L30: Allergy and Hypersensitivity

Question 1

Hypersensitivity

Answer 1

Adaptive immune response which occurs in an inappropriate or exaggerated way, resulting in tissue damage of some other detrimental response in the host

Question 2

Type 1 Hypersensitivity

Answer 2

Immediate hypersensitivity. Antigens (allergens) often environmental. IgE and mast cells are central mediators, end results ranges from discomfort to death.

Question 3

Anaphylactic reactions

Answer 3

1. Rapid response (2-30mins)
2. Due to interaction of antigen with IgE associated with surface of Mast cells and basophils
3. Activates either to cause production of effectors responsible for various types of anaphylaxis
4. Vary in extent and severity
5. Systemic reaction termed anaphylactic shock - affects breathing and blood pressure
6. Localised reactions less severe - hay fever, hives, asthma

Question 4

Type 1 Hypersensitivity Mechanisms (5)

Answer 4

1. Exposure
2. Antigen presentation
3. Activation of Th2 helper cells
4. IgE production
5. Binding of IgE to mast cells

Question 5

Type 1 Hypersensitivity mechanisms in GIT, Airways and Blood Vessels

Answer 5

GIT: increase fluid secretion and peristalsis - expulsion of GIT contents
Airways: decrease diameter, increase mucous secretion - congestion and blockage of airways; swelling and mucus secretion in nasal passages
BV: increase blood flow and permeability - increase fluid in tissues = increase flow of lymph to LN, increase cells and protein in tissues and effector responses in tissues.

Question 6

Degranulation of mast cells (3)

Answer 6

1. Chemoattractants: e.g. cytokines
2. Activators: e.g. histamine
3. Spasmogens: e.g. histamine, leukotrienes and prostaglandinds

Question 7

Type 2 Hypersensitivity

Answer 7

Anitbody dependent cytotoxic hypersensitivity. Occurs when antibodies bind to either self antigens (cell surface and ECM) or foreign antigens on cells. Cell death occurs from phagocytosis, NK cell activity or complement-mediated lysis. Pathology occurs when destruction of the tissues leads to illness in the host.

Question 8

Examples of Type 2 reactions (3)

Answer 8

1. Reactions against blood cells and platelets (transfusion reactions, haemolytic disease of the newborn, certain drug reactions)
2. Reactions against tissue antigens (Myasthenia Gravis)
3. Hyperacute graft rejection (from a few minutes to 48h after transplantation)

Question 9

Five major blood groups involved in transfusion reactions (5)

Answer 9

1. ABO
2. Rhesus
3. Kell
4. Duffy
5. MN

Question 10

ABO blood group reactivities (genotypes, antigens on RBCs and antibodies in serum)

Answer 10

A: AA, AO; A; anti-B
B: BB, BO; B; anti-A
AB: AB, A and B; none
O: OO, H, anti-A & anti-B

Question 11

Universal donor/recipient

Answer 11

Donor: The RBCs of O donors have no A, B or Rh antigens therefore can be accepted by any person
Recipient: The serum of AB+ patients contain no antibodies to A, B or Rh antigens, therefore they can accept RBC from any person.

Question 12

Haemolytic disease of the newborn (HDNB):

Answer 12

Erythroblastosis fetalis, occurs when Rh- mother bears an Rh+ child, usually only occurs on second and subsequent pregnancy, antibodies made by pregnant women cross placenta and react with foetal RBCs. Rh+ antigens don’t cross over into the mother in the first birth, but after they are exposed to Rh antigens and develop a sensitisation response. If the mother has a subsequent pregnancy, she has a primed response to the Rh antigens. The maternal antibodies can cross the placenta and lyse the foetal RBCs. To prevent this, the mother can be injected with anti-Rh antibodies after the first birth to eliminate any Rh+ cells and prevent sensitisation.

Question 13

Type 3 Hypersensitivity

Answer 13

Immune-complex (IC) disease: caused by the deposition of immune (IgG/IgM/Ag complement) complexes in blood vessels and tissues. Under appropriate conditions, IgG and soluble Ag can precipitate, causing large aggreagtes which activate platelets, neutrophils, mast cells and basophils.

