7. Autoinflammatory and Autoimmune Diseases 1

Question 1

What is immunopathology?

Answer 1

Damage to the host caused by the immune response. Quite often the problems that occur after infection will actually be a result of the immune response rather than the pathogen itself (e.g. abscesses)

Question 2

What are fevers / malaise seen in primary EBV caused by? And what is the immune response?

Answer 2

Pathogen. Adaptive immune response - cytokine

Question 3

What are abscess formations caused by and what is the immune response?

Answer 3

Pathogen. Innate immune response - neutrophils

Question 4

What is sacroiliac joint inflammation in an individual with ankylosing spondylitis caused by and what is the immune response?

Answer 4

No obvious pathogen. Innate immune response - cytokines

Question 5

What is anaemia due to red cell haemolysis secondary to anti-red cell antibodies caused by and what is the immune response?

Answer 5

No obvious pathogen. Adaptive immune response - antibodies

Question 6

What does auto-inflammatory or autoimmune disease refer to?

Answer 6

Immunopathology in the absence of infection

Question 7

If the disease is driven by components of the innate immune system, what is it described as being?

Answer 7

Auto-inflammatory

Question 8

If the disease is driven by abnormalities in components of the adaptive immune response, what is it described as being?

Answer 8

Autoimmune

Question 9

If the diseases is driven by mixed innate/adaptive system, what is it described as being?

Answer 9

Mixed (auto-inflammatory and autoimmune)

Question 10

What occurs in auto-inflammatory diseases?

Answer 10

Local factors at sites predisposed to disease lead to activation of innate immune cells such as macrophages and neutrophils, which result in tissue damage.

Question 11

What occurs in autoimmune disease?

Answer 11

Aberrant T and B cell responses in primary and secondary lymphoid organs leads to breaking of tolerance with the development of immune-reactivity towards self-antigens. The adaptive immune response plays the predominant role in the clinical expression of disease. Organ-specific antibodies may be present for a long time before the diseases manifest.

Question 12

How does the spectrum of immunological disease vary?

Answer 12

This ranges from the monogenic auto-inflammatory diseases to the monogenic autoimmune diseases

Question 13

Which immunological diseases are more common, monogenic or polygenic?

Answer 13

Most polygenic diseases are pretty common

Question 14

What are examples of rare monogenic auto-inflammatory diseases?

Answer 14

Familial mediterranean fever, TRAPS

Question 15

What are examples of polygenic auto-inflammatory disease?

Answer 15

Crohns disease, UC, osteoarthritis, giant cell arteritis, Takayasu’s arteritis

Question 16

What are examples of mixed pattern diseases?

Answer 16

Ankylosing spondylitis, psoriatic arthritis, Behcet’s syndrome

Question 17

What are examples of polygenic auto-immune diseases?

Answer 17

Rheumatoid arthritis, Myasthenia Gravis, pernicious anaemia, Graves disease, systemic lupus erythematosus, primary biliary cirrhosis, ANCA associated vasculitis, Goodpasture disease

Question 18

What are examples of rare monogenic auto-immune diseases?

Answer 18

APS-1, APECED, ALPS, IPEX

Question 19

What causes monogenic auto-inflammatory disease?

Answer 19

Mutations in gene encoding a protein involved in a pathway associated with innate immune cell function. This often leads to abnormal signalling via key cytokine pathways involving TNF-alpha and/or IL1

Question 20

Which monogenic auto-inflammatory diseases are autosomal dominant?

Answer 20

Muckle Wells syndrome, familial cold auto-inflammatory syndrome, chronic infantile neurological cutaneous articular syndrome, TNF receptor associated periodic syndrome

Question 21

Which monogenic autoinflammatory diseases are autosomal recessive?

Answer 21

Hyper IgD with periodic fever syndrome and familial mediterranean fever

Question 22

What gene and protein is involved in Muckle Wells Syndrome?

Answer 22

Gene: NLRP3 gain of function. Protein: NALP3, cryopyrin

Question 23

What gene and protein is involved in familial cold auto-inflammatory syndrome?

