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Introduction to the Immune Response The central problem dealt with by the immune system is invasion by microbial pathogens The main task of the immune system is to distinguish self from non-self It must not attack and destroy self, but must eliminate: 1. Whole organisms (bacteria and fungi) 2. Intracellular pathogens (viruses) Innate VS Acquired Immunity Innate immunity Natural immunity, very old in evolution Anatomic barriers: skin- epidermis has keratin, low pH, prevents bacterial growth mucous membranes- trap organisms Physiologic barriers: Temperature, pH, oxygen tension, soluble factors Soluble factors include: lysosyme- found in mucous, cleaves bacterial peptidoglycans interferons- antiviral effects, produced by infected cells complement- series of proteins, form a cascade on exposure to sialic acid, lead to bacterial lysis Endocytosis/Phagocytosis Endocytosis (all cells) delivers macromolecules to endosomes Phagocytosis (monocytes, macrophages, neutrophils) engulfs particles/organisms via receptors, degrades them in lysosomes the receptor for this binds lipopolysaccharides on bacteria. Inflammatory Response Vasodilation- increase in blood vessel diameter increase in capillary permeability, exudate released influx of phagocytic cells Margination- adherence to capillary wall Extravasation- exit from capillary Chemotaxis-migration towards area of inflammation Soluble mediators involved in inflammation Acute phase proteins- released by liver,bind polysaccharides, initiate complement cascade Histamine- released following injury, stimulate vasodilation Kinins- released following injury, stimulate vasodilation, stimulate pain receptors in skin Receptors involved in innate immunity Discriminate between pathogens and self Use germline-encoded receptors that recognize patterns Toll-like receptors (TLR) Binding of these receptors activates the innate cell Examples of TLRs and their ligands TLR-2- Certain bacterial lipoproteins and glycolipids TLR-4- LPS, found in membranes of Gram- bacteria TLR-5- Flagellin, a protein found in flagella TLR-6- Certain bacterial lipoproteins and glycolipids TLR-9- unmethylated CpG dinucleotides (found in bacteria) Acquired Immunity (Adaptive, Specific) Characterized by more rapid, stronger memory response (anamnestic) First appears in evolution in cartelagenous fishes Can detect subtle changes in proteins, carbohydrates, and lipids This response is specific It must detect self versus non-self It must differentiate different forms of non-self Antigen (Ag)- the molecule or structure against which the immune response is directed The immune response only sees bio-organic molecules The antigenic universe is incredibly diverse This diversity must be overcome by the immune response Genetic change (mutation) Can rapidly alter Ags on pathogens (AIDS virus has 1-3 mutations per progeny) The antigenic universe is constantly changing B and T cells: bear receptors for antigens, that distinguish self from non-self These receptors/cells help remove Ag from the body B cell receptor- antibody (Ab) Abs can be found on the cell surface or in secreted forms T cell receptor (TCR) Only found on the T cell surface Binds Ag on the surface of other cells Robert Koch- discovered antibody responses Injected animals with bacteria or toxins. A transferable substance in blood protected against challenge Theories of Ab formation Instructional: Ag helps determine specificity of Ab molecule Selective: Ag selects pre-made Ab Side Chain Theory- Paul Ehrlich (~ 1900) Agent (Ag) binds to side-chain receptor Results in release of receptor Induces production and release of more side-chain receptor Repertoire of Ab exists independently of Ag Ag selects particular side chain it reacts with Karl Landsteiner (1930’s-40’s) Made synthetic organic molecules All induced Ab resposes Too much diversity! Cast doubt on selective theories Linus Pauling (1930’s-40’s) Selected Abs were “blanks”, influenced by Ag to generate diversity Failed to explain memory or self recognition Clonal Selection Theory Burnett (1950s) Only certain cells make Ab Every one of these cells makes a different Ab Each cell produces Abs of a single specificity Ab is displayed on cell surface Specificity of Ab is generated randomly Any cell making self-reactive Abs is eliminated Cells reacting to antigen proliferate (clonal expansion) Some cells become Ab producers (plasma cells) Other cells become long-lived (memory cells) Generation of Diversity 1. Multiple genes encoding different