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− | # | + | {{toplink |
+ | |backcolour = FFE4E1 | ||
+ | |linkpage =WikiBlood | ||
+ | |linktext =WIKIBLOOD | ||
+ | |thispagemap= Immunodeficiencies(Concept Map) - WikiBlood | ||
+ | |sublink1 =Immunology - WikiBlood | ||
+ | |subtext1 =IMMUNOLOGY | ||
+ | |pagetype =Blood | ||
+ | }} | ||
+ | |||
+ | ==Introduction== | ||
+ | [[Image:Immunodeficiencies Map.jpg|thumb|right|150px|Immunodeficiency Diagram - Copyright nabrown RVC]] | ||
+ | Like any system in the body the immune system can go wrong. Autoimmunity is when the immune system begins to attack itself. Immunodeficiency is when the immune system fails to protect itself from disease. | ||
+ | |||
+ | If the immunodeficient defect is present at birth and is therefore a result of a genetic or developmental abnormality, it is called primary immunodeficiency. | ||
+ | |||
+ | Secondary immunodeficiency, soemtimes called aquired immunodeficiency, is the loss of immune function during life, caused by exposure to harmful agents. | ||
+ | |||
+ | Immunodeficiencies can be treated by the replacement of the defective or missing protein, cells or gene. However, in veterinary medicine, vaccinations and drugs are the most common treatments for immunodeficiency. | ||
+ | |||
+ | ==Primary Immunodeficiency== | ||
+ | |||
+ | *Primary immunodeficiencies may affect either the innate or adaptive immune system | ||
+ | *They are categorised by either the type or the developmental stage of the cells involved | ||
+ | *Lymphoid cell disorders affect T or B cells (or both) | ||
+ | *Myeloid cell disorders affect phagocytic function | ||
+ | *The severity of the immunodeficiency depends on at which stage in development the problem occurs | ||
+ | **E.g. Defects early on in development will affect the entire immune system | ||
+ | *T cell deficiencies can affect both the cell-mediated and humoral response as T cells play a central role in the immune system | ||
+ | |||
+ | ===Deficiencies of Innate Immunity=== | ||
+ | |||
+ | ====Canine Cyclic Haematopoiesis==== | ||
+ | *Also called '''Grey Collie Syndrome''' | ||
+ | *Autosomal recessive | ||
+ | *Insertion mutation in AP3B1 gene | ||
+ | *Diluted grey coat colour, stunted growth, poor wound healing | ||
+ | *Neutropenia every 2 weeks which lasts 3-4 days due to cyclic production of cells from bone marrow | ||
+ | *Recurrent infections, e.g. pyrexia, diarrhoea, gingivitis and arthritis | ||
+ | |||
+ | ====Canine Leukocyte Adhesion Deficiency (CLAD)==== | ||
+ | *Occurs in Irish Setters | ||
+ | *Missence mutation of -Cys-36-Ser- in CD18 molecule | ||
+ | **CD18 is required for neutrophil migration and phagocytosis | ||
+ | *Recurrent bacterial infection | ||
+ | *Neutrophilia (neutrophils remain in the blood and are unable to fight infection in the tissue) | ||
+ | |||
+ | ====Bovine Leukocyte Adhesion Deficiency (BLAD)==== | ||
+ | *Occurs in Holstein cattle | ||
+ | *Missence mutation of -Asp-128-Gly in CD18 molecule | ||
+ | *Recurrent infection, e.g. pneumonia | ||
+ | |||
+ | ===Deficiencies of Adaptive Immunity=== | ||
+ | |||
+ | ====Equine Severe Combined Immune Deficiency (Equine SCID)==== | ||
+ | *Autosomal recessive | ||
+ | *Occurs in 2-3% of Arabian foals | ||
+ | *Defect in DNA-dependent protein kinase gene | ||
+ | **Gene codes for a DNA repair enzyme involved in V(D)J recombination for antigen receptors of lymphocytes (e.g. Ig and TCR) | ||
+ | *No functional B or T cells | ||
+ | *Foals develop infections (usually aorund 8 weeks of age as maternal antibody in colostrum wanes around this time) | ||
+ | *Foals usually die from bronchopneumonia | ||
+ | |||
+ | ====Canine X-Linked Severe Combined Immune Deficiency (Canine SCID)==== | ||
+ | *Affects Basset Hounds and Corgis | ||
+ | *X-linked recessive defect in the gene conding for the IL-2 receptor | ||
+ | **IL-2 receptor is a receptor for the cytokine IL-2 which causes T cells to proliferate | ||
+ | *Causes lymphoid hypoplasia, stunted growth and increses the animal's susceptibility to infection | ||
