and Elbably et al. (2013).
California Mastitis Test
Screening of subclinical mastitis was performed by the California Mastitis Test (CMT)
with the guideline of Iqbal et al. (2006). About 5 ml milk was mixed with equal volume of CMT
reagent in mastitis paddle. Mixing was accomplished by gentle circular motion of the paddle in a
horizontal plane. The reaction developed almost immediately with milk containing a high
concentration of somatic cells. The peak of reaction was obtained within 10 seconds and scored.
Statistical analysis
All the collected data through questionnaire was entered into an Excel sheet of Microsoft
Office Excel (2003) and transferred for analysis to R software and SPSS version 16.0. Firstly, all
the data were labelled into sub heading and analyzed by using descriptive statistics for the
frequency and cross tabulation tables. In Univariable analysis p ≤ 0.25 was considered significant
while risk factors significant in the univariable analysis were furtherly selected as potential
candidates for multivariate analysis using the Binary Logistic Regression with the forward
Stepwise method. All the risk factors in the Logistic Regression, having p ≤ 0.05 were considered
significantly associated with mastitis and the strength of association was determined by the Odds
Ratio (OR) at 95% Confidence interval (CI).
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RESULTS
Descriptive Epidemiology
Prevalence of Clinical and Subclinical Mastitis
A total of 1036 buffaloes were examined for mastitis. Of the population studied, the
animals examined in district Lahore were 598 buffaloes belonging to 25 herds, while the remaining
438 were from 25 herds maintained in Bhimber district. The overall prevalence of mastitis was
recorded 49.0% (508/1036 animals). The prevalence of mastitis recorded in Lahore was 55.5%
(332/598 animals) while in district Bhimber it was 40.2% (176/438 animals) (Table 3.1).
Among mastitis cases the prevalence of clinical mastitis was 10.2% (106/1036 animals) as
a whole. However, the prevalence of clinical mastitis in district Lahore was 11.9% (71/598 animals)
whereas it was 8.0% (35/438 animals) in district Bhimber. The overall prevalence of subclinical
mastitis was 38.8% (402/1036) as diagnosed with a California mastitis test. The district wise
prevalence was subclinical mastitis was 43.6% (261/598 animals) and 32.2% (141/438 animals)
in the districts of Lahore and Bhimber, respectively.
Among the total of 508 cases of mastitis 20.9% (106/508) were of clinical mastitis while
the remaining 79.1% (402/508) was subclinical mastitis. The clinical and subclinical mastitis on
district wise among the mastitis cases was 21.4% (71/332) and 78.6% (261/332) in Lahore while
in Bhimber it was 19.9% (36/176) and 80.1% (141/176), respectively.
Prevalence of Mastitis on the basis of Herd Size
The herds were categorized into three groups i.e. Small comprising of 5-10 animals,
medium sized 11-30 animals and large having more than 30 animals. The overall prevalence of
mastitis was 40.2%, 46.5% and 52.6% in small, medium and large herds, respectively. In district
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Lahore the herd wise mastitis prevalence was 45.7%, 52.5 % and 56.8%, while in district Bhimber
it was 29.9%, 40.3% and 44.0%, respectively (Table 3.2).
Age wise distribution of mastitis
The dairy animals were categorized into three age groups; G1 (3-5 years), G2 (6-8 years)
and G3 (9 and above). The prevalence of mastitis recorded in was 38.2%, 40.8% and 68.9% in
G1, G2 and G3, respectively. In district Lahore the prevalence of mastitis in different age groups
was 44.8%, 46.7%, 71.0% of G1, G2 and G3, respectively. Similarly, in Bhimber it was 29.4%,
36.1% and 64.5% in G1, G2 and G3, respectively (Table 3.3).
Breed wise distribution of mastitis
The dairy buffaloes were categorized into three groups on the basis of their breed B1 (Nili
Ravi), B2 (Kundhi) and B3 (Non-descriptive). The prevalence of mastitis in buffaloes on the basis
of the breed was recorded 52.2%, 40.0% and 44.7% in B1, B2 and B3, respectively. In the district
Lahore prevalence of mastitis was recorded 58.1%, 50.0%, and 47.4% while in Bhimber it was
44.1%, 28.3% and 39.3%, respectively (Table 3.4).
Parity wise prevalence of mastitis
The dairy buffaloes were categorized into three groups on the basis of their parity P1 (1
parity) P2 (2-5 parity) and P3 (>6 parity). The overall prevalence of mastitis on the basis of parity
was recorded 26.1%, 48.4% and 58.0% in P1, P2 and P3, respectively. In district Lahore
prevalence of mastitis was recorded 32.1%, 54.2% and 65.1% in P1, P2 and P3, respectively.
Similarly, the prevalence of mastitis on the basis of lactation number was recorded in Bhimber
17.5%, 41.1% and 47.1% in P1, P2 and P3, respectively (Table 3.5).
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Stage of lactation wise prevalence of mastitis
The dairy animals were divided into three categories (early, mid and late) on the basis of
their lactation stage. The overall prevalence of mastitis was recorded as 43.5%, 55.4% and 43.8%,
in early, mid and late stage of lactation, respectively. In the district Lahore prevalence of mastitis
on the basis of stage of lactation was recorded 46.7%, 63.0% and 50.8%, while in district Bhimber
it was 39.2%, 44.6% and 34.9% in early, mid and late, respectively (Table 3.6).
Quarter level prevalence
The quarter wise prevalence of mastitis among LF, RF, LR, and RR was recorded at 9.4%,
28.0%, 8.2% and 19.4%, respectively. In district Lahore the quarter wise prevalence of mastitis
was 11.0%, 30.8%, 10.5% and 22.7%, while in district Bhimber it was 7.1%, 24.2%, 5.0% and
14.8%, respectively (Table 3.7). The one quarter, two quarters, three quarters and four quarters
prevalence were recorded 38.5%, 5.8%, 4.1% and 0.7%, respectively. In district Lahore the quarter
level prevalence of mastitis was recorded 42.1%, 7.2%, 5.4% and 0.8%, while in district Bhimber
it was 33.6%, 3.9%, 2.3% and 0.5%, respectively (Table 3.8).
Udder Shape
In dairy buffaloes the udder shape was categorized in two i.e. pendulous and normal. The
prevalence of mastitis was the highest in pendulous udder (51.6%) than normal (43.0%) (Table
3.10). In the district Lahore prevalence of mastitis on the basis of udder shape was 58.0% (243/419)
and 49.7% (89/179) in pendulous and normal udder, respectively. In district Bhimber it was
recorded as 42.9% (132/308) and 33.8% (44/130) in pendulous and normal udder, respectively.
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Teat Shape
Teats shape was categorized into three types on the basis of shape, i.e., funnel, round, and
flat. The whole prevalence of mastitis in funnel, round and flat teats was recorded 51.1%, 47.2%
and 49.3%, respectively (Table 3.10). In the Lahore prevalence of mastitis was recorded 54.9%
(73/133), 53.8% (98/182) and 56.9% (161/283) while in Bhimber it was 45.7% (43/94), 38.1%
(51/134) and 39.1% (82/210) in funnel, round and flat teats, respectively.
Ease of milking
In dairy buffaloes ease of milking was categorized in two (soft milking and hard milking).
The prevalence of mastitis in soft milking was highest 44.7% (421/941) and lowest in hard
milking 91.6% (87/95) (Table 3.10). In district Lahore the prevalence of mastitis was in soft
milking (51.3% (278/542/) and in hard milking it was 96.4% (54/56). In district Bhimber the
prevalence of mastitis was in soft milking 35.9% (143/399) and in hard milking it was 84.6%
(33/39).
Milking Techniques
The milking techniques were categorized such as complete hand milking and knuckling.
The prevalence of mastitis in animals milked by knuckling was 51.3% as compared with complete
hand milking was 43.3% (Table 3.11). In district Lahore the prevalence of mastitis on the basis of
milking techniques was recorded relatively higher in knuckling milking 57.5% (233/405) than
complete hand milking 51.3% (99/193). Similarly, in district Bhimber the prevalence of mastitis
was higher 43.8% (145/331) in knuckling than complete hand milking 29.0% (31/107).
Number of animals milked by same milker
The dairy buffaloes were categorized on the basis of the number of animals milked by the
same milker into three groups G1 (1-5), G2 (6-10), G3 (>11). The whole prevalence of mastitis
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was recorded 53.9% and 47.7% and 49.4% in G1, G2 and G3, respectively (Table 3.11). In the
Lahore prevalence of mastitis was recorded 57.2% (91/159), 53.7% (182/339) and 59.0% (59/100)
and in Bhimber it was 28.6% (6/21), 41.8% (145/347) and 35.7% (25/70) in G1, G2, and G3,
respectively.
Frequency of dung removal
In dairy buffaloes the frequency of dung removal was categorized in two i.e. once in a day
and twice in a day. The prevalence of mastitis was recorded higher in once in a day (49.8%) than
twice in a day (43.0%) (Table 3.11).
Condition of floor
The floor bedding on dairy farms were categorized as concrete and soiled bedding. The
prevalence of mastitis was higher in soiled (50.4%) than concrete floor 45.4% (Table 3.11). In
district Lahore the prevalence of mastitis was on soiled floor 69.1% (284/411) and on concrete
floor 55.2% (48/87). The prevalence of mastitis was on solid floor 39.5% (96/243) and on concrete
floor 41.0% (80/195) in district Bhimber.
Source of water
There were three categories of source of water, such as pond, canal and sub-surface water
prevalence of mastitis was 50.8%, 46.0%, and 56.3%, respectively (Table 3.11). In district Lahore
the prevalence of mastitis was recorded at 55.4% (113/204), 52.5% (155/295) and 64.6% (64/99)
in the pond, canal and sub-surface water, respectively. While in district Bhimber it was 43.3%
(55/127), 38.6% (100/259) and 40.4% (21/52/) in river, pond and sub-surface water, respectively.
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Tick infestation
The prevalence of mastitis on basis of tick present on farm was recorded 55.8% while it
was 41.8% where ticks were not present (Table 3.11). In district Lahore the prevalence of mastitis
was 64.8% (184/284), while in district Bhimber it was 45.7% (116/254) were ticks were present.
The prevalence of mastitis without tick infestation was 47.1% (148/314) and 32.6% (60/184) in
district Lahore and Bhimber, respectively
Reproductive disorders
The prevalence of mastitis on the basis of reproductive disorders was recorded 62.8%
while the prevalence of mastitis was 45.0% where reproductive disorders was absent (Table 3.9).
In district Lahore the prevalence of mastitis was 50.7% (231/456) with history of reproductive
disorder and it was 71.1% (101/142) without reproductive disorder. While in district Bhimber it
was 50.0% (46/92) where reproductive disorder was present and it was 37.6% (130/346) where
reproductive disorder was absent.
Exposure to FMD
The prevalence of mastitis on the basis of history of exposure to FMD was recorded 58.4%
while prevalence of mastitis was 47.2% where FMD history was not reported (Table 3.11). In
district Lahore the prevalence of mastitis was 70.4% (69/98) where FMD history was present and
it was 52.6% (263/500) where FMD was not reported. In district Bhimber it was 41.2% (28/68)
with history of FMD exposure and it was 40% (148/370) without FMD history.
Previous exposure of mastitis
The overall prevalence of mastitis was 74.9% in buffaloes having previous exposure to mastitis
while it has 47.3% in buffaloes without previous record of mastitis (Table 3.10). In district Lahore
it was recorded as 81.6% (84/103) in previously exposed to mastitis and 50.1% (248/495) not
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exposed to mastitis. In district Bhimber it was 65.8% (50/76) in previously exposed to mastitis
and it was 34.8% (126/362) in not exposed to previous mastitis.
Univariable and Multivariable Analysis of Risk Factors
In total 25 variables were studied and analyzed by univariable analysis. Out of these 25
variants; 23 variables were further selected for multivariable analysis to estimate the independence
of the effect of the variables on the basis of selection criteria (Table 3.9, 10, 11). The final model
identified 12 variables as potential risk factors of mastitis in buffaloes (Table 3.12).
Area
In univariable analysis the prevalence of mastitis was significantly associated (p< 0.001) in district
Lahore as compared to district district Bhimber (Table 3.9). Similarly in multivariable analysis
area was significantly associated (p< 0.017) with the prevalence of mastitis (Table 3.12).
Herd size
With univariable analysis the prevalence of mastitis was significantly associated (p< 0.02)
with larger herds (OR of 1.65, 95% CI 1.07-2.54) when compared with small herds, while medium
herd was not statistically significant with a prevalence of mastitis (Table 3.9). In multivariable
analysis herd size was not statistically significant (p>0.05).
Breed
The univariable analysis showed that the Kundhi breed had less prevalence of mastitis as
compared with Nili Ravi breed was associated significantly (p> 0.002). The odds ratio of
Kundhi was 0.61 times less than the odds of Nili Ravi breed when compared with Kundhi
breed. Similarly, Kundhi breed was associated significantly (p>0.193) with a prevalence of
mastitis when compared with Non-descriptive breed (Table 3.9). The multivariable analysis
showed that the Nili Ravi breed was highly associated (p<0.003) with a prevalence of mastitis
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when compared with Kundhi breed. The odds of Kundhi breed showed that prevalence of mastitis
is 0.61 times less than Nili Ravi breed (Table 3.12).
Age wise distribution of mastitis
The univariable analysis showed that older age buffaloes (>8 years) were significantly
associated (p< 0.001) with the prevalence of mastitis than young (3-5 years) and adult (>5-8 years)
groups having OR 3.59 with 95% confidence interval (CI) of 2.63-4.89 (Table 3.9). In old age
buffaloes, there is three times risk of mastitis as compared to young buffaloes. The multivariable
analysis showed that older age buffaloes were highly significant (p< 0.001) with a prevalence of
mastitis having OR 2.22 with 95% confidence interval (CI) of 1.44-3.43 when compared to young
buffaloes. Similarly, adult buffaloes also had significance (p< 0.008) associated with prevalence
of mastitis when compared to young buffaloes. The odds of adult buffaloes exposure was 0.53 (CI
95%: 0.34-0.85) times less than the exposure in young buffaloes (Table 3.12).
