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Florida State University Libraries
Honors Theses The Division of Undergraduate Studies
2012
The Effects of Nicotine on NeurotrophicFactor Expression in the Adult Male ZebraFinchJessica Peoples
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Abstract: (Nicotine, Zebra Finch, Brain-Derived Neurotrophic Factor)
This thesis examines the effects of nicotine on the expression of Brain-
Derived Neurotrophic Factor (BDNF) in the brain of adult male zebra
finches (Taeniopygia guttata) under isolated and social housing
conditions. BDNF, which is essential for survival, growth, and
neuroplasticity of neurons, is significantly decreased in patients with
affective disorders, such as depression and schizophrenia. A significant
number of these patients use tobacco products, which induce an increase
in plasma BDNF levels. Isolated rodents exposed to nicotine showed an
increase in central BDNF levels. The zebra finch is an established model
to study cognitive functioning, and as such we examined how nicotine
interacts with BDNF expression in zebra finch brain areas involved in
cognitive functioning such as the song nuclei and the hippocampal area.
Adult male zebra finches were exposed to nicotine and the expression of
BDNF was examined between isolated and social housed male zebra
finches, using immunocytochemistry. The results show that the housing
conditions did not have an effect on the expression of BDNF in the
examined song nuclei or the hippocampal area. However, nicotine
induced an increased expression of BDNF in the song nuclei HVC, RA
(Robust Nucleus of the Archistriatum), and Area X. The HVC and RA
contain nicotinic acetylcholinergic receptors, which could explain our
finding. Area X is involved in song learning, which is not applicable to
our animals, as adult animals have a crystallized pattern. The results
could be explained by the fact that Area X might be under direct control
of the HVC.
THE FLORIDA STATE UNIVERSITY
COLLEGE OF ARTS & SCIENCES
THE EFFECTS OF NICOTINE ON NEUTROTROPHIC FACTOR
EXPRESSION IN THE ADULT MALE ZEBRA FINCH
BY
JESSICA PEOPLES
An Honors Thesis submitted to the Department of Chemistry & Biochemistry in
partial fulfillment of the requirements for graduation with Honors in the Major
Degree Awarded:
Spring Semester, 2012
The members of the Defense Committee approve the thesis of Jessica Peoples defended on April
6, 2012.
__________________________
Dr. Susanne Cappendijk
Thesis Director
__________________________
Dr. Brian Miller
Committee Member
__________________________
Dr. Kenneth Knappenberger Jr
Committee Member
Acknowledgments
I would like to acknowledge the Committee members, Dr. Susanne Cappendijk, Dr. Kenneth
Knappenberger, and Dr. Brian Miller, for all their help and guidance. Also, I would like to thank
other members of the Cappendijk Lab; Will Perry, Monica Rodriguez, Chris Jones, Jessica
Andrews, Melanie Rucci, Kirsten Brown, Jordan Burdick, and David Alarcon. I would also like
to acknowledge all my family for all the support they have provided through the years.
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Table of Contents
Chapters Page
I. Background of the Study……………………………………………………………..2
II. Hypothesis of the Study………………………………………………………………7
III. Aim of the Study……………………………………………………………………...8
IV. Materials and Methods………………………………………………………………..9
a. Animals and Treatment Conditions……………………………………….9
b. Housing Conditions……………………………………………………….11
c. Tissue Preparation, Storage, and Analysis………………………………..12
V. Results………………………………………………………………………………...17
VI. Conclusions…………………………………………………………………………...27
VII. Future Studies……………………………………………………………………......29
VIII. References………………………………………………………………………......30
Addendum………………………………………………………………………………..33
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I. Background of the Study
Neurotrophic factors are small proteins essential for the functioning, survival, and
nourishment of neurons. There are three families of neurotrophic factors, Brain Derived
Neurotropic factor (BDNF, Figure 1), Glial Derived Neurotropic factor (GDNF), and Tumor
Necrosis factor-alpha (TNF-α), which are all found in the central nervous system, and BDNF
is shown to be reduced in socially isolated laboratory animals (Akutagawa and Konishi,
1998).
Figure 1: Brain Derived Neurotrophic Factor:
Space Filling Model (left) and Ribbon Diagram (right)
People suffering from affective disorders, such as depression and schizophrenia, demonstrate
lower levels of neurotropic factors, including BDNF, in the hippocampus, the prefrontal
cortex, and the amygdala (Dwivedi et al., 2003; Hing et al., 2012). It has been shown that
people suffering from affective disorders, such as schizophrenia, and mood disorders, often
use tobacco products (Buckley et al., 2011; Kalman et al., 2005; Ray et al., 2011). Nicotine
(Figure 2) is highly used by these patients because it enhances their focus and cognitive
functioning. According to the Centers of Disease Control and Prevention (CDC), 29% of
smokers are more likely to experience daily depression symptoms as compared to 19% of
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non-smokers (CDC, 2011). Also, according to the National Institute on Drug Abuse, 41% of
respondents from a national survey with mental illnesses are smokers, and the smoking rate
for schizophrenia patients is as high as 90% (NIDA, 2010).