Answer 23

Gene: NLRP3 gain of function. Protein: NALP3, cryopyrin

Question 24

What gene and protein is involved in chronic infantile neurological cutaneous articular syndrome?

Answer 24

Gene: NLRP3 gain of function. Protein: NALP3, cryopyrin

Question 25

What gene and protein is involved in TNF receptor associated periodic syndrome?

Answer 25

Gene: TNFRSF1. Protein: TNF receptor

Question 26

What gene and protein is involved in hyper IgD with periodic fever syndrome?

Answer 26

Gene: MK. Protein: mevalonate kinase

Question 27

What gene and protein is involved in familial mediterranean fever?

Answer 27

Gene: MEFV. Protein: Pyrin-Marenostrin

Question 28

Which three monogenic auto-inflammatory diseases involve a gain of function mutation in NLRP3 which encodes a protein called cryoprin, which is involved in the inflammatory pathway?

Answer 28

Muckle Wells syndrome, familial cold auto-inflammatory syndrome, chronic infantile neurological cutaneous articular syndrome

Question 29

Which monogenic autoinflammatory disease involves a mutation in MEFV which encodes Pyrin-Marenostrin which is a negative regulator of this inflammatory pathway?

Answer 29

Familial mediterranean fever

Question 30

What is the inflammasome complex pathway activated by?

Answer 30

The pathway is activated by toxins, pathogens and urate crystals

Question 31

Describe the inflammasome complex pathway

Answer 31

1. Pathway is activated by toxins, pathogens and urate crystals.
2. These act via cryoprin and ASC to activate procaspase 1.
3. The activation of procaspase 1 leads to production of IL1 and NFkappaB (which is a transcription factor that regulates the expression of genes including TNFalpha)

Question 32

What is a negative regulator of the inflammasome complex pathway?

Answer 32

Pyrin-Marenostrin

Question 33

So, in terms of the inflammasome complex pathway, what will mutation in cryopyrin lead to?

Answer 33

A gain of function mutation in cryopyrin will lead to more inflammation

Question 34

So, in terms of the inflammasome complex pathway, what will mutation in Pyrin-Marenostrin lead to?

Answer 34

A loss of function mutation in Pyrin-Marenostrin will lead to more inflammation

Question 35

What is the inheritance pattern of familial mediterranean fever?

Answer 35

Autosomal recessive

Question 36

What is Pyrin-Marenostrin mainly expressed by?

Answer 36

Pyrin-Marenostrin is mainly expressed by neutrophils

Question 37

What does a defective gene (e.g. in familial mediterranean fever) lead to?

Answer 37

Defective gene leads to failure to regulate cryopyrin driven activation of neutrophils

Question 38

What is the clinical presentation of familial mediterranean fever?

Answer 38

Periodic fevers lasting 48-96 hours associated with: abdominal pain due to peritonitis; chest pain due to pleurisy/pericarditis; arthritis; rash. Associated with long term risk of AA amyloidosis

Question 39

Familial mediterranean fever is associated with long-term risk of AA amyloidosis. What occurs in AA amyloidosis?

Answer 39

The liver produces serum amyloid A as an acute phase protein. Serum amyloid A then deposits in the kidneys, liver and spleen. Deposition in the kidneys is most problematic because it can lead to nephrotic syndrome and renal failure.

Question 40

What is the treatment for familial mediterranean fever?

Answer 40

Colchicine 500 mcg BD. If this doesn’t work then Anakinra and Etanercept.

Question 41

How does colchicine treat familial mediterranean fever?

Answer 41

Binds to tubulin in neutrophils and disrupts neutrophil functions including migration and chemokine secretion

Question 42

What should be given if colchicine does not work in familial mediterranean fever and why?

Answer 42

If this doesn’t work, then you should try and block the cytokines that are mediating this inflammatory response. Anakinra - IL1 receptor antagonist or Etanercept - TNF-alpha inhibitor

Question 43

What are monogenic autoimmune diseases caused by?

Answer 43

Caused by mutation in gene encoding a protein involved in a pathway associated with adaptive immune cell function

Question 44

What are three types of pathogenesis involved in monogenic autoimmune disease?