+ | *Animal usually dies from pneumonia or sepsis as the level of maternal antibody decreases | ||
+ | |||
+ | ====Selective IgA deficiency of German Shepherd Dogs==== | ||
+ | *Poorly understood | ||
+ | *Linked to other disease syndromes such as deep pyoderma, inflammatory bowel disease, anal furunculosis and disseminated aspergillosis | ||
+ | *IgA deficiency so more susceptible to mucosal disease | ||
+ | |||
+ | ====Immunodeficiency of Weimaraners, Irish Wolfhounds and Miniature Dachshunds==== | ||
+ | *Unknown aetiology | ||
+ | *Inherited defects | ||
+ | *Low levels of circulating IgM and IgG | ||
+ | *Impaired neutrophil function | ||
+ | *Causes recurrent pyrexia and infections | ||
+ | **E.g. Rhinitis and bronchopneumonia in Irish Wolfhounds due to low IgA | ||
+ | **E.g. Pneumocytosis in Miniature Dachshunds due to low IgG | ||
+ | |||
+ | ===Labatory Examples of Severe Combined Deficiency=== | ||
+ | |||
+ | *Severe Combined Immune Deficiency(SCID) | ||
+ | **No functional B or T cells | ||
+ | |||
+ | *Arthymic nude mice (no thymus) | ||
+ | **No functional T cells | ||
+ | **Cell-mediated immunodeficiency | ||
+ | |||
+ | *Knock-out mice | ||
+ | **E.g. Gene coding for CD4, CD8, IL-10 removed | ||
+ | |||
+ | ==Secondary Immunodeficiency== | ||
+ | |||
+ | *There are many causes of secondary immunodeficiency | ||
+ | **Most deficiencies are not genetic | ||
+ | **Most are agent-induced, such as from X-ray radiation and immunosuppressive drugs | ||
+ | |||
+ | ===Viral Causes=== | ||
+ | |||
+ | ====Feline Leukaemia Virus (FeLV)==== | ||
+ | [[Image:FeLV Electron Micrograph.jpg|thumb|right|150px|FeLV Electron Micrograph [http://phil.cdc.gov/phil/home.asp Public Health Image Library] Image #5610]] | ||
+ | *Oncogenic retrovirus | ||
+ | *Causes neoplasia (lymphoma), myelosuppression (anaemia) and immunosuppression (of T cells) | ||
+ | *2 strains: | ||
+ | **FeLV-A | ||
+ | ***Natural strain | ||
+ | **FeLV-B | ||
+ | ***Formed through FeLV-A recombining with endogenous retroviral sequences in the feline genome | ||
+ | ***Increases the risks of lymphoma | ||
+ | **FeLV-C | ||
+ | ***Formed from the spontaneous mutation of FeLV-A | ||
+ | ***Is more myelosuppressive | ||
+ | *Virus replicates in the oropharyngeal lymphoid tissue causing a viraemia (virus circulating in the bloodstream) which then spreads to the systemic lymphoid tissue | ||
+ | *Shed in saliva | ||
+ | *Passed by oronasal route, e.g. mutual grooming | ||
+ | *Kittens between 6 weeks and 6 months are most susceptible | ||
+ | *60% of cats will become immune to the disease and recover | ||
+ | *Cats that are persistantly viraemic will progress to develop FeLV-associated diseases | ||
+ | *Some cats will become viraemic again if treated with corticosteroids or stressed if the infection lies dormant in the bone marrow | ||
+ | *Diagnosis: | ||
+ | **ELISA | ||
+ | **Rapid-Immuno-Migration | ||
+ | **Western Blot | ||
+ | **Virus Isolation | ||
+ | **Immunofluorescence | ||
+ | **PCR | ||
+ | **Antibiotics for secondary infection | ||
+ | **Anti-retroviral therapy | ||
+ | *For vaccinations see [[Vaccines - WikiBlood#Cat Vaccinations|here]] | ||
+ | |||
+ | ====Feline Immunodeficiency Virus (FIV)==== | ||
+ | *Lentivirus | ||
+ | *Subtypes A, B and D | ||
+ | *Causes increased suscepitbilty to infections and neoplasia | ||
+ | *Specifically destroys CD4+ T cells | ||
+ | *Virus is present in saliva, blood and other bodily fluids | ||
+ | *Feral and outdoor cats (mostly tom cats) most at risk | ||
+ | *Virus replicates in lymphoid tissue | ||
+ | *Can remain asymptomatic | ||
+ | *Causes pyrexia and lymphadenopathy | ||
+ | *Transmitted by biting | ||
+ | *Diagnosis: | ||
+ | **ELISA | ||
+ | **Rapid-Immuno-Migration | ||
+ | **Western Blot | ||
+ | **Virus Isolation | ||
+ | **Immunofluorescence | ||
+ | **PCR | ||
+ | *Treatment: | ||
+ | **Antibiotics for secondary infection | ||
+ | **Anti-retroviral therapy | ||
+ | *For vaccinations see [[Vaccines - WikiBlood#Cat Vaccinations|here]] | ||
+ | |||
+ | ====Bovine Immunodeficiency Virus (BIV)==== | ||
+ | *Lentivirus (non-oncogenic) | ||