Question 14

Types of Type 3 reactions (route of ag delivery, resulting disease and site of IC deposition)

Answer 14

1. Intravenous (high dose): vasculitis, nephritis, arthritis; blood vessel walls. renal glomeruli, joint spaces
2. Inhaled: farmer’s lung; alveolar/capillary interface
3. Subcutaneous: arthus reaction; perivascular area

Question 15

Immune complex process

Answer 15

ICs form every time an antibody encounters an antigen. In primates, CR1 receptors (bind C3b) on erythrocytes (RBCs) bind ICs that have fixed complement. ICs bound to RBCs are transported to liver and spleen for removal by fixed tissue macrophages. Larger complex are cleared most efficiently

Question 16

Issues with clearing IC

Answer 16

Clearance of RBC-bound ICs removes most of the active CR1 from circulation, therefore when IC formation is continuous, efficiency of IC clearance is impaired. Patients with low level of complement have poor binding of IC to RBH, thus there is reduced removal by the liver and spleen. Problems arise when uncleared ICs deposit in blood vessels and other tissues.

Question 17

Examples of IC disease:

Answer 17

1. Serum sickness
2. Post-streptococcal glomerulonephritis
3. Rheumatoid arthriris
4. Farmer and Pigeon Fancier’s lung
5. Arthus reacton

Question 18

Serum sickness

Answer 18

Occurs when foreign serum proteins are introduced. Long-lasting nature of serum proteins results in prolonger Ab production and formation of ICs. ICs deposit in the kidneys, blood vessels and joints causing arthritis, nephritis and vasculitis. Symptoms disappear when ICs cleared.

Question 19

Type 4 (Cell mediated) reactions

Answer 19

Takes longer - delayed type hypersensitivity. Delay is due to the time required for T cells to migrate and accumulate at site of reaction. Delayed type hypersensitivities are due to TD cells. Cytokines attract macrophages and initiate tissue damage

Question 20

Contact hypersensitivity

Answer 20

Contact dermatitis. Antigen are simple chemicals (haptens) like nickle, plant material, soaps and cosmetics, initial contact sensitises while second contact leads to erythema, itching etc. within 12-48hr

Question 21

Central role of Th1 cell in DTH (4)

Answer 21

Antigen is processed by tissue macrophages and stimulates Th1 cells:

1. Chemokines: recruit macrophages to site of antigen deposition
2. IFN-y: induces expression of vascular adhesion molecules, activates macrophages, increasing release of inflammatory mediators
3. TNFa/b: cause local tissue destruction, increases expression of adhesion molecules on local blood vessels
4. IL-3/GM-CSF: stimulate monocyte production by bone marrow stem cells

Question 22

Stages of DTH reaction

Answer 22

1. Ag uptake, processing and presentation by APC
2. TH1 effector cell recognises antigen and releases cytokines which act on vascular endothelium
3. Recruitment of phagocytes and inflammatory cells

Question 23

Granulomatous hypersensitivity

Answer 23

Occurs in lungs in response to microbacterium tuberculosis. TB lives intracellularly in macrophages, inducing a granuloma response. A typical granuloma has a core of epitheloid cells and macrophages. Centre may be necrotic as in TB. Core is surrounded by cuff of lymphocytes and there may be fibrosis.

Question 24

General mechanism of DTH

Answer 24

1. Contact-sensitising agent penetrates the skin and binds to self protein taken up by Langerhan cells
2. Langerhan cells present self-pepides haptenated with contact-sensitising agents to Th1 cells which secrete IFN-y and other cytokines
3. Activated keratinocytes secrete cytokines such as IL-1 and TNF-a and chemokines such as CXCL8 (IL8), CXC11 (IP-9) and CXCL9 (Mig)
4. Products of keratinocytes and Th1 cells activate macrophages to secrete mediators of inflammation