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Dr. Fang-Ping Huang Department of Pathology, Immunology Division, Room 216 Tel. 2855 4864

Dr. Fang-Ping Huang Department of Pathology, Immunology Division, Room 216 Tel. 2855 4864 Email: fphuang@hkucc.hku.hk. Essence and Advances in Contemporary Immunobiology. The immune system - an overview (basic concepts, features) Developmental biology of the immune system (Dr. L. Lu)

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Dr. Fang-Ping Huang Department of Pathology, Immunology Division, Room 216 Tel. 2855 4864

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  1. Dr. Fang-Ping Huang Department of Pathology, Immunology Division, Room 216 Tel. 2855 4864 Email: fphuang@hkucc.hku.hk

  2. Essence and Advances in Contemporary Immunobiology • The immune system - an overview (basic concepts, features) • Developmental biology of the immune system (Dr. L. Lu) • Recent advances in lymphocyte lineage commitment (Dr. L. Lu) • Apoptosis & the molecular cell death pathways (Dr. L. Lu) • Antigen recognition by T cells & its MHC restrictions • Pathways of antigen processing, presentation & co-stimulations • Dendritic cells & the initiation of immune responses • Immune regulation & dys-regulation in health & in diseases

  3. The immune system – an overview • Basic concepts in immunology • Vaccination & the history of immunology • Types of immunity • The adaptive immune system • Immunological specificity & memory • B cells & humoral immune response • T cells & cell-mediated immune response • The concepts of ‘self/non-self’ & ‘self-tolerance’

  4. Basic concepts in Immunology • Organisms and microorganisms • Bacteria, viruses, fungi & parasites • Infections and diseases Infection == disease • Mechanisms of defense • The immune system • Cells & soluble factors • Immunity and Immunology

  5. ‘Immunity’ • Original meaning: • “exemption from taxes” • Other extended meaning: • “ diplomatic immunity” • In the context of Immunology: • collective mechanisms against diseases

  6. Edward Jenner (1749-1823) & The Discovery of Vaccination (1796) “Vaccinia (cowpox)” & “human smallpox”

  7. Eradication of smallpox (1979, WHO)

  8. Vaccination A process of induction of immunity to a pathogen by deliberate injection of a weaken, modified or related form of the pathogen which is no longer pathogenic.

  9. Other historic events & important findings: • L. Pasteur (1880s) • Vaccines against cholera, and rabies • R. Kock (late 19th century) • Infections caused by microorganisms • P. Ehrlich et al. (1890s) • Serum factors transfer of immunity • Behring & Kitasato (1890s) • Antibodies in serum bound to pathogens • Porter & Edelman (1960s) • Antibody structure • J. Gowans (1960s) • Immunological importance of lymphocytes

  10. Size of the immune system?

  11. Dendritic cell (sentinel)

  12. Lymph Node

  13. The bursa of Fabricius in birds

  14. Cells, tissues and organs of the immune system • Immune cells are bone marrow-derived, & distributed through out the body • Primary lymphoid organs: • Thymus: T cell maturation • Bone marrow (bursa of Fabricius in birds): B cell maturation • Secondary lymphoid organs: • Lymph nodes • Spleen • Mucosal lymphoid tissues (lung, gut)

  15. Questions: • How may vaccines protect us from infections? • What may actually occur in our immune system following a vaccination?

  16. Types of immunity • Innate (natural) immunity • Phagocytes etc. • Early, rapid responses, but limited & ‘non-specifc’ • Adaptive (acquired) immunity • Lymphocytes (B & T cells) • Take time but powerful - ‘specificity + memory’

  17. Measles attacks & immunological memory

  18. “Memory” in adaptive immunity • 1st infection  memory  2nd infection slow response fast response pathogen proliferate pathogen killed disease no disease symptoms no symptom

  19. Memory & specificity – key features of the adaptive immunity

  20. Immunological memory & vaccination • Natural infections: 1st infection memory  2nd infection slow response fast response pathogens multiply pathogens disposed Symptoms/disease no disease • Vaccination memory  nature infections no disease fast response pathogens disposed no disease

  21. Vaccination protects us from infection by inducing the adaptive immune response, but bypassing the need for a primary infection

  22. Theoretical basis for immunological specificity and memory • Theory of Clonal Selection • Establishment of lymphocyte memory pool

  23. Ehrlich’s “Side-chain Hypothesis” (1900) 1 2 3 4

  24. Burnet’s “Clonal Selection” Theory Each lymphocyte produces one type of Ag receptors only, antigen selects and stimulates cells carrying receptors specific for the antigen 1 2 n 2 2 2 2 2 2

  25. s s s s s s s s s s s s s s s s s s s s s s s s s s s s s s s s s s s s s s s s s

  26. Immunological memory • The ability of the immune system to respond more rapidly and effectively to specific pathogens that have been encountered previously. • Reflection of the pre-existence of a clonally expanded population (pool) of antigen specific lymphocytes.

  27. The adaptive immune mechanisms • Humoral immune responses • B cells and antibodies • Cell mediated immune responses • Cytotoxic T cell (Tc) • Helper T cells (TH)

  28. The Immune Recognition Molecules of the Adaptive Immune System • Immunoglobulin (Ig) • B Cell Receptor (BCR) • Antibody (Ab) • T Cell Receptor (TCR) • Major Histocompatibility Complex (MHC)

  29. B Cells work chiefly by secreting soluble substances known as antibodies (Ab)

  30. Ab basic structure domains

  31. Ab V and C regions

  32. Antibody functions • Neutralization: e.g. toxins, viruses • Opsonization: bind pathogens for recognition by other immune cells (e.g. phagocytes)

  33. Tc Target Tc

  34. TH cells play a central role in the immune system

  35. CD4+ T cells in HIV infection

  36. Immunological tolerance • A state of unresponsiveness to a particular Ag - Ag specific • to Ags derived from body’s own tissues/cells - self tolerance • to pathogen-derived/foreign Ags

  37. The concepts of immunological ‘self’ & ‘non-self’ • Immune system does not attack self tissues or cells under normal condition, but how? • Central tolerance – “thymic education” • Peripheral tolerance – failed-safe mechanisms

  38. Central tolerance – “thymic education” • Early in life (foetal stage) • T cells are important, which develop in the thymus • TCR specificities: randomly generated  many auto-reactive • T cells recognize self components (Ag) in the thymus  removed • Non-self reactive cells  selected, matured & exported

  39. Peripheral tolerance • Post-thymic “continuing education” • not all self Ags present in the thymus • some auto-reactive cells can escape • Mechanisms: • Deletion • Inactivation (anergy) • Suppression

  40. A question for thoughts: Does the immune system mount responses simply to anything that is “non-self”?

  41. Summary Immunity: • Innate (natural) • Adaptive (acquired) • Humoral (B cells, Abs) • Cellular (T, NK, MQ) The adaptive immunity: • Key features: specificity & memory • Types: humoral & cell-mediated responses • Key players: T & B lymphocytes • TH cells play a central role in the induction & maintenance of immune responses Principle of vaccination: • Vaccination protects us from infection by inducing protective immunity, through establishment of specific immunological memory but bypassing the need for primary infection Immunological tolerance: • Tolerance induction is Ag specific • Central & peripheral mechanisms

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