Transcript Immunology
Immunology IMMUNOLOGY Sherko A Omer MB ChB, MSc., PhD 1 Immunology LYMPHOID ORGANS AND TISSUES 2 Immunology LYMPHOID ORGANS AND TISSUES In the primary organs (thymus and mammalian bursa equivalent) lymphopoiesis occurs, lymphoid stem cells differentiates to lymphocytes which acquire several surface markers and become able to discriminate between self and non self. In secondary lymphoid organs (lymph nodes, spleen, MALT), there are the environments in which the lymphocytes can interact with immunogens to induce an immune response. 3 Immunology THYMUS 4 Immunology THYMUS Thymus is composed from cortical and medullary epithelial cells, stromal cells, interdigitating cells and macrophages. These ‘accessory’ cells are important in the differentiation of the immigrating T cell precursors and their ‘education’ (positive and negative selection) prior to their migration into the secondary lymphoid tissues. 5 Immunology THYMUS 6 Immunology THYMUS The thymus has an interactive role with the endocrine. Thymic epithelial cells produce the hormones thymosin and thymopoietin and in concert with cytokines (such as IL-7) are probably important for the development and maturation of thymocytes into mature T cells. 7 Immunology THYMIC SLECTION Positive selection of cells whose receptor binds MHC molecules. Negative selection and death of cells with high-affinity receptors for self-MHC or selfMHC+ self-antigen. 8 Immunology THYMIC DISORDERS Impairment of thymus development leads to immune deficiency such as in DiGeorge Syndrome (cellular immune deficiency, congenital cardiac anomalies, abnormal fascies and hypoparathyroidism). Patient with systemic lupus erythematosus (SLE) or myasthenia gravis may show lymphoid hyperplasia or thymoma. 9 Immunology MAMMALIAN EQUIVALENT BURSA Not identical organ such as bursa Gut associated lymphoid tissue (appendix, Peyer’s patches) histologically resembles the birds bursa. In human foetal liver and bone marrow are equivalent to bursa where B cell differentiation and maturation take place. 10 Immunology MAMMALIAN EQUIVALENT BURSA The bone marrow gives rise to all of the lymphoid cells that migrate to the thymus and mature into T cells, as well as to the major population of conventional B cells. B cells mature in the bone marrow and undergo selection for non-self before making their way to the peripheral lymphoid tissues. 11 Immunology LYMPH NODES Encapsulated round or beanshaped structures that are present in high numbers at junctions of major lymphatic tracts. In the resting state lymph nodes are about 1-25 mm in length but they enlarges during infection and when they are invaded by malignancy. 12 Immunology Structure of a lymph node 13 Immunology LYMPH NODES Within the cortex there are few aggregations of predominately B cells with mIgD (primary follicles). Activation of B cells in the germinal centre of primary follicles results in division of B cells to generate secondary follicles that contain mostly IgG-bearing B cells. 14 Immunology LYMPH NODES In secondary follicles stimulated B cells matures to plasma cells in cords in the medulla where they secrete Immunoglobulin. In the deep cortex or paracortical area, T lymphocytes are the predominant cell population. DCs are also present in this area, where they present antigen to T lymphocytes. 15 Immunology LYMPH NODES The medulla, less densely populated, is organized into medullary cords draining into the hilar efferent lymphatic vessels. Plasmablasts can be easily identified in the medullary cords. 16 Immunology SPLEEN 17 Immunology SPLEEN The spleen is the major site of immune responses to bloodborne antigens. The spleen is also an important filter for the blood. Its red pulp macrophages clear the blood of microbes and other particles. The spleen is the major site for the phagocytosis of antibody-coated (opsonised) microbes. 18 Immunology MUCOSAL-ASSOCIATED LYMPHOID TISSUES MALT encompass the lymphoid tissues of the intestinal tract, genitourinary tract, tracheobronchial tree, and mammary glands. MALT are unencapsulated and contain both T and B lymphocytes, the latter predominating. 19 Immunology MUCOSAL-ASSOCIATED LYMPHOID TISSUES GALT (Gut-associated lymphoid tissues) is the designation proposed for all lymphatic tissues found along the digestive tract. Three major areas of GALT that can be identified Tonsils Peyer’s patches, located on the submucosa of the small intestine and the appendix Scanty lymphoid tissue is present in the lamina propria of the gastrointestinal tract 20 Immunology MUCOSAL-ASSOCIATED LYMPHOID TISSUES Lymphoid complexes along the gastrointestinal tract; volume of the rings indicates the relative amount of lymphoid tissue. 