bio 328 immunology phagocytosis and intracellular killing
TRANSCRIPT
Bio 328 Immunology
Phagocytosis and Intracellular killing
PHAGOCYTOSIS.
Professional phagocytes:
- Neutrophils (PMN, microphages)
- Monocytes/macrophages (mononuclear phagocytes).
Neutrophil
Monocyte
Niels Borregaard (1997)
PHAGOCYTOSIS.
Chemotaxis:
- Chemoattractants:
fMLP chemokines
anaphylatoxins
PAF, Leukotriene B4
- Extravasation.
Rolling, adhesion, diapedesis, migration.
PHAGOCYTOSIS.
- Recognition (opsonization)
- Ingestion
- Killing
phagolysosome fusion
O2 burst
- Digestion
Innate, active host defenses
Soluble defenses
Cellular defenses
Initiation adaptive immune
response
http://www.youtube.com/watch?v=fpOxgAU5fFQ
Brown GD (2006) Dectin-1: a signalling non-TLR pattern-recognition receptorNat Rev Immu 6: 33–43 doi:10.1038/nri1745
Methods of pathogen recognition by pattern-recognition receptors (PRRs).
Griffin FM, Griffin JA, Leider JE and Silverstein SC (1975) J. Exp. Med. Figure 3.
Griffin FM, Griffin JA, Leider JE and Silverstein SC (1975) J. Exp. Med. Figure 3.
PHAGOCYTOSIS.
Oxygen burst: increased
- consumption of oxygen
- consumption of glucose
- production of superoxide anion, hydrogen peroxide, hydroxyl anion
- production of CO2
- production of lactic acid
- production of bleach
Results: Bone marrow derived murine neutrophil Respiratory burst
Eric Campbell, 2010.
Increased consumption
Increased production
OxygenGlucose
LactateCO2
ROPBleach
NADPH+H+
NADP+
Glucose
6 CO2 MPO
Lysosome
O2
O2- H2O2
Pathogen
Oxygen burstneutrophils
OxidaseHMS
gp91p22
Cytb558
gp91
p22gp91 p22
Rac-2
GTP
Rac-2
GTPp67
p67
P67NOXA
p47
p47
P47NOXO
P
P
Rac-2
GDP
+PNADP+NADPH+H+
GEF
O2 O2-
MembraneHeme
HemeHeme
NOX-Organizer
NOX-Activator
Nitric oxide synthase
Possible oxidant-generating reactions of stimulated PMNs
Monoxygenase IReduction of one O2,
one O in hydroxyarginine,one O in water
Monoxygenase IIReduction of one O2
one O in NO,one O in water
2x 4 electrons required to reduce 2 O2 are derived from: NH3 NO (5 electrons) and
1.5 NADPH+H+ 1.5 NADP+ (3 electrons)
L-arginine + O2 + NADPH+H+ NO + L-citruline + NADP+
Ribbon diagram of human defensin. Numbers indicate the position of the cysteine residues; disulphide bonds are shown in yellow.
The defensin dimer is stabilized by multiple hydrogen bonds and hydrophobic interactions at the monomer-monomer interface. The top of the dimer is polar; the base is apolar.
Rat peritoneal neutrophils, which often contain ringed nuclei are stained (antibody) for the presence of defensins. Defensins (blue) are present in the cytoplasm and have a granular distribution.
Neutrophil extracellular traps: an additional antibacterial weapon.
Nature Reviews Immunology 9, 364-375 (May 2009)
Shigella flexneri entrapped by NETs.
Shigella flexneri entrapped by NETs.
Pseudomonas aeruginosa entrapped by mast cell extracellular traps.
Pseudomonas aeruginosa entrapped by mast cell extracellular traps.
PHAGOCYTOSIS.
Deficiencies:
- Chronic Granulomatous Disease
- G6PD-deficiencies
- Chediak-Higashi syndrome
- Leukocyte adhesion deficiency
- Neutrophil specific granule Deficiency
- Myeloperoxidase deficiency
Results: CGD mouse bone marrow neutrophil Respiratory burst
(Eric Campbell, 2010)
Chediak Higashi Syndrome: defect in LYST, lysosomal trafficking regulator
Leukocyte adhesion defect type 1 presenting with recurrent pyoderma gangrenosum
Father and daughter with autosomal dominant (AD) hyperimmunoglobulin E syndrome (HIES). Note the father's distinctive facies with prominent forehead, deep-set eyes, broad nasal bridge, and wide interalar distance.
Mother and son with autosomal dominant (AD) hyperimmunoglobulin E syndrome (HIES). Note the mother's distinctive facies. She had a history of multiple deep-seated abscesses that took months to heal after incision and drainage.
Hyperimmunoglobulin E or Job’s Syndrome: Defect in IL-17 secretion.
The End