Parity wise prevalence of mastitis
The univariable analysis showed the prevalence of mastitis was highly significant (p<
0.001) with the increase in the parity number OR of 16.43 with 95% confidence interval of 5.91-
45.68. (Table 3.9). The multivariable analysis showed that prevalence of mastitis was statistically
significant (p<0.001) when increase parity number with OR. 9.14 having 95% confidence interval
of 2.9-28.82 (Table 3.12).
Stage of lactation wise prevalence of mastitis
The univariable analysis showed that mid lactation stage was significant (p< 0.003)
associated with prevalence of mastitis when compared to the early lactation stage with OR 1.61 at
95% CI of 1.17-2.21 (Table 3.9). The prevalence of mastitis was non-significant (p>0.942) in late
lactation stage when compared to early stage. The odds of late lactation were (OR 1.01) having
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less than one times prevalence of mastitis (95% CI of 0.72-1.42). The multivariable analysis
showed that mid lactation stage significantly higher (p>0.003) with a prevalence of mastitis (OR
1.85; 95% CI, 1.23-2.79) while late lactation stage was not statistically associated with prevalence
of mastitis (p>0.05) (Table 3.12).
Reproductive disorders
The reproductive disorder was associated with the prevalence of mastitis (p<.001) in
univariable analysis. Buffaloes with reproductive disorder were two times more prone to mastitis
as compared to healthy buffaloes (OR 2.064) (Table 3.9). In multivariable analysis,
reproductive disorder was not associated with prevalence of mastitis (p>0.05).
Udder Shape
The univariable analysis showed that pendulous udder was strongly associated with
prevalence of mastitis when compared to normal udder (Table 3.10).
Teat Shape
In the univariable analysis flat teats were associated (p< 0.125) with a prevalence of
mastitis in funnel teat shape when compared to funnel shaped teat OR (1.06) (Table 3.10). In
multivariate analysis teat shape was not associated with prevalence of mastitis (p<0.05).
Previous exposure to Mastitis
The previous exposure of mastitis was highly associated (p<.000) with a prevalence of
mastitis having OR. 3.846 in univariable analysis (Table 3.10). In multivariable analysis the
buffaloes with previous exposure to mastitis were three times more prone to infection as compared
to new exposure of mastitis OR. 3.44 (955 CI; 2.14-5.53). Similarly, previous exposure to mastitis
was strongly associated with prevalence of mastitis (p<.001) (Table 3.12).
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Ease of milking
The univariable analysis showed that soft teat consistency may be due to loose teat
sphincter was highly significant (p<.000) with a prevalence of mastitis when compared with hard
teat consistency having OR.13.432 (95% CI; 6.43-28.02) (Table 3.11). In multivariable analysis,
soft teat was highly significant (p<. 001) associated with prevalence of mastitis having OR. 14.48
(95% CI; 6.43-32.58) (Table 3.12).
Udder Odema
The univariable analysis showed that udder edema was strongly associated (p<.000) with
the prevalence of mastitis having OR.13.747 at 95% CI of 5.92-23.95 (Table 3.10). In
multivariable analysis udder edema was significant (p>0.023) with prevalence of mastitis having
OR. 4.92 (1.25-19.36 at 95% CI) (Table 3.12).
Lesions on udder and teat
The lesions on the udder or teat were statistically associated (p<.000) with the
prevalence of mastitis while buffaloes having a lesion on udder and teat were 13 times more
prone to mastitis as compared to not lesion on the udder or teat in univariable analysis (OR
13.061; 6.25-27.26) (Table 3.10). In multivariable analysis lesions on the udder or teat were
highly significant (p<. 001) with a prevalence of mastitis having OR 6.84 (2.88- 16.21) at 95%
confidence interval (CI) (Table 3.12).
Swelling on udder and teat
The swelling on udder and teat was highly associated (p<.000) with the prevalence of
mastitis having OR. 11.917 (Table 3.10) in univariable analysis while in multivariable analysis, it
was not associated with prevalence of mastitis.
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Condition of floor
The univariable analysis showed that soiled floor was significant (p<.086) associated with
prevalence of mastitis having OR.1.222 (95%CI; 0.929-1.609) (Table 3.11). But in
multivariable analysis condition of floor was non-significant.
Frequency of dung removal
The frequency of dung removal has significant (p>0.171) effect on prevalence of mastitis
in univariable analysis (Table 3.11) while in multivariable analysis it was not associated with
prevalence of mastitis.
Source of water
In univariable and multivariable analysis the source of water has non-significant effect on
prevalence of mastitis.
Exposure to FMD
The exposure to FMD was associated with the prevalence of mastitis (p<.008) with having
OR. 1.57 (Table 3.11) by univariable analysis. The multivariable analysis, exposure to FMD was
as that prevalence of mastitis was significant p< 0.020. Buffaloes with a history of FMD exposure
were 1.67 more prone to mastitis as compared to healthy buffaloes (OR 1.67; 95% CI; 1.08-2.58)
(Table 3.12).
Udder wash
The univariable analysis showed buffaloes without udder washing at milking time have
significant effect on prevalence of mastitis (p<.042) (Table 3.11).
Teat dipping
The univariable analysis showed buffaloes without teat dipping were associated with
prevalence of mastitis (p<.042) than teat dipped buffaloes. Buffaloes without teat dipping were
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1.40 times more susceptible to mastitis (95% CI; 1.01-1.95) (Table 3.11). In the multivariable
analysis, prevalence of mastitis had a significant effect (p>0.03). Buffaloes without teat dipping
were 1.76 times more susceptible to mastitis (95% CI; 1.04-2.97) (Table 3.12).
Milking Techniques
Milking method knuckling was found to be highly associated (p>0.019) with the
prevalence of mastitis by univariable analysis as compared with complete hand milking (OR 1.38;
95% CI, 1.05-1.80) (Table 3.11).
Tick infestation
The tick infestation was strongly associated with the prevalence of mastitis (p<.000)
having OR. 1.757, when compared to non-tick infestation buffaloes (Table 3.11) by univariable
analysis. Similarly, in multivariable analysis the prevalence of mastitis was highly significant
(p<.001). Buffaloes with tick infestation were two times more prone to mastitis when compared
with non-tick infestation (OR. 2.83; 95% CI; 1.99-4.01) (Table 3.12).
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Table 3.1: Prevalence of Clinical and Subclinical Mastitis in Lactating Buffaloes
Districts Mastitis Total examined Frequency Prevalence
(%) 95% CI
Lahore
Clinical 598 71 11.8 9.5-14.6
Subclinical 598 261 43.6 39.7-47.6
Total 598 332 55.5 51.5-59.4
Bhimber
Clinical 438 35 8.0 5.7-10.8
Subclinical 438 141 32.2 27.9-36.7
Total 438 176 40.2 35.5-44.8
Overall
Clinical 1036 106 10.2 8.4-12.1
Subclinical 1036 402 38.8 35.8-41.8
Total 1036 508 49.0 46-52
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Table 3.2: Prevalence of Mastitis on basis of Herd size in Lactating Buffaloes
Districts Herd Size Total examined Mastitic Prevalence
(%) 95% CI
Lahore
5-10 animals 35 16 45.7 29.2-62.2
11-30 animals 204 107 52.5 45.6-59.2
More then 30 359 204 56.8 51.7-61.9
Total 598 332 55.5 51.5-59.5
Bhimber
5-10 animals 67 20 29.9 19.8-41.6
11-30 animals 196 79 40.3 33.6-47.2
More then 30 175 77 44.0 36.8-51.4
Total 438 176 40.2 36.4-44.1
Overall
5-10 animals 102 41 40.2 31-49.9
11-30 animals 400 186 46.5 41.6-51.4
More then 30 534 281 52.6 48.4-56.8
Total 1036 508 49.0 46-52
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Table 3.3: Prevalence of Mastitis on basis of Age in Lactating Buffaloes
Districts Age Total examined Mastitic Prevalence
(%) 95% CI
Lahore
3-5 years 172 77 44.8 37.4-52.2
6-8 years 195 91 46.7 39.7-53.7
9 and above 231 164 71.0 64.9-76.6
Total 598 332 55.5 51.5-59.5
Bhimber
3-5 years 187 55 29.4 23.2-36.2
6-8 years 144 52 36.1 28.6-44.2
9 and above 107 69 64.5 55.1-73.1
Total 438 176 40.2 35.7-44.9
Overall
3-5 years 382 146 38.2 36.6-44.8
6-8 years 316 129 40.8 35.5-46.3
9 and above 338 233 68.9 63.8-73.7
Total 1036 508 49.0 46-52
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Table 3.4: Prevalence of Mastitis on basis of Breed in Lactating Buffaloes
Districts Breed Total examined Mastitic Prevalence
(%) 95% CI
Lahore
Nili Ravi 425 247 58.1 53.4-62.7
Kundhi 116 58 50.0 41- 59
Non-descriptive 57 27 47.4 34.70-60.3
Total 598 332 55.5 51.5-59.4
Bhimber
Nili Ravi 311 137 44.1 38.6-49.6
Kundhi 99 28 28.3 20-37.4
Non-descriptive 28 11 39.3 22.7-58.1
Total 438 176 40.2 35.7-44.9
Overall
Nili Ravi 736 384 52.2 48.6-55.8
Kundhi 215 86 40.0 33.6-46.7
Non-descriptive 85 38 44.7 34.4-55.3
Total 1036 508 49.0 46-52
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Table 3.5: Prevalence of Mastitis on basis of Parity in Lactating Buffaloes
Districts Parity Total examined Mastitic Prevalence
(%) 95% CI
Lahore
1 Parity 81 26 32.1 24.6-41.7
2-5 Parity 282 153 54.2 49.3-59.1
6> Parity 235 153 65.1 59.8-70.1
Total 598 332 55.5 52.2-58.8
Bhimber
1 Parity 57 10 17.5 10.4-27.1
2-5 Parity 226 93 41.1 35.8-46.6
6> Parity 155 73 47.1 40.6-53.7
Total 438 176 40.2 36.4-44.1
Overall
1 Parity 138 36 26.1 19.3.33.9
2-5 Parity 508 246 48.4 44.1-52.8
6> Parity 390 226 58.0 53-62.8
Total 1036 508 49.0 46-52
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Table 3.6: Prevalence of Mastitis on basis of Stage of Lactation in Lactating Buffaloes
Districts Lactation stage
Total examined Mastitic Prevalence
(%) 95% CI
Lahore
Early 135 63 46.7 38.1-55.4
Mid 276 174 63.0 57.2-68.6
Late 187 95 50.8 43.6-57.9
Total 598 332 55.5 51.5-59.4
Bhimber
Early 97 38 39.2 29.8-49.1
Mid 195 87 44.6 37.7-51.6
Late 146 51 34.9 27.5-42.9
Total 438 176 40.2 35.5-44.8
Overall
Early 232 101 43.5 37.2-49.9
Mid 471 261 55.4 50.9-59.9
Late 333 146 43.8 38.6-49.2
Total 1036 508 49.0 46-52
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Table 3.7: Quarter wise Prevalence of Mastitis in Lactating Buffaloes
Districts Quarter Total Quarter examined
Mastitic Quarter
Prevalence (%) 95% CI
Lahore
LF 598 66 11.0 8.7-13.7
LR 598 184 30.8 27.2-34.6
RF 598 63 10.5 8.2-13.1
RR 598 136 22.7 19.5-26.2
Bhimber
LF 438 31 7.0 4.9-9.8
LR 438 106 24.2 20.4-28.4
RF 438 22 5.0 3.2-7.4
RR 438 65 14 11.7-18.4
Overall
LF 1036 97 9.4 7.7-11.2
LR 1036 290 28.0 25.3-30.7
RF 1036 85 8.2 6.6-10.1
RR 1036 201 19.4 17.1-21.9
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Table 3.8: Prevalence of Mastitis in Lactating Buffaloes having Mastitis in 1, 2, 3 and 4 Quarters
Districts No. of Quarter Total buffalo examined Total positive Prevalence (%)
Lahore
One quarter 598 252 42.1
Two quarter 598 43 7.2
Three quarter 598 32 5.4
Four quarter 598 05 0.8
Bhimber
One quarter 438 147 33.6
Two quarter 438 17 3.9
Three quarter 438 10 2.3
Four quarter 438 02 0.5
Overall
One quarter 1036 399 38.5
Two quarter 1036 60 5.8
Three quarter 1036 42 4.1
Four quarter 1036 07 0.7
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Table 3.9: Univariable Analysis for Association of different Risk Factors with Mastitis *Significant: 𝑃𝑃< 0.25
Risk Factors Level Total examined +Ve No. -Ve No. OR 95% CI P-value
Area Lahore 598 332 266
0.54 .42- .69 <0.001* Bhimber 438 176 262
Herd Size
Small (5-10) 102 41 61 Ref. - -
Medium (11-30) 400 186 214 1.29 .83-2.01 0.25*
Large (> 31) 534 281 256 1.65 1.07-2.54 0.02*
Breed Nili Ravi 736 384 352 Ref. - -
Kundhi 215 86 129 0.61 .45-0.83 0.002*
Non-descriptive
85 38 47 0.74 .47-1.16 0.193*
Age 3-5 year 382 146 236 Ref. - -
6-8 year 316 129 187 1.12 0.82-1.51 0.48 >9 338 233 105 3.59 2.63-4.89 <0.001*
Parity 1st 138 36 102 Ref. - -
2 to 5 508 246 262 1.64 1.01-2.65 0.044* >6 390 226 164 3.96 2.36-6.64 <0.001*
Stage of
Lactation
Early 232 101 131 Ref. - -
Mid 471 261 210 1.61 1.17-2.21 0.003* Late 333 146 187 1.01 .72-1.42 0.942
Reproductive
Disorder
No 802 361 441 2.064 1.53-2.78 0.000* Yes 234 147 87
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Table 3.10: Univariable Analysis for Association of different Risk Factors with Mastitis
*Significant: 𝑃𝑃< 0.25
Risk Factors Level Total examined +Ve No. -Ve No. OR 95% CI P-value
Teat shape
Funnel 227 116 111 Ref. - -
Round 316 149 167 0.85 0.61-1.2 0.364
Flate 493 243 250 1.06 0.75-1.49 0.125*
Udder shape Normal 309 133 176
0.709 .543-.927 0.012* Pendolous 727 375 352
Previous mastitis No 857 374 483
3.846 2.67-5.53 .000* Yes 179 134 45
Ease of milking Soft 941 421 520
13.432 6.43-28.02 .000* Hard 95 87 08
Udder odema No 996 471 525
13.747 4.21-44.87 .000* Yes 40 37 3
Lesion on udder
and teat
No 943 423 520 13.061 6.25-27.26 .000*
Yes 93 85 08
Swelling on
udder and teat
No 940 421 519 11.917 5.92-23.95 .000*
Yes 96 87 09
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Table 3.11: Univariable Analysis for Association of different Risk Factors with Mastitis
*Significant: 𝑃𝑃< 0.25
Risk Factors Level Total
examined +Ve No. -Ve No. OR 95% CI P-value
Condition of
floor
Concrete 282 128 154 1.222
.929-
1.609 0.086*
Soiled 754 380 374
Frequency of
dung removal