21 Immunology MUCOSAL-ASSOCIATED LYMPHOID TISSUES 22 Immunology MUCOSAL-ASSOCIATED LYMPHOID TISSUES 23 Immunology MUCOSAL-ASSOCIATED LYMPHOID TISSUES 24 Immunology MUCOSAL-ASSOCIATED LYMPHOID TISSUES M cells, present largely in the dome epithelia of Peyer’s patches, particularly at the ileum. These cells take up small particles, virus, bacteria, and deliver them to sub-mucosal macrophages, where the engulfed material will be processed and presented to T and B lymphocytes. 25 Immunology LYMPHOCYTE RECIRCULATION 26 Immunology LYMPHOCYTE RECIRCULATION The cells of the lymphatic system circulate continuously and reach all parts of the body with a few exceptions (vitreous body, brain, testicles). They reach the lymph nodes, skin, and intestine via a specialized endothelium of post-capillary venules, the so-called high endothelial venules (HEV). The cells of this endothelium are much higher than normal endothelial cells. 27 Immunology LYMPHOCYTE RECIRCULATION In response to certain chemotactic factors, lymphocytes migrate to the underlying tissue (diapedesis). The lymphatic cells re-enter the circulation through efferent lymph vessels that merge into the thoracic duct. The lymphocytes enter the spleen via arterioles and sinusoids and exit the organ via the splenic vein 28 Immunology LYMPHOCYTE RECIRCULATION Mucosal B cells circulate between different segments of the MALT, including the GALT, the mammary glandassociated lymphoid tissue, and the lymphoid tissues associated with the respiratory tree and urinary tract. T cells migrate to lymph nodes. The selectivity in migration is due to presence of homing receptors on lymphocytes surface that can bind with the endothelial cells in HEV. CD44, on lymphocytes and endothelium are important in these routings. 29 Immunology LYMPHOCYTE RECIRCULATION 30 Immunology ADHESIOIN MOLECULES Surface molecules called cell adhesion molecules (CAMs) that interact with ligands, including other CAMs, expressed on the membrane of T and B lymphocytes. Three main families of CAMs have been defined: Selectins Immunoglobulin superfamily of CAMs Integrins 31 Immunology MAJOR HISTOCOMPALABILITY COMPLEX Mammalian species possess a tightly linked cluster of genes, the major histocompatibility complex (MHC). The MHC is referred to as the Human Leukocyte Antigen (HLA) complex in humans and as the H-2 complex in mice. MHC are important in graft rejection. 32 Immunology MAJOR HISTOCOMPALABILITY COMPLEX Class I MHC genes encode glycoproteins expressed on the surface of nearly all nucleated cells; the major function of the class I gene products is presentation of peptide antigens to TC cells. 33 Immunology MAJOR HISTOCOMPALABILITY COMPLEX Class II MHC genes encode glycoproteins expressed primarily on antigen-presenting cells (macrophages, dendritic cells, and B cells), where they present processed antigenic peptides to TH cells. Class III MHC genes encode, in addition to other products, various secreted proteins that have immune functions, including components of the complement system and molecules involved in inflammation 34 Immunology MAJOR HISTOCOMPALABILITY COMPLEX Class II MHC genes encode glycoproteins expressed primarily on antigen-presenting cells (macrophages, dendritic cells, and B cells), where they present processed antigenic peptides to TH cells. Class III MHC genes encode, in addition to other products, various secreted proteins that have immune functions, including components of the complement system and molecules involved in inflammation. 35 Immunology INHERITANCE OF MHC An individual inherits one haplotype from the mother and one haplotype from the father. The alleles are codominantly expressed; that is, both maternal and paternal gene products are expressed in the same cells. The chance of two siblings to have both haplotypes identical is 25%, one haplotype identical is 50% and zero haplotype identical is 25%, provided the chance of recombination is neglected. 36 Immunology INHERITANCE OF MHC 37 Immunology INHERITANCE OF MHC 38 Immunology MHC CLASS I MOLECULE 45-kiloDalton (kDa), chain associated noncovalently with a 12-kDa 2-microglobulin molecule. The chain is a transmembrane glycoprotein encoded by polymorphic genes within the A, B, and C regions of the human HLA complex. 2-Microglobulin is a protein encoded by a highly conserved gene located on chromosome 15. 