In the cholinergic nervous system pathway, acetylcholine is the neurotransmitter that is
synthesized, stored and released by cholinergic neurons. The key molecules that transduce
the acetylcholine message are the cholinergic muscarinic and neuronal nicotinic
acetylcholine receptors (nAChRs, Figure 3) (Gotti et al., 2004). Nicotine, which mimics
acetylcholine, acts on a variety of peripheral and centrally located nicotinic acetylcholine
receptors, and induces effects of several brain functions depending on the subtype of the
receptor with which it interacts as well as the localization of the targeted nAChR subtypes
(Hogg et al., 2004; Picciotto et al., 2001). The nAChR’s expression is altered during
development and aging as well as in diseases and disorders such as Attention-Deficit /
Hyperactivity Disorder (ADHD), depression, schizophrenia, Alzheimer’s Disease, autism,
Parkinson’s Disease, Lewy Body Dementia, and at least one form of familial epilepsy (Potter
et al., 2006; Quik et al., 2007; Singh et al., 2004; Steinlein, 2004).
There are currently 16 different types of homomeric and heteromeric nAChRs. Three
receptor subtypes that are abundantly present in the brain are the α-4, α-6, and α-7 subunits
(Wu and Lukas, 2011). The α-7 receptor is of particular interest in the Cappendijk lab
because it is found in the Hippocampal Area (HA) and Robust Nucleus of the Archistriatum
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(RA) of the zebra finch (Cappendijk personal observations, Lovell et al., 2008, Salgado-
Commissariat et al., 2004) and involved in cognitive functioning (Levin et al., 2002).
Figure 2: Nicotine Molecule (University of Delaware) Figure 3: Heteropentameric and Homopentameric Nicotinic
Acetylcholine Receptors (nAChRs)
The male zebra finch (Taeniopygia guttata) is the animal model used in the Cappendijk Lab.
Song birds, such as the zebra finch, have the sexually dimorphic ability to learn vocal
behavior, which is reflected in the brain. The male brain contains a well delineated song
system, in contrast to the female brain usually has absent or diminished song related nuclei.
The neural song system is a series of anatomically distinct nuclei in the thalamus, basal
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ganglia, and cortex that are dedicated to the production and plasticity of song (Jarvis and
Nottebohm, 1997). The HVC provides major input into the anterior vocal pathway through
the activation of the Area X, which then has an output to the Dorsolateral Nucleus of the
Medial Hypothalamus (DLM). The DLM directs output to the Lateral Magnocellular Nucleus
of the Anterior Neostriatum (LMAN) which in its turn affects the RA.
Thus the RA, which is located in the posterior vocal pathway, receives input from both the
HVC and the LMAN. The RA gives a signal to nXII (nucleus XII), which connects to the
syrinx. The posterior pathway is directly involved in the song production, while the anterior
pathway is indirectly involved through the LMAN-RA connections. The anterior vocal
pathway is mainly involved in song acquisition and maintenance of the song pattern. These
described pathways are shown in Figure 6.
The zebra finch passes through the stages of song development only once in life. Once the
song learning period is completed at 3 months, the song is fixed, or crystallized, for life. The
HVC is a potential site where auditory feedback signals could interact with song motor
commands. However, when that feedback is disturbed, the spectral and temporal features of
the crystallized song change (Nordeen and Nordeen, 1992; Leonardo and Konishi, 1999;
Hough and Volman, 2002; Roy and Mooney, 2007). We have shown that, exposure to
nicotine affects the vocalization pattern in adult male zebra finches (Cappendijk et al., 2010).
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There is evidence that although expression is low, adult male zebra finches express BDNF
(Brain-Derived Neurotrophic Factor) in the nuclei of both the anterior and posterior vocal
pathways (Akutagawa and Konishi, 1998). Exposure to a social environment could stimulate
the expression of BDNF and other neurotrophic factors. In elderly people, BDNF levels
increased significantly after socialization and exercise (Coelho et al., 2011). Therefore, we
speculate that socially housed male zebra finches will express high levels of BDNF, but
isolated males will experience an increase in BDNF expression once exposed to nicotine.
