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Immunopathology: Type II and Type III Reactions

This article discusses examples of Type II and Type III hypersensitivity reactions, including complement dependent reactions, transfusion reactions, autoimmune diseases, and transplant rejection. It provides an overview of the mechanisms and pathogenesis involved in these immune responses.

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Immunopathology: Type II and Type III Reactions

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  1. Type II Reaction – some examples • Complement dependent reactions • Transfusion reactions • Erythroblastosis fetalis • Autoimmune hemolytic anemia • ADCC • Killing of parasites and tumor cells • Transplant rejection • Cellular dysfunction • Myasthenia gravis • Grave’s disease • Antibodies against Extracellular antigens • Good Pasture’s syndrome –autoantibodies bind to Glomerular & Alveolar BM proteins • Pemphigus Vulgaris – autoantibodies against intercellular proteins (desmosomes)

  2. Immunopathology Type III Hypersensitivity • Type III reactions involve immune complexes of antibody and antigen. • The antibodies are of IgM or IgG type, but the antigen is usually a soluble antigen. • Reactions due to large amounts of persistent immune complexes in tissues and organs • Larger complexes are removed by the mononuclear phagocyte system. Most pathogenic complex of small or intermediate size circulate longer and bind less avidly to MPS • Major target – Blood vessels (vasculitis)

  3. Systemic immune complex disease • First phase – formation of antigen-antibody complexes in the circulation after the introduction of antigen (about 5 days after the introduction) • Second phase – deposition of complexes • Third phase – the development of inflammatory reaction (About 10 days) • -Due to activation of complement vaculitis is the hallmark feature • - During acute phase of the disease consumption of complement causes a decrease in serum levels

  4. Type III Hypersensitivity • Immune complex mediated disease can be • Generalized (serum sickness – injection of exogenous serum ) • Localized (Arthus reaction)

  5. Type III reaction -Examples • Acute – post streptococcal glomerulonephritis • Chronic - SLE

  6. Normal Renal Biopsy

  7. Immunopathology Type III reaction - Glomerulonephritis

  8. Post Streptococcal Glomerulonephritis, E.M • Sub-epithelial “Humps” • Neutrophil with granules in cytoplasm

  9. Local immune complex (Arthus reaction) disease • Localized area of tissue necrosis resulting from immune complex vasculitis • Develops when antigen is intracutaneously introduced into an individual having circulating antibodies against that antigen. • In contrast to anaphylactic reaction which starts immediately, arthus reaction develops over a period of hours and peaks 4-10 hrs after injection • Erythema and edema due to Fibrinoid necrosis of vessels with vasculitis are important morphological features

  10. Fig 5-11 IC Vasculitis

  11. ImmunopathologyType IV reaction(Cell Mediated) • The Type IV, or delayed-type hypersensitivity reaction (DTH), does not require antibody. • Involves CD 4 + and CD 8+ lymphocytes • Example : TB granuloma Contact Dermatitis

  12. Type IV Hypersensitivity (Granulomatous Inflammation)

  13. granuloma

  14. Tuberculin test • PPD • Intradermal injection • Erythema (redness) and hardening (induration) after 2-3 days indicates previous exposure • Fully developed lesions have perivascular cuffing of CD4+ lymphocytes

  15. Contact Dermatitis • Induced by nickel, cosmetics, poison-ivy • Small molecules penetrate skin • Conjugate to self proteins • Sensitization • Second contact - Ags presented to sensitized TH1cells • Cytokines secreted lead to inflammation • Inflammation is severe to cause vesicle formation (Eczematous dermatitis)

  16. Type IV Reaction – T Cell Mediated Toxicity • CTLs kill via perforins, very similar to the way complement kills cells with the MAC. • Also produces granzymes which causes apoptosis • -increases Fasligand which causes apoptosis by binding to Fas of target cells • Play an important role in. • Resistance against viral infections. • Transplant rejection.