39 Immunology MHC CLASS I MOLECULE Class I molecules are present on the surface of all nucleated cells and on platelets. CD8+ cells can recognize antigen only when this antigen is associated with self class I molecule on the surface of cells (virally infected, tumour cell) this is called MHC restriction. 40 Immunology MHC CLASS I MOLECULE CD8+ cells cannot recognize antigen alone or when these antigens are associated with different MHC class I molecules. Class I molecules are called major transplantation antigens because they are recognized by host during graft rejection. 41 Immunology MHC CLASS II MOLECULE Consist of two different polypeptide chains, a 33-kDa chain and a 28-kDa chain. 1 and 2 domains in one chain and 1 and 2 domains in the other. The membrane-proximal 2 and 2 domains, like the membrane-proximal 3/-2-microglobulin domains of class I MHC molecules, bear sequence similarity to the immunoglobulin-fold structure. 42 Immunology MHC CLASS II MOLECULE The membrane-distal portion of a class II molecule is composed of the 1 and 1 domains and forms the antigen binding cleft for processed antigen. 43 Immunology MHC CLASS II MOLECULE Class II molecules are present on surface of B cells, APCs, activated T cells, and in some conditions on resting T cells, thyroid cells. CD4+ cells can recognize antigens only when the antigen is associated with self MHC class II molecule and these molecules are responsible for Graft Versus Host reaction (GVH). 44 Immunology 45 Immunology DETECTION OF HLA MOLECULES HLA molecules can be identified on lymphocytes by: Lymphocytotoxicity test (antibody against HLA molecules with added complement) for detection of both class I and II molecules. Molecular methods. 46 Immunology HLA AND DISEASE ASSOCIATION Most of the diseases associated with HLA are autoimmune in nature; some are infectious (e.g., malaria). Diseases are of unknown aetiology and pathophysiology and with a hereditary pattern of distribution. The diseases are related to immunological abnormalities. 47 Immunology HLA AND DISEASE ASSOCIATION The explanation of HLA disease relation: HLA molecules may act as receptors for etiological agents HLA may act as selective sites for antigen and then the cell present this antigen to induces an immune response The causative agent may mimic HLA molecule 48 Immunology HLA AND DISEASE ASSOCIATION Disease Ankylosing spondylitis Rheumatoid arthritis SLE Multiple sclerosis ID diabetes mellitus Myasthenia gravis Associated HLA Allele B27 DR4 DR3 DR2 DR4/DR3 DR3 Relative Risk 90 10 5 5 20 10 49 Immunology ANTIGEN AND IMMUNOGEN Immunogenicity and antigenicity are related but distinct Immunogenicity is the ability to induce a humoral and/or cell-mediated immune response. Antigenicity is the ability to combine specifically with antibodies and/or TCR. 50 Immunology ANTIGEN AND IMMUNOGEN Small molecules called haptens, are antigenic but incapable, by themselves, of inducing a specific immune response. Haptens lack immunogenicity. Although a substance that induces a specific immune response is usually called an antigen, it is more appropriately to be called an immunogen 51 Immunology IMMUNOGENICITY DETERMINANTS Foreignness, immune system can distinguish self from nonself (foreign) and only reacts against nonself molecules to induce an immune response. Molecular size, potent immunogens have molecular weight more than 100 000 Da while molecules with less than 10 000 Da are none or weak immunogens. 52 Immunology IMMUNOGENICITY DETERMINANTS Chemical complexity, proteins and polysaccharides are among the most potent immunogens, small polypeptide chains, nucleic acids, and even lipids can be immunogenic provided given in an appropriate circumstances. Susceptibility to antigen processing and presentation, Macromolecules that cannot be degraded and presented with MHC molecules are poor immunogens. 53 Immunology IMMUNOGENICITY DETERMINANTS Genetic background of the host, different animal species and different strains of one given species may show different degrees of responsiveness to a given immunogen. Dosage and method of antigen administration, an insufficient dose will not stimulate an immune response either because it fails to activate enough lymphocytes or it may induce tolerance, conversely, an excessively high dose can also induce tolerance 54 Immunology IMMUNOGENICITY DETERMINANTS The method of immunogen administration, a given dose of antigen may elicit no detectable response when injected intravenously, but a strong immune response is observed if injected intradermally. The presence of DCs in the dermis may be a critical factor determining the enhanced immune responses when antigens are injected intradermally. Use of Adjuvants, adjuvants when administered along with immunogens enhance the specific response. 