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NONSPECIFIC DEFENSES OF THE HOST Innate Immunity (Non-Adaptive Immunity) (Pre-existing immunity) Immunity you are born with Does not change/adapt during life in response to infection HOST IMMUNE SYSTEM There are over 400 known pathogens of man and each of us is likely to come into contact with at least 150 of them within our life span Include: Viruses (10-20 nm) Bacteria (1-2 um) Protozoa (50-100um) Fungi (10um-10cm) Parasites (Worms & Flukes) (>10cm) Why Do We Need An Innate Immune System? Replication rate of extracellular bacteria with an average doubling time of 20 minutes Dead within 24hrs !!! = 2 x 1021 Innate Immune System comprises of a Cellular arm (cells) and a Humoral arm (soluble factors) IMMUNOLOGY Study of how the body limits invasion by non-self and recognises and eliminates altered self - damaged cells and cancer cells HAEMATOLOGY Study of blood cells and their origins and the homeostatic mechanisms that control coagulation Most types of blood cell are components of the immune system INFECTION Differences between infectious agents and their sites of replication necessitate different immune mechanisms for their control •VIRUSES (DNA & RNA, intracellular replication) •BACTERIA (intracellular / extracellular replication) •FUNGI •PROTOZOA •WORMS DEFENCE AGAINST INFECTION •Physical barriers •Non-adaptive (Innate) immunity •Adaptive immunity NONSPECIFIC RESISTANCE • Defenses that protect the host against ANY pathogen – Mechanical factors – Chemical factors Specific Resistance Specific Resistance, or immunity is based on antibody production It is a defense against a particular microorganism Mechanical Factors The intact skin consists of the dermis, an inner thicker portion composed of connective tissue, and the epidermis, an outer, thinner portion consisting of several layers of epithelial cells The top layer of epidermal cells contains the protein keratin (remember—fungi produce keratinase) • Dermis – Inner thicker portion • Epidermis – Outer, thinner portion • Keratin (waterproofing) SKIN SKIN INFECTIONS • Rare in unbroken skin • Sweat washes microbes off • Cuts and burns may get infected –Subcutaneous infections –Staphylococcus spp. MUCOSAL SURFACES • Epithelial layer • Connective tissue Bronchi Intestine MUCOSAL SURFACES (cont.) •Gastrointestinal tract •Respiratory tract •Urinary tract •Reproductive tract MUCOSAL SURFACES (cont.) • Mucus traps microorganisms • Physical barrier • Cilia lower respiratory tract • Washing (sweat) MUCOSAL SURFACES (cont.) • Mucosal irritation or damage facilitates infection (smoking) • Substances produced by pathogens –Treponema pallidum Flushing of Cavities • Prevents colonization –Tears (lysozyme—breaks down NAG/NAM) –Saliva –Urine –Feces –Sebum (unsaturated fatty acids of sebum inhibit growth of certain pathogens) CHEMICAL FACTORS • Skin –Sebaceous glands •Unsaturated fatty acids •pH 3-5 LYSOZYME • Enzyme that degrades peptidoglycans –Gram positives more susceptible than Gram negatives LYSOZYME (cont.) • Sweat • Saliva • Tears • Nasal secretions GASTRIC JUICE • Hydrochloric acid (pH 1.2 to 3) –Helicobacter pylori •Neutralizes acidic pH • Enzymes • Mucus BLOOD • Iron-binding proteins –Lactoferrins –Transferrins • Iron unavilable for pathogens DEAD TISSUE leads to INFECTION Mechanical, chemical or thermal injury Debride wounds Interruption of blood supply – infarction DEFENCE AGAINST INFECTION •Physical barriers •Non-adaptive (Innate) immunity •Adaptive immunity A variety of immune mechanisms utilising proteins and cells that act in concert to control and eradicate infection Immune mechanisms are targeted by molecular recognition of micro-organisms INNATE IMMUNITY •Mast cells increase blood flow and vascular permeabilitybring components of immunity to site of infection •Phagocytes engulf (phagocytose) and destroy micro-organisms •Complement activate mast cells, attract phagocytes, opsonize and lyze micro-organisms •Acute phase proteins activate complement and