Immune response to infections Factors influencing the extent and severity of infection • Pathogen factors – Dose – Virulence of organism – Route of entry • Host factors – Integrity of non-specific defences – Competence of the immune system – Genetic influences – Previous exposure to antigen – Existence of co-infection Immune response to viral infections – Non-speciphic immunity • Interferons ( a and b) • Natural killer cells (NK cells) • Receptor-like molecules in various secretions – Speciphic immunity • Antibodies – neutralization of extracellular viruses • Tc lymphocytes – elimination of virus-infected cells Mechanisms of antiviral immunity The action of interferon (IFN) Natural killers (NK cells) • Originate in non-T non-B lymphocyte lineage. • Morphologically: large granulated lymphocytes (LGL). • Recognition of target cells in antigen non- speciphic. • Virus infected and tumor cells are killed. • Target cells are recognisd mainly by decreased HLA-I expression. • Cytotoxic mechanisms are similar to Tc cells: perforin and induction of apoptosis. Viral strategies to evade the immune response • Antigenic variations – antigenic drift - minor changes – antigenic shift - major changes • Long-term survival in a host – Viral persistence – Viral latency – Oncogenic transformation • Immunosuppressive effect of viruses Immunosuppressive effects of viruses • Suppression of T-cells : HIV, morbilli, CMV, • Inhibition of MHC antigens expression: CVM (binds b-2 microglobulin), Adenoviruses, RSV - decreased expression of HLA antigens • Production of inhibitory cytokies: EBV ( IL- 10 - like factor) Damage of a host caused by anti-viral immune response • Autoimmune diseases: hemolytic anemia after EBV infection, autoimmune hepatitis induced by hepatitis-B virus • Immune complex diseases: arthritis in hepatitis B, vasculitis • Tc - meadited diseases: rash in exanthematic viral diseases, myocarditis caused by coxackie virus Immune responses to bacterial infections • Non-specific immunity – Mechanical barriers – Phagocytosis – Complement system • Specific immunity – Antibodies - opsonisation, complementactivation, neutralisation of toxins, binding to receptors – T-lymphocytes - against intracellular parasites Bacterial evasions of immune defences • Antiphagocytic machanisms: toxins, capsular polysaccharides • Inhibition of the complement system: Str. pyogenes, E. coli, N. meningitidis • Antigenic variations: Borrelia recurrentis • Proteases lysing IgA - Neisseria, Haemophilus • Sequestration in avascular regionsSalmonella typhi in the gall bladder and urinary tract • Intracellular parasitism Macroorganism damage caused by the immune response to bacterial infection • Autoimmune diseases – Cross-reactivity of bacterial and corporal antigens - rheumatic fever – Type-II hypersensitivity - autoimmune hemolytic anemia caused by Mycoplasma infection – Heat shock proteins – Superantigens (streptococcal, staphylococcal) • Immunocomplex diseases • Type IV hypersensitivity- cavitatoin in pulmonary tuberculosis Activation of TCR by antigen and superantigen MHC class II Signal transduction Superantigen T cell APC TRC Signal transduction αβ α β αβ α β Antigen Mechanisms of anti-fungal resistance • Normal bacterial flora • Phagocytic cells • T-lymphocytes -probably most important • Antibodies - usually present, but no protective effect Imunity against parasites • Different mechanisms involved against different parasites. • Immune response frequently leads to premunity – the situation when the parazite perzists, however it does not lead to dissemination and new infections. • IgE and esinophils play a crucial role. Downloaded from: StudentConsult (on 4 August 2013 10:32 AM) © 2005 Elsevier Role of IgE and mastocytes in protection against parasites