Once in a day 922 459 463 1.315
.888-
1.947 0.171*
Twice in a day 114 49 65
Source of
water
Pond 331 168 163 Ref. - -
Canal 554 255 299 0.86 .62-1.19 0.357
Sub-surface 151 85 66 1.25 .85-1.1 0.259
Exposure to
FMD
No 870 411 459 1.57 1.12-2.19 0.008*
Yes 166 97 69
Udder wash No 704 330 374
0.763 .588- .922 0.043* Yes 332 178 154
Teat dipping Yes 171 96 75
1.407 1.01-1.95 0.042* No 865 412 453
Milking
technique
Complete
hand 300 130 170
1.381 1.05-1.80 0.019*
Knuckling 736 378 358
Tick
infestation
No 498 208 290 1.757 1.37-2.24 .000*
Yes 538 300 238
No. of animal
milked by
same milker
G1 (1-5) 180 97 83 Ref. - -
G2 (6-10) 686 327 359 0.5963 - 0.408
G3 (> 11 170 84 86 0.7580 - 0.485
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Table 3.12: Multivariable Analysis of Potential Risk Factors with Prevalence of Mastitis
*Significant: 𝑃𝑃< 0.05
Potential risk
factors
Level Regression
Coefficient
Standard
error
OR 95% CI P-value
(Wald)
P-value
(LR)
Age 3-5 year Ref. < 0.001*
6-8 year -0.6274 0.2349 0.53 0.34-0.85 0.008
<9
0.7963 0.2214 2.22 1.44-3.42 < 0.001
Breed Nili Ravi Ref. 0.008*
Kundhi -0.6162 0.2068 0.54 0.36-0.81 0.003
Non-
descriptive
-0.3717 0.2957 0.69 0.39-1.23 0.209
Parity 1st Ref. < 0.001*
2-5 0.8927 0.3150 2.44 1.32-4.53 0.005
>6 1.8057 0.3310 6.08 3.18-11.64 < 0.001
Lactation stage Early Ref. 0.01*
Mid 0.6156 0.2101 1.85 1.23-2.79 0.003
Late 0.2972 0.2185 1.35 0.88-2.07 0.174
Previous exposure
to mastitis
No Ref. < 0.001*
Yes 1.2357 0.2418 3.44 2.14-5.53 < 0.001
Exposure to FMD No Ref. 0.022*
Yes 0.5111 0.2229 1.67 1.08-2.58 0.022
Lesion on
uddder/teat
No Ref. < 0.001*
Yes 1.9225 0.4404 6.84 2.88-16.21 < 0.001
Udder odema No Ref. 0.009*
Yes 1.5940 0.6986 4.92 1.25-19.36 0.023
Tick infestation No Ref. < 0.001*
yes 1.0394 0.1788 2.83 1.99-4.01 < 0.001
Ease of milking Hard Ref. < 0.001*
Soft 2.6727 0.4138 14.48 6.43-32.58 < 0.001
Teat Dipping No Ref. 0.033*
Yes 0.5656 0.2666 1.76 1.04-2.97 0.034
Area Lahore Ref. 0.017*
Bhimber -0.4346 0.1829 0.65 0.45-0.93 0.017
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DISCUSSION
Prevalence of Clinical and Subclinical
In the present study the overall prevalence of mastitis was 49.0%. Among these 49.0%
clinical mastitis was 10.2%, while subclinical mastitis was 38.8%. The finding of previously study
conducted in Khyber Pakhtunkhwa province of Pakistan by Ali et al. (2014), who reported that
overall prevalence of clinical and subclinical mastitis was 13.6% and 41.8 %, respectively which
is close to the present study. Prevalence of mastitis in present study agreed with a prevalence of
mastitis from previous studies carried in Sudan by Nigo et al. (2013), Junaidu et al. (2011) in
Nigeria and Hashemi et al. (2011) in Iran. The findings in the present study are in accordance to
Ali (2009) who reported prevalence of clinical mastitis was 14.0% to 31.75% in Faisalabad,
Pakistan, while, the finding of some previous studies (Mustafa et al. 2014: Bilal et al. 2004) who
reported the prevalence of mastitis in buffaloes was more than 40.0% in Lahore and Faisalabad,
Pakistan, respectively.
The results of the present study about the prevalence of subclinical mastitis (38.0%) are in
accordance with previous studies by Ayano et al. (2013) in Ethiopia, Nigo et al. (2013) in Sudan,
Hashmi and Muneer (1981) in Lahore, Pakistan, Anwar and Chaudhry (1983) who reported
prevalence of subclinical mastitis was 31.0% to 47.0% in cattle and buffaloes in Lahore, Pakistan.
The prevalence of subclinical mastitis was reported by Mustafa et al. (2014) as 59.6%, which was
higher than present study. However, the prevalence of subclinical mastitis in this study is relatively
higher than Sarkar et al. (2013) and Rahman et al. (2009) in Bangladesh who reported prevalence
of subclinical mastitis as 9.0% to 20.0%. In present study significant statistical association of
mastitis with locality (p-value =.000), is supported by a previous two studies Nigo et al. (2013) in
Sudan and Biffa et al. (2005) in Ethiopia, p-value =.003 and p-value=.001, respectively.
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Area wise prevalence of mastitis
In the present study, the prevalence of mastitis was different in both localities 55.5% and 40.2%
in Lahore and Bhimber, respectively. Our finding is supported by previous studies conducted by
Nigo et al. (2013) in Sudan and Biffa et al. (2005) in Ethopia who reported that the prevalence of
mastitis was different in different localities. Basically, mastitis is a complex disease involving
interactions of several factors, mainly of management, environment, and other factors relating to
animal and causative organisms. Its prevalence is expected to vary from place to place. In this
study, the prevalence of mastitis varies from previous studies. It might be due to different
geographical locations, animal genetics, milking methods and management practices that applied
in farms in different localities. This difference in prevalence of mastitis in area wise may be due
to different management practices and environmental contamination.
Various studies has been conducted on prevalence of mastitis and with the passage of time
prevalence of mastitis is increases. Previously a study was conducted in 2011 in district Lahore
and prevalence of mastitis was recorded in buffalo as 40.7% (Ali et al. 2011). The present study
shows, trend of mastitis in increases in Lahore. Increased prevalence is related with increased
buffalo population and poor management practices on dairy farms. The prevalence of mastitis was
high in district Lahore as compared to district Bhimber. The reason behind could be geographical
location. The district Lahore have large population as compared to District Bhimber. District
Lahore is an urban area and dairy farms are located close to urban population and industrial area
and dairy farms are in form of large size population colonized as compared to district Bhimber.
Quarter wise prevalence
In our study, quarter level prevalence was recorded (16.2%) while district wise it was 18.17%
and 12.9%, Lahore and Bhimber, respectively. The quarter wise prevalence of mastitis among LF,
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RF, LR, and RR was recorded at 9.4%, 28.0%, 8.2% and 19.4%, respectively. The mastitis was
higher in hind quarters as comparable to forequarters. Results of the present study were in line
with previous studies of Bilal and Muhammad (2004), Nigo et al. (2013), Gebrekrustos et al.
(2012), Shari et al. (2005) and Chishty et al. (2007) who reported that in hindquarters prevalence
of mastitis was higher than that of front quarters. Single quarter involvement was seen in maximum
number of animals and this is congruent with the finding of Ali (2009) and Hussain et al. (2013)
who reported that single quarter involvement was high and very rare involvement of the all quarters.
In the present study quarter wise prevalence of mastitis showed that highest prevalence was in
single and two quarters, which were in accordance to Iqbal and Siddique (2004), Mahantesh et al.
(2014) who reported that mastitis involvement was more in a single quarter (52.7%), Similarly
Singh and Shankar have recorded higher incidence of mastitis in a single quarter (17.4%), as
compared to two (2.6%), three (0.3%), and four quarters (2.7%). The present study was in line to
Ali et al. (2014), Mustafa et al. (2014), Hussain et al. (2013), Bilal et al. (2004) who reported that
prevalence of mastitis was higher in rear quarters than in fore quarters in buffaloes. Bilal and
Muhammad (2004) reported a higher incidence in hind quarters (63.1%) and forequarters (36.8%)
in buffaloes. Results of the present study are in accordance with previous studies (Egan and
Meancy1987) who reported that the higher prevalence in left rear quarter (34.0%) followed by the
right front (28.0%), right rate (21.8%) and left front (15.3%). Further, among hind quarters, left
hind quarters were found to be more susceptible to infection. The prevalence of mastitis in left rear
quarters was higher than in other quarters. The possible explanation about the left rear quarters
may be due to practices adopted by farmers. In Pakistan, the farmers, mostly milked the buffaloes
from the left side. When milker milked the right rear quarter his hand touches the left quarter
continuously. If the milker’s hand is contaminated it can transmit the infectious to the left rear
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quarter. In our view, buffalo hind quarters are large size and have high milk production as
compared to front quarters. The hind quarters are more exposed to dirt when they lie down on the
floor as well as they are more contaminated with fecal materials. It may be due to reasons that
unhygienic conditions of the legs and presence of contaminated dung can help in the occurrence
of mastitis. Also, they are in direct touch with the hind limbs at milking time. The difference in
quarter wise prevalence of mastitis is probably due to the fact that predisposing factors like teat
size, injury, defective sphincters, and so forth could vary from quarter to quarter.
Previous exposure to Mastitis
In our study previous exposure of mastitis was statistically significant (p<. 001) with a
prevalence of mastitis having OR 3.84 at 95% CI of 2.67-5.53) by univariable analysis. In
multivariable analysis, it was highly significant (p<. 001) having OR 3.44 of 2.14-5.53. The
present study significant association (p<.000) of previous exposure to mastitis was in accordance
with previous studies (Abera et al. 2012; Nigo et al. 2013; Biffa et al. 2005) who reported a
significant association (p<.000) of previous exposure to mastitis with a prevalence of mastitis.
Elbably et al. (2013) described that previous exposure to mastitis was at greatest risk of being re-
infected, and stress factors could put the glands at greater risk of re-infection. In our study, the
dairy animals with previous history of mastitis are three times more susceptible to mastitis as
described by Biffa et al. (2005) who reported that dairy animals with a history of previous mastitis
are two to five times more susceptible to mastitis than those without a history of previous mastitis.
Previously affected dairy animals are at greater risk of being re-infected, suggesting that repeated
challenges of the mammary tissues with microorganisms coupled with other stress factors could
put the glands at greater risks of re-infection. Findings of the present study are in line with previous
studies (Erskine et al. 2002; Lents et al. 2002) who reported that treatment of clinical mastitis may
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suppress the clinical signs, but infective agents are not completely eliminated and infection may
remain in subclinical form.
Herd size wise distribution of mastitis
In the present study, the prevalence of mastitis was increased as the herd size increased.
These findings are in accordance to Ali et al. (2014), Nigo et al. (2013), Kivaria et al. (2013) and
Islam et al. (2010) who reported that the prevalence of mastitis was high in large size herds as
compared to small size herds. In the univariable analysis, the large herd size was significantly (p<
0.02, having OR 1.65 at 95% CI of 1.07-2.54) associated with prevalence of mastitis which is in
accordance to Ali et al. (2014), Kivaria et al. (2013), Nigo et al. (2013) and Islam et al. (2010)
who reported significant (p< 0.05) association of large herd's size with a prevalence of mastitis.
Age wise distribution of mastitis
In the present study, the prevalence of mastitis was in G1 (3-5 years) G2 (6-8 years) D3 (9
and above), 38.2%, 40.8% and 68.9%, respectively. It has been observed from the present results
that prevalence of mastitis increased with increase in age. Findings of the present study are in line
to previous study conducted by Ali et al. (2014), Ali (2009), Ayano et al. (2013), Kurjogi et al.
(2014), Naghmana et al. (1984), Biffa et al. (2005) and Rasool et al. (1985) who reported that rate
of mastitis increase with age. Similarly, Bhikane et al. (2002), Kumar and Sharma (2002) and
Elbably et al. (2013) reported the prevalence of mastitis in the age of 9 years old was higher than
younger animals. The univariable analysis shows that age wise was mastitis is highly significant
(p< 0.000). The logistic regression showed in final Step that it age group 6-8 years was highly
significant (p< 0.000) with OR. 2. 22 (1.44-3.43). In present results, age was shown significantly
(p<0.000) associated with prevalence of mastitis which is close to previous study conducted by
Makibib et al. (2010) who reported that age was significant (p < 0.05) associated with prevalence
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of mastitis. This study agreed that increase in prevalence rates with the advancing age may be
due to gradual suppression of the immune system of the body and structural changes in the udder
and teats. This higher prevalence at this age might be due to decreased immunity of dairy animals
and resistance of bacteria to antibiotics that were indiscriminately used for the treatment of mastitis
during previous infections.
