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Transcript
Immunology Chapter 20 • • • • • • • • Richard L. Myers, Ph.D. Department of Biology Southwest Missouri State Temple Hall 227 Springfield, MO 65804 417-836-5307 [email protected] Homepage: http://science.smsu.edu/~myers Autoimmunity • Autoimmunity results when the immune system responds to self-components – tolerance usually protects an individual – protection is through clonal anergy or clonal suppression • A breakdown in tolerance can lead to selfreactive clones of T or B cells – can cause serious damage to cells and organs Organ-specific disease • Humoral or cell-mediated damage can be directed to target organs • Cellular damage – antibodies or lymphocytes bind to cellmembrane antigens – cause cellular lysis/inflammatory response – function of the organ is gradually lost Hashimoto’s thyroiditis • Autoantibodies are produced – also sensitized TTDH cells • Characterized by infiltration of lymphocytes, macrophages and plasma cells into the thyroid – the inflammatory response causes a goiter – an enlargement of the thyroid gland • Autoantibodies react with thyroid proteins, interfering with iodine uptake Autoimmune anemias • Includes 1) pernicious anemia, 2) autoimmune hemolytic anemia and 3) druginduced hemolytic anemia • Pernicious anemia caused by antibodies to an intestinal protein, intrinsic factor – prevents uptake of vitamin B12 • Autoimmune hemolytic anemia caused by autoantibodies to RBC antigens – results in complement-mediated lysis or antibody-mediated opsonization Goodpasture’s syndrome • Autoantibodies specific for basement membrane antigens produced – bind to membranes of kidney glomeruli and alveoli of the lungs – complement activation leads to cell damage and inflammatory response • Damage is progressive kidney damage – and pulmonary hemorrhage Insulin-dependent diabetes • Insulin-dependent diabetes mellitus (IDDM) – caused by autoimmune attack on the pancreas – large numbers of TDTH cells and macrophages – directed to insulin-producing cells (beta cells) • Result is decreased production of insulin – therefore increased levels of blood glucose • Beta cell destruction mediated by cytokines – also lytic enzymes from activated macrophages – autoantibodies may also contribute Normal islets (left) and diabetic (right). Note selective loss of beta cells (brown) and infiltlration by lymphocytes Diseases caused by autoantibodies • Antibodies bind to hormone receptors – stimulate inappropriate activity • Graves’ disease is a good example – thyroid-stimulating hormone (TSH) binds to a receptor on thyroid cells – activates adenylate cyclase to stimulate thyroid hormones • In Graves’ an autoantibody is produced to the receptor for TSH Diseases caused by blocking-autoantibodies • Autoantibodies bind to hormone receptors – act as antagonists – inhibit receptor function • Myasthenia gravis is the prototype disease – autoantibodies are produced to the acetylcholine receptors – on motor end-plates of muscles – inhibits muscle activation Systemic autoimmune diseases • Represent a generalized defect in immunity – – – – hyperactive T and B cells cause tissue damage from autoantibodies and cell-mediated also immune complexes important Systemic lupus erythematosus • SLE is the best example of a systemic autoimmune disease • Usually occurs in young women – characterized by fever, weakness, joint pain, erythematous lesion, pleurisy and kidney dysfunction • Patients produce autoanibodies to a variety of tissue antigens like DNA, histones, etc. – diagnosis made by identifying ANA Animal models for autoimmunity • We understand more about autoimmunity because of animal models – autoimmunity develops spontaneously – can also be induced experimentally • Examples of spontaneous autoimmunity – systemic lupus erythematosus – nonobese diabetic (NOD) mouse Experimentally induced autoimmunity • Several experimental animal models are very similar to certain autoimmune diseases • Experimental autoimmune encephalomyelitis – an excellent model for understanding autoimmunity – produced by immunizing animals with MBP • in Freund’s adjuvant – animals develop cellular infiltration of myelin sheaths resulting in demyelination and paralysis – model for multiple sclerosis Role of CD4 in autoimmunity • CD4 is the primary mediator of autoimmunity • However, to become autoimmune – must possess MHC and T-cell receptors capable of binding self-antigens Evidence for association of MHC • There is association between expression of a particular MHC allele and suceptibility to autoimmunity • Can be shown by using antibodies to HLA alleles – some allelles occur at higher frequency amoung autoimmune individuals – association expressed as relative risk – values above 1 indicate association Mechanism for induction • Autoimmunity usually develops from a number of different events • Sequestered antigens – – – – – myelin basic protein is a good example normally sequestered from the immune system by the blood brain barrier trauma or an infection releases antigens i.e., sperm after vasectomy, lens protein after eye damage and heart antigens after infarction • Molecular mimicry – Some bacteria and viruses possess antigens identical to the host – fairly common – i.e., cross-reacting antibodies causing rheumatic fever – another example are the heat-shock proteins – produced by cells following temperature – these proteins found in a variety of pathogens – therefore, when you make a response to a pathogen’s heat-shock proteins, it will crossreact through molecular mimicry • Inappropriate expression of class II MHC – in insulin-dependent diabetes mellitus (IDDM) healthy beta cells do not express class II MHC – same for thyroid acinar cells – an inappropriate expression sensitizes T cells to peptides derived from the beta cells or thyroid cells Treatment of autoimmune disease • Treatments are aimed at reducing symptoms • They provide nonspecific suppression of the immune response – does not differentiate between good and bad • Use immunosuppressive drugs – i.e., corticosteroids, azathioprine and cyclophamide – patients at greater risk for infections or cancer Assignment • Read Chapter 21, Immunodeficiency Diseases • Review question 3 (pg 521)