Currently, it is not clear how nicotine interacts with neurotrophic factors within the zebra
finch. To examine the effects of nicotine on the neurotrophic factor, BDNF, within the male
zebra finch, immunocytochemistry assays were performed.
Figure 4: Immunocytochemistry (Leica Microsystems, 2011) Figure 5: 3, 3’-Diaminobenzidine (Sigma-Aldrich)
Immunocytochemistry (Figure 4) involves the interaction between a specific antigen, primary
antibodies, and secondary antibodies. The antigen (1), in our case BDNF, is bound by the
primary antibody, BDNF antibody (2), which is then also bound by the secondary antibody,
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Biotinylated anti-goat IgG (3). This secondary antibody will bind a specific enzyme, Avidin
Biotin Complex (4), which when exposed to its substrate, in this case 3, 3’-
Diaminobenzidine (DAB, Figure 5), induces a brown colored stain, and identifies a cell as
positive for BDNF presence.
II. Hypothesis of the Study
Chronic exposure to nicotine increases the expression of BDNF mRNA in the hippocampus
of rats (Kenny et al., 2000). In humans, exposure to nicotine increases plasma BDNF levels,
especially in patients suffering from neurodegenerative disorders such as schizophrenia
(Zhang et al., 2010). Plasma levels of BDNF were also shown to be elevated in socially
active elderly women. These subjects were considered active in respect to their living
environment and participated in exercise programs (Coelho et al., 2011).
In respect to BDNF expression in the zebra finch, it is known that the expression of BDNF in
the song system is inversely correlated with the age of the animals. BDNF is implied to play
a role in song learning and memory of young male zebra finches (Akutagawa and Konishi,
1998). Cappendijk et al., (2010) demonstrated that nicotine affects the song production in
the adult male zebra finches. Currently there is no knowledge about the effect of nicotine on
BDNF expression in the adult male zebra finches.
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Based upon these previous reports, I hypothesize that the expression of BDNF in nuclei of
the song system and in the hippocampal area of a social housed zebra finch will show a
higher expression of BDNF when compared with an individual housed animal. In addition, I
hypothesize that nicotine will increase the expression of BDNF in the song nuclei; HVC,
Area X, LMAN, and RA, and the Hippocampal Area of the adult male zebra finch.
III. Aim of Study
Study the effects of nicotine on BDNF expression in the song nuclei and the Hippocampal
Area of the adult male zebra finch under isolated and social housing conditions. The HVC,
which is part of both the anterior and the posterior pathways, will be examined. In addition,
song nuclei which are part of the anterior vocal pathway; Area X and the LMAN, and the
RA, which is part of the posterior vocal pathway, will be examined (Figure 6).
Figure 6: Parasagittal section of the adult male zebra finch Figure 7: Adult male zebra finch brain after ICC.
brain. D= dorsal, V= ventral, P= posterior, and A=anterior.
black arrows represent the anterior vocal pathway and grey
arrows represent the posterior vocal pathway.
HVC
LMAN
Area X
RA
Hippocampal Area
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IV. Materials & Methods
a. Animals and Treatment Conditions
A total of 32 adult male zebra finches (bodyweight 12-15 gram) were tested. The animals
were randomly divided into two groups: 16 were housed in recording cages (single
housed) and 16 were housed in aviary room (social housed) (see Table 1). The animals
were tested for a total of 90 days.
After a 5 day treatment with saline (0.03ml/10g body weight, s.c., twice a day), in which
the animals were habituated to handling and to the injection procedure, the animals were
randomly divided into two equal groups. One group received the nicotine treatment (0.18
mg/kg, s.c., twice a day), which corresponds to a human intake of 8-10 cigarettes per day.
The other group received the control treatment, referred to as the saline-treated group.
During the saline pretreatment and the nicotine treatment, each animal was injected twice
a day at 7am and 7pm. Each animal was sacrificed using an overdose of Equithesin (0.06
mL/10 g body weight, i.m.) about seventy-five days after the last drug administration.
The tissue was first harvested and then flash frozen with 2-methylbutyrate and stored at
-20˚C until further analysis.
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Table 1: Animal Housing and Treatment Housing Nicotine‐treated Saline‐treated Single Housed Recording Room
1, 2, 7, 8, 10, 11, 15, 16 3, 4, 5, 6, 9, 12, 13, 14
Group Housed Aviary Room, 4 birds/cage
3‐1, 3‐2, 3‐3, 3‐4, 4‐1, 4‐2, 4‐3, 4‐4
1‐1, 1‐2, 1‐3, 1‐4, 2‐1, 2‐2, 2‐3, 2‐4
The following animals were excluded from tissue analysis:
1. Single housed animals: The brain tissue of #6 (saline) broke into pieces during the
flash freeze procedure with 2-methylbutyrate. Animal #10 (nicotine) died during the
course of the experiment after the nicotine treatment was finished. Animals #15
(nicotine) and #16 (nicotine) were considered irreversibly stressed and were removed
from the ongoing experiment.
