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PowerPoint® Lecture Slides for MICROBIOLOGY Hypersensitivities, Autoimmune Diseases, and Immune Deficiencies Hypersensitivity Any immune response against a foreign antigen that is exaggerated beyond the norm 4 types Type I (immediate) Type II (cytotoxic) Type III (immune-complex mediated) Type IV (delayed or cell-mediated) Type I (Immediate) Hypersensitivity Localized or systemic reactions that result from the release of inflammatory molecules in response to an antigen Develop within seconds or minutes following exposure to an antigen Commonly called allergies and the antigens that stimulate them are called allergens Mast Cells Found in sites close to body surfaces such as the skin and the walls of the intestines and airways Characteristic feature is a cytoplasm filled with large granules Granules contain a mixture of potent inflammatory chemicals Inflammatory molecules released from mast cells Molecules Role in hypersensitivity reaction Released during degranulation Histamine Kinins Smooth muscle contraction, increased vascular permeability, irritation Smooth muscle contraction, inflammation, irritation Proteases Damage tissues and activate complement Synthesized in response to inflammation Leukotrienes Slow prolonged smooth muscle contraction Prostaglandins Some contract smooth muscles, others relax it Basophils and Eosinophils Basophils Leukocytes that contain granules that stain with basophilic dyes Granules filled with inflammatory chemicals similar to those in the mast cells Sensitized basophils bind IgE and degranulate in the same way as mast cells Basophils and Eosinophils Eosinophils Leukocytes that contain granules that stain with the dye eosin Granules contain inflammatory mediators and leukotrienes that contribute to the severity of a hypersensitivity response Mast cell degranulation stimulates the release of eosinophils that migrate to the site of mast cell degranulation where they then degranulate Clinical Signs of Localized Allergic Reactions Type I hypersensitivity reactions are usually mild and localized Site of the reaction depends on the portal of entry Inhaled allergens may cause hay fever, an upper respiratory tract response Marked by watery nasal discharge, sneezing, itchy throat and eyes, and excessive tear production Commonly caused by mold spores, pollens, flowering plants, some trees, and dust mites Clinical Signs of Localized Allergic Reactions Inhaled allergens that are small may reach the lungs Cause asthma Characterized by wheezing, coughing, excessive production of mucus, and constriction of the smooth muscles of the bronchi Some foods may contain allergens Cause diarrhea and other gastrointestinal signs and symptoms Local dermatitis Produces hives, or uticaria, due to release of histamine and other mediators into nearby skin tissue and the leakage of serum from local blood vessels Clinical Signs of Systemic Allergic Reactions Degranulation of many mast cells at once causes the release of large amounts of histamine and inflammatory mediators Acute anaphylaxis or anaphylactic shock can result Clinical signs are those of suffocation Bronchial smooth muscle contracts violently Leakage of fluid from blood vessels causes swelling of the larynx and other tissues Contraction of the smooth muscle of the intestines and bladder Must be treated promptly with epinephrine Treatment of Type I Hypersensitivity Administer drugs that counteract the inflammatory mediators released by degranulation Antihistamines neutralize histamine Asthma treated with an inhalant containing corticosteroid and a bronchodilator Epinephrine neutralizes many of the mechanisms of anaphylaxis Relax smooth permeability muscle and reduce vascular Used in the emergency treatment of severe asthma and anaphylactic shock Diagnosis of type I hypersensitivity Type II (Cytotoxic) Hypersensitivity Results when cells are destroyed by an immune response, often due to the combined activities of complement and antibodies Is a component of many autoimmune diseases 2 significant examples Destruction of blood cells following an incompatible blood transfusion Destruction of fetal red blood cells in hemolytic disease of the newborn ABO System and Transfusion Reactions Blood group antigens are the surface molecules of red blood cells The ABO blood group consists of two antigens designated A antigen and B antigen Each person’s red blood cells have either A antigen, B antigen, both antigens, or neither Transfusion reaction can result if individual receives blood of a different blood type Donor’s blood group antigens may stimulate the production of antibodies in the recipient that bind and eventually destroy the transfused cells Transfusion Reactions If recipient has preexisting antibodies to foreign blood group antigens Immediate destruction of donated blood cells can occur by two mechanisms Antibody-bound cells may be phagocytized by macrophages and neutrophils Hemolysis- antibodies agglutinate complement ruptures them cells, and Can result in kidney damage, blood clotting and stress on the liver Transfusion Reactions If recipient has no preexisting antibodies to foreign