proteins with different specificities 2. Multiple gene segments which can differentially combine 3. Different junctional joining of gene segments, changing triplet codons 4. Somatic mutation events Orchestration of the Immune Response Immune system cells are generated from bone marrow stem cells Primary lymphoid tissues: Bone marrow- Generates B cells, macrophages, dendritic cells, granulocytes Thymus- Generates T cells Cells from primary lymphoid tissues usually move to secondary tissues Spleen, lymph nodes, tonsils, etc. Effector functions generally occur in secondary lymphoid tissues Cells Critical to Immune Response Antigen presenting cells (APC) Macrophages, dendritic cells (DC) Trap Ag, process Ag, present it on the cell surface Ag presented in context of major histocompatability molecules (MHC) Also can express soluble proteins (cytokines) to activate cells Part of the innate immune system, but activate acquired immunity Effector Cells B cells- Make and secrete Ab Bind and remove (neutralize) Ag Help phagocytes engulf Ag (opsonization) Ab binding Ag can activate complement cascade, causing lysis of bacteria T cells- react to Ag on the cell surface (associated with MHC molecules) CD4 T cells- respond to Ag by secreting cytokines, help other cells CD8 T cells- kill cells expressing Ag on their surface (with MHC) Stops spread of viruses Can kill tumor cells Anatomy of the Immune System The cells and organs of the immune system are connected by blood and lymph Communication is achieved by surface interactions and via cytokines The immune response has two basic aspects: Antigen elimination Inflammation Altered vascular permeability Edema Erythema Fever Cells of the Immune System Granulocytes Neutrophils (PMNs) 50-60% of circulating white cells Phagocytic FcR Short lived Mast Cells/Basophils/Eosinophils Highly granular Granules contain mediators FcR-usually holdHighly IgE granular If IgE cross-linked, release mediators Monocytes/Macrophages Phagocytic FcR allows binding to Ag:Ab complexes Ag presentation Initiates responses of T cells Dendritic Cells (DC) Found all over body Long processes, intercalate between cells Can trap Ag on surface, traffic to Lymph nodes Also found in tissues present Ag and aid differentiation Inflammatory cells are not Ag-specific Interact with Ag via secondary receptors (FcR) Involved in inflammation Activation of acquired responses Cells of the Immune System Lymphocytes Ag-specific B cells Formed in bone marrow in mammals Produce Ab On cell surface Secreted Virgin B cells are IgM+ IgD+ Memory B cells are IgG+, IgA+, IgE+ Do not express IgD T cells Formed in thymus Express T cell markers CD3, CD4, CD8 Ag-specific via TCR CD4 cells = helper CD8 cells = cytotoxic B cells make Ab T cells regulate immune response do not secrete their receptor Lymphatic System Fluid in blood leaks out of capillaries must be returned to circulation pressure in vessles too great to diffuse back Lymphoid system recovers fluid Picked up in capillary sinuses These coalesce into lymphatic vessels Form into larger ducts Fluid returned to subclavian vein Pumped by action of adjacent muscles Drains every part of body Lymph nodes screen for pathogens Nodes packed with leukocytes (lymphocytes, APCs, no granulocytes) Organs of the Immune System Lymph Node Cortex Paracortex Mostly virgin B cells Local concentrations called follicles Proliferation leads to germinal centers Mostly T cells Can move up to help B cells Exit to blood Medulla B cells differentiate into plasma cells Cells egress from here Ag enters via afferent vessel Enters cortical sinus Percolates through Trapped by DC/Macrophages B and T cells activated Bone Marrow Stem cells reside here, differentiate Into B cells, myeloid/erythroid lineages Memory cells and plasma cells reside here Cytokines cause stem cell differentiation and proliferation Thymus T cell differentiation occurs here Progenitors from marrow enter Move to subcapsular space Percolate through Pick up T cell markers Commit to CD4 or CD8 lineage Cells learn self from non-self Spleen White Pulp Functions like lymph node WBC arrive via blood, no afferent lymphatics Leave via efferent lymphatics Red Pulp Removes old RBC Recovers iron Gut Associated Lymphoid Tissue (GALT) Largest lymphoid tissue Contains IgA+ B cells gd T cells present M cells endocytose Ag in lumen Transport it to pocket Seen by immune cells in pocket Ag transported by M cells activates B cells in follicle B cells differentiate into IgA-producing plasma cells Plasma cells migrate to submucosa an secrete IgA