Answer 44

Abnormality in tolerance;

abnormality of regulatory T cells; abnormality of lymphocyte apoptosis

Question 45

What is APECED? And what type of disease is it?

Answer 45

Autoimmune polyendocrinopathy candidiasis ectodermal dystrophy syndrome - monogenic autoimmune disease

Question 46

What is the inheritance of pattern of APECED?

Answer 46

Autosomal recessive

Question 47

What is the defect in APECED?

Answer 47

Defect in autoimmune regulator (AIRE).

Question 48

What is AIRE?

Answer 48

Autoimmune regulator. This is a transcription factor that is vital in the development of T cell tolerance in the thymus. It upregulates the expression of self-antigens by thymic cells which T cells are selected against. It promotes the apoptosis of auto-reactive T cells.

Question 49

What does a defect in AIRE lead to?

Answer 49

Failure of central tolerance and the release of auto-reactive T cells

Question 50

What diseases can APECED cause?

Answer 50

This disease can cause multiple autoimmune conditions: hypoparathyroidism; Addison’s disease; hypothyrodism; diabetes mellitus; vitiligo; enteropathy. NOTE: top two are the most common. Patients are also predisposed to candidiasis

Question 51

Why are APECED patients at risk of candidiasis?

Answer 51

This is because they produce antibodies against cytokines (IL17 and IL22) which increases their risk of candidiasis infection

Question 52

What is IPEX?

Answer 52

Immune dysregulation, polyendocrinopathy, enteropathy, X-linked syndrome.

Question 53

What is IPEX caused by?

Answer 53

Caused by mutations in Foxp3 (Forkhead box p3)

Question 54

What gene is required for the development of Treg cells?

Answer 54

Foxp3

Question 55

What does the lack of Treg cells in IPEX mean?

Answer 55

The lack of Treg cells means that these patients fail to negatively regulate T cell responses, leading to autoantibody formation. These patients end up developing autoimmune diseases: enteropathy, diabetes mellitus, hypothyroidism, dermatitis.

Question 56

What is ALPS?

Answer 56

Autoimmune lymphoproliferative syndrome

Question 57

What is ALPS due to?

Answer 57

Due to mutations in TNFRSF6 gene which encodes FAS (involved in FAS pathway). Disease is heterogeneous depending on the mutation

Question 58

What does the FAS mutation in ALPS cause?

Answer 58

This causes a defect in apoptosis of lymphocytes. Which in turn causes a failure of tolerance (as autoreactive lymphocytes do not die by apoptosis) and there is failure of lymphocyte homeostasis (you keep on producing more and more lymphocytes)

Question 59

What is the clinical phenotype of ALPS?

Answer 59

High lymphocyte count; large spleen and large lymph nodes; autoimmune diseases; commonly autoimmune cytopaenias; lymphoma

Question 60

What causes polygenic auto-inflammatory disorders?

Answer 60

Mutations in genes encoding proteins involved in pathways associated with innate immune cell function. They also tend to be slightly localised. Local factors at predisposed sites can lead to activation of innate immune cells such as macrophages and neutrophils, with resulting tissue damage. As these diseases are mainly to do with the innate immune system, their HLA associations are less strong.

Question 61

What are polygenic auto-inflammatory disorders not characterised by?

Answer 61

In general, these diseases are NOT characterised by the presence of auto-antibodies

Question 62

How many chromosomal regions have been identified that are associated with susceptibility to develop Crohn’s disease?

Answer 62

Linkage analysis studies showed 8 identified chromosomal regions associated with susceptibility to develop Crohn’s disease. There are 10 loci.

Question 63

What is the best known chromosomal region associated with Crohn’s disease and what genes are associated with it?

Answer 63

Best known as IBD1 on chromosome 16. This gene has been identified as being NOD2 (or CARD-15 (caspase activating recruitment domain 15). Three mutations of this gene have been found to be associated with Crohn’s disease.

Question 64

What percentage of Crohn’s disease patients have mutations associated with Crohn’s disease?

Answer 64

NOD2 gene mutations are present in about 30% of patients (i.e. it is NOT a necessary mutation to develop Crohn’s)

Question 65

What is the increase in risk of Crohn’s disease due to NOD2?