opsonise SPECIFIC IMMUNITY For each different antigen there is a specific receptor 1011 different antigens 1 2 3 4 1011 different receptors 1 3 2 4 Exposure to infection Resistance to infection •Climate •Vectors •Population •Housing •Water / sewage •Public health •Mutation •Age •Previous exposure •Vaccination •Nutrition •Disease •immunodeficiency PHAGOCYTOSIS is the body’s second line of defense • Ingestion of particulated matter by a cell –Phagocytes (white blood cells) –Phagocytosis derived from the Greek work “to eat” and “cell” Formed Elements in Blood --Blood fluid is called plasma --Cells and cell fragments of the blood are the formed elements --Most important ones in Immunology are the leukocytes (WBC) --Decreased leukocyte counts are called leukopenia (I.e.Thrombocytopenia) A differential white blood count detects leukocyte number changes Leukocytes are subdivided into three categories GRANULOCYTES---have granules in their cytoplasm (neutrophils, basophils, eosinophils) LYMPHOCYTES (are note phagocytic—occur in lymphoid tissue) MONOCYTES (lack granules & are phagocytic only after maturing into MQ) PHAGOCYTES • Neutrophils (60-70%) –Initial phagocytic cells • Monocytes/Macrophages (38%) –Final phagocytic cells Granulocytes Eosinophil (0-2%) Neutrophils (45-74%) In Blood Eosinophils Target – Worms and flukes Filarial Nematode Larvae Wucheria bancrofti Migrates within tissues Granulocytes are mostly neutrophils that wander in the blood and can pass through capillary walls to reach trauma sites MQ are highly phagocytic cells called wandering MQ’s b/c of their ability to migrate Fixed MQ’s (histiocytes) enter tissue/organs and remain there (I.e. Kupffer cells in the liver) PHAGOCYTOSIS • Chemotaxis • Adherence • Ingestion • Digestion Avoiding Contact with Phagocytes • Bacteria can avoid the attention of phagocytes in a number of ways • Pathogens may invade or remain confined in regions inaccessible to phagocytes. Certain internal tissues (e.g. the lumens of glands, the urinary bladder) and surface tissues (e.g. the skin) are not patrolled by phagocytes. • Some pathogens are able to avoid provoking an overwhelming inflammatory response. Without inflammation the host is unable to focus the phagocytic defenses. Some bacteria or their products inhibit phagocyte chemotaxis For example, Streptococcal streptolysin suppresses neutrophil chemotaxis, even in very low concentrations Fractions of Mycobacterium tuberculosis are known to inhibit leukocyte migration. • Some pathogens can cover the surface of the bacterial cell with a component which is seen as "self" by the host phagocytes and immune system. Such a strategy hides the antigenic surface of the bacterial cell. • Phagocytes cannot recognize bacteria upon contact and the possibility of opsonization by antibodies to enhance phagocytosis is minimized. • Staphylococcus aureus produces cell-bound coagulase which clots fibrin on the bacterial surface • Treponema pallidum, the agent of syphilis, binds fibronectin to its surface. • Group A streptococci are able to synthesize a capsule composed of hyaluronic acid. Hyaluronic acid is the CHEMOTAXIS • Chemical attraction of phagocyte to microorganism –Microbial products –Damaged tissue –White blood cell components ADHERENCE & ENGULFMENT (INGESTION) • Attachment of phagocyte plasma membrane to microorganism INGESTION • Pseudopods extend from phagocyte plasma membrane and engulf the microorganism forming the phagosome A pathogen is only a pathogen if it “tricks” the immune system’s defense missiles (phagocytes) Inhibition of Phagocytic Engulfment • Some bacteria employ strategies to avoid engulfment (ingestion) if phagocytes do make contact with them • Many important pathogenic bacteria bear on their surfaces substances that inhibit phagocytic adsorption or engulfment • Clearly it is the bacterial surface that matters • Resistance to phagocytic ingestion is usually due to a component of the bacterial cell surface (cell wall, or fimbriae, or a capsule). Classical