Parity wise prevalence of mastitis
In the present study it has been observed that the prevalence of mastitis increases as the
parity number increases. The prevalence of mastitis continuously increased with increase in parity
number. Our findings are in line with the finding of Biffa et al. (2005), Ali et al. 2014 and Chishty
et al. (2007), who reported prevalence of mastitis increased with parity number. The present study
reveals parity numbers were highly significant (p< 0.000, OR 16.43 having 95% CI of 5.91-45.68)
with a prevalence of mastitis and these findings are similar to finding of previous studies (Elbably
et al. 2013; Biffa et al. 2005; Ali, 2009) who reported parity has a significant association with the
prevalence of mastitis. This increase in mastitis could be due to increasing ease of penetration of
teat duct by a pathogen and accumulation of previous infection as it was confirmed by Tadesse
and Chanie (2012) that old dairy animals especially after four calving are more prone to mastitis.
Stage of lactation wise prevalence of mastitis
In the present study, it has been observed that the prevalence of mastitis was high in mid
lactation as compared to early and late stage of lactation. The present study finding is in line with
Breen et al. (2009); Almaw et al. (2007) and Abera et al. (2012) who reported prevalence of
mastitis was higher in mid lactation than early and late stage of lactation. In our study, the mid
stage of lactation was significantly (p<.003) associated with prevalence of mastitis when
compared, having OR 1.61 at 95% CI of 1.17- 2.21. Regarding stage of lactation current results
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agreed with the findings of Hussain et al. (2013), Almaw et al. (2007) and Abera et al. (2012) who
reported that the stage of lactation was significantly (P-value 0.01) associated with prevalence of
mastitis. This may be due to high milk production in mid lactation, incomplete milking,
continuously milking for a long time, and putting pressure on a teat, changes in both immune
function and nonspecific host defense mechanism.
Udder Shape
In the present study the prevalence of mastitis was higher in pendulous udder (51.6%)
rather than normal udder (43.0%) respectively. The relationship between udder shape and
prevalence of mastitis was significant (P<0.012). The present studies were similar to previous
studies conducted by Ali (2009), Compton et al. (2008), Breen et al. (2009) and Hussain et al.
(2013) that mastitis was higher in pendulous udder than normal udder. Our univariable analysis is
close to Sarkar et al. (2013) and Ali (2009) who reported that pendulous type of udder had
significant (p<0.05) association with prevalence of mastitis and pendulous udders because
pendulous udder sweep the ground all the time that facilitate ascending entry of mastitic pathogens.
Additionally, the pendulous type of udder does not wear well and hanging down due to bigger
size, and it is more likely to become injured than an udder held up close to the body. It might be
due to the reason that, pendulous udder get injuries and abrasion which may facilitate pathogens
to grow.
Teat Shape
The overall prevalence of mastitis funnels, round and flat shaped teats was recorded 51.1%,
47.2% and 49.3%, respectively. In the present study, mastitis prevalence was high in flat and
round teat than funnel shaped teat. In the present study, flat teats were associated (p<0.125) with
a prevalence of mastitis in funnel shaped teats when compared having OR 1.06 at 95% CI of 0.75-
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1.49. The results of the present study are in accordance to previous studies conducted by Ali (2009)
who reported a significant association of teat shape with a prevalence of mastitis. The reasons for
flat shaped teat may have more chances of exposure to environmental contamination and injuries.
Lesion on udder and teat
The overall prevalence of mastitis in the present study, on the basis of lesion on udder and
teat was 18.3%. Similarly, Matios et al. (2009) and Chishty et al. (2007) reported teat injuries and
lesions predispose the udder to infection that might be the reason of higher prevalence of mastitis
in injured teats. Furthermore, it was reported by Uddin et al. (2009) and Sori et al. (2005) that teat
injury provides a medium for the growth of the pathogenic bacteria, which affect the udder and in
case of injuries, the risk of an infection increases. Results of the present study are in accordance
to Elbably et al. (2013) and Bekele and Molla (2001) who suggested that heavy tick infestation
and teat lesions might be responsible for udder infection and also lead to udder abnormalities and
deformities of teats. The lesions on udder and teat were highly significant (p<.000, OR 13.06 at
95% CI of 6.25-27.26) on the prevalence of mastitis, same as in multivariable analysis, it was
highly significant (p<. 001, OR 6.84 at 95% CI of 2.88-16.21) and these findings were in
accordance to Biffa et al. (2005) and Ali (2009) who reported mastitis was significantly associated
with udder/teat injuries. In Pakistan, as part of the traditional dairy husbandry practices, calves are
kept away from their dams over a long period of time and are only allowed to suckle for a short
duration and inadequate milk supply, calves suck vigorously, inducing teat injuries and hence
exposing dams to teat injuries.
Udder edema
The udder edema was strongly associated (p<. 000) with the prevalence of mastitis having
OR 13.747 while in logistic regression it was significant p<0.02 to OR 4.92 (1.25-19.36). Findings
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of the present study are in line with Ali (2009) who reported a highly significant association
between mastitis status and predisposing factors like udder edema and teat edema.
Milking Techniques
The prevalence of mastitis in animals milked by knuckling was high (51.3%) as compared
with complete hand milking (25.6%). Milking method, knuckling was found to be highly
associated (p>0.019) with the prevalence of mastitis by univariable analysis as compared with
complete hand milking (OR 1.38; 95% CI, 1.05-1.80). The present study is in accordance to
Chishty et al. (2007) and Ali, (2009) who reported that there is a significant association between
knuckling milking and prevalence of mastitis in buffaloes. This high prevalence of mastitis in
buffaloes milked by folding thumb might be due to trauma inflicted by knuckling milking. The
use of knuckling technique predisposed the mastitis. Moreover, the use of folded thumb the teat
cistern is injured and has often been considered to be conducive to the development of adverse
effects of the teat canal.
Ease of milking
The soft milking was highly significant (p<.000) when compared with hard milking having
OR 13.43 at 95% CI of 6.43-28.02. In logistic regression it was highly significant (p<.001) with
OR 14.48 at 95% CI of 6.43-32.58). Similarly, in previous studies (Chishty et al. 2007 and Ali,
2009) who reported highly significant association between the soft milking and prevalence of
mastitis. This high prevalence of mastitis in soft milking might be due to loose sphincter of teat
and infectious agents can easily enter and grow in teat canal and udder.
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Teat dipping
The teat dipping was significantly (p< .042, OR 1.40) associated with prevalence of
mastitis. Present study agreed with Hillerton et al. (1993) and Hu et al. (1990) who reported
mastitis prevalence can be minimized by using teat dipping before and after milking.
Number of animals milked by same milker
In the present study, the prevalence of mastitis was recorded 53.9%, 47.7% and 49.4%
in G1, G2 and G3, respectively. It has been observed that the prevalence of mastitis increases
with increasing number of animals milked by same milker. In general, mastitis was increased as
the number of animals milked by same milker increased, but it had non-significant effect on
prevalence of mastitis. The present study findings are accorded with Oliver, (1975) and Ali, (2009)
who reported the prevalence of mastitis increases with increasing number of animals milked by
same milker. In developing countries like Pakistan, dairy animals are milked mostly by the hand
milking method and milk is often used as a lubricant during milking and milker’s hands are often
heavily soiled with milk during this process. It is predominantly caused by contagious mastitis
pathogens which are usually transmitted at the time of milking. Infectious agents of mastitis may
be transmitted from infected to uninfected animals through milkers hands, especially owning to
the proclivity of using milk foam in the milking as a lubricant.
Frequency of dung removal
The prevalence of mastitis was recorded highest in dung is removed once in a day, 49.8%
than twice in a day (43.0%). The univariable analysis showed that a frequency of dung removal
has a significant effects on prevalence of mastitis (P<0.171, OR 1.31 at 95% CI of 0.88-1.94).
Similar results by Carrol (1977) that with once in a day cleaning of sheds, the incidence of mastitis
in buffaloes was 21.1%, whereas when cleaning of sheds was done twice a day, 15.8% of animals
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developed mastitis. In the present study, findings have a significant effect on mastitis same as to
Nago et al. (2013) and Ali (2009). Environmental mastitis pathogens with reservoirs in dung, floor,
bedding etc. Are only occasionally associated with mastitis. Therefore, mastitis control practices
directed against environmental mastitis pathogens are not likely to be as potentially rewarding as
practices aimed at controlling contagious pathogens.
Condition of floor
The prevalence of mastitis was higher on soiled floor, 50.4% than concrete floor 45.4%.
The univariable analysis showed that condition of floor has no significant effect (p<.086) with
mastitis. Similarly, Ali (2009) and Mukabib et al. (2010) reported non-significant association
condition of floor with a prevalence of mastitis in buffaloes. In Pakistan mostly dairy animals are
managed on soiled floor. In soiled floor buffaloes udders and legs are not properly clean before
milking and infection can easily transmit at milking time from diseased to healthy animal.
Source of water
The prevalence of mastitis was 50.8%, 46.0% and 56.3% pond, canal, subsurface water,
respectively. In pond and canal the prevalence of mastitis was higher as compare to subsurface
water. Similarly, previous studies by Nigo et al. (2013), Kivaria et al. (2004) who reported that
river and pond mostly have stagnant water where microorganism can be multiplied and be
transmitted from infected animals to non-infected animals. The source of water has no significant
effect on prevalence of mastitis.
Tick infestation
The prevalence of mastitis on basis of tick infestation was 55.8% in exposed animals.
High tick infestation might have contributed to the occurrence of injuries which causes mastitis.
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Tick infestation in this study showed a significant association with mastitis (p<.000), similar to
Tolosa et al. 2013 and Biffa et al. (2005) who reported a significant association (P <0.01) with a
prevalence of mastitis. The present study agreed with previous studies by Almaw et al. (2008),
Bekele and Molla (2001) and Elbably et al. (2013) who reported that ticks transmit the mastitis
widely throughout the world and ticks left small abrasion and lesion on teat and udder skin which
may let the ease of organisms penetration inside udder.
Reproductive disorders
The prevalence of mastitis on the basis of reproductive disorder was recorded 62.8%
which were highly significant (p<.000) with mastitis. Ali (2009) determined a significant
association with the reproductive disorders and mastitis prevalence in buffaloes. The association
between prevalence of mastitis and reproductive disorders was in line with the findings reported
previously by Esmatand Badr (1996) and Ali, (2009) who reported that reproductive disorders
were three times more likely to develop mastitis. Dairy Buffaloes with the retained placenta were
likely to develop mastitis. According to Bilal (1999) dairy buffaloes having retained placenta,
metritis, vaginal prolapses and dystocia at calving are risk factors of mastitis.
Exposure to FMD
In present study exposure to FMD in both univariable and multivariable analysis has significant
effect on mastitis. Diseases like FMD and pox are particularly known to predispose mastitis in
cattle and buffaloes. According to Radostits et al. (2000) observation, foot and mouth disease,
vesicles may appear on the teat as to the involvement of the teat orifice to mastitis.
In conclusion, dairy buffaloes should be regularly screened and monitored for prevention
and control of mastitis. The husbandry management practices should be kept in consideration
while combating mastitis. Basically mastitis is interaction effects of various management practices,
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such as the interaction of teat dipping before and after milking and proper sanitation of the farm
have significant effects on mastitis prevention. The control strategies should be based on the
improvement of management practices since these factors predispose animals to mastitis. The
study showed that various risk factors are significantly associated with the prevalence of mastitis,
which need to be considered in the control of the disease. Particularly, special importance should
be given to prevention and control of subclinical mastitis. Knowledge of the potential risk factors
is vital for the control of bovine mastitis. In general, mastitis can be prevented by implementation
of various hygienic and preventive measures.
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CHAPTER 4 EXPERIMENT-2
ANTIBIOTICS RESISTANCE AND SENSITIVITY OF STAPHYLOCOCCUS AUREUS
CAUSING MASTITIS IN BUFFALOES
ABSTRACT
The present study was conducted to determine the antibiotic sensitivity of Staphylococcus aureus
isolated from mastitis buffaloes. Clinical mastitis was diagnosed on the basis of physical
examination of the udder, teats and milk. Subclinical mastitis was diagnosed with the help of
California Mastitis Tests. Among a total of 1036 buffaloes, 508 were found to have mastitis
(49.0%). A total of 673 mastitic milk samples from different animal quarters were collected from
different livestock farms having 106 and 567 clinical and subclinical mastitis, respectively. The
prevalence of mastitis was 49.0% with 95% Confidence interval of 46.4-51.5, while prevalence
per quarter was 16.2% with 95% Confidence interval of 15.3-17.2. From these 673 milk samples,
Staphytect plus test confirmed 236 (35.0% at 95% CI 32- 38.2) isolates as coagulase positive
Staphylococcus aureus. Antibiotic sensitivity of all coagulase positive Staphylococcus aureus was
performed by disk diffusion method. The sensitivity of gentamycin, oxytetracycline,
erythromycin, kanamycin, chloramphenicol, tylosin, ciprofloxacin, doxycycline, amoxicillin,
streptomycin and trimethoprim to Staphylococcus aureus was 80.1%, 75.4%, 74.6%, 73.3%,
72.4%, 71.6%, 69.9%, 69.1%, 63.2%, 56.0% and 54.7%, respectively. While on the other hand,
the resistance pattern of gentamycin, oxytetracycline, erythromycin, kanamycin, chloramphenicol,
tylosin, ciprofloxacin, doxycycline, amoxicillin, streptomycin and trimethoprim was 11.0%,
19.9%, 15.3%, 20.8%, 20.8%, 28.4%, 22.9%, 17.3%, 36.8%, 34.3% and 45.3%, respectively.
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Keywords: Mastitis, Buffaloes, Staphylococcus aureus, California mastitis Test, Antibiotics.
INTRODUCTION
Pakistan is rich in livestock, which contributes 11.8% of total GDP with 35 million rural
populations engaged in raising livestock (Anonymous, 2014). The buffalo population in this
country is 34.7 million heads (Anonymous, 2014). Buffaloes are recognized as the second most
important milk producing species around the world (FAO, 2010). Among the various diseases
which affect milk production, mastitis is a major one (Shakoor, 2006). Mastitis is basically a
tenderness of the mammary gland and is characterized by physical, chemical and pathological
changes in the milk and glandular tissue. In the case of subclinical mastitis, milk is apparently
normal with an increase in the somatic cell count (Radostits et al. 2000). In Pakistan, mastitis
eradication may not be possible, but hygienic management practices can reduce the incidence
(Rahman et al. 2009). It has been observed by Mustafa et al. (2011) that the prevalence of mastitis,
both clinical and subclinical in buffalo was 40.4% and 59.6%, respectively.