Answer 65

Abnormal allele of NOD2 increases the risk of Crohn’s disease by: 1.5-3 x if ONE copy; 14-44 x if TWO copies

Question 66

NOD2/CARD-15 mutations are also seen in which other conditions apart from Crohn’s disease?

Answer 66

The same mutations are also found in patients with Blau syndrome and some forms of sarcoidosis

Question 67

Where is NOD2 expressed?

Answer 67

NOD2 is expressed in the cytoplasm of myeloid cells (macrophages, neutrophils and dendritic cells)

Question 68

What does NOD2 normally do?

Answer 68

It acts as a microbial sensor (recognises muramyl dipeptide)

Question 69

How is NOD2 associated with Crohn’s disease?

Answer 69

The precise mechanism by which this causes Crohn’s is UNKNOWN, however it has been suggested that this mutation affects the capacity of cells in the gut to sense intracellular microbes which then leads to an abnormal inflammatory response.

Question 70

What are the combination of factors that lead to the development of Crohn’s disease?

Answer 70

Abnormal NOD2/CARD15, environmental factors (microbes), and other genetic influences. This leads to expression of pro-inflammatory cytokines/chemokines; leukocyte recruitment; release of proteases, free radicals

Question 71

What can you see on histology of Crohn’s disease?

Answer 71

Focal inflammation in/around crypts, formation of granulomata and tissue damage with mucosal ulceration

Question 72

What are clinical features of Crohn’s disease?

Answer 72

Abdominal pain and tenderness; diarrhoea (blood, pus and mucus); fever; malaise

Question 73

What is the treatment for Crohn’s disease?

Answer 73

Corticosteroids, azathioprine, anti-TNFalpha antibodies, anti-IL12/23 antibodies

Question 74

What are mixed pattern diseases caused by?

Answer 74

Caused by mutations in genes encoding proteins involved in pathways associated with innate AND adaptive immune cell function

Question 75

What are features of mixed pattern diseases?

Answer 75

HLA associations may be present; auto-antibodies are NOT usually a feature

Question 76

What genes are involved in ankylosing spondylitis?

Answer 76

IL23R, ERAP1 (ARTS1), ANTXR2, ILR2, HLA B27

Question 77

What condition is IL23R gene relevant to and what does it code for?

Answer 77

Ankylosing spondylitis. IL23 receptor

Question 78

What condition is ERAP1 (ARTS1) gene relevant to and what does it code for?

Answer 78

Ankylosing spondylitis. Type 1 TNF receptor shedding aminopeptidase regulator/ER aminopeptidase 1

Question 79

What condition is ANTXR2 gene relevant to and what does it code for?

Answer 79

Ankylosing spondylitis. Anthrax toxin receptor 2

Question 80

What condition is ILR2 gene relevant to and what does it code for?

Answer 80

Ankylosing spondylitis. Interleukin receptor type II.

Question 81

What condition is HLA B27 gene relevant to and what does it code for?

Answer 81

Ankylosing spondylitis. Human leukocyte antigen B27.

Question 82

What gene accounts for <50% overall genetic risk of ankylosing spondylitis?

Answer 82

HLA B27

Question 83

What does IL23 receptor do?

Answer 83

Receptor for IL23 which promotes differentiation of Th17 cells

Question 84

What does type 1 TNF receptor shedding aminopeptidase regulator/ER aminopeptidase 1 do?

Answer 84

Cleaves surface cytokine receptors and trims peptides for presentation by class I HLA molecules

Question 85

What does anthrax toxin receptor 2 do?

Answer 85

Involved in forming capillaries and maintaining structure of basement membrane

Question 86

What does interleukin receptor type II do?

Answer 86

Decoy receptor that inhibits activity of IL1

Question 87

What does human leukocyte antigen B27 do?

Answer 87

Presents antigen to CD8 T cells. Ligand for killer immunoglobulin receptor.

Question 88

How inheritable is ankylosing spondylitis?

Answer 88

HIGHLY HERITABLE - > 90%. Around 50% of the heritability of AS comes down to HLA-B27

Question 89

Where does ankylosing spondylitis tend to occur?