+ | *Causes a persistent viral infection and lymphocytosis | ||
+ | *Immunocompromised cattle may develop secondary infections | ||
+ | *The tranmission is not well known, but the following possibilities are being researched: | ||
+ | **Through milk | ||
+ | **Through infected semen (e.g.artificial insemination) | ||
+ | **Placental transfer | ||
+ | *Diagnosis: | ||
+ | **Western Blot | ||
+ | **PCR | ||
+ | |||
+ | ===Toxic Causes=== | ||
+ | |||
+ | *Poisons | ||
+ | |||
+ | ===Iatrogenic Causes=== | ||
+ | |||
+ | *Drugs | ||
+ | **Corticosteroids | ||
+ | **Ciclosporin | ||
+ | **Cytoxic cancer therapy | ||
+ | |||
+ | ===Other Causes=== | ||
+ | |||
+ | *Malnutrition | ||
+ | |||
+ | *Chronic disease | ||
+ | |||
+ | *Stress | ||
+ | |||
+ | *Senescence | ||
+ | |||
+ | ==Links== | ||
+ | |||
+ | *[[Viruses|Viruses - WikiBugs]] | ||
+ | |||
+ | *[[Innate Immune System - WikiBlood]] | ||
+ | |||
+ | *[[Adaptive Immune System - WikiBlood]] | ||
+ | |||
+ | ==[[Immunodeficiencies Flashcards - WikiBlood|Immunodeficiencies Flashcards]]== | ||
+ | |||
+ | ==References== | ||
+ | |||
+ | *Ivan Roitt: '''Essential Immunology,''' Ninth edition | ||
+ | |||
+ | *Goldsby, Kindt, & Osbourne '''KUBY Immunology,''' Fourth edition | ||
+ | |||
+ | *Dr Brian Catchpole BVetMed PhD MRCVS | ||
+ | |||
+ | ==Creators== | ||
+ | |||
+ | [[Natalie Brown]] |
Revision as of 13:05, 8 September 2008
|
Introduction
Like any system in the body the immune system can go wrong. Autoimmunity is when the immune system begins to attack itself. Immunodeficiency is when the immune system fails to protect itself from disease.
If the immunodeficient defect is present at birth and is therefore a result of a genetic or developmental abnormality, it is called primary immunodeficiency.
Secondary immunodeficiency, soemtimes called aquired immunodeficiency, is the loss of immune function during life, caused by exposure to harmful agents.
Immunodeficiencies can be treated by the replacement of the defective or missing protein, cells or gene. However, in veterinary medicine, vaccinations and drugs are the most common treatments for immunodeficiency.
Primary Immunodeficiency
- Primary immunodeficiencies may affect either the innate or adaptive immune system
- They are categorised by either the type or the developmental stage of the cells involved
- Lymphoid cell disorders affect T or B cells (or both)
- Myeloid cell disorders affect phagocytic function
- The severity of the immunodeficiency depends on at which stage in development the problem occurs
- E.g. Defects early on in development will affect the entire immune system
- T cell deficiencies can affect both the cell-mediated and humoral response as T cells play a central role in the immune system
Deficiencies of Innate Immunity
Canine Cyclic Haematopoiesis
- Also called Grey Collie Syndrome
- Autosomal recessive
- Insertion mutation in AP3B1 gene
- Diluted grey coat colour, stunted growth, poor wound healing
- Neutropenia every 2 weeks which lasts 3-4 days due to cyclic production of cells from bone marrow
- Recurrent infections, e.g. pyrexia, diarrhoea, gingivitis and arthritis
Canine Leukocyte Adhesion Deficiency (CLAD)
- Occurs in Irish Setters
- Missence mutation of -Cys-36-Ser- in CD18 molecule
- CD18 is required for neutrophil migration and phagocytosis
- Recurrent bacterial infection
- Neutrophilia (neutrophils remain in the blood and are unable to fight infection in the tissue)
Bovine Leukocyte Adhesion Deficiency (BLAD)
- Occurs in Holstein cattle
- Missence mutation of -Asp-128-Gly in CD18 molecule
- Recurrent infection, e.g. pneumonia
Deficiencies of Adaptive Immunity
Equine Severe Combined Immune Deficiency (Equine SCID)
- Autosomal recessive
- Occurs in 2-3% of Arabian foals
- Defect in DNA-dependent protein kinase gene
- Gene codes for a DNA repair enzyme involved in V(D)J recombination for antigen receptors of lymphocytes (e.g. Ig and TCR)
- No functional B or T cells
- Foals develop infections (usually aorund 8 weeks of age as maternal antibody in colostrum wanes around this time)
- Foals usually die from bronchopneumonia