blood group antigens Transfused cells circulate and function normally for a while Eventually recipient’s immune system mounts a primary response against the foreign antigens that destroys them Happens over an extended period such that severe symptoms and signs don’t occur ABO Blood Group Characteristics and Donor/Recipient Matches RH System and Hemolytic Disease of the Newborn Based on the rhesus, or Rh, antigen Antigen that is common to the red blood cells of humans and rhesus monkies Transports anions and glucose across the cytoplasmic membrane Rh positive (Rh+) individuals have the Rh antigen on their red blood cells while Rh- individuals do not Preexisting antibodies against Rh antigen do not occur Risk of hemolytic disease of the newborn Prevention of Hemolytic Disease of the Newborn Administer anti-Rh serum to Rh- pregnant women Destroys any fetal red blood cells that may have entered the body Sensitization of the mother does not occur and subsequent pregnancies are safer Drug-Induced Cytotoxic Reactions Some drug molecules can form haptens Spontaneously bind to blood cells or platelets and stimulate the production of antibodies Can produce various diseases Immune thrombocytopenic purpura Agranulocytosis Hemolytic anemia Type III (Immune-Complex Mediated) Hypersensitivity Due to the formation of antigen-antibody complexes, also called immune-complexes Can cause systemic or localized reactions Systemic Systemic lupus erythematosus Rhematoid arthritis Localized Hypersensitivity pneumonitis Glomerulonephritis Localized Type III Hypersensitivity Reactions Hypersensitivity pneumonitis Individuals become sensitized when antigens are inhaled deep into the lungs, stimulating the production of antibodies Subsequent inhalation of the same antigen stimulates the formation of immune complexes that activate complement Localized Type III Hypersensitivity Reactions Glomerulonephritis Immune complexes circulating in the bloodstream are deposited on the walls of glomeruli (small blood vessels in the kidney’s) Damage to the glomerular cells impedes blood filtration Result is kidney failure and ultimately death Type IV (Delayed or Cell-Mediated) Hypersensitivity Inflammation due to contact with certain antigens occurs after 12-24 hours Result from the interactions of antigen, antigenpresenting cells, and T cells Delay in this response reflects the time it takes for macrophages and T cells to migrate to and proliferate at the site of the antigen Type IV (Delayed or Cell-Mediated) Hypersensitivity 4 examples Tuberculin response Allergic contact dermatitis Graft rejection Graft versus host disease Tuberculin Response Skin of an individual exposed to tuberculosis or tuberculosis vaccine reacts to an injection beneath the skin of tuberculin Used to diagnose contact with antigens of M. tuberculosis No response when tuberculin injected into the skin of a never infected or vaccinated individual A red hard swelling (induration) develops when tuberculin is injected into a previously infected or immunized individual Tuberculin Skin Test Tuberculin Response The tuberculin response is mediated by memory T cells When first infected with M. tuberculosis, the resulting cell-mediated response generates memory T cells that persist in the body When sensitized individual is injected with tuberculin, dendritic cells migrate to the site and attract memory T cells T cells secrete cytokines that attract more T cells and macrophages to produce a slowly developing inflammatory response Macrophages ingest and destroy the tuberculin, allowing the tissue to return to normal Allergic Contact Dermatitis A cell-mediated immune response resulting in an intensely irritating skin rash Response triggered by chemically modified skin proteins that the body regards as foreign Can happen when a hapten, such as the oil from poison ivy and related plants, binds to proteins on the skin In severe cases, TC cells destroy so many skin cells that acellular, fluid-filled blisters develop Other haptens include formaldehyde, cosmetics, and chemicals used to produce latex Can be treated with corticosteroids Graft Rejection Rejection of tissues or organs that have been transplanted Grafts perceived as foreign by the recipient undergo rejection Graft rejection is a normal immune response against foreign major histocompatibility complex (MHC) proteins on the surface of graft cells Likelihood of graft rejection depends on the degree to which the graft is foreign to the recipient Based on the type of graft The Characteristics of the Four Types of Hypersensitivity Reactions Autoimmune Disease Due to phenomenon of autoimmunity whereby the body produces antibodies and cytotoxic T cells that target normal body cells Most autoimmune diseases appear to develop spontaneously and at random Some common features of autoimmune disease have been noted Occur more often in older individuals More common in women than men Theories to Explain the Etiology of Autoimmunity T cell may encounter self-antigens that are normally “hidden” in sites where T cells rarely go (sequestered antigens eg. the lens, sperm & CNS) Infections with a variety of microorganisms may trigger autoimmunity