55 Immunology ADJUVANTS Substances that, when mixed with an immunogen and injected with it, enhance the immunogenicity of that immunogen. Adjuvants are often used to boost the immune response when immunogenicity to a material is low or when only small amounts of an immunogen/antigen are available. Examples of adjuvant are Freund’s complete adjuvant (mineral oil, lanolin and killed Mycobacteria) used in animal experiments and Aluminum hydroxide used in vaccines 56 Immunology ADJUVANTS Adjuvants augment the immune response appear to be through one or more of the following effects: Antigen persistence is prolonged Co-stimulatory signals are enhanced Local inflammation is increased The nonspecific proliferation of lymphocytes is stimulated 57 Immunology HAPTEN Chemical coupling of a hapten to a large protein, called a carrier, yields an immunogenic hapten-carrier conjugate Animals immunized with such a conjugate produce antibodies specific for: Hapten determinant Unaltered epitopes on the carrier protein New epitopes formed by combined parts of both the hapten and carrier 58 Immunology EPITOPE (Antigenic Determinate) Sites on or within the antigens with which the antibody or TCR reacts. Structurally an epitope may be in the form of 4-5 amino acids or sugar resides in a linear or conformational form. The numbers of epitopes of an antigen are vary and related to the size of the antigen, the sum of the epitopes determines the specificity of that antigen. 59 Immunology EPITOPE T cells can be trigged by immunogen with one epitope while B cells need at least two epitopes to be triggered. Diagram of sperm whale myoglobin showing locations of five sequential (linear) epitopes 60 Immunology EPITOPE Linear sequence of peptides recognized by T cells Antigenic determinants (epitopes) required by antibodies 61 Immunology T-DEPENDENT AND T-INDEPENDENT ANTIGEN B cells respond to antigen either in a T- dependent (needs TH) or a T- independent fashion. T- independent antigens have high molecular weight with linearly arranged repeating antigenic determinants and are highly resistant to degradation by body enzymes Examples of T-independent antigens are Pneumococcal polysaccharides, Escherichia coli lipo-polysaccharides, and polyvinyl pyrolidine. 62 Immunology T-DEPENDENT AND T-INDEPENDENT ANTIGEN Most natural antigens are TD and requires antigen processing by antigen presenting cells (APCs). Feature Immune response Secondary response Isotype switching Memory cell induction T- independent antigen T- dependent antigen Weak Strong IgM IgM or IgG Negative Positive Poor Good 63 Immunology EXOGENOUS & ENDOENOUS ANTIGEN Exogenous (foreign)… from outside Exogenous antigen include microbial, environmental (pollens and pollutants) and medications. Immune system try to eliminate foreign antigens, but in some instances, the immune response itself may have a deleterious effect, resulting in hypersensitivity or in autoimmune disease. 64 Immunology EXOGENOUS & ENDOENOUS ANTIGEN Endogenous antigens are part of self, the immune system is usually tolerant to them. The response to self-antigens may have an important role in normal catabolic processes (i.e., antibodies to denatured IgG may help in eliminating antigen-antibody complexes from circulation; antibodies to oxidized low density lipoprotein (LDL) may help in eliminating a potentially toxic lipid . 65 Immunology EXOGENOUS & ENDOENOUS ANTIGEN However, the loss of tolerance to self-antigens can also result in autoimmune diseases. Endogenous antigens that distinguish one individual from another within the same species and are termed “alloantigens”, these elicit immune responses when cells or tissues of one individual are introduced into another. 66 Immunology EXOGENOUS & ENDOENOUS ANTIGEN Separate antigen-presenting pathways are utilized for endogenous and exogenous antigens. The mode of antigen entry into cells and the site of antigen processing determine whether antigenic peptides associate with class I MHC molecules in the rough endoplasmic reticulum or with class II molecules in endocytic compartments 67 Immunology 68 Immunology 69 Immunology MITOGEN A substance which causes DNA synthesis and blast transformation, mitogen has also immunostimulatory effects by increasing expansion of B and/or T cells. Concanavalin A (Con A) Phytohaemagglutinin (PHA) Pokeweed mitogen (PWM) Lipopolysaccharide (LPS) T cells T cells T and B cells B cells 70