2. Group housed animals: Animal #1-1 (saline) was found dead during the
experiment. The stored tissue of animals #1-2 (saline), 1-3 (saline), and 4-1 (nicotine)
broke into pieces during preparations for cutting. Animal #1-4 (saline) was found
dead near the conclusion of the experiment. Animal #4-2 (nicotine) was isolated with
an injured leg, and was removed from the analysis as a potential inflammation might
affect the expression of neurotrophic factors (Cho et al., 1997; Tarsa et al., 2010).
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b. Housing Conditions
Single and social housed animals were both kept in rooms on the basement floor of the
Research Building of the College of Medicine (Room 180E, 180C, respectively).The
rooms were kept at 80˚C ±2˚C under a 14L/10D regimen (lights on at 8:00am). Both
single and social housing cages contained food/water trays and were lined with paper.
Food and water was available ad libitum during the whole length of the experiment and
was changed on a daily basis.
1. Single housing: The single housed cages, in our laboratory referred to as the
recording cages, measure 10.5”L x 13.0”W x 16.3”H (26.7cm x 33.0cm x 41.4cm,
see Figure 8). These cages contain sensors located on the food and water trays, as
well as on the upper and lower perches to record locomotor activity. Song recordings
were taken on a daily basis from 8:00am-2:00pm, when no entrance of personnel was
allowed. The Cappendijk lab has the exclusive use of 16 recording cages.
2. Social housing: The social housed cages measured 15.0”L x 30.0”W x 17.0”H
(38.1cm x 76.2cm x 43.2cm, see Figure 9). Four social cages were used, each holding
four animals.
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Figure 8: Single Housing Recording Cage Figure 9: Social Housing Cage
c. Tissue Preparation, Storage, and Analysis
We proposed in our preliminary version of this Honors Thesis to use free-floating
sections. However, this free-floating ICC technique was not performed because we found
that, although the tissue was stored in an anti-freeze solution, the tissue was denatured
while stored in the refrigerator until use. Therefore, we switched to a fixed tissue
procedure.
1. Immunocytochemistry (ICC): In this paragraph the different steps to perform
the ICC are explained. This protocol requires two consecutive days to be
completed and is performed at room temperature.
a. Day 1: 0.25% H2O2 Solution, 5% Normal Goat Serum, and Antibody Serum
solutions are prepared and stored in the refrigerator. Brain tissue is removed
from the -20˚C freezer and briefly placed on dry ice to keep the tissue cold.
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Each brain is placed on a flat surface, and divided with a sharp razor blade in
the parasagittal plane. Then, one half of each brain tissue specimen was cut on
a cryostat at 30µm in the parasagittal direction.
1. The tissue cut on the cryostat is immediately transferred onto slides. The
slides are then placed on a Roto-mix (Figure 10). Each animal has two
separate slides: one control and one antibody. The control slides are used to
visualize a baseline expression of BDNF.
2. Rinse slides in Xylene for 1x5’.
3. Rinse slides in 100% EtOH for 1x5’.
4. Rinse slides in 95% & 80% EtOH for 1x3’ each.
5. Rinse slides in dH2O for 1x3’.
6. Treat slides with 0.25% H2O2 for 1.5’. Roto-mix must be turned off during
this time to prevent the rupturing of cells.
7. Turn Roto-mix on and rinse slides 2x5’ with 0.02M Phosphate Buffer
Solution (PBS).
8. Pre-incubate slides in 5% Normal Goat Serum for 20’.
During this time, prepare humidifying chambers using foil, petri dishes (2
large and 2 small), water, and paper towels (Figure 11).
9. Incubate slides in antibody serum overnight in humidifying chambers on
Roto-mix. Primary incubation is done with 1.5mL of Antibody Serum plus
7.5µL of BDNF antibody for antibody slides and 1.5mL of Antibody
Serum for control slides.
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Figure 10: Slides during ICC Figure 11: Humidifying Chambers
b. Day 2: Biotinylated anti-goat IgG serum (1:200 dilution) prepared and stored
in refrigerator.
1. Remove dishes from humidifying chambers and replace excess antibody
and control serums into corresponding tubes. If collected correctly, serums
can be re-used for up to 4 weeks. Slides remain on Roto-mix.