Canine X-Linked Severe Combined Immune Deficiency (Canine SCID)
- Affects Basset Hounds and Corgis
- X-linked recessive defect in the gene conding for the IL-2 receptor
- IL-2 receptor is a receptor for the cytokine IL-2 which causes T cells to proliferate
- Causes lymphoid hypoplasia, stunted growth and increses the animal's susceptibility to infection
- Animal usually dies from pneumonia or sepsis as the level of maternal antibody decreases
Selective IgA deficiency of German Shepherd Dogs
- Poorly understood
- Linked to other disease syndromes such as deep pyoderma, inflammatory bowel disease, anal furunculosis and disseminated aspergillosis
- IgA deficiency so more susceptible to mucosal disease
Immunodeficiency of Weimaraners, Irish Wolfhounds and Miniature Dachshunds
- Unknown aetiology
- Inherited defects
- Low levels of circulating IgM and IgG
- Impaired neutrophil function
- Causes recurrent pyrexia and infections
- E.g. Rhinitis and bronchopneumonia in Irish Wolfhounds due to low IgA
- E.g. Pneumocytosis in Miniature Dachshunds due to low IgG
Labatory Examples of Severe Combined Deficiency
- Severe Combined Immune Deficiency(SCID)
- No functional B or T cells
- Arthymic nude mice (no thymus)
- No functional T cells
- Cell-mediated immunodeficiency
- Knock-out mice
- E.g. Gene coding for CD4, CD8, IL-10 removed
Secondary Immunodeficiency
- There are many causes of secondary immunodeficiency
- Most deficiencies are not genetic
- Most are agent-induced, such as from X-ray radiation and immunosuppressive drugs
Viral Causes
Feline Leukaemia Virus (FeLV)
- Oncogenic retrovirus
- Causes neoplasia (lymphoma), myelosuppression (anaemia) and immunosuppression (of T cells)
- 2 strains:
- FeLV-A
- Natural strain
- FeLV-B
- Formed through FeLV-A recombining with endogenous retroviral sequences in the feline genome
- Increases the risks of lymphoma
- FeLV-C
- Formed from the spontaneous mutation of FeLV-A
- Is more myelosuppressive
- FeLV-A
- Virus replicates in the oropharyngeal lymphoid tissue causing a viraemia (virus circulating in the bloodstream) which then spreads to the systemic lymphoid tissue
- Shed in saliva
- Passed by oronasal route, e.g. mutual grooming
- Kittens between 6 weeks and 6 months are most susceptible
- 60% of cats will become immune to the disease and recover
- Cats that are persistantly viraemic will progress to develop FeLV-associated diseases
- Some cats will become viraemic again if treated with corticosteroids or stressed if the infection lies dormant in the bone marrow
- Diagnosis:
- ELISA
- Rapid-Immuno-Migration
- Western Blot
- Virus Isolation
- Immunofluorescence
- PCR
- Antibiotics for secondary infection
- Anti-retroviral therapy
- For vaccinations see here
Feline Immunodeficiency Virus (FIV)
- Lentivirus
- Subtypes A, B and D
- Causes increased suscepitbilty to infections and neoplasia
- Specifically destroys CD4+ T cells
- Virus is present in saliva, blood and other bodily fluids
- Feral and outdoor cats (mostly tom cats) most at risk
- Virus replicates in lymphoid tissue
- Can remain asymptomatic
- Causes pyrexia and lymphadenopathy
- Transmitted by biting
- Diagnosis:
- ELISA
- Rapid-Immuno-Migration
- Western Blot
- Virus Isolation
- Immunofluorescence
- PCR
- Treatment:
- Antibiotics for secondary infection
- Anti-retroviral therapy
- For vaccinations see here
Bovine Immunodeficiency Virus (BIV)
- Lentivirus (non-oncogenic)
- Causes a persistent viral infection and lymphocytosis
- Immunocompromised cattle may develop secondary infections
- The tranmission is not well known, but the following possibilities are being researched:
- Through milk
- Through infected semen (e.g.artificial insemination)
- Placental transfer
- Diagnosis:
- Western Blot
- PCR
Toxic Causes
- Poisons
Iatrogenic Causes
- Drugs
- Corticosteroids
- Ciclosporin
- Cytoxic cancer therapy
Other Causes
- Malnutrition
- Chronic disease
- Stress
- Senescence
Links
Immunodeficiencies Flashcards
References
- Ivan Roitt: Essential Immunology, Ninth edition
- Goldsby, Kindt, & Osbourne KUBY Immunology, Fourth edition
- Dr Brian Catchpole BVetMed PhD MRCVS