A wide variety of organisms are associated with mastitis, however the most frequent
pathogens are bacteria, such as Staphylococcus aureus, Escherichia coli, Streptococcus
dysagalactiae, Streptococcus uberis, Streptococcus agalactiae (Radostits et al. 2000). However,
more than 50% of cases of mastitis are caused by Staphylococcus aureus (Shakoor, 2006).
Staphylococcus aureus creates pockets in the inner lining of mammary gland, which is bounded
by fibrous tissue and where antibiotics cannot respond. In Pakistan, antibiotic therapy during dry
period and teat dipping are not in practice, that’s why losses due to mastitis are higher (Arshad,
1999). The cure rate of Staphylococcus aureus mastitis was 52.0% (Sol et al. 2000).
Changes in the nature of proteins expressed by the organism, mutation or horizontal
changes in its genome may lead to bacterial resistance. It is common that with the passage of time
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bacteria may develop resistance to currently available antibacterial drugs by either new mutations
or the exchange of genetic information that is, putting old resistant genes into new hosts (Tenover,
2006). For example, methicillin resistance of Staphylococcus aureus is primarily due to changes
in the penicillin binding protein that consequently inhibit cell wall synthesis. Expression of
the different gene results in an alternative penicillin binding protein that has a low affinity for most
ß-lactam antibiotics, thereby allowing, these strains replicate in the presence of methicillin and
related antibiotics. The objectives of the present study were to determine the prevalence of mastitis
in buffalo and the evaluation of commonly used antibiotics in the treatment of mastitic buffaloes.
MATERIALS AND METHODS
Sampling procedure and sampling area
A cross sectional study was carried out for investigation of the prevalence of mastitis in
dairy buffaloes. The present study was conducted in the peri-urban area of district Lahore and
district Bhimber.
Selection Criteria and Diagnosis of Mastitis
Only lactating buffaloes were incorporated in the present study and those which were
pregnant, in the dry period and heifers were excluded. Animals suffering with clinical mastitis
were diagnosed upon physical examination by the presence of clinical signs such as swelling of
the udder and teat, udder edema, udder and teat injury, abnormal milk secretion etc. Animals with
normal udder quarters were screened by California Mastitis Test (CMT) (Iqbal et al. 2006). A total
of 4144 quarters of buffaloes was examined by CMT from 1036 lactating buffaloes. Animal and
quarter wise prevalence of mastitis was recorded in a questionnaire.
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Collection, Transportation and Culturing of Samples
The recommendation of National Mastitis Council (1990) was considered for the
collection, transportation, culturing and isolates of Staphylococcus aureus. All milk samples were
collected in sterilized screw capped vials and samples transported by placing them in the crushed
ice to the Microbiology Laboratory in the Department of Epidemiology and Public Health,
University of Veterinary and Animal Sciences, Lahore. Conventional methods were used for the
isolation and identification of Staphylococcus aureus.
Staph. 110 medium was used as a selective medium for growth of Staphylococcal species.
Biochemical tests performed were Gram’s staining, catalase test, coagulase test, Mannitol salt ager
and Staphytect plus test (Oxoid UK). After confirmation, pure culture of Staphylococcus aureus
was preserved in 20% glycerol for further study.
Antibiotic Sensitivity of Staphylococcus aureus
According to the guideline of Clinical Laboratory Standard Institute (CLSI. 2005), the disk
diffusion method was performed for antibiotic sensitivity. Staphylococcus aureus ATCC 25923
was used as the quality control organism and trimethoprim, erythromycin, ciprofloxacin,
doxycycline, amoxicillin, streptomycin, tetracycline, tylosin, gentamycin, kanamycin,
chloramphenicol were used in antibiotics sensitivity testing, taking into account the previous
historical records over one decade that these antibiotics were commonly used in the treatment of
buffalo mastitis (Hussain et al. 2013; Hameed et al. 2008).
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RESULTS
A total of 673 milk samples from 1036 lactating buffaloes was collected. The animal wise
prevalence of mastitis was 49.0% with 95% confidence interval of 46.4-51.5. While the prevalence
of clinical and subclinical mastitis was 10.2% and 38.8%, respectively. The table (4.1) indicates
that, only 236 confirmed as Staphylococcus aureus by coagulase test, mannitol salt agar and
staphytect plus test. All these 236 isolates of Staphylococcus aureus were subjected to antibiotic
sensitivity test by disk diffusion method. The zones of inhibition of antibiotics were recorded with
antimicrobial zone gauge. The resistance and sensitivity of Staphylococcus aureus to antibiotics
has been shown in a number (n=236) and percentage (%) in table 4.2, respectively. The resistant
pattern of gentamycin, erythromycin, doxycycline, oxytetracycline, kanamycin, chloramphenicol,
ciprofloxacin, tylosin, streptomycin, amoxicillin and trimethoprim was 11.0%, 15.3%, 17.3%,
19.9%, 20.8%, 20.8%, 22.9%, 28.4%, 34.3% 36.8% and 45.3%, respectively (Table 4.2). The
sensitivity of gentamycin, oxytetracycline, erythromycin, kanamycin, chloramphenicol, tylosin,
ciprofloxacin, doxycycline, amoxicillin, streptomycin and trimethoprim to Staphylococcus aureus
was 80.1%, 75.4%, 74.6%, 73.3%, 72.4%, 71.6%, 69.9%, 69.1%, 63.2%, 56.0% and 54.7%,
respectively.The graphical presentation of resistance and sensitivity of Staphylococcus aureus
has been shown in figure 4.1 and 4.2.
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Table No. 4.1. Isolation and identification of Staphylococcus aureus
Gram’s Staining
Catalase test Slide coagulase test
Staphytect plus test
Mannitol salt ager test
+Ve -Ve +Ve -Ve +Ve -Ve +Ve -Ve +Ve -Ve 407 - 407 - 236 171 236 171 236 171
Table No. 4.2. Percentage (%) and numbers of Staphylococcus aureus resistant, intermediate
and sensitivity to antibiotics (n=236)
Antibiotics Resistant Intermediate Sensitive
Gentamycin 11.0% (26) 9.0% (21) 80.1% (189)
Oxytetracycline 19.9% (47) 4.6% (11) 75.4% (178)
Erythromycin 15.3% (36) 10.2% (24) 74.6% (176)
Kanamycin 20.8% (49) 6.0% (14) 73.3% (173)
Chloramphenicol 20.8% (49) 6.8% (16) 72.4% (171)
Tylosin 28.4% (67) 0.0% (0) 71.6% (169)
Ciprofloxacin 22.9% (54) 7.2% (17) 69.9% (165)
Doxycycline 17.3% (41) 13.5% (32) 69.1% (163)
Amoxicillin 36.8% (87) 0.0% (0) 63.2% (149)
Streptomycin 34.3% (81) 9.7% (23) 56% (132)
Trimethoprim 45.3% (107) 0.0% (0) 54.7% (129)
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Figure 4.1. Pattern of resistant of Staphylococcus aureus against Antibiotics.
45.3
0%
36.8
0%
34.3
0%
28.4
0%
22.9
0%
20.8
0%
20.8
0%
19.9
0%
17.3
0%
15.3
0%
11%
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Figure 4.2. Pattern of sensitivity of Staphylococcus aureus against Antibiotics.
80.1
0%
75.4
0%
74.6
0%
73.3
0%
72.4
0%
71.6
0%
69.9
0%
69.1
0%
63.2
0%
56%
54.7
0%
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DISCUSSION
Mastitis is economically unbearable and complicated disease in dairy industry worldwide.
Staphylococcus aureus is considered as a leading causative organism of mastitis in dairy animals.
Due to the complex nature of Staphylococcus aureus, the treatment and control of mastitis are
failed. The drug resistance is a significant feature of Staphylococcus aureus (Wyder et al. 2011).
Antibiotic resistance is an emerging problem all over the world. Mastitis in dairy animals is the
common reason for antibiotic use in dairy animals. Staphylococcus aureus resistance is increased
in case of mastitis to several antibiotics. In this study, the resistance to trimethoprim is high as
compared to other drugs, it might be due to its constant use in the last decades. In Pakistan, all
these tested antibiotics are in practice in case of mastitis treatment, but among them trimethoprim,
amoxicillin, streptomycin, ciprofloxacin and oxytetracycline are regularly used in mastitis
treatment.
In the present study, trimethoprim sensitivity against Staphylococcus aureus was 54.7%
and its resistance was 45.3%. Our finding is accordance in with many studies (Wang et al. 2015;
Kurjogi et al. 2011; Hussain et al. 2013; Ikiz et al. 2013) who reported the sensitivity of
trimethoprim was 50 to 77%. In this study, the resistance to trimethoprim is high as compared to
other drugs, it might be due to its constant use in the last decades. Amoxicillin sensitivity in the
present study was 63.2%, which is similar to previous studies (Farooq et al. 2008, Idriss et al.
2014; Jeykumar et al. 2013; Khan et al. 2004) who reported amoxicillin as a suitable drug for
treatment of mastitis. Tylosin was 71.6% sensitive in the present study, which was not in line with
the study of Brinda et al. (2010) who reported its sensitivity 28%. This might be due to frequent
use to tylosin in their localities. In the present study, streptomycin sensitivity against
Staphylococcus aureus mastitis was 56%, same as in previous studies (Idriss et al. 2014; Kurjogi
et al. 2011; Farooq et al. 2008) reported their sensitivity from 50 to 80%. Staphylococcus aureus
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sensitivity against antibiotic may be attributed to geographical variation. In the present study,
ciprofloxacin sensitivity against Staphylococcus aureus mastitis was 69.9%. Same as in some
previous studies (Wang et al. 2015; Jeykumar et al. 2013; Li et al. 2009; Unakal et al. 2010; Khan
et al. 2004) reported their sensitivity from 50 to 90%. Staphylococcus aureus sensitivity might be
attributed to the extent from locality to locality.
In the current study, Staphylococcus aureus was 75.4% sensitive and less resistance to
oxytetracycline (19.9%). These findings are in accordance with previous studies who reported
that Staphylococcus aureus was 59 to 88% sensitive to oxytetracycline (Jeykumar el al. 2013; Li
et al. 2009; Khan et al. 2004; Zahid et al. 2004; Ikiz et al. 2013). The results of the current study
revealed that the isolates were 74.6% sensitive to erythromycin. It is in line with many previous
studies (Khan et al. 2004; Alekish et al. 2013; Brinda et al. 2010; Gianneechini et al. 2002; Unakal
et al. 2010) who reported erythromycin sensitivity ranging from 78 to 95%. The sensitivity of
ciprofloxacin was Staphylococcus aureus was 69.9%, which is in compliance with the studies
(Jeykumar et al. 2013; Khan et al. 2005; Mustafa et al. 2014; Hussain et al. 2013) who reported
ciprofloxacin as the drug of choice. In the present study, doxycycline sensitivity was 69.1%, which
is similar to previous studies conducted by Wang et al. (2015) and Alekish et al. (2013) who
reported the sensitivity of doxycycline in mastitis was 50 to 70%. In this study Staphylococcus
aureus was 73.3% sensitive to kanamycin similarity, in previous studies (Idriss et al. 2014; Farooq
et al. 2008; Anjum et al. 2010) described kanamycin as the drug of choice in mastitis. Some other
studies (Mustafa et al. 2014; Kurjogi et al. 2011; Brinda et al. 2010; Anjum et al. 2010) who also
reported their sensitivity less than 40%. Staphylococcus aureus isolated from buffalo mastitis was
72.4% sensitive to chloramphenicol, which is close to the previous finding by Wang et al. (2015),
Li et al. (2009) and Khan et al. (2004) who reported 52 to 91% respectively. The present study
reveals, the sensitivity of gentamycin to Staphylococcus was 80.1%. Gentamycin has been shown
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as the drug of choice against Staphylococcus aureus similarly, many studies (Akram et al. 2013;
Jeykumar et al. 2013; Anjum et al. 2010; Hameed et al. 2008; Iqbal et al. 2004) who reported
gentamycin as a drug of choice in case of Staphylococcus aureus and its sensitivity was 80%.
In conclusion, for successful treatment of mastitis, antibiotic susceptibility testing should
be done to regulate the effectiveness of antibiotics. Proper isolation and identification of the
causative organisms and proper selection of antibiotics play important role in minimizing and
control of the mastitis. In our study the resistant pattern of trimethoprim, amoxicillin, streptomycin
and ciprofloxacin was high as compared to other used antibiotics. Thus, select the appropriate
antibiotic and mastitis treatment should be started after antibiotic sensitivity testing. Furthermore,
there is a need to routinely investigate and record the resistance and sensitivity of Staphylococcus
aureus mastitis in dairy buffaloes.
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a molecular approach. Res Vet Sci. 91: 34-357.
Zahid I 2004. Studies on comparative incidence of subclinical and clinical mastitis and in vitro
antibiotic susceptibility of isolates from Holstein-Friesian and Jersey cows and buffaloes.
Pak Vet J. 24(2): 76-81.
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CHAPTER 5 EXPERIMENT-3
MOLECULAR CHARACTERIZATION OF COAGULASE AND FIBRONECTIN
BINDING PROTEIN A GENES OF STAPHYLOCOCCUS AUREUS ISOLATED FROM
MASTITIS IN RIVER BUFFALOES
ABSTRACT
Mastitis is a major dairy herd problem mainly caused by Staphylococcus aureus. Virulent
coagulase and fibronectin binding protein A genes of S. aureus from mastitic buffalo milk samples,
collected from 50 dairy herds located in Lahore and Bhimber districts. A total of 1036 buffaloes
and 4144 quarters were screened for clinical and subclinical mastitis. Among total of 673 milk
samples, S. aureus was isolated from 236 samples. The S. aureus isolates were subjected to
molecular characterization of coagulase and fibronectin binding protein A genes and phylogenetic
tree (using MEGA6.1 software package) was constructed. It revealed that the coa gene of S. aureus
isolated from mastitic buffalo milk samples, could be grouped in two clades which were closely
related to S. aureus isolates from Japan, India and Taiwan, while S. aureus isolates from Germany,
UK and USA were distantly related. Phylogenetic tree based on fnbA gene sequences indicated
that all Pakistani isolates were clustered together in one clade in closeness with isolates from
Switzerland and Ireland. While isolates from Thailand and USA were placed distantly. These
results indicated the genetic relatedness of Pakistani isolates with other reported isolates from
different parts of the world. This particular knowledge may support in effective diagnosis,
treatment and control of mastitis in river buffaloes in Pakistan. These findings will also be helpful
in future for designing suitable mastitis control strategies in the country.