examples of antiphagocytic substances on the bacterial surface include • Polysaccharide capsules of S. pneumoniae, Haemophilus influenzae, Treponema pallidum and Klebsiella pneumoniae • M protein and fimbriae of Group A streptococci • Surface slime (polysaccharide) produced as a biofilm by Pseudomonas aeruginosa • O polysaccharide associated with LPS of E. coli • K antigen (acidic polysaccharides) of E. coli or the analogous Vi antigen of Salmonella typhi DIGESTION • Within cytoplasma the phagosome fuses with lysosome (digestive enzymes) forming the phagolysosome LYSOSOME CONTENTS • Lysozyme • Hypochlorous acid • Lipases • Toxic O2 • Proteases • Nucleases Survival Inside of Phagocytes • Some bacteria survive inside of phagocytic cells, in either neutrophils or macrophages • Bacteria that can resist killing and survive or multiply inside of phagocytes are considered intracellular parasites • In this case, the environment of the phagocyte may be a protective one, protecting the bacteria during the early stages of infection or until they develop a full complement of virulence factors • The intracellular environment guards the bacteria against the activities of extracellular bactericides, antibodies, drugs, etc. BACTERIAL INTRACELLULAR PATHOGENS Organism Disease Mycobacterium tuberculosis Tuberculosis Mycobacterium leprae Listeria monocytogenes Salmonella typhi Shigella dysenteriae Yersinia pestis Brucella species Legionella pneumophila Leprosy Listeriosis Typhoid Fever Bacillary dysentery Plague Brucellosis Pneumonia Typhus; Rocky Mountain Spotted Fever Chlamydia; Trachoma Rickettsiae Chlamydia • Many intracellular parasites have special (genetically-encoded) mechanisms to get themselves into host cells that are nonphagocytic • Intracellular pathogens such as Yersinia, Listeria, Salmonella, Shigella and Legionella possess complex machinery for cellular invasion and intracellular survival • These systems involve various types of non-toxin virulence factors • Sometimes these factors are referred to as bacterial invasins • Still other bacteria such as Bordetella pertussis and Streptococcus pyogenes, have recently been discovered in the intracellular habitat of epithelial cells • Intracellular parasites survive inside of phagocytes by virtue of mechanisms which interfere with the bactericidal activities of the host cell. PREVENTION OF PHAGOSOME AND LYSOSOME • Replicate inside phagocyte • Shigella • Mycobacterium • Mycobacteria (including M. tuberculosis) have waxy, hydrophobic cell wall and capsule components (mycolic acids), which are not easily attacked by lysosomal enzymes • In Salmonella typhimurium, the pH that develops in the phagosome after engulfment actually induces bacterial gene products that are essential for their survival in macrophages. KILLING OF PHAGOCYTE • Toxins • Staphylococcus –Actinobacillus • B. abortus and Staphylococcus aureus are vigorous catalase and superoxide dismutase producers, which might neutralize the toxic oxygen radicals that are generated by systems in phagocytes • S. aureus produces cell-bound pigments (carotenoids) that "quench" singlet oxygen produced in the phagocytic vacuole • Escape from the phagosome • Early escape from the phagosome vacuole is essential for growth and virulence of some intracellular pathogens • This is a clever strategy employed by the Rickettsiae • Rickettsia enter host cells in membrane-bound vacuoles (phagosomes) but are free in the cytoplasm a short time later, perhaps in as little as 30 seconds • A bacterial enzyme, phospholipase A, may be responsible for dissolution of the phagosome membrane. • Listeria monocytogenes relies on several molecules for early lysis of the phagosome to ensure their release into the cytoplasm • These include a pore-forming hemolysin (listeriolysin O) and two forms of phospholipase C • Once in the cytoplasm, Listeria induces its own movement through a remarkable process of host cell actin polymerization and formation of microfilaments within a comet-like tail Killing