Section I Immunology Nonspecific Mechanisms To Fight Infection Skin & Mucous Membranes – – – – – – Sweat gland secretions (acidic) Bacterial flora release acids Saliva, tears and mucous secretion Lysozyme in.
Download ReportTranscript Section I Immunology Nonspecific Mechanisms To Fight Infection Skin & Mucous Membranes – – – – – – Sweat gland secretions (acidic) Bacterial flora release acids Saliva, tears and mucous secretion Lysozyme in.
Section I Immunology Nonspecific Mechanisms To Fight Infection Skin & Mucous Membranes – – – – – – Sweat gland secretions (acidic) Bacterial flora release acids Saliva, tears and mucous secretion Lysozyme in tears and perspiration Nostril hairs Stomach acid Phagocytic White Cells and Natural Killer Cells Neutrophils ( majority of wbc’s) - Released from bone marrow – Enter by amoeboid mov’t; live only a few days – Attracted by a chemical signal (i.e., pus) – Capable of phagocytosis or cell lysis (engulf) – Arrive first, eliminate microorganisms & die Phagocyte ingesting polystyrene beads These phagosomes deliver their contents to lysosomes Phagocytic White Cells and Natural Killer Cells (cont.) Monocytes migrate to the tissues (organ & connective) where they enlarge and become macrophages – From bone marrow – Use pseudopodia to phagocytize cells (e.g. bacteria, viruses, & cell debris) – Secrete lysozyme and interferon – Expose molecules of digested bodies to more specialized calls, such as B and Th lymphocytes Phagocytic White Cells (cont.) Eosinophils: Understanding The Immune System - Phagocytes and Granulocytes – Have digestive enzymes in granules which are discharged against pathogen or parasitic worms and Phagocyte antigen - antibody complexes Cells within the tissues of the Immune System Natural Killer Cells or NK To attack, cytotoxic T cells need to recognize a specific antigen, whereas natural killer or NK cells do not. Both types contain granules filled with potent chemicals, and both types kill on contact. The killer binds to its target, aims its weapons, and delivers a burst of lethal chemicals. Mature T cell & Macrophages Bind to receptor on target cells Recruit other cells Can serve as interleukins in that they serve as a messenger between leukocytes or wbc’s Antimicrobial Proteins Complement System – ~ 20 proteins which interact – Attract phagocytes (call chemotaxis) to foreign cells and help destroy by promoting cell lysis Antimicrobial Proteins (cont.) Interferons – Secreted & produced by virus-infected cells – Types: alpha, beta, and gamma – Stimulate production of proteins that inhibit viral replication (including neighboring cells) – Not a virus-specific defense – Works best against short-term infections such as colds and influenza – Activates phagocytes which enhances their ability to ingest and kill microorganisms – Can be mass produced to be tested as treatments for viral infections and cancer Inflammatory Response Occurs when there is damage to tissue due to physical injury or entry of microorganism Vasodilation of small vessels increases the blood supply to the area (redness) Dilated vessels become more permeable, allowing fluids to move in, resulting in a localized edema Inflammatory Response (cont.) Chemical signals initiate the inflammatory response – Histamine released from cells called Basophils and mast cells in connective tissue – Prostaglandins released from white blood cells and damaged tissue (cause increased blood flow) – The increased blood flow delivers clotting elements which help block the spread of pathogenic microbes and begins the repair process Inflammatory Response (cont.) Macrophages destroy pathogens and clean up area Pus may develop before absorbed by the body Bone marrow may release more leukocytes Fever develops due to toxins produced or due to pyrogens released by leukocytes – Fever can inhibit growth of some micro’s Complement System These complement proteins help the antibodies destroy bacteria The diagram shows the C1 encountering an antibody bound to an antigen The end product punctures the cell membrane of the target cell Complements illustrated Section II Immune System Defends the Body Against Specific Invaders Antigen /Antibody Connection Foreign molecules, or antigens, carry distinctive markers, characteristic shapes called epitopes that protrude from their surfaces. Our Immune system has the ability to recognize many millions of distinctive non-self molecules, and to respond by producing molecules, or antibodies - also cells - that can match and counteract each one of the non-self