  17. THANK YOU

  18. Transplant Rejection

  19. Transplant rejection • Mechanisms involved in transplant rejection • T cell mediated – delayed type hypersensitivity • Direct pathway via recipient CD4+ and CD8+ recognition of MHC Class I & II antigens on donor APCs (interdigitating dentritic cells) • Indirect pathway whereby processing of antigen by the recipient’s APCs is required • Antibody mediated

  20. Renal Transplant rejection • Hyperacute: due to preformed antibodies, usually in multiparous women - rare because of antibody screening (Arthus reaction-Type III) • Acute • Vascular rejection (type II) • Cellular (tubulo-interstitial) rejection (type IV) – Good response to treatment • Chronic

  21. Renal transplant rejection-Hyperacute Rejection • Caused by preformed antibodies in the recipient • Occurs within minutes • Grossly kidney purple and swollen • Widespread acute arteritis and arteriolitis • Thrombosis of vessels • Ischemic necrosis • Results in loss of graft

  22. Hyperacute Rejection • Microthrombi • PMN’s

  23. Acute Rejection • Occurs as early as 10-14 days. • Decreased renal function. May have fever and tenderness of the graft. • Tubulointerstitial (cellular) or vascular(humoral) rejection

  24. Acute Vascular Rejection • Humorally mediated • Vascular inflammation • Necrotizing vasculitis (rejection vasculitis) • Intimal thickening • Responds less well to therapy

  25. Acute Rejection - Vascular (Micro)

  26. Acute Tubulointerstitial (Cellular) Rejection • Cell mediated • Lymphocytic infiltrate of the interstitium and tubulitis (T cells of both types – CD4 & CD8) • Responds well to therapy

  27. . Acute tubulointerstitial rejection Mononuclear interstitial infiltrate

  28. Chronic Rejection • After fourth month • Vascular changes • Intimal fibrosis • Progressive luminal narrowing • Interstitial fibrosis and tubular atrophy • Ischemic glomerulosclerosis • No effective therapy

  29. Chronic rejection

  30. Immunopathologymanagement • Host vs. graft reactions • With kidney transplants, a close match of MHC I and II antigens is sought (less important with heart and liver transplants, where size of the donor organ is paramount) • Transplant rejection is treated with immunosuppressive drugs such as cyclosporine (inhibits IL-2 formation) or anti-thymocyte globulin (anti-CD3)

  31. Bone Marrow Transplant • Hematopoietic malignancies • Aplastic anemia • Immunodeficiency states • Certain non-hematopoietic malignancies

  32. Complications of Allogeneic BM Transplants • Graft versus host disease • Immunologically competent cells from donor • Affects liver, skin, gut (jaundice, rash, diarrhea) • Acute or chronic • GVH can be prevented by depleting donor T cells before grafting • Graft versus leukemia effect may be beneficial (CML-Donor T cells are deliberately introduced) • Rejection of allogeneic (donor) marrow cells- Host T cells and NK cells

  33. GVH disease • Acute • Within days to weeks • Skin, liver & intestine are affected • Generalized rash with desquamation • CMV infection – sometimes fatal • Chronic • May follow acute or may begin insidiously • Changes may resemble scleroderma

  34. Immunopathology Chronic GVH

  35. Immunodeficiency diseases • Primary immunodeficiency-genetic • Secondary immunodeficiency – Infections - Immunosuppression - Malnutrition

  36. Primary Immunodeficiency • Inherited, genetically determined • Many X-linked • Males more at risk • Affects • HMI • CMI • Complement • Phagocytes

  37. Primary Immunodeficiencies • Most manifest in infancy between 6 months & 2 years • Noted because of the susceptibility of the affected children to recurrent infections

  38. B-cell Deficiencies • Disease • Recurrent pyogenic bacterial infections • Staphylococci, Streptococci, pneumococci • Normal immunity to viral, fungal infections

  39. Immunopathology Primary Immunodeficiencies • Deficiencies of antibody-producing cells (B cells) • Congenital (Bruton) X-linked hypogammaglobulinemia • Common variable immune deficiency(1:50,000 to 1:200,000) • X linked hyper IgM syndrome • Selective IgA deficiency (common – 1:700)

  40. X-linked Agammaglobulinemia • Failure of B cell precursors to differentiate to mature B cells due to deficiency of Bruton’s tyrosine kinase (btk) • Complete Ig molecules are not produced • Free heavy chains are seen in the cytoplasm • Occurs almost entirely in males • Becomes apparent at 6 months of age • Respiratory infections by Strep. Pneumoniae, staph and hemophilus;Viral infections & protozoal infections are also common • 35% develop infectious arthritis(Mycoplasma) • B cells and plasma cells are depleted • Prophylactic immunoglobulin therapy

  41. Common Variable Immunodeficiency (CVID) • Common Variable Hypogammaglobulinemia –all immunoglobulin chains • Group of disorders –Sporadic and inherited • Cause (etiology) generally unknown – unidentified gene in HLA locus • Affects older patients 20s-30s • Both gender affected • Recurrent bacterial and giardia infections • B-cell cannot differentiate into Ab producing cells • 50 fold increased risk for gastric cancer

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