as a result of molecular mimicry Occurs when an infectious agent has an antigenic determinant that is similar or identical to a self-antigen The body produces autoantibodies that damage body tissues Failure of the normal control mechanisms of the immune system (diminished suppressor T cell function) Categories of Autoimmune Disease Two major categories Single tissue diseases Systemic diseases Single Tissue Autoimmune Disease Can commonly affect various tissues Blood cells Endocrine glands Nervous tissue Autoimmunity Affecting Blood Cells Production of autoantibodies to leukocytes (granulocytopenias) Combating infections is difficult Production of autoantibodies to blood platelets (thrombocytopenias) Blood does not clot Autoimmunity Affecting Blood Cells Production of autoantibodies to red blood cells resulting in hemolytic anemia Autoantibodies made can be of different classes IgM-activate complement resulting in lysis of red blood cells IgG-serve as opsonins that promote phagocytosis of the red blood cells Some cases of autoimmune hemolytic anemia develop after a viral infection or treatment with certain drugs Alters the surface of red blood cells so they are recognized as foreign, triggering an immune response Autoimmunity Affecting Endocrine Organs Production of autoantibodies or T cells can be against various endocrine organs Islets of Langerhans within the pancreas Can lead to the development of type I diabetes mellitus Results from the inability to produce insulin Some cases develop following a viral infection or in people with a genetic predisposition Autoimmunity Affecting Endocrine Organs Thyroid gland Can cause Grave’s disease Autoantibodies bind and stimulate receptors on the cytoplasmic membranes of the cells in the anterior pituitary gland Stimulated hormone cells produce thyroid-stimulating • Results in excessive production of thyroid hormone and growth of the thyroid gland Autoimmunity Affecting Nervous Tissue Multiple sclerosis Cytotoxic T cells attack and destroy the myelin sheath that insulates the brain and spinal cord neurons and increases the speed of nerve impulses along the neurons Results in deficits neuromuscular function in vision, May be triggered by a viral infection speech, and Systemic Autoimmune Diseases Systemic lupus erythematosus Rheumatoid arthritis Systemic Lupus Erythematosus (SLE) Generalized immune disorder that results from a loss of control of both humoral and cell-mediated immune response Autoantibodies against DNA result in immune complex formation Deposition of complexes in the skin result in a characteristic butterfly-shaped rash for which the disease is named Complexes deposit glomerulonephritis in glomeruli and cause Complex deposition in the joints results in arthritis Systemic Lupus Erythematosus (SLE) Autoantibodies can also occur against red blood cells, platelets, lymphocytes, and muscle cells Cause of lupus is unknown Develops in some patients due to a complement deficiency Treated with immunosuppressive drugs to reduce autoantibody formation, and with corticosteroids to reduce inflammation Rheumatoid Arthritis Results from a type III hypersensitivity reaction B cells in the joints produce autoantibodies against collagen that covers joint surfaces The resulting immune complement bind mast cells complexes and Inflammatory chemicals released Inflammation causes damage to the tissues which in turn cause damage to joints Inflammation erodes the neighboring bony structure joint cartilage and Rheumatoid Arthritis Joints become distorted and lose their range of motion Causes are unknown Treated with anti-inflammatory drugs to prevent further joint damage, and methotrexate to inhibit the humoral immune response Immunodeficiency Diseases Conditions resulting from defective immune mechanisms Opportunistic infections can play an important part of these diseases Immunodeficiency Diseases 2 general types Primary Result from some genetic or developmental defect Develop in infants and young children Acquired Develop as a direct consequence of some other recognized cause Develop in later life Primary Immunodeficiency Diseases Primary Immunodeficiency Diseases Disease Defect Manifestation Chronic Granulomatous Ineffective neutrophils Disease Uncontrolled Infections Severe Combined Immunodefficiency Disease A lack of T cells and B cells No resistance to any type of infection, leading to rapid death Bruton-type agamma- A lack of B cells therefore lack of Immunoglobulins Death from overwhelming Bacterial Infections A lack of T cells thus no cell-mediated immunity Death from overwhelming viral infections globulinaemia DiGeorge Anomaly Acquired Immunodeficiency Diseases Result from a number of causes Severe stress Suppression of cell-mediated immunity results from an excess production of corticosteroids, which is toxic to T cells Malnutrition and environmental factors Inhibits production of B cells and T cells Acquired Immunodeficiency Diseases Acquired immunodeficiency syndrome (AIDS) from infection with HIV Infects and kills helper T (CD4) cells When helper T cells reach critically low levels, infected individuals lose the ability to fight off infections