molecules. Antigen/Antibody Continued (2) An antigen can be a bacterium or a virus, or even a portion or product of one of these organisms. Tissues or cells from another individual also act as antigens; that's why transplanted tissues are rejected as foreign. How Antibodies are Produced Third Line of Defense Specificity: recognize and eliminate microorganisms and foreign molecules – Antigen: foreign substances that elicit an immune response Can be molecules exhibited on the surface of, produced by, or released from bacteria, viruses, fungi, protozoans, parasitic worms, pollen, insect venom, transplanted organs, or worn-out cells Each has a unique molecular shape Stimulates production of an antibody that defends specifically against the particular antigen Third Line of Defense (cont.) Antibody: antigen-binding immunoglobulin (protein), produced by B cells; functions as the effector in an immune response. Third Line of Defense Continued: Diversity: ability to respond to invaders which are recognized by their antigenic markers – Based on a variety of lymphocyte pop’s – Each antibody-producing lymphocyte is stimulated by a specific antigen; lymphocytes synthesize and secrete the appropriate antibody Third Line of Defense (cont.) Memory: your immune system can recognize previously encountered antigens and react faster Acquired immunity is a resistance to some infection encountered earlier in life (e.g. chicken pox) Self/nonself recognition: the ability to distinguish between the body’s own molecules versus foreign molecules – Failure leads to autoimmune disorders which destroy body’s own tissue Active Versus Passive Acquired Immunity Active Immunity: conferred by recovery from an infectious disease – Depends on each person’s immune system – Acquired naturally from an infection or artificially by vaccination – Vaccines can be inactivated bacterial toxins, killed microorganisms, or weakened living microorganisms Can no longer cause the disease Can act as antigens and stimulate immune response Active Versus Passive Acquired Immunity (cont.) Passive immunity can be transferred from one person to another by the transfer of antibodies – Antibodies can cross the placenta to the fetus – Some from nursing infants through milk – Persists a few weeks or months until infant’s own system defends its body – Can be transferred artificially from an animal or human already immune to the disease Rabies is treated by injecting antibodies from people vaccinated against rabies Short in duration, but permits your body to begin to produce antibodies against the virus Humoral Immunity and CellMediated Immunity Humoral Immunity: produces antibodies in response to toxins, free bacteria, and viruses – Synthesized by certain lymphocytes and circulate in blood plasma and lymph Cell-mediated Immunity: the response to intracellular bacteria and viruses, fungi, protozoans, worms, transplanted tissues, and cancer Cells of the Immune System Lymphocytes – Responsible for both humoral and cellmediated immunity in that there are two main classes; B cells and T cells Develop from multipotent stem cells in bone marrow, differentiate when they reach the site of maturation B cells (B lymphocytes): the humoral immune and in the bone marrow until maturation T cells (T lymphocytes): the cell-mediated immune response; migrate to the thymus gland to mature Types of cells: B Cells B cells (B lymphocytes): the humoral immune and in the bone marrow until maturation Cells of the Immune System (cont.) – Mature cells (B and T) are concentrated in the lymph nodes, spleen, and other lymphatic organs They are there to contact antigens Antigen receptors are on the membranes of both The receptors on a B cell are membrane-bound antibody molecules which will recognize specific antigens The T cell antigen receptors are proteins (not antibodies) embedded in the membrane which recognize specific antigens Cells of the Immune System (cont.) Effector Cells – Actually defend the body during an immune response – Result from a division of lymphocytes when the binding of antigens to their antigen receptors – Activated B’s give rise to effector cells called plasma cells which secrete antibodies that eliminate the activating antigen – Activated T cells produce two types: Helper T cells: secrete cytokines Cytotoxic T cells: destroy infected and cancer cells Cells of the Immune System (cont.) Helper T cells: secrete cytokines; carry the T4 marker; essential for turning on antibody production; activate cytotoxic T cells Cytotoxic T cells: destroy cells