1 / 44

MICR 304 Immunology & Serology

MICR 304 Immunology & Serology. Lecture 14 Hypersensitivities Chapter 9.24, 9.25;13.1 – 13.4, 13.6 – 13.12, 13.14, 13.16 –19. Overview of Today’s Lecture. Definition Classification of hypersensitivities Key players in hypersensitivities Immunopathology of hypersensitivities.

afra
Télécharger la présentation

MICR 304 Immunology & Serology

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. MICR 304 Immunology & Serology Lecture 14 Hypersensitivities Chapter 9.24, 9.25;13.1 – 13.4, 13.6 – 13.12, 13.14, 13.16 –19

  2. Overview of Today’s Lecture • Definition • Classification of hypersensitivities • Key players in hypersensitivities • Immunopathology of hypersensitivities

  3. Definition of Hypersensitivity • Hypersensitivity reactions are immune responses to innocuous, non-infectious, environmental antigen that lead to symptomatic reactions upon re-exposure • Harmful immune responses • Hypersensitivity diseases result from repetitively occurring reactions • Antigen is in this context “allergen”

  4. Key Players in Hypersensitivities Eosinophils • IgE • IgG • Complement • Mast cells • Basophils • Eosinophils • Phagocytes, Dendritic cells, NK cells • T-cells

  5. Properties of IgE and IgG * activated

  6. High affinity (FceRI) IgE is captured without antigen binding Present on resting mast cells, basophils Present on activated eosinophils Cross-linking with antigen granule release Low affinity (FceRII) Present on many cells B-Lymphocytes Activated T-lymphocytes Phagocytes Dendritic cells Thymic epithelial cells Two Types of IgE Receptors

  7. Production of IgE • Under primary influence of IL4, also IL13 • Antigen-dependent dendritic cells promote development of TH0 to TH2 in the absence of inflammation • Exposure of TH0 to certain cytokines will promote TH2 development • IL4, IL5, IL9, and IL13 • Mast cells and TH2 secrete IL4 • TH2 secrete IL4, IL5, IL9, and IL13 • B-cell respond to IL4 , IL13, CD40 (B-ly): CD40L (TH) • JAK signal transduction pathway • phosphorylation of STAT (signal transducer and activator of transcription) • Ig- class switch to IgE

  8. Mast Cells • Mast cells derive from bone marrow, myeloid lineage • Prominent histamine rich granules • Line body surfaces • In vascularized connective tissues just beneath epithelial surfaces • Primary function is to alert to local infection • High affinity IgE receptor • Release granules upon receptor cross-linking • Role in defense against parasites, allergy

  9. Mast Cells are Activated Upon IgE Cross-Linking

  10. Mast Cell Products • Histamine, Heparin • Toxic • Endothelial permeability increase, edema • Smooth muscle contraction • Chymase, tryptase • Tissue remodeling • Cytokines • IL4, IL13: IgE, TH2 response • TNFa: Proinflammatory • Chemokines: Recruit eosinophils, basophils • Lipid mediators • PAF: recruit leukocytes, activates neutrophils, eosinophils, platelets • Leukotriene, prostaglandins: smooth muscle cell contraction, mucus secretion, increased vascular permeability

  11. Mast Cells Amplify IgE Production

  12. Mast Cell Effects Depend on Site of Activation

  13. Anaphylaxis • Disseminated mast cell activation • Widespread increase in vasopermeability leads to catastrophic drop in blood pressure (shock) • Airway constriction causes breathing problems • Swelling of epiglottis can cause suffocation

  14. Basophils • Myeloid cell lineage • Develop under the influence of IL3, IL5, GM-CSF, TGFb • IL3 + TGFb increase basophil production and decrease eosinophil production • Polymorphonuclear • Basophil granules • Histamin

  15. Basophils In peripheral blood (but enter tissue during inflammation) Lobular nucleus Tryptase +/? Life span hours Mast Cells In tissue around blood vessels (skin, epithelial mucosa, in particular gut, lung) Round nucleus Tryptase (a serine protease) +++ Survive months to years Differences Between Basophils and Mast Cells

  16. Eosinophils • Derive from bone marrow • Myeloid lineage • Granules contain major basic protein (arginine rich) • Predominant in connective tissue, subepithelial in respiratory, intestinal and urogenital tract • Express high affinity IgE receptor after activation • Can present antigen to T cells • Promote TH1 apotosis • Two major effector functions • Direct killing via exocytosis • Orchestrating an inflammatory response

  17. Eosinophils Secrete a Range of Highly Toxic Molecules • Tissue remodeling • Peroxidase • Collagenase • Matrix metalloprotease • Direct Killing • Toxic proteins • Major basic protein • Cationic protein • Neurotoxin • Oxidative burst • Inflammation • Cytokines • IL3, IL5, GM-CSF • CXCL-8 • Lipid mediators Anti-parasitic, activate mast cells, proinflammatory