2. Rinse slides in 0.02M PBS for 2x5’.
3. Incubate slides in Biotinylated anti-goat IgG serum for 30’.
Avidin Biotin Complex (ABC) Reagent prepared and mixed on Roto-mix
for 30-60’ before storage in refrigerator.
4. Rinse slides in 0.02M PBS for 2x5’.
5. Incubate slides in ABC Reagent for 30’.
DAB + H2O2 prepared and stored in refrigerator.
6. Rinse slides in 0.02M PBS for 2x5’.
7. Turn lights off in the room, and re-cover dishes with foil.
Lights must be turned off because DAB stain is light sensitive.
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8. Incubate slides in DAB + H2O2 until sections appear rusty brown.
The incubation period range can vary from 1 minute to 12 hours or
overnight, if necessary.
9. Once staining is sufficient, rinse slides in dH2O for 5’ to stop the staining
reaction.
c. Thionin Counterstain: The Thionin counterstain is used as a contrast stain in
order to better visualize cells with primary stain.
1. Slides should remain shielded from light throughout the counterstaining
protocol.
2. Place slides in slide holder, and refresh all EtOH and dH2O tubs.
3. Dehydrate slides in 70% & 95% EtOH for 30 seconds.
4. Dehydrate slides in 100% EtOH for 2x30seconds (2 different tubs).
5. Soak slides in Xylene in hood for 5’.
6. Let slides dry in hood for 10’.
7. Soak slides in dH2O for 8’.
8. Stain slides in Thionin for 2’.
9. Rinse slides in dH2O to remove excess stain.
10. Soak in 70% EtOH + ~1mL Glacial Acetic Acid.
Start with 30 seconds and increase exposure time for lighter stain, if
necessary.
11. Dehydrate slides in 70% EtOH for 30 seconds.
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12. Dehydrate slides in 95% and 100% EtOH for 2x30 seconds each (2
different tubs).
13. Place slides in Xylene I for 30 seconds.
14. Place slides in Xylene II for 30 seconds.
Do not remove slides from Xylene II to prevent sections from drying out.
15. Coverslip with Permount one slide at a time.
16. Let slides dry overnight. Make sure they are shielded from light.
17. After slides are dry, morphological analysis of the tissue takes place
using a Leica DM5500B (Figure 12).
2. Brain Tissue Analysis: Analysis was performed using all slides. Each individual
section was sketched, and the areas of interest were outlined. For tissue to be
counted with labeling, at least one half of all sections on one slide had to display
labeling for area of interest. So for example, if a slide contained 8 sections at least
4 sections needed to show labeling in a specific area to be analyzed. Then, an
outline was made, and areas of interest were defined as labeled or non-labeled.
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Figure 12: Leica DM5500B
V. Results
During the test-runs with practice tissue, I was running into some technical problems while
performing the ICC, which I will describe in this paragraph. I needed to solve these problems
first, before I was able to perform a reliable ICC on brain tissue isolated from the single and
social housed animals.
a. Free-floating Immunocytochemistry
A free-floating ICC method was proposed to be used to analyze the tissue. With the
free-floating method, tissue was cut in the parasagittal direction at 30µm using a
cryostat. The tissue was then placed in 12-well plates with a 1% sodium
azide/antifreeze solution and stored at 4˚C. This protocol was first described by
Watson et al., (1986), and adapted by Lucas and Lee, (2009). We received the
protocol directly from Dr. Lee’s Lab. The first few ICC’s performed proved the
presence of BDNF labeling in the brain tissue. However, only limited amounts and
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sections of tissue could be mounted to slides due to holes present in the tissue. It was
hypothesized that the tissue must either be deteriorating while in storage or tearing
during the ICC protocol.
Problem-solved solution: To test this hypothesis, a 4.5 hour PBS wash was
performed, and tissue was immediately mounted to slides and stained with Thionin.
The PBS wash produced the same results as previous ICC’s; therefore, it was
concluded that the tissue must be deteriorating while in the storage solution. It was
then decided to change the ICC protocol to one in which the tissue is immediately
transferred to slides before the performance of the ICC, which we refer to as a fixed
tissue ICC.
b. Fixed Tissue ICC
The fixed tissue ICC protocol was not originally used because there were some
previous episodes that tissue would fall off the slides. We hypothesized that this
could be due to performing ICC’s at room temperature on frozen tissue. Also, the
fixed tissue protocol was not originally used because this Honors Thesis project
required a large volume of tissue to be simultaneously labeled, and the optimal
method to accomplish this goal would be using free-floating method. To our surprise
when we performed our first fixed tissue ICC, multiple large holes were present in the
tissue. We hypothesized that the H2O2 treatment was the culprit, and the damage to
the tissue was caused by a H2O2 concentration that was either too high and/or the
treatment was too long.