infected by viruses or cancer; subset of T cells Cytokines Cytokine: lymphokines can be produced by lymphocytes & monokines by monocytes & macrophages Section III Clonal Selection of Lymphocytes; Basis for Immunological Specificity and Diversity Response Due to Diversity of Antigen-Specific Lymphocytes Each lymphocyte will respond to only one antigen Determined during embryonic development before antigen are encountered Clonal Selection – antigenic-specific selection of a lymphocyte that activates clones of effector cells that eliminate the antigen that provoked the initial immune response Response Due to Diversity of Antigen-Specific Lymphocytes (cont.) When an antigen enters the body, it binds to receptors on specific lymphocytes – those lymphocytes are activated and begin dividing – These divisions make identical effector cells or clones that bind to the antigen that stimulated the response – e.g., a B cell when activated, will proliferate to make plasma cells that secrete an antibody which acts as a antigen receptor for the specific antigen that activated the original B cell Section IV Memory Cells Action in a Secondary Immune Response Primary Immune Response Primary Immune Response – the making of lymphocytes to form clones of effector cells specific to antigen 5 to 10 day lag between exposure and effector cells Lymphocytes to effector T cells & plasma cells during this time period B cell/Helper T cell/Plasma cell 2nd Immune Response 2nd immune response – when the body is exposed to previously encountered antigens Response is faster and more prolonged Antibodies more effective at binding to antigen 2nd Immune Response (cont) This is called immunological memory – Based on memory cells produced during clonal selection Not active during primary response New clones of effector and memory cells are the 2nd response Section V Self/nonself Recognition with Molecular Markers Surface of Lymphocytes Surfaces have antigen receptors that detect foreign molecules that enter the body – No lymphocytes reactive against the body’s own molecules under normal conditions Surface of Lymphocytes (cont.) Self-tolerance – lack of a destructive immune response to the body’s won cells – Develops (before birth) when T & B lymphocytes begin to mature in the thymus and bone marrow – Any lymphocytes with receptors for molecules present in the body at that time are destroyed Only has antigen receptors for foreign molecules Surface of Lymphocytes (cont.) Mayor histocompatibility complex (MHC or HLA) are glycoproteins within the plasma membrane; Histocompatibility Molecules – – – – “Self-markers” coded by a family of genes 20 MHC genes & 100 alleles for each gene No one has the same markers except identical twins Two main classes of MHC molecules Class 1 MHC molecules on nucleated cells (fig. 43.16) Class 2 MHC molecules on specialized cells like (fig. 43.17) macrophages, B, and active T cells Section VI The Humoral Response; B Cells Defend against Pathogens by Generating Specific Antibodies Background Facts B cells differentiate into a clone of plasma cells that secrete antibodies (fig. 43.17) Most effective against pathogen is blood or lymph Memory cells produce and form the basis for 2nd immune response Activation of B Cells First step: binding of the antigen to specific antigen-receptors on the surface of B cells 2nd step is the B cell activation involving macrophages & helper T cells; ends with the production of plasma cells (p. 909 fig 43.14 & p. 911, fig 43.17) – Macrophage phagocytes pathogens Activation of B cells (cont.) – Pieces of digested antigen bind to class 2 MHC molecules that are moved and present on the surface of macrophage – This is called an antigen-presenting cell – Helper T cell specific of the presented antigen binds to self/nonself MHC complex – T cell is activated and forms a clone of helper T cells Activation of B cells (cont.) – These T cells secrete cytokines which elicit other B cells with the same antigen (Fig. 43.17) – T cell contact activates these B cells to form a clone of plasma cells – Each plasma cell (=effector cell) then secretes antibodies specific for the antigen Antibody and cell – mediated Responses Activation of B cells (cont.) – Each macrophage can display a # of different antigens depending on the type of pathogen phagocytized – B cells again are specific and can bind to and display only one type of antigen – Macrophages are nonspecific & can enhance specific defense by selectively activating helper T cells which in turn activate B cells specific for the antigen – Helper T cells are antigen-specific T-dependent & T-independent Antigens T-dependent antigens – antigens that evolve the cooperative response involving macro’s, helper T’s, & B cells T-independent antigens – antigens that trigger humoral immune responses without macrophage or T cell involvement – Stimulated by the antigen which binds to several antigen receptors on the B cells surface T-dependent & T-independent Antigens (cont.) – Usually weaker – No memory cells are generated Whether dependent or independent, a B cell gives rise to a clone of plasma cells – Each effector cell secretes up to 2000 antibodies / sec for 4 to 5 days Molecular Basis of AntigenAntibody Specificity Antigens are proteins or large polysaccharides of the outer part of pathogens or transplanted cells – Can be coats of viruses, capsules, and cell walls of bacteria – Molecules of transplanted tissues and organ or blood cells are recognized as foreign Antibodies recognize the surface of an antigen or the epitope, not the entire antigen molecule (see fig. fig 43.10), sometimes call the antigenic determinant Molecular Basis of AntigenAntibody Specificity (cont) Antibodies are Proteins in a Class Called Immunoglobulins (lgs) – See fig. 43.18 – Structure associated with its function – Y-shaped with 4 polypeptide chains: two identical light chains and two identical heavy chains – All 4 chains have constant C regions that vary little in a.a. sequence Molecular Basis of AntigenAntibody Specificity (cont) – At the tips of the Y are variable (V) regions; show extensive variation from antibody to antibody Functions as antigen-binding sites that result in specific shapes that fit and bind to specific antigen epitopes This site is responsible for the antibody’s ability to identify specific epitope and stem (constant) regions through which the antibody inactivates or destroys the antigenic invader Molecular Basis of AntigenAntibody Specificity (cont) – 5 types of constant regions which are the five major classes of mammalian immunoglobins (table 43.18) IgM – 5 Y-shapes monomers; appear in the initial exposure to an antigen IgG – most abundant’ fights against bacteria, viruses, and toxins in blood IgA – in mucous membranes; prevent bacteria and viruses from attaching to epithelial surfaces; in saliva, tears, perspiration IgD – found on B cells; initiates differentiation of B cells IgE – stimulates basophils and mast cells to release histamine and cause allergic reaction when triggered by an antigen Section VII In the Cell-Mediated Response, T Cells defend Against Intracellular Pathogens The Cell-Mediated Immune Response It is the defense that combats pathogens that have already entered cells Key components are helper T cells (TH) and cytotoxic T cells (TC) T cells cannot detect free antigens in the body fluids The receptor of a helper T cell recognizes the molecular combination of an antigen fragment with a class 2 MHC The Cell-Mediated Immune Response (cont.) The receptor of a cytotoxic T cell recognizes the combination of an antigen fragment with a class 1 MHC molecule The MHC-antigen complex displayed on an infected body cell stimulates T cells to multiply and form clones of TH and TC which recognized the pathogen The Cell-Mediated Immune Response (cont.) (TH) cells stimulate B cells to secrete antibodies against T-dependent antigens in a humoral response (TH) cells also activate other types of T cells to mount cell-mediated responses to antigens Helper T cells are able to stimulate other lymphocytes by receiving and sending cytokines such as interleuking-2. Increased levels of cytokines also increase the cell-mediated response by stimulating another class of T-cells into cytotoxic cells (effector cells) Section VIII Complement Proteins Participate in Both Nonspecific and Specific Defenses Complement Proteins circulate in the Blood in Inactive Forms Complement protein attaches to, and bridges the gap between, two adjacent antibody molecules This antibody-complement activates proteins to from a membrane attack complex Complement Proteins circulate in the Blood in Inactive Forms (cont.) This membrane attack complex lyses the pathogen’s membrane producing a lesion and the lyses of the cell There is also a nonspecific defense mechanism Complement and phagocytes work together two ways – Opsonization where the proteins attach to a foreign cell and stimulate phagocytes to engulf the cell – In immune adherence, where they coast a microbe which causes to adhere to blood vessel walls and sets it up for circulating phagocytes