Keywords: Buffalo, Mastitis, Staphylococcus aureus, Coagulase, Fibronectin binding protein A.
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INTRODUCTION
Mastitis is an inflammation of the parenchyma of the udder which also results in physical,
chemical and pathological changes in the udder. Inflammation of the udder may be caused by any
kind of injuries such as physical trauma, chemical irritants, toxins or infectious agents. The bovine
mastitis is one of the major disease responsible for reduction in milk production (Hussain et al.
2012). Mastitis is manifested in two forms, i.e. clinical and subclinical. The clinical mastitis is
manifested by abnormal milk with or without udder swelling, while in subclinical mastitis milk
production may decrease and bacterial counts increase in milk with no physical abnormality
(Radostits et al. 2000). However, subclinical mastitis is diagnosed by somatic cell count by various
methods such as White Side Test, California Mastitis Test and Surf Filed Mastitis Test. The
prevalence of subclinical mastitis is 20-40 times more as compared to clinical mastitis (Erskine,
2002).
S. aureus is considered the most common causative agent of mastitis in dairy animals and
it possesses property of genetic heterogeneity. Its genetic variability has contributed to the
emergence of distinct epidemiologic profiles of strains prevalent in a herd (Fitzgerald et al. 2003;
Karimuribo et al. 2005; Tollersrud et al. 2000). S. aureus does not have a host preference among
animal species (Aires-de-Sousa et al. 2007; Mork et al. 2005). Staphylococcus aureus is
responsible for a variety of infections in human and animals (Bartlett and Hulten, 2010; Gu et al.
2013; Khan et al. 2013) and treatments become more difficult due to its emerging strains. S. aureus
can be divided into a number of subtypes, among them only a few are responsible for mastitis in
different geographical locations of the world (Aarestrup et al. 1994; Hookey et al. 1999). Rapid
and accurate identification of S. aureus is important for the control and prevention of the infectious
mastitis (Hookey et al. 1998).
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Pathogenesis of mastitis may be caused by extracellular toxins, enzymes and surface
antigens (Luong et al. 2003; O’Riordan and Lee, 2004). Coagulase gene of S. aureus is considered
an important virulence factor. Amplification of S. aureus coagulase gene (coa) has been
recommended as an accurate method for identification of virulent strains of S. aureus (Morandi et
al. 2010; Sabat et al. 2006; Goh et al. 1992). Sequencing of the coagulase gene shows great
diversity in S. aureus population (Costa et al. 2012). Information regarding the genetic diversity
of Staphylococcus aureus isolated from mastitis in cow is available but such information regarding
S. aureus from buffalo mastitis is limited (Faryal et al. 2009). Various studies described that bovine
mastitis is caused by a wide variety of Staphylococcus aureus genotypes (Smith et al. 2005).
Staphylococcus aureus from mastitis represents a genetic heterogeneity (Fagiolo and Lai, 2007;
Fournier et al. 2008). It has more than 50 virulence factors, which enable it to attach to a variety
of hosts, and cause a multitude of diverse infections and the fibronectin binding protein A (fnbA)
is one of them. Pathogenicity of Staphylococcus aureus is due to the expression of cell surface
protein that can bind to host proteins (Broughan et al. 2011; Burke et al. 2010; Nashev et al. 2004;
Novick, 2000). Among different virulent genes, either fnbA or fnbB gene of Staphylococcus aureus
is considered a major virulence factor causing bovine mastitis. In pathogenesis, the first step of
infection starts with the adherence of the pathogen to the teat canal of the udder (Ahmed et al.
2001; Arrecubieta et al. 2008). Effective entrance of bacteria into host occurs by possible when
there is the formation of a bridge between bacterial fibronectin binding proteins (fnbps) and host
fibronectin (Fowler et al. 2000). The present study was designed to find the genetic diversity of
Staphylococcus aureus isolated from buffaloes with mastitis on the basis of fnbA gene. So the
present study was designed to find the genetic diversity of S. aureus isolated from buffaloes with
mastitis on the basis of coagulase gene.
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MATERIALS AND METHODS
Collection of milk samples
The present study was carried out in District Lahore (Punjab) and Bhimber (Azad Jammu
and Kashmir), Pakistan. Lactating buffalo disregards of the parity were selected while buffaloes
in the dry period and heifer were excluded. A total of 4144 quarters from 1036 buffaloes was
screened for the presence of clinical and subclinical mastitis. Fifty dairy herds were screened (25
from each district). The data were collected and categorized into three groups (small, medium and
large having 5 to 10, 11 to 30, and more than 31 dairy buffaloes, respectively) during the study
period. Clinical mastitis was diagnosed on the basis of signs and symptoms while subclinical
mastitis was diagnosed California Mastitis Test (CMT) as discussed by Iqbal et al. (2006). All the
milk samples positive for clinical or subclinical mastitis were collected in sterilized screw capped
vials and transported to the Microbiology Laboratory, Department of Epidemiology and Public
Health, University of Veterinary and Animal Sciences, Lahore in a cooler to maintain temperature
below 4oC. The samples were processed within 12 h after collection from the field.
Isolation and identification of S. aureus
Each of the collected samples was streaked on Staph-110 and sheep blood agar plates.
Gram’s staining followed by a biochemical test, e.g., Catalase test, Coagulase test, Staphytect plus
test and Mannitol fermentation were performed for the characterization of the S. aureus isolates.
Pure cultures of S. aureus were preserved in 20% glycerol and kept at -80oC till further use.
DNA Extraction
After microbiological examination of Staphylococcus aureus, pure cultures were
preserved in 20% glycerol in eppendrof tubes and freeze down at -80 ºC freezer for further
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investigations. Before DNA extraction freeze down samples were streaked on Sheep blood
ager and after 24 hour incubation 4 to 5 fresh colonies of Staphylococcus aureus were
dissolved in normal saline. DNA extraction was performed as prescribed by Genomic DNA
Purification Kit (Thermo Scientific USA). For DNA extraction mixed 200 μl of sample
with 400 μl of lysis solution and incubates at 65°C for 5 min. Then instantly add 600 μl of
chloroform, gently emulsified by inversion and centrifuge the sample at 10,000 rpm for 2
min. Precipitation solution was prepared by mixing 720 μl of sterile deionized water with
80 μl of supply 10X concentrated precipitation solution. Transfer the upper aqueous DNA
to a new tube and add 800 μl of freshly prepared precipitation solution, mixed gently by
several inversions for 1-2 min and centrifuge at 10,000 rpm (~9400 x g) for 2 min.
Supernatant discarded completely and dissolved DNA pellet in 100 μl of NaCl solution by
vortexing gently. Add 300 μl of cold ethanol, let the DNA precipitate (10 min at -20°C)
and spin down (10,000 rpm for 3-4 min). Removed ethanol and wash pellet once with 70%
cold ethanol and dissolve DNA in 100 μl of sterile deionized water by vortexing.
DNA Quantification and storage
DNA quantification of the every sample was done with the help of Gel
electrophoresis using 0.8 % Agarose gel and DNA ladder 100 bp (Fermentas USA). All
extracted DNA samples were adjusted at same concentration level i.e.50 ng/uL. DNA
quantification was also done with Nanodrop Thermo (Fermentas USA) for further
confirmation. Extracted DNA was dissolved in nucleus free water and working aliquots
were made while stock DNA samples were being stored at -20 ºC freezer.
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Selection of Primers
Primers for gene coagulase and fibronectin binding protein A were synthesized from
GeneWorks Australia as reported previously by Kumar et al. (2011).
S.no. Primer Name Nucl. No Sequence (5'--------3')
1 Staph_Coag-F 22 AACAAAGCGGCCCATCATTAAG
2 Staph_Coag-R 23 TAAGAAATATGCTCCGATTGTCG
3 FBNA-F 17 GCGGAGATCAAAGACAA
4 FBNA-R 18 CCATCTATAGCTGTGTGG
Primers Optimization and PCR Amplification
PCR reactions were carried out in 25 μL reaction mixtures, using 50 ng of DNA, 10 mM
of Tris HCl (pH 8.8 at 25 oC), 50 mM of KCl, 0.08%, MgCl2 (2 mM), 250 μM of each dNTPs, 0.2
μM of forward and reverse primers and 0.5 U of Taq DNA polymerase (Thermo Fisher Scientific
Inc. USA). DNA isolated from pure culture of Staphylococcus aureus ATCC 25923 was taken as
positive control while nuclease free water was taken as negative control. The PCR mixture without
template was taken as PCR control to check for the possibility of any contamination.
DNA amplification was carried in thermocycler (Kyratec SC 200) with following cyclic
conditions: Initial denaturation at 95 oC for 5 min followed by 30 cycles of denaturation at 94 oC
for 30 sec, annealing at 52 oC and 57 oC for 30 sec for Coagulase and Fibronectin binding protein
A gene, respectively. Then extension at 72 oC for 30 sec. A final extension at 72 oC was carried
out for 5 min. All the PCR products were run on 1.2 % agarose gel stained with ethidium bromide
and visualized under UV light in Gel Documentation System (BioRad USA) and gel photographs
were saved for future reference.
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Sequencing and Phylogenetic Analysis
Positive PCR products were precipitated with 70 % ethanol (80µL) and finally dissolved
in 20 µL of double distilled deionized water. The representative samples of coa and fnbA (coa =11
and fnbA =07) gene were sent to Australian Genome Research Facility Ltd (AGRF), University of
Adelaide for Sanger’s sequencing. Sequences were edited using Codon Code Aligner and highest
similarities of coa gene with that of other strains were searched using the BLAST tool of GenBank,
NCBI. (Woo et al. 2001). Phylogenetic trees of all sequences were constructed using MEGA6.1
by Neighbor Joining method (Sudhir and Sudhindra, 2000) with 1000 bootstrap values (Tamura et
al. 2011). Alignments, pairwise distance estimations, and similarities/variations at nucleotides
levels of all Pakistani sequences and those reported from NCBI GeneBank were also performed
by using MEGA6.1 software.
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RESULTS
Identification of S. aureus isolates from mastitic milk samples
A total of 4144 quarters from 1036 buffaloes was screened and 673 (106 clinical and 567
subclinical) milk samples from 508 buffaloes were examined for mastitis. Out of 106 clinical
mastitis milk samples examined, 71 belonged to Lahore and 35 to Bhimber; whilst, out of 567
subclinical mastitis milk samples that were examined, 365 belonged to Lahore and 202 to Bhimber.
Among these 673 milk samples, 437 isolates of Staphylococci were recovered. All these 437
isolates of Staphylococci were Gram positive, catalase positive and showed hemolytic property on
5% sheep blood agar. Out of these isolates, only 236 were confirmed coagulase positive S. aureus.
Amplification of coa and FnbA gene PCR Products
Among the total 236 S. aureus isolated, PCR was performed on 11 isolates. These 11
representative isolates were selected on from different location/sampling pockets. The results of
amplification of coa gene has been shown in figure 5.1. The PCR products were categorized into
five classes on the basis of their molecular size on electrophoresis of agarose gel. The
approximately the product size was from 430 to 840 bp. But the majority of isolates having product
size 575 bp. In case of FnbA gene all the strains having same product size 1150 bp on agarose gel.
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Figure 5.1. Agarose gel electrophoresis of coa gene PCR amplification products. 100 bp DNA ladder, lane 1-2: 540 bp, lane 3,6: 550 bp, lane 4-5,10: 525 bp, lane 7: 430 bp and lane 9: 840.
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Figure 5.2 Agarose gel electrophoresis of FnbA gene PCR amplification products. 100 bp plus DNA ladder, lane 1-10: 1150 bp.
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Phylogenetic tree of coa gene of S. aureus isolates/strains from Pakistan and different
geographical locations
Coagulase gene from S. aureus strains were amplified and PCR products of 430 to 840 bp
were confirmed on agarose gel. PCR products were sequenced and nucleotide sequences were
compared with other coagulase gene sequences in the GenBank. Phylogenetic tree was constructed
by aligning coagulase gene sequences of the present study isolates with selected coagulase gene
sequences in the GenBank. Phylogenic tree of all Pakistani (n=11) sequences was constructed
separately (Figure 5.3) and then combined with all other sequences (n=9) in the NCBI GenBank
database. Phylogenetic tree showed that all Pakistani isolates were grouped together in two clades
with high bootstrap values showing high genetic relatedness with some isolates from Japan
(GenBank accession numbers AB373752 and AB373753), while some isolates from India
(JX240355) and Taiwan (CP003603 and CP003166) were relatively distantly placed as compared
to above mentioned Japanize isolates. Isolates from Germany (AJ306908), UK (FN433596 and
BX571856) and USA (CP006044) were placed distantly as compared to isolates from Japan, India
and Taiwan (Figure 5.4).
Phylogenetic tree of fnbA gene of S. aureus isolates/strains from Pakistan and different
geographical locations
The isolated sequence was compared with other fnbA gene sequences found in NCBI
GenBank. PCR product size was approximately 1150bp and phylogenetic tree was constructed by
aligning fnbA gene sequences with fnbA gene sequences found in GenBank. Phylogenic tree of all
Pakistani (n= 7) sequences was constructed separately (Figure. 5.5) and combined with all other
sequences founded from NCBI GenBank (n=10). Phylogenetic tree showed that all Pakistani
isolates were grouped together in one clades with high bootstrap values showing closeness with
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isolates from Switzerland (AM07599 and AM076025) and Ireland (AM749008 and AM749014)
while isolates from Thailand (JN848748 and JN848745) and USA (JF809640 and JF809661) were
placed distantly (Figure 5.6).