  18. Classification of Hypersensitivities by Mechanism in Four Types • Type I (“Allergy”) • Soluble antigen: IgE: Mastcells • Immediate-type • Atopy: Exaggerated tendency to mount an IgE response • Type II • Cell associated antigen: IgG: phagocytes, NK cells • Type III • Soluble antigen  Antigen-Antibody complexes • Type IV • T-cell mediated Antibody Cell

  19. Immunological Mechanisms of Hypersensitivities

  20. Type I Hypersensitivities (Allergies)

  21. Antigen is soluble Antibody is IgE Mast cell degranulation Pathogenesis of Type I Hypersensitivity

  22. IgE Mediated Reactions to Allergens • Always involve mast cell mast cell degranulation • Symptomatic depends on site of entry and mast cell activation and dose

  23. Examples for Inhaled Allergens dead skin / dander Dust mite (Dermatophagoides sp.) dust mite fecal pellet pollen mineral 92608A plant debris

  24. Allergens Promote TH2 Development Can easily spread in tissue and reach subepithelial APC (primarily DC) with subsequent Th2 priming Typical for inhaled allergens

  25. Enzymatic Activity of Some Allergens Enables Easy Penetration of Epithelial Cell Barriers The cysteine protease Der p 1 is from fecal pellets of house dust mite. Protease inhibitors may be a novel therapeutic approach for allergies.

  26. Both environmental and inherited factors are important Environment: Exposure to infectious agents in early childhood drives a TH1 response Too hygienic environment with too little infectious agents drive a TH2 response Susceptibility genes for asthma IL4, IL4 receptor High affinity IgE receptor MHC II allele TCR a locus Genes and Environment in Allergies Allergies!! Less allergies!!

  27. Allergic Reactions Can be Divided into 2 Phases • Immediate within minutes • Histamine mediated • Smooth muscle cell contraction • Vascular endothelium leakage Lung Skin • Late after several hours • Chemokine mediated • Inflammatory cell influx PFER: Peak expiratory flow rate

  28. Immediate and Late Phase in Acute Allergy

  29. Food Allergies • About 1 – 4 % of European and US population suffers from true food allergies • 25% of true food allergies are against peanuts • 30,000 anaphylactic reactions and 200 deaths per year in US • Food allergens have high resistance against gastric pepsin • Allergens are resorbed and activate resident mast cells • Urticaria and asthma after systemic dissemination the allergen

  30. Approaches to Treat Allergies

  31. Pathogenesis of Type II Hypersensitivity • Antigen is cell-or matrix associated • Antibody isIgG  Activation of complement • Hemolysis, platelet lysis • Binding through Fcg receptors • Phagocytosis  Antibody itself induces cell changes

  32. Pathogenesis of Type III Hypersensitivity • Soluble antigen • Antibody is IgG • Deposition of immune complexes • Activation of complement • Inflammation • Local (Arthus reaction) • Systemic (serum sickness)

  33. Arthus Reaction: Local Type III Hypersensitivity

  34. Serum sickness: Systemic Type III Hypersensitivity

  35. Pathogenesis of Type IV Hypersensitivity • Mediated by T-cells • Soluble antigen: TH mediated • TH1 • TH2 • Cell associated antigen: CTL mediated

  36. Type IV Hypersensitivity Responses are Mediated by Antigen-specific Effector T cells Antigen injected into skin Antigen absorbed through skin Antigen absorbed through gut

  37. Injected Allergen and TH1 Mediated Type IV Hypersensitivity Cell infiltrate!! Example: Tuberculin skin test

  38. Examples for Positive Tuberculin Tests

  39. TH1 Cytokines in Type IV Hypersensitivity Response

  40. Absorbed Allergen and TH1 Mediated Type IV Hypersensitivity Example: Contact dermatitis

  41. TH2 Mediated Type IV Hypersensitivity Immediate Late Eosinophils!! Example: Chronic asthma

  42. Chronic Asthma Can Lead to Complete Airway Occlusion Dense inflammatory infiltrate with eosinophils, neutrophils, and lymphocytes Mucus plug in the airways

  43. CTL Mediated Type IV Hypersensitivity • Example: Poison ivy contact dermatitis • Lipid soluble allergen is absorbed through skin and crosses cell membranes • Allergen modifies self peptides • Presentation of modified self peptide via MHC I to CTL • Destruction of modified cell

  44. Additional Resources Accessed 5/17/2008 http://medicalimages.allrefer.com/large/epiglottis.jpg http://www.denniskunkel.com/product_info.php?products_id=9797

More Related