Answer 89

It tends to occur at specific sites where there are high tensile forces (entheses - sites of insertion of ligaments or tendons). This feature of localisation is characteristic of auto-inflammatory disease

Question 90

What feature is characteristic of auto-inflammatory disease?

Answer 90

Localisation

Question 91

How does ankylosing spondylitis present?

Answer 91

Low back pain and stiffness; enthesitis; large joint arthritis

Question 92

What is the treatment for ankylosing spondylitis?

Answer 92

NSAIDs; immunosuppression:

anti-TNFalpha and anti-IL17

Question 93

What causes polygenic autoimmune disease?

Answer 93

Mutations in genes encoding proteins involved in pathways associated with adaptive immune cell function. Aberrant B and T cell responses in primary and secondary lymphoid organs lead to breaking of tolerance with development of immune reactivity towards self-antigens.

Question 94

What are features of polygenic autoimmune disease?

Answer 94

HLA associations are common, auto-antibodies are found

Question 95

What are factors contributing to polygenic autoimmune disease?

Answer 95

Genetic polymorphisms and environmental factors

Question 96

What diseases (due to genetic polymorphisms - HLA) are associated with polygenic autoimmune disease?

Answer 96

Goodpasture disease, Graves disease, systemic lupus erythematosus, type I diabetes, rheumatoid arthritis

Question 97

What is the susceptibility allele in Goodpasture syndrome?

Answer 97

HLA-DR15

Question 98

What is the relative risk (fold) of Goodpasture disease with susceptibility allele?

Answer 98

10

Question 99

What is the susceptibility allele in Graves disease?

Answer 99

HLA-DR3

Question 100

What is the relative risk (fold) of Graves disease with susceptibility allele?

Answer 100

4

Question 101

What is the susceptibility allele in SLE?

Answer 101

HLA-DR3

Question 102

What is the relative risk (fold) of SLE with susceptibility allele?

Answer 102

6

Question 103

What is the susceptibility allele in type I diabetes

Answer 103

HLA-DR3/DR4

Question 104

What is the relative risk (fold) of T1DM with susceptibility allele?

Answer 104

25

Question 105

What is the susceptibility allele rheumatoid arthritis?

Answer 105

HLA-DR4

Question 106

What is the relative risk (fold) of rheumatoid arthritis with susceptibility allele?

Answer 106

4

Question 107

What does HLA do?

Answer 107

HLA presentation of antigen is required for the development of T cell and T cell-dependent B cell responses

Question 108

What are examples of genetic polymorphisms affecting T cell activation, leading to polygenic autoimmune disease?

Answer 108

PTPN22, CTLA4

Question 109

What conditions is PTPN22 associated with?

Answer 109

SLE, rheumatoid arthritis, T1DM

Question 110

What conditions is CTLA4 associated with?

Answer 110

SLE, auto-immune thyroid disease, T1DM, (rheumatoid arthritis)

Question 111

What is PTPN 22?

Answer 111

Protein tyrosine phosphatase non-receptor 22. Lymphocyte specific tyrosine phosphatase which suppresses T cell activation. Allelic variants found in: SLE, RA, T1DM

Question 112

What is CTLA4?

Answer 112

Cytotoxic T lymphocyte associated protein 4. Expressed by T cells and transmits inhibitory signal to control T cell activation (regulates T cell function). Allelic variants found in: autoimmune thyroid disease, T1DM, SLE, (RA)

Question 113

What happens if PTPN 22 becomes mutated?

Answer 113

So, if it becomes mutated you will fail to control T cell activation leading to the presence of more reactive T cells. This will predispose you to the development of autoimmune disease.

Question 114

What is central tolerance?

Answer 114

Deletion of auto-reactive B cells and T cells in the site where they mature

Question 115

What is peripheral tolerance?

Answer 115

T cells CANNOT be activated without co-stimulation. Co-stimulatory molecules are upregulated in the presence of infection/inflammation e.g. CD40L-CD40, CD80/86-CD28. Regulatory T cells play an important role in tolerance: Tregs, Tr1, CD8 regs. Immune privilege: some areas of the body are less accessible to the immune system (e.g. eyes, testes, CNS)

Question 116

What does the Gel and Coombs test classify?