Phagocytes Before Ingestion • Many Gram-positive pathogens, particularly the pyogenic cocci, secrete extracellular enzymes that kill phagocytes • Many of these enzymes are called hemolysins because their activity in the presence of red blood cells results in the lysis of the RBC • Extracellular proteins that inhibit phagocytosis include the Exotoxin A of Pseudomonas aeruginosa which kills macrophages • bacterial exotoxins (Bacillus anthrax toxin EF & Bordatella pertussis toxin AC) which decrease phagocytic activity INFLAMMATION • A localized protective response of the body to tissue injury –Pain –Heat –Redness –Swelling –Loss of function INFLAMMATION FUNCTIONS • To destroy invading agents • Walling off invading agents • Repair or replace damaged tissue Vasodilatation & Increased Permeability of Blood Vessels -Vasodilatation is the 1st stage of inflammation -It involves an increase in blood vessel diameters more blood flow to the injured area -Responsible for the redness, heat, edema (swelling), & pain of inflammation -Histamine is released by injured cells & increases permeability of immune system cells to the site of injury THE COMPLEMENT SYSTEM part II COMPLEMENT SYSTEM • 30 different serum proteins involved in: –Lysis (destruction) of foreign cells –Inflammation –Phagocytosis Blood Serum Blood clot COMPLEMENT SYSTEM • Two cascade activation paths: –Classical (immune system) •Antibodies –Alternative •Interaction with Polysaccharides (mostly bacterial) •Protein C3 activates both the alternative & the classical pathway •Major components of the classical pathway are C1 and C9 Classical pathway is initiated by the binding of AB’s to Ag Alternative pathway is initiated by the interaction of foreign particle with the protein factors (important in combating enteric G- MO) Classical pathway Alternative pathway •Endotoxin (Lipid A) trigger the alternative pathway •The alternative pathway is often known as the lectin pathway •MQ interacting w/ the foreign particle stimulate the liver to secrete lectin, which assists in the opsonization of MO What is opsonization? • Increases the susceptibility of microorganisms to ingestion by phagocytes Complement system & inflammation •C5a is the most potent complement protein triggering inflammation •It causes mast cells to release vasodilators such as histamine so that blood vessels become more permeable •it increases the expression of adhesion molecules on leukocytes and the vascular endothelium so that leukocytes can squeeze out of the blood vessels and enter the tissue (diapedesis) •it causes neutrophils to release toxic oxygen radicals for extracellular killing; and it induces fever COMPLEMENT SYSTEM FUNCTIONS • Cytolysis –Formation of membrane attack complexes by the complement proteins –Damage of plasma membrane • leakage and death of the cell COMPLEMENT SYSTEM FUNCTIONS • Inflammation –Triggers histamine release • Increased blood vessel permeability • Promotes migration of cells to site of inflammation (Humoral) classical pathway Alternative pathway SPECIFIC DEFENSES OF THE HOST: THE IMMUNE RESPONSE IMMUNITY • Specific response to foreign microorganisms or substances –Antibodies –Specialized lymphocytes (B and T) ANTIGENS • Foreign substances or microorganisms that provoke an immune response Types of immunity Acquired immunity Natural Active Passive Artificial Active Passive Infection Colostrum Vaccines Antiserum COLOSTRUM • Fluid rich in protein and immune factors, secreted by the mammary glands during the first few days of lactation SERUM • Fluid remaining after blood has clotted • Fluid where most antibodies are found –Antiserum Blood Serum Blood clot SEROLOGY • The study of antibodies and antigens IMMUNE SYSTEM • Humoral or antibodymediated –B lymphocytes • Cell-mediated –T lymphocytes (TH & TC) HUMORAL IMMUNE RESPONSE • Against: –Bacteria –Bacterial toxins –Viruses outside of cells CELLULAR IMMUNE RESPONSE • Against: –Intracellular agents –Fungi –Protozoa –Helminths –Viruses inside cells ANTIGENS • Proteins • Polysaccharides • Lipids and nucleic acids only if combined with proteins or polysaccharides EPITOPES OR ANTIGENIC DETERMINANTS • Antibodies specifically combine with a small segment of the antigen called the antigenic determinant or epitope to form an antigen-antibody complex • The antigen-antibody reaction is characterized by specificity HAPTEN • Small molecule that needs a large molecule carrier to behave as an antigen • Drugs and pesticides are low molecular weight molecules and can be treated as haptens • By conjugation to larger carrier molecules (albumin), low molecular weight drugs and pesticides can be made antigenic • Not antigenic unless attached to a carrier molecule – Penicillin – Penicillin binding to certain blood proteins (albumin) can become antigenic Penicillin allergy ANTIBODIES OR IMMUNOGLOBULINS (Igs) • Y-shaped proteins made in response to an antigen • Antibodies specifically bind to that antigen by two antigen-binding sites Receptor for macrophages CLASSES OF IMMUNOGLOBULINS • IgG • IgM • IgA • IgD • IgE IMMUNOGLOBULIN G (IgG) –80% of all Igs –Cross blood vessels and enter tissue fluids –Cross human placenta IMMUNOGLOBULIN G (IgG) (cont.) • Protects against circulating bacteria and viruses • Neutralizes bacterial toxins • Trigger the complement system • Facilitates phagocytosis IMMUNOGLOBULIN M (IgM) • 1st AB that appears in response to an AG—however their conc. declines rapidly –Used for diagnosis • 5-10% of all Igs • Pentamer (5 “Y”s) joined by a j chain • Do not cross placenta b/c too big IMMUNOGLOBULIN M (IgM) (cont.) • Predominant AB in the blood typing process rx • Hi IgM conc. Represents an active disease • Aggregates antigens • Triggers the complement system • Facilitates phagocytosis • Antigen receptor of B cell IgM pentamer “J” chain IMMUNOGLOBULIN A (IgA) • 10 - 15% of all Igs • Most common in mucous membranes and body secretions –Mucus, saliva, tears and milk IMMUNOGLOBULIN A (IgA) (cont.) • Dimer (2 “Y”s) joined by a j chain • Prevents attachment (adherence) of pathogens to mucosal surfaces IgA dimer Secretory component “J” chain IMMUNOGLOBULIN E (IgE) • 0.002% of all Igs • Bind to mast cells and basophils • Involved in allergies • Effective against parasitic worms IMMUNOGLOBULIN D (IgD) • Structurally similar to IgG • Unknown function in serum • Antigen receptor on B cell surfaces IgM IgG IgA IgE IgD ANTIGEN-ANTIBODY REACTION • Neutralization –Viruses and toxins • Agglutination (clumping of AG &AB so phagocytes can ingest them better) –Bacterial cells • Precipitation –Soluble antigens viruses (b) Neutralization of viruses by antibodies No access to cell receptors IMMUNE SYSTEM • Humoral or antibodymediated –B lymphocytes • Cell-mediated –T lymphocytes B CELLS AND HUMORAL IMMUNITY • Stem cells in bone marrow –Adults • Liver –Fetuses CLONAL SELECTION OF B CELLS Activated B cell (Lymphocyte) Memory cells Plasma cells (Igs-producing) CLONAL DELETION • During fetal development, clones of lymphocytes that react with self antigens are eliminated (self-tolerance) PLASMA CELLS • Secrete antibodies (Igs) against specific antigens • Short lived • Produce 2000 antibodies per second T-CELL MEDIATED IMMUNITY • Derived from stem cells –Adults •Bone marrow –Fetuses •Liver T-CELL MEDIATED IMMUNITY (cont.) • Mature and differentiate in thymus • Mature T cells migrate to lymphoid organs T-CELL MEDIATED IMMUNITY (cont.) • Clonal selection determines proliferation of T cells that carry out cell-mediated immunity • Respond only to antigens presented by macrophages TYPES OF T CELLS • Cytotoxic (TC) CD8 –Kill altered cells • Helper (TH) CD4 –Activate B, TH, and TC cells TYPES OF T CELLS (cont.) • Delayed Hypersensitivity (TD) CD4 and CD8 –Anti-cancer, allergies • Suppressor (TS) CD4 and CD8 – Suppress immune response NATURAL KILLER (NK) CELLS • Non-T lymphocytes • Not specific • Kill altered cells CYTOKINES (INTERLEUKINS) • Chemical messengers of the immune system –Interleukin-1 •Stimulates TH cells –Interleukin-2 •Proliferation of TH cells