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Problem-solved Solution: Immediately after cutting, tissue was analyzed by
Immunocytochemistry (ICC). A total run of 7 ICC’s were performed, testing different
concentrations and different exposure times of H2O2.
Table 2: H2O2 Treatment Trials
Trial # Date [H2O2] (%) Time (min)
1a 11/16/11 1 7.5
1b 11/16/11 0.5 15
2 11/29/11 0.5 10
3 12/5/11 0.5 5
4 1/5/12 0.25 5
5* 1/11/12 0.25 3.5
6 1/23/12 0.25 3.5
7 1/30/12 0.25 1.5
*Trial #5 was repeated because slides were ruined by personnel from another lab while using the hood.
Acclimation steps using Xylenes, a series of alcohols (100%, 95%, & 80%), and
dH2O was included in the protocol at the beginning of Day 1 to help the tissue remain
on the slides. A total run of 7 ICC’s were performed using 1%, 0.5% and 0.25% H2O2
in 0.02M PBS for 15, 5, 3.5, and 1.5 minutes in various combinations to find the most
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ideal concentration and exposure time with H2O2 that did not induce tissue damage.
Table 2 illustrates the series of ICC test trials. For each trial, a minimum of 4 days
was needed to perform the protocol, stain the tissue with Thionin, allow slides to dry,
and analyze the tissue with the microscope.
Conclusion: Based upon these trials, it was concluded to perform the future ICC’s
exposing the tissue to a 0.25% H2O2 in 0.02M PBS solution for 1.5 minutes.
c. Analysis of Experimental Groups of BDNF Expression
The expression of BDNF of the anterior and posterior vocal pathways and the
Hippocampal Area was analyzed and the intensity of BDNF labeling was compared
within each male zebra finch, between nicotine and saline male zebra finches, and
between the isolated and social groups. When comparing the brain areas of interest,
the total male zebra finches analyzed were: 11 single, 9 social, 11 nicotine, 9 saline,
20 BDNF and control. The total male zebra finches for the BDNF intensity were 12
single, 10 social, 11 nicotine, 11 saline, 22 BDNF and control. While cutting with the
cryostat, some saline tissue appeared to have dried out and shrunken while stored at -
20˚C. Animals #14 and #2-4 were so dry that they could not be analyzed for the
nuclei of the vocal pathways or the Hippocampal Area. However, BDNF intensity
was still included for these two specimens.
The order in which the tissue was cut and analyzed is shown in Table 3.
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Table 3: ICC Analysis
ICC # Date Animal #’s
1 2/6/12 3, 7
2 2/9/12 2-1, 3-3
3 2/13/12 8, 9
4 2/15/12 2-3, 3-4
5 2/17/12 11, 12
6 2/20/12 2-4, 4-4
7 2/22/12 1, 13
8 2/24/12 2-2, 3-1
9 2/29/12 2, 4, 14
10 3/2/12 5, 3-2, 4-3
.
1. Effect of Housing Conditions on BDNF Expression
For isolated and socially housed zebra finches, the HVC, LMAN, RA, and Area X
song nuclei and the Hippocampal Area were analyzed for BDNF expression. In
addition, the overall intensity of BDNF labeling was analyzed. The ranking of
high, medium, or low was used for the overall intensity of BDNF. A total of 11
single animals and 9 social animals were analyzed for the BDNF expression. A
total of 12 single animals and 10 social animals were analyzed for the overall
BDNF intensity.
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Figure13: BDNF expression in the HVC of single and social Figure 14: BDNF expression in the Hippocampal Area of single
groups. and social groups.
Figure 15: BDNF expression in the RA of single and social groups. Figure 16: BDNF expression in Area X of single and social groups.
Figure 17: Isolated Male Zebra Finch #9 (2,000x in Area X). Figure 18: Social Male Zebra Finch #4-4 (2,000x in Area X).
Black bar corresponds to 100µm. Black bar corresponds to 100µm.
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Figure 19: BDNF expression in the LMAN of single and social Figure 20: Overall intensity of BDNF expression between single
groups. and social groups.
Conclusion: The song nuclei located in the anterior and/or posterior pathway and
the Hippocampal Area showed no significant difference in BDNF expression
between isolated and social housed male zebra finches. The labeling intensity of
most of isolated and social animals fell within the medium to low range. It was
concluded that the housing conditions of the animals does not affect the
expression of BDNF in any of the brain areas examined.