Answer 116

Gel and Coombs (1960s) classified skin test hypersensitivity reactions according to the type of immune response observed. This classification was broadly looking at whether a response was antibody OR T cell mediated. These are the effector mechanisms for immunopathology.

Question 117

What is the Gel and Coombs classification?

Answer 117

Type I: immediate hypersensitivity which is IgE mediated. Type II: antibody reacts with cellular antigen. Type III: antibody reacts with soluble antigen to form an immune complex. Type IV: delayed-type hypersensitivity. T cell mediated response.

Question 118

In type I IgE mediated reactions, what does the allergen tend to be?

Answer 118

This is almost always to FOREIGN antigens (e.g. pollen, drugs). However, it is possible that there is some involvement of self-antigens in this type of reaction in some cases of eczema

Question 119

Describe what happens in IgE mediated reactions

Answer 119

Type I hypersensitivity reaction which results in a rapid allergic reaction. Pre-existing IgE antibodies bind to allergens. IgE is bound to Fc epsilon receptors on mast cells and basophils. This results in cell degranulation. Inflammatory mediators are released.

Question 120

What are the inflammatory mediators released in IgE mediated reactions?

Answer 120

Pre-formed: histamine, serotonin, proteases. Synthesised: leukotrienes, prostaglandins, bradykinin, cytokines

Question 121

What do inflammatory mediators in IgE reactions lead to?

Answer 121

Increased vascular permeability, leukocyte chemotaxis, smooth muscle contraction

Question 122

What is antibody driven immune reaction?

Answer 122

This is when antibodies bind to cell-associated antigens. This is basically always autoimmune. Binding of antibodies to a cell can lead to antibody-dependent destruction

Question 123

How doe antibody-dependent destruction occur in type II hypersensitivity reactions?

Answer 123

1. Binding of antibodies to a cell can lead to antibody-dependent destruction. 2. Antibodies can activate complement (by binding to C1). 3. Antibodies (bound to cells) can also bind to receptors on NK cells (releases cytolytic granules and membrane attack) or macrophages (phagocytosis) which will also result in cell death. 4. Binding of antibodies could also lead to receptor activation or blockade (sometimes considered type V responses).

Question 124

What are examples of autoimmune conditions with type II hypersensitivity reaction (antibody driven immune reactions)?

Answer 124

E.g. in Graves’ disease, the antibodies will bind to the TSH receptor and stimulate it. They can also bind to the receptor and block its normal function (e.g. Myasthenia Gravis)

Question 125

In Goodpasture syndrome, what is the auto-antigen, leading to an antibody driven immune reaction?

Answer 125

Noncollagenous domain of basement membrane collagen type IV

Question 126

What pathology is associated with Goodpasture disease?

Answer 126

Antibody driven immune reaction leading to glomerulonephritis and pulmonary haemorrhage

Question 127

In pemphipus vulgaris, what is the auto-antigen, leading to an antibody driven immune reaction?

Answer 127

Epidermal cadherin

Question 128

What pathology is associated with pemphigus vulgaris?

Answer 128

Blistering of skin

Question 129

In Graves disease, what is the auto-antigen, leading to an antibody driven immune reaction?

Answer 129

Thyroid stimulating hormone (TSH) receptor

Question 130

What pathology is associated with Graves disease?

Answer 130

Hyperthyroidism

Question 131

In myaesthaenia gravis, what is the auto-antigen, leading to an antibody driven immune reaction?

Answer 131

Acetylcholine receptor

Question 132

What pathology is associated with myaesthenia gravis?

Answer 132

Muscle weakness

Question 133

What is type III hypersensitivity?

Answer 133

Immune complex driven. These antibodies can be generated against endogenous proteins (e.g. anti-nuclear antibodies) or to exogenous substances (e.g. drugs)

Question 134

What happens in immune complex driven hypersensitivity?