Pairwise similarities and divergence among substitutions of Coagulase gene
Table 5.3 shown the similarities and divergence among Pakistani and NCBI reported
strains from the world. All the Pakistani strains of coagulase gene were 99.98-100% similar while
their divergence was 0.02%. The Japanizes strains were close to Pakistan strains and their
similarity and divergence was 99.97% and 0.03%, respectively. The Pakistani strains were 99.93%
similar and 0.07% divergent from Indian and German strains. Similarly, the Pakistani strains were
99.94% similar and 0.06% were divergent from the UK and Taiwan reported strains.
Pairwise similarities and divergence among substitutions of FnbA
In table 5.4 the similarities and divergence among Pakistani and NCBI reported strains has
been shown. All the Pakistani strains of FnbA were 99.96-100% similar while their divergence
was 0.04%. The Switzerland strains were close to Pakistan strains and their similarity and
divergence was 97.1% and 2.9%, respectively. The Pakistani strains were 96-97.2% similar and
2.8-3.2% divergent from strains reported from Ireland. The Pakistani strains were 91.3-91.8%
similar and 8.2-8.7% were divergent from Thailand and USA reported strains.
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Figure 5.3. Coa Phylogenetic tree (MEGA6.1, NJ method with 1000 bootstrap value) showing
evolutionary relationship among all Pakistani strains.
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Figure 5.4. Phylogenetic tree (MEGA6.1, NJ method with 1000 bootstrap value), based on coagulase gene sequences, showing evolutionary relationship of Pakistani strains/isolates with selected reference strains from different geographical locations. Pakistani strains/isolates have been indicated with closed triangles.
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Figure 5.5. Fibronectin Binding Protein A, Phylogenetic tree (MEGA6.1, NJ method with 1000 bootstrap value) showing evolutionary relationship among all Pakistani strains.
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Figure 5.6. Phylogenetic tree (MEGA6.1, NJ method with 1000 bootstrap value), based on
FnbA gene sequences, showing evolutionary relationship of Pakistani strains/isolates with selected reference strains from different geographical locations. Pakistani strains/isolates have been indicated with closed triangles.
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Table 5.1. Coa Pairwise genetic distance among all Pakistani strains.
S. No.
Name of isolates 1 2 3 4 5 6 7 8 9 10 11
1 S.aureus/coa/76/LH(Pak) 0.00 0.00 0.00 0.01 0.01 0.01 0.01 0.01 0.01 0.01
2 S.aureus/coa/79/LH(Pak) 0.00 0.00 0.00 0.01 0.01 0.01 0.01 0.01 0.01 0.01
3 S.aureus/coa/83/LH(Pak) 0.00 0.00 0.00 0.01 0.01 0.01 0.01 0.01 0.01 0.01
4 S.aureus/Coa/66/BM(Pak) 0.00 0.00 0.00 0.01 0.01 0.01 0.01 0.01 0.01 0.01
5 S.aureus/coa/65/LH(Pak) 0.02 0.02 0.02 0.01 0.00 0.00 0.00 0.00 0.00 0.00
6 S.aureus/coa/75/LH(Pak) 0.02 0.02 0.02 0.01 0.00 0.00 0.00 0.00 0.00 0.00
7 S.aureus/coa/80/LH(Pak) 0.02 0.02 0.02 0.01 0.00 0.00 0.00 0.00 0.00 0.00
8 S.aureus/coa/32/BM(Pak) 0.02 0.02 0.02 0.01 0.00 0.00 0.00 0.00 0.00 0.00
9 S.aureus/coa/41/LH(Pak) 0.01 0.01 0.01 0.02 0.00 0.00 0.00 0.00 0.00 0.00
10 S.aureus/coa/44/LH(Pak) 0.01 0.01 0.01 0.02 0.00 0.00 0.00 0.00 0.00 0.00
11 S.aureus/coa/39/LH(Pak) 0.02 0.02 0.02 0.01 0.00 0.00 0.00 0.00 0.00 0.00
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Table 5.2. FnbA Pairwise genetic distance among all Pakistani strains
S. No. Name of isolates 1 2 3 4 5 6 7
1 S.aureus/FnbA /76/LH(Pak) 0.00 0.00 0.00 0.00 0.00 0.01
2 S.aureus/FnbA /32/BM(Pak) 0.00 0.00 0.00 0.00 0.00 0.01
3 S.aureusFnbA /23/BM(Pak) 0.00 0.00 0.00 0.00 0.00 0.01
4 S.aureus/FnbA /65/LH(Pak) 0.00 0.00 0.00 0.00 0.00 0.01
5 S.aureus/FnbA /67/LH(Pak) 0.00 0.00 0.00 0.00 0.00 0.01
6 S.aureus/FnbA /79/LH(Pak) 0.00 0.00 0.00 0.00 0.00 0.01
7 S.aureus/FnbA /66/BM(Pak) 0.04 0.04 0.04 0.04 0.04 0.04
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Table 5.3. Pairwise genetic distance relationship between isolated strains and some reference strains based on coagulase gene sequence.
S. No.
Name of isolates 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19
1 S.aureus/coa/76/LH(Pak)
0.00
0.00
0.00
0.01
0.01
0.01
0.01
0.01
0.01
0.01
0.01
0.01
0.02
0.02
0.02
0.02
0.02
0.02
2 S.aureus/coa/79/LH(Pak)
0.00
0.00
0.00
0.01
0.01
0.01
0.01
0.01
0.01
0.01
0.01
0.01
0.02
0.02
0.02
0.02
0.02
0.02
3 S.aureus/coa/83/LH(Pak)
0.00
0.00
0.00
0.01
0.01
0.01
0.01
0.01
0.01
0.01
0.01
0.01
0.02
0.02
0.02
0.02
0.02
0.02
4 S.aureus/Coa/66/BM(Pak)
0.00
0.00
0.00
0.01
0.01
0.01
0.01
0.01
0.01
0.01
0.01
0.01
0.02
0.02
0.02
0.02
0.02
0.02
5 S.aureus/coa/65/LH(Pak)
0.02
0.02
0.02
0.01
0.00
0.00
0.00
0.00
0.00
0.00
0.01
0.01
0.02
0.02
0.01
0.01
0.02
0.02
6 S.aureus/coa/75/LH(Pak)
0.02
0.02
0.02
0.01
0.00
0.00
0.00
0.00
0.00
0.00
0.01
0.01
0.02
0.02
0.01
0.01
0.02
0.02
7 S.aureus/coa/80/LH(Pak)
0.02
0.02
0.02
0.01
0.00
0.00
0.00
0.00
0.00
0.00
0.01
0.01
0.02
0.02
0.01
0.01
0.02
0.02
8 S.aureus/coa/32/BM(Pak)
0.02
0.02
0.02
0.01
0.00
0.00
0.00
0.00
0.00
0.00
0.01
0.01
0.02
0.02
0.01
0.01
0.02
0.02
9 S.aureus/coa/41/LH(Pak)
0.01
0.01
0.01
0.02
0.00
0.00
0.00
0.00
0.00
0.00
0.01
0.01
0.02
0.02
0.01
0.01
0.02
0.02
10 S.aureus/coa/44/LH(Pak)
0.01
0.01
0.01
0.02
0.00
0.00
0.00
0.00
0.00
0.00
0.01
0.01
0.02
0.02
0.01
0.01
0.02
0.02
11 S.aureus/coa/39/LH(Pak)
0.02
0.02
0.02
0.01
0.00
0.00
0.00
0.00
0.00
0.00
0.01
0.01
0.02
0.02
0.01
0.01
0.02
0.02
12 S.aureus/coa/Japan(AB373752)
0.03
0.03
0.03
0.02
0.02
0.02
0.02
0.02
0.02
0.02
0.02
0.00
0.01
0.02
0.01
0.01
0.01
0.02
13 S.aureus/coa/Japan(AB373753)
0.03
0.03
0.03
0.02
0.02
0.02
0.02
0.02
0.02
0.02
0.02
0.00
0.01
0.02
0.01
0.01
0.01
0.02
14 S.aureus/coa/India(JX240355)
0.07
0.07
0.07
0.07
0.06
0.06
0.06
0.06
0.05
0.05
0.06
0.05
0.05
0.03
0.01
0.01
0.02
0.03
15 S.aureus/coa/UK(FN433596)
0.06
0.06
0.06
0.07
0.06
0.06
0.06
0.06
0.05
0.05
0.06
0.07
0.07
0.11
0.03
0.03
0.02
0.00
16 S.aureus/coa/Taiwan(CP003603)
0.06
0.06
0.06
0.05
0.04
0.04
0.04
0.04
0.04
0.04
0.04
0.03
0.03
0.02
0.10
0.00
0.02
0.03
17 S.aureus/coa/Taiwan(CP003166)
0.06
0.06
0.06
0.05
0.04
0.04
0.04
0.04
0.04
0.04
0.04
0.03
0.03
0.02
0.10
0.00
0.02
0.03
18 S.aureus/coa/Germany(AJ306908)
0.07
0.07
0.07
0.07
0.07
0.07
0.07
0.07
0.07
0.07
0.07
0.05
0.05
0.09
0.07
0.08
0.08
0.02
19 S.aureus/coa/UK(BX571856) 0.0
6 0.0
6 0.0
6 0.0
7 0.0
6 0.0
6 0.0
6 0.0
6 0.0
5 0.0
5 0.0
6 0.0
7 0.0
7 0.1
1 0.0
0 0.1
0 0.1
0 0.0
7 The number of base substitutions per site from averaging over all sequence pairs within each group is shown. The diagonal bold faced numbers show the mean inter populational evolutionary diversity estimates.
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Table 5.4. Pairwise genetic distance relationship between isolated strains and some reference strains based on fibronectin binding protein A.
S.
No. Name of isolates 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17
1 S.aureus/FnbA /76/LH(Pak) 0.00 0.00 0.00 0.00 0.00 0.01 0.02 0.02 0.02 0.02 0.02 0.04 0.04 0.04 0.04 0.04 2 S.aureus/FnbA /32/BM(Pak) 0.00 0.00 0.00 0.00 0.00 0.01 0.02 0.02 0.02 0.02 0.02 0.04 0.04 0.04 0.04 0.04 3 S.aureusFnbA /23/BM(Pak) 0.00 0.00 0.00 0.00 0.00 0.01 0.02 0.02 0.02 0.02 0.02 0.04 0.04 0.04 0.04 0.04 4 S.aureus/FnbA /65/LH(Pak) 0.00 0.00 0.00 0.00 0.00 0.01 0.02 0.02 0.02 0.02 0.02 0.04 0.04 0.04 0.04 0.04 5 S.aureus/FnbA /67/LH(Pak) 0.00 0.00 0.00 0.00 0.00 0.01 0.02 0.02 0.02 0.02 0.02 0.04 0.04 0.04 0.04 0.04 6 S.aureus/FnbA /79/LH(Pak) 0.00 0.00 0.00 0.00 0.00 0.01 0.02 0.02 0.02 0.02 0.02 0.04 0.04 0.04 0.04 0.04 7 S.aureus/FnbA /66/BM(Pak) 0.04 0.04 0.04 0.04 0.04 0.04 0.02 0.02 0.02 0.02 0.02 0.04 0.04 0.04 0.04 0.04 8 S.aureus/FnbA /Switerland(AM07599) 0.29 0.29 0.29 0.29 0.29 0.29 0.29 0.00 0.00 0.02 0.02 0.04 0.04 0.04 0.04 0.04 9 S.aureus/FnbA /Switerland(AM076025) 0.29 0.29 0.29 0.29 0.29 0.29 0.29 0.01 0.00 0.02 0.02 0.04 0.04 0.04 0.04 0.04
10 S.aureus/FnbA /Switerland(AM076007) 0.29 0.29 0.29 0.29 0.29 0.29 0.29 0.01 0.00 0.02 0.02 0.04 0.04 0.04 0.04 0.04 11 S.aureus/FnbA /Ireland(AM749008) 0.32 0.32 0.32 0.32 0.32 0.32 0.31 0.28 0.28 0.28 0.00 0.04 0.04 0.04 0.04 0.04 12 S.aureus/FnbA /Ireland(AM749014) 0.32 0.32 0.32 0.32 0.32 0.32 0.31 0.28 0.28 0.28 0.00 0.04 0.04 0.04 0.04 0.04 13 S.aureus/FnbA /USA(JF809633) 0.87 0.87 0.87 0.86 0.87 0.86 0.86 0.82 0.82 0.82 0.83 0.83 0.00 0.00 0.00 0.00 14 S.aureus/FnbA /USA(JF809640) 0.87 0.87 0.87 0.87 0.87 0.86 0.86 0.83 0.83 0.82 0.84 0.84 0.00 0.00 0.00 0.00 15 S.aureus/FnbA /USA(JF809661) 0.86 0.86 0.86 0.86 0.86 0.86 0.86 0.82 0.82 0.81 0.83 0.83 0.00 0.01 0.00 0.00 16 S.aureus/FnbA /Thailand(JN848748) 0.87 0.87 0.87 0.86 0.87 0.86 0.86 0.82 0.82 0.82 0.83 0.83 0.00 0.01 0.00 0.00 17 S.aureus/FnbA /Thailand(JN848745) 0.87 0.87 0.87 0.86 0.87 0.86 0.86 0.82 0.82 0.82 0.83 0.83 0.00 0.01 0.00 0.00
The number of base substitutions per site from averaging over all sequence pairs within each group is shown. The diagonal bold faced numbers show the mean inter populational evolutionary diversity estimates.
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DISCUSSION
Mastitis is common in dairy herds around the globe. It leads to economic losses and is a
serious threat to animal and public health. Udder infection with Staphylococcus aureus considered
to be the leading cause. Mastitis can be minimized by investigation of particular pathogens and
their virulence factors involved in pathogenesis. The molecular characterization of pathogens is an
essential part to track the spread of contagious infections from one region to others or among dairy
herds (Khan et al. 2013). With the development of molecular techniques and their application, now
it is possible to differentiate between pathogenic and nonpathogenic strains of S. aureus.