2. Effect of Drug Treatment on BDNF Expression
The HVC, LMAN, RA and Area X song nuclei and the Hippocampal Area were
analyzed for BDNF expression. The overall intensity of BDNF expression was
analyzed in the same manner as the housing conditions analysis. A total of 11
nicotine animals and 9 saline animals were analyzed for BDNF expression. A
total of 11 nicotine and 11 saline animals were analyzed for the overall BDNF
intensity. As stated earlier, we expected animals exposed to nicotine would have
an increased expression of BDNF in both the song nuclei and the Hippocampal
Area.
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Figure 21: BDNF expression in the HVC of nicotine and saline Figure 22: BDNF expression in the Hippocampal Area of nicotine
treatments. and saline treatments.
Figure 23: BDNF expression in the RA of nicotine and saline Figure 24: BDNF expression in Area X of nicotine and saline
treatments. treatments.
Figure 25: BDNF expression in the LMAN of nicotine and saline Figure 26: Overall intensity of BDNF expression between nicotine
treatments. and saline treatments.
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Figure 27: Saline Male Zebra Finch #5 (2,000x in LMAN) Figure 28: Nicotine Male Zebra Finch #11 (2,000x in LMAN)
Black bar corresponds to 100µm. Black bar corresponds to 100µm.
Conclusion: Nicotine treatment increased BDNF expression in all the song nuclei,
with exception of the LMAN. In addition, in the Hippocampal Area no difference
was observed in BDNF expression between nicotine and saline treated animals.
3. BDNF versus Control Labeling of Brain Tissue
BDNF expression in the HVC, LMAN, RA, Area X, and the Hippocampal Area,
and the overall BDNF intensity were analyzed in the same manner as the housing
condition and drug treatment analysis. A total of 20 BDNF slides and 20 control
slides were analyzed for BDNF expression. A total of 22 BDNF slides and 22
control slides were analyzed for overall BDNF intensity. The control sections
were used to show the baseline expression of BDNF.
26 | P a g e
Figure 29: Male Zebra Finch #8Nicotine Control (125x) Figure 30: Male Zebra Finch #8 Nicotine BDNF (125x)
Black bar corresponds to 2mm. Black bar corresponds to 2 mm.
Figure 31: Male Zebra Finch #12 Saline Control (125x)\ Figure 32: Male Zebra Finch #12 Saline BDNF (125x)
Black bar corresponds to 2 mm. Black bar corresponds to 2 mm.
Conclusion: Labeling with BDNF antibody showed a more intense labeling of
brain tissue in both saline and nicotine exposed animals, which implies that the
labeling we observed in our animals is specific.
27 | P a g e
VI. Conclusions
a. Housing Conditions
We conclude that the isolated and social housing conditions did not have any effect
on the expression of BDNF. This is evident from the nearly equal amounts of adult
male zebra finches expressing BDNF in the nuclei of the anterior and the posterior
vocal pathways as well as in the Hippocampal Area. My hypothesis that zebra finches
housed under social conditions were expected to have a higher expression in song
nuclei and the Hippocampal Area proved not to be correct. A possible explanation
that my hypothesis was incorrect is that in a social environment male zebra finches
are not only exposed to other males, but they have visual contact with females. As
such, male zebra finches exhibit direct and indirect song while isolated zebra finches
only show indirect song. Based upon our results, we can conclude that BDNF
expression is not affected by direct song behavior. In addition, we would expect that
socially housed animals would vocalize more often and be more active compared to
isolated animals, and as such we would expect based on clinical findings that BDNF
expression would be elevated. We did not observe this which implies that BDNF
expression is not directly affected by housing conditions.
b. Drug Treatments
In conclusion, the significant differences in BDNF expression of nicotine compared
to saline animals in the HVC, RA, and Area X implies that nicotine increases the
28 | P a g e
BDNF expression. BDNF is a factor that is important for the growth, survival, and
neuroplasticity. Our findings suggest that nicotine acts as a neuroprotector in the
HVC, RA, and Area X. Earlier reports have shown that the HVC contains α-7
nicotinic receptors, which might explain our increased expression of BDNF measured
in this song nucleus. However, in the RA it was reported that nicotinic receptor
subtypes were present (Salgado-Commissariat et al., 2004), but this finding was not
confirmed by other groups. So it could be that another subtype of nAChR is present in
this nucleus, which does not affect BDNF expression.
Another explanation might be that adult male zebra finches have a crystallized song,
and as it is known that BDNF expression in the adult male zebra finch brain is low
compared to young animals, which are learning their song, so an increase in the
LMAN is not anticipated. This explanation also supports, on one hand, the finding
that in the Hippocampal Area no difference between nicotine and saline exposed
animals were observed. On the other hand, the Hippocampal Area also contains α-7
nAChRs, so if BDNF is activated through α-7 nAChR, similar as in the HVC, we
should have observed an effect on BDNF expression. This discrepancy could be due
to the role of other nAChRs that could be present in the Hippocampal Area and/or the
HVC. The increase of BDNF in both the RA and Area X could be due to a direct
effect of BDNF increased expression in the HVC, as in both nuclei no types of
nAChRs are demonstrated yet.