Answer 134

Antibody binds to soluble antigen to form circulating immune complex. The immune complexes deposit in the blood vessels (especially in the kidneys. Through their Fc portion, the antibodies can activate complement and activate inflammatory cells. This can also lead to tiny bleeds in various places which gives rise to the purpuric rash.

Question 135

What are the effects of type III hypersensitivity?

Answer 135

Immune complex formation and deposition in blood vessels; complement activation and infiltration of macrophages and neutrophils; cytokine and chemokine expression; granule release from neutrophils; increased vascular permeability; inflammation and damage to vessels (cutaneous vasculitis, glomerulonephritis, arthritis)

Question 136

SLE is a type III hypersensitivity disease, involving which autoantigen?

Answer 136

DNA, histones, RNP

Question 137

RA is a type III hypersensitivity disease, involving which autoantigen?

Answer 137

Fc region of IgG, arthritis

Question 138

What pathology does SLE have (immune complex driven)?

Answer 138

Rash, glomerulonephritis

Question 139

What pathology does RA have (immune complex driven)?

Answer 139

Arthritis

Question 140

What is type IV hypersensitivity reaction?

Answer 140

T cell driven. CD8 cells will recognise self-peptides presented by HLA Class I molecules leading to damage to cells. Cytolytic granules are released from primed CD8 T cell, causing tissue cell damage. You can also have CD4 cells recognising peptides presented by HLA Class II molecules. This results in cytokine production, which results in tissue damage and inflammation caused by macrophages. (CD4 T cell can also directly signal macrophages?)

Question 141

Insulin dependent diabetes mellitus is a type IV hypersensitivity disease with which autoantigen?

Answer 141

Pancreatic Beta cell antigen

Question 142

What is the pathology of insulin dependent diabetes mellitus?

Answer 142

Beta cell destruction: CD8+ T cells

Question 143

RA is a type IV hypersensitivity disease with which autoantigen?

Answer 143

Unknown synovial joint antigen

Question 144

What is the pathology of RA?

Answer 144

Joint inflammation and destruction

Question 145

Multiple sclerosis and experimental autoimmune encephalities (EAE) involve which autoantigens?

Answer 145

Myelin basic protein, proteolipid protein, myelin oligodendrocyte, glycoprotein

Question 146

What is the pathology of multiple sclerosis and experimental autoimmune encephalitis?

Answer 146

Brain infiltration by CD4+ T cells

Question 147

Summarise mechanisms for immunopathology and examples of type I hypersensitivity reactions

Answer 147

Anaphylactic hypersensitivity; involves IgE and mast cells, e.g. anaphylaxis, atopic asthma. Rarely autoimmune

Question 148

Summarise mechanisms for immunopathology and examples of type II hypersensitivity reactions

Answer 148

Cytotoxic hypersensitivity; involves Ab binding to cells with complement mediated host cell destruction (or inhibition/activation or receptor signalling). E.g. Goodpasture disease, Graves disease. Often autoimmune.

Question 149

Summarise mechanisms for immunopathology and examples of type III hypersensitivity reactions

Answer 149

Immune complex hypersensitivity; involves deposition of Ab/Ag complexes in tissue e.g. SLE, serum sickness. Sometimes autoimmune.

Question 150

Summarise mechanisms for immunopathology and examples of type IV hypersensitivity reactions

Answer 150

Delayed hypersensitivity, involves T cells and cytokines e.g. diabetes, allergic contact dermatitis. Sometimes autoimmune.

Question 151

Which polygenic autoimmune diseases are organ specific?

Answer 151

Graves disease (very organ specific?), Hashimotos thyroiditis, pernicious anaemia, myaesthenia gravis, Goodpasture disease, T1DM

Question 152

Which polygenic autoimmune disease is neither organ specific nor organ non-specific?

Answer 152

RA

Question 153

Which polygenic autoimmune disease is organ non-specific?

Answer 153

SLE, Sjogren’s syndrome, systemic sclerosis, dermato/polymyositis, ANCA associated vasculitis

Question 154

Are polygenic autoimmune diseases organ-specific or organ non-specific?

Answer 154

Polygenic autoimmune diseases occur on a spectrum where some diseases are very organ specific and others are non-specific