Staphylococcus is a normal inhabitant of the skin and nails. The isolation of Staphylococcus aureus
from milk alone is unequivocal to determine its role in the pathogenesis. S. aureus virulent gene
surveillance could be helpful in detecting genetic diversity among these major mastitis causing
pathogens. In the present study the identification of virulent strains coagulase and fibronectin
binding protein A were targeted. Coagulase enzyme activity is the principle criteria for diagnosis
of S. aureus from other coagulase negative Staphylococcus because coagulase can convert
fibrinogen to fibrin.
In S. aureus identification, coagulase production (coagulase test) has been considered as
an important criteria for phenotypic identification (Upadhyay et al. 2012; Gharib et al. 2013). In
molecular investigation coagulase gene amplification has been considered as a more accurate
method for Staphylococcus aureus typing. But in case of molecular identification, the presence of
coagulase gene is highly polymorphic and does not give similar amplicons in amplification. This
amplicon difference in coagulase gene size is due to that 3’ end contains a series of 81bp tandem
repeats and number of which may differ between strains (Upadhyay et al. 2012: Goh et al. 1992).
Coagulase gene consists of three distinct regions: (i) the N-terminus containing the prothrombin-
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binding site, (ii) a central region which is highly conserved, and (iii) a C-terminal region, each
encoding 27-amino acid residues (Janwithayanuchit et al. 2006).
The present study showed that prevalence of coagulase positive S. aureus was quite
common in both localities studied (i.e. Lahore and Bhimber) and molecular characterization of S.
aureus coa gene showed genetic variation. Similarly, prevalence of S. aureus mastitis in buffaloes
is of great concern in Asian countries and these animals are major contributor to the milk industry
(Aires-de-Sousa et al. 2007; El- Jakee et al. 2010). Present study agreed with previous study that
PCR amplifications of coa gene, revealing extensive polymorphism with predominance of one or
more of coa gene amplified products responsible for mastitis in buffaloes (Sindhu et al. 2010). The
phenotypic and genotypic variation was observed in some of the cases. These observations are
supported by previous reports as a mutation in the coding sequence or a plasmid number (Kumar
et al. 2010). Virulence factor diversity and their various combinations might cause changes in the
level of pathogenicity, and spreading of infections within and between animals (Fournier et al.
2008; Kumar et al. 2010). The end region of coa gene differs among S. aureus isolates, both in
their number and in location (Goh et al. 1992), so the coagulase is an important feature used
worldwide for epidemiological investigations of S. aureus. It is also the easiest gene to analyze
polymorphism and generates multiple distinct polymorphism patterns.
The present study results showed heterogeneity in the coa gene of S. aureus strains in
Pakistan and it was in accordance with the heterogeneity reported elsewhere in other strains of S.
aureus (Aarestrup et al. 1995; Khan et al. 2013; Momtaz et al. 2011; Su et al. 2000). Less variation
in coa gene of S. aureus was found in the present study, which agrees with Mork et al. (2005) that
small number of closely related genotypes of S. aureus are responsible for mastitis in a locality.
The coagulase gene is polymorphic and genetically variable and this polymorphism is due to multi
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allelic forms at the 3' end of the gene, which differs in their sequence and restriction sites (Wisal
et al. 2005). The PCR amplicons variation in size of coagulase gene could be due to polymorphism
among different isolates obtained from different herds and previous studies have also confirmed
PCR product variation using molecular analysis of the coagulase gene (Kalorey et al. 2007;
Reinoso et al. 2008; Khan et al. 2013); however, the reason of this polymorphism is still unknown
(Saei et al. 2009). Present study agreed with the previous study conducted by Khan et al. (2013)
in Pakistan that this polymorphism may be due to mutations by which different nucleotides are
inserted or deleted particularly in the 3´ end the coagulase gene. The different coa gene products
and their polymorphism for Staphylococcus aureus and it showed great genotypic variability
among the organisms (Sanjiv et al. (2008).
In the present study, coagulase strains produced five types of amplicon (430, 525, 540, 550
and 840 bp) and only one was dominant (525bp). These five types of amplicons are in accordance
with findings of Sanjiv et al. (2008) reported that a single coa genotype was dominant from 5
genotypes and PCR amplification produced 400, 500, 600, 900 and 1000-bp amlicons with 600-
bp being the most common in a geographical region. In the present study, PCR product size ranged
from 430 to 840 bp which is close in size from PCR product variation (500 to 580 bp) reported by
Hookey (1998), confirming the polymorphic nature of coagulase gene found in different strains
of S. aureus. In 2004, similarly finding were observed by Salasia et al. in Germany and amplicons
of 510, 600, 680, 740, or 850 bp size, but only one was dominant.
Previous studies suggested that mastitis is caused by S. aureus strains harboring more than
one coa genotype and that only 1 or 2 genotypes were dominated (Aslantas et al. 2007; da Silva
and da Silva, 2005; Nashwa et al. 2011). Momtaz et al. (2011) suggested that mastitis in cattle is
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caused by certain strains of S. aureus, mostly carrying a coagulase gene, and this information might
be helpful for control and management of mastitis caused by S. aureus.
Fibronectin Binding Protein A
In the present study, the molecular characterization of Staphylococcus aureus fnbA gene
shows genetic variation and can be helpful in the reduction of mastitis and control of this disease.
Some virulent factors are accountable for the adhesion and studies showed that the rate of infection
by fnbA genes is 100% (Nashev et al. 2004). Fibronectin binding proteins play an important role
in virulence action of Staphylococcus aureus infection (Foster and Hook, 1998; Aricola et al. 2005).
FnbA genes 99% were detected by Mishaan et al. (2005) from orthopedic infections while in
another study rate of fnbA gene infection was 76.1% (Zmantar et al. 2008). The genetic component,
namely fnbA, is responsible for both clinical and subclinical mastitis. Moreover, the distribution
of pathogenic characteristics is equally responsible for maintaining mastitis and this information
provides clues for control of such harmful bacterial strains. (Kumar et al. 2011). The variability in
phenotypic and genotypic patterns may be due to the different sites in which the Staphylococcus
aureus is isolated such as clinical and subclinical mastitis milk.
In the present study, PCR product size was 1150bp which is close to 1279bp (Yapar and
Avkan, 2011) and 1280bp Kumer et al. 2011 and it was different in size (191bp) Kouidhi et al.
2010) and 128bp (Atshan et al. 2012) that confirming the polymorphic nature of fnbA gene found
in different strains of Staphylococcus aureus. The present study agreed with previous study
conducted by Kumar et al. (2010) that animals infected with harmful strains could be helpful in
the culling and control of mastitis. It could be recommended from this studies that healthy
buffaloes must be milked first and those having mastitis milked at last or with a separate milking
unit as it is suggested by Voelk et al. (2014). Similarly, other additional management practices
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may be beneficial, such as treating or culling, biosecurity measures, wearing gloves, fore stripping,
teat cleaning, and post milking teat disinfection.
The present study results showed heterogeneity in Staphylococcus aureus strains of
Pakistan based on fnbA gene sequence and is an important factor in controlling human and bovine
Staphylococcus aureus infections. This heterogeneity could cause mutations in gene of S. aureus.
Similarly, heterologous expression of fnbA gene of Staphylococcus aureus has been reported by
Que et al. (2001). Almost all strains of Staphylococcus aureus have fibronectin-binding proteins
A encoded by fnbA gene (Jonsson et al. 1991). The evidence for the virulent nature of fnbA gene
had been demonstrated by Kuypers and Proctor (1989). Staphylococcus aureus fnbA gene is the
key factor for pathogenesis and because it can form biofilm and adhesion to host (Kouidhi et al.
2010; Palmqvist et al. 2005). Adhesion formation is considered as a major virulence factor
(Vaudaux et al. 1990).
It is concluded from present study that sequence analysis of virulent genes of S. aureus is
very important for epidemiological investigation of outbreak (mastitis). S. aureus isolates showed
genetic diversity in their virulent genes, but only a few gene variants were predominant. The
present study also revealed that the strain variation of S. aureus could be occurring within and
between herds and also between different locations.
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CHAPTER 6 SUMMARY
Mastitis is one of the commonest problem in dairy herds; responsible for toll of economic
losses. The etiology is complex and considered to be the outcome of the interaction of various
factors associated with the host, pathogens and the environment. The present study was carried out
in two districts with different ecology i.e. Lahore and Bhimber. In the present study, prevalence of
mastitis, its risk factors, S. aureus (most common pathogen of mastitis), antibiotic sensitivity and
virulent factor coagulase and Fibronectin binding protein A were focused.
A cross sectional study was carried out between January to December 2012 to estimate the
prevalence of mastitis and to investigate various epidemiological risk factors. A total of 1036
buffaloes was examined for mastitis. Of the population studied, the animals examined in district
Lahore were 598 buffaloes belonging to 25 herds, while the remaining 438 were from 25 herds
maintained in Bhimber district. The overall prevalence of mastitis was recorded 49%. The
prevalence of mastitis in Lahore was 55.5%, while in district Bhimber it was 40.2%. Among
mastitis cases the prevalence of clinical mastitis was 10.2% as a whole. However, the prevalence
of clinical mastitis in district Lahore was 11.8%, whereas it was 8% in district Bhimber. The
overall prevalence of subclinical mastitis was 38.8%. The district wise prevalence of subclinical
mastitis was 43.6% and 32.2% in districts of Lahore and Bhimber, respectively. The overall
prevalence of mastitis was 40.2%, 46.5% and 52.6% in small, medium and large herds,
respectively. The quarter level prevalence was recorded as 16.20% (673/4144 quarters from 1036
animals). The district wise prevalence of mastitis at quarter level was recorded 18.17% in district
Lahore while it was 12.87% in district Bhimber. The buffaloes having mastitis in one quarter, two
quarters, three quarters and four quarters were 78.5%, 12%, 8% and 1.5%, respectively. The
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SUMMARY
prevalence of mastitis was increased as the age of buffaloes increased. The prevalence of mastitis
was highest in Nili Ravi 52.2% as compared to Kundhi and non-descriptive 40% and 44.7%,
respectively.
In Univariable analysis: area, herd size, age, breed, parity, stage of lactation, reproductive
disorders, udder shape, previous exposure to mastitis, ease of milking, udder edema, lesion on
udder/teat, swelling on udder/teat, condition of floor, frequency of dung removal, exposure to
FMD, udder wash, teat dipping, milking techniques and tick infestation were significantly
associated (𝑃𝑃 < 0.25) with a prevalence of mastitis. These 20 significant variables were further
selected for multivariable analysis to estimate the independence of the effect of the variables. The
final models identified were area, age, breed, parity, stage of lactation, udder shape, ease of milking,
previous exposure to mastitis, udder edema, lesions on udder/teat, exposure to FMD, teat dipping
and tick infestation were significantly associated (p< 0.05) with a prevalence of mastitis.
A total of 673 mastitic quarter milk samples from different buffalo quarters were collected
from different livestock farms having 106 and 567 clinical and subclinical mastitis, respectively.
These milk samples were subjected to microbiological examination. From these milk samples, 236
isolates were confirmed as coagulase positive S. aureus. The sensitivity of gentamycin,
oxytetracycline, erythromycin, kanamycin, chloramphenicol, tylosin, ciprofloxacin. doxycycline,
amoxicillin, streptomycin and trimethoprim to S. aureus was 80.1%, 75.4%, 74.6%, 73.3%,
72.4%, 71.6%, 69.9%, 69.1%, 63.2%, 56% and 54.7%, respectively. While on the other hand the
resistant pattern of gentamycin, oxytetracycline, erythromycin, kanamycin, chloramphenicol,
tylosin, ciprofloxacin, doxycycline, amoxicillin, streptomycin and trimethoprim was 11%, 19.9%,
15.3%, 20.8%, 20.8%, 28.4%, 22.9%, 17.3%, 36.8%, 34.3% and 45.3%, respectively.
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SUMMARY
The identification of virulence factors such as the coa and fnbA is necessary for minimizing
and control strategies of mastitis. The virulent genes were amplified by using gene specific primers.
In case of coa gene the PCR amplicon products were categorized into five classes on the basis of
their molecular size on electrophoresis of agarose gel. Approximately the product size was from
430 to 840 bp. But, the majority of isolates were having product size 575 bp. In case of fnbA gene
all the strains having same product size 1150 bp on agarose gel. The PCR products were sent to
Australian Genome Research Facility Ltd, University of Adelaide for sequencing. In phylogenetic
analysis it revealed that the coa gene of S. aureus strains, isolated were grouped in two clades
which were closely related to S. aureus isolates from Japan, India and Taiwan, while S. aureus
isolates from Germany, UK and Canada were distantly related. These findings will be helpful in
future for mastitis control strategies. In case of fnbA gene sequences showed, that all Pakistani
isolates were grouped in one clades with high boot strap values showing closeness with isolates
from Switzerland and Ireland. While isolates from Thailand and USA were placed distantly.
The pairwise distance of coa showed that similarities and divergence showed that all the
Pakistani strains of coagulase gene were 99.98-100% similar while their divergence was 0.02%.
The Japanizes strains were close to Pakistan strains and their similarity and divergence was 99.97%
and 0.03%, respectively. The Pakistani strains were 99.93% similar and 0.07% divergent from
Indian and German strains. Similarly, Pakistani strains were 99.94% similar and 0.06% were
divergent from the UK and Taiwan reported strains. The pairwise distance of fnbA showed that
similarities and divergence showed that all the Pakistani strains of fnbA were 99.96-100% similar
while their divergence was 0.04%. The Switzerland strains were close to Pakistan strains and their
similarity and divergence was 97.1% and 2.9%, respectively. The Pakistani strains were 96-97.2%
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SUMMARY
similar and 2.8-3.2% divergent from strains reported from Ireland. The Pakistani strains were 91.3-
91.8% similar and 8.2-8.7% were divergent from Thailand and USA reported strains.
Mastitis can be minimized by improving the management and animal related these
potential risk factors. Screening of lactating buffaloes should be done on a regular basis. Pre and
post teat dipping is recommended. Wear the gloves or hand wash before and after milking. The
mastitis treatment should be started after antibiotic sensitivity and select the appropriate antibiotic.
These molecular information of virulent genes of S. aureus could be helpful in the control of
mastitis and development of vaccines.
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