29 | P a g e
VII. Future Studies
In a follow-up study, we would like to examine the expression of the other neurotrophic
factors, GDNF and TNF-α, as due to unexpected technical issues we were not able to
perform these studies for this project.
As BDNF stimulates new neuron growth, we also would like to propose to expand the
time of observation following the end of administration of nicotine, and label the brain
tissue with Neuronal Nuclei (neuN), a vertebrate neuron-specific nuclear protein which
reacts with most neuronal cell types throughout the central and peripheral nervous
systems, and as such we could further examine the role of nicotine as a neuroprotector.
BDNF plays a role in the developing zebra finch, and is correlated to song expression.
We would like to examine the BDNF expression in juvenile animals learning their song
while exposed to nicotine. This experiment will further our understanding of the role of
nicotine in processes of learning and memory.
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24. Ray, M.T., Weickert, C.S., Wyatt, E., &Webster, M.J., (2011) Decreased BDNF, trkB-TK+
and GAD67 mRNA Expression in the Hippocampus of Individuals with Schizophrenia and
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25. Roy, A., Mooney, R., (2007) Auditory Plasticity in a Basal Ganglia-forebrain Pathway
during Decrystallization of Adult Birdsong. The Journal of Neuroscience 27, 6374-6387.
26. Salgado-Commissariat, D., Rosenfield, D.B., Helekar, S.A., (2004) Nicotine-Mediated
Plasticity in Robust Nucleus of the Archistriatum of the Adult Zebra Finch. Brain Research
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27. Singh, A., Potter, A., Newhouse, P., (2004) Nicotine Acetylcholine Receptor System and
Neuropsychiatric Disorders. IDrugs: The Investigational Drugs Journal 7, 1096-1103.
28. Steinlein, O.K., (2004) Nicotine Receptor Mutations in Human Epilepsy. Progress in Brain
Research 145, 275-285.
29. Tarsa, L., Balkowiec, E., Kratochvil, F.J., Jenkins, V.K., McLean, A., Brown, A.L., Smith,
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30. Watson, R.E., Wiegand, S.J., Clough, R.W., Hoffman, G.E., (1986) Use of Cryoprotectant
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Subtypes. Biochemical Pharmacology 82, 800-807.
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T.R., (2010) Nicotine Dependence and Serum BDNF Levels in Male Patients with
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IX. References for Images Figure 1: http://chronopause.com/index.php/2011/05/31/going-going-gone%E2%80%A6-
part-2/. 11 March 2012.
Figure 2: http://www.udel.edu/chem/white/C643/Quinine%20by%20Susan%20Lorenz/. 11
March 2012.
Figure 3: http://countyourculture.com/tag/receptor/. 11 March 2012.
Figure 4: http://www.leica-microsystems.com/science-lab/an-introduction-to-
immunohistochemistry-and-in-situ-hybridisation/. 17 March 2012.
Figure 5: http://www.sigmaaldrich.com/catalog/product/sial/d8001?lang=en®ion=US. 18
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Addendum
The following table discusses corrections made to the text; however, none of these corrections
changed the outcome of these experiments.
Page Correction
2 Add (Figure 2) following nicotine
3 Remove extra space in front of Attention (check if this due to indent lining)
Replace the word pentamers with subunits
4 Replace the word however….brain, with “ in contrast to the female brain
which”
5 Add a comma to the last sentence of the page after the word “that”
6 Remove the reference (Kenny et al., 2001)
Should …will be performed, not read “were performed”
7 Place a comma after “In humans,…..
9 Add after 8-10 cigarettes the words “per day”
10 &21 Animal 4-3 was used in the ICC, and did not die.
12 Add in the sentence “….stored in the refrigerator” the words “until use.”
Place a period after the last word on this page
14 There is an extra space between nr. 4 and 5, make sure that this removal does
not affect your page numbers for the big sections.
15 Under c, underline also the word Counterstain in the heading
17 Remove et al., from the reference from Lucas and Lee as they are only with
the two of them
20 When I count the analyzed animals, I have 10 nicotine animals in table 1,
check this number
23 Add in the conclusion after “…posterior pathway” the words “and the
Hippocampal Area”
27 Under section a, add “in” between as the Hippocampal Area so it reads “as
well as in the Hippocampal Area”
Last line of text replace implies with imply