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Immunity to Infectious Micro-Organisms Anti-viral Immune Responses and Viral Evasion of Host Responses. ********** Immunity to Bacterial Diseases and Bacterial Evasion of Host Responses. ********** Emerging Infectious Diseases, Pandemic Disease, and Bioterrorism ********** Immunity to Protozoa, Multicellular Parasites, and Fungi Folder Title: MicroInfect(NoTP) Updated: December 08, 2013 This is a Turning Point Slide to Open the System to Accept Your Transmitted Questions. No need to answer. Rank 1 2 3 4 5 6 Responses Infectious Agents Pathogenic for Humans and for Veterinary and Farm Animals (Part 1) Viruses • Enveloped RNA Viruses (HIV, Influenza, Hepatitis C) • Naked RNA Viruses {Polio, Hepatitis A, Rhino-viruses (common cold)} • Enveloped DNA Viruses (Herpes Simplex, Epstein Barr – Mononucleosis, Variola major - Smallpox, Vaccinia - cowpox, Hepatitis B) • Naked DNA Viruses (Adeno-viruses; SV40 Virus; Polyoma viruses) “Envelop” = lipid bilayer membrane, host-derived; Contains proteins and glycoproteins derived from pathogen or from the host. Bacteria • Gram Positive (No 2nd cell envelop) - Anthrax, Staphylococci, Streptococci • Gram Negative (2nd Cell envelop with membrane endotoxins) - E coli • Extra-cellular (i.e. pathogen is outside of host cells): Neisseria gonorrhoeae; Streptococcal pneumonia • Intracellular (i.e. pathogen gets inside of host cells): Listeria Monocytogenes; Tuberculosis; Typhus (rickettsia) • Exotoxin Producers: Diptheria, Anthrax, Botulism, Tetanus, Yersinia pestis Infectious Agents Pathogenic for Humans and for Veterinary and Farm Animals (Part 2) Protozoans • Plasmodium falciparum - Malaria • Trypanosoma brucei - Sleeping Sickness • Trypanosoma cruzei - Chagas Disease Fungal (Yeast) Diseases • Ring-worm; Athletes feet • Candidiasis • Oral "Thrush"; Other opportunistic fungal pathogens • Cryptococcus gattii: Emerging invasive air-borne Lung & Brain pathogen – See Scientific American, December 2013, pp. 50-57 – Increased host range and infectivity due to global climate change Multi-Cellular Parasitic Diseases • Parasitic Worms - (Helminths) • Schistosomiasis (worm pathogen transmitted by snails Pathogenicity of Infectious Diseases in Humans 1 Billion Infected World-Wide 15 Million Deaths per Year Greatest Impact in Third-World Countries • No Economic Incentive to Develop Treatments • Potential Liabilities in Testing and from Failures Significance of the "Global Village” • Emergence of resistance to Tuberculosis • Emigration of cholera and leishmaniasis • Disease survival in susceptible patient pools – polio; measles • Pandemic Influenza From Kuby Immunology, 4th Ed. p. 426 Infectious Diseases in 1996 Viral and Bacterial Viral, Bacterial and Protozoan Bacterial Protozoan Viral Viral Viral and Bacterial Bacterial Protozoan Protozoan Viral Protozoan Multi-cellular (Helminth) Multi-cellular (Helminth) Viral Multi-cellular (Helminth) Syphilis (2014) (By bacterium Treponema pallidum) New Cases 69,000 Causes of Death - Worldwide p. 448 Non-Immunological Host Barriers to Infection Epithelial Surfaces • Gastrointestinal, respiratory, genito-urinary linings • Ciliated epithelium and mucous secretions • Epidermal barriers Cellular Secretions • Biochemical barriers : Enzymes (can come from innate immune response system) • Chemical barriers: pH, oxidants (can come from innate immune responses) Physical Barriers Elevated Temperature (Fever) Cellular Competition: Gut flora Innate Natural Immune Responses to Infectious Agents Gram-positive Bacteria - Peptidoglycan (exposed) • Activates alternative complement pathway - C3b • Opsonizes Bacteria for Enhanced Host Phagocytosis Gram-negative Bacteria - 2nd Envelope over Peptidoglycan • • • • Bacterial Endotoxins - e.g. Lipopolysaccharide Stimulates Cytokines (TNF, IL-1, IL-6) From Macrophages and endothelial cells Activates Macrophages Interferon Stimulation by Viral Infectious Agents • Can Directly inhibit viral production • Can activate and stimulate NK Cells to attack virally infected cells • Possibly by viral effect on MHC Class I Protein Synthesis Innate Natural Immunity and AntiViral Responses Type I Interferons (IFN and IFN) • Produced by Virally-infected Cells • Also from Monocytes, Macrophages, and Fibroblasts Mechanims of Action of IFN and IFN • Infected cell produces membrane receptors for IFN and • Activates an RNAase that cleaves viral RNA • Inactivates viral protein synthesis by effects on dsRNA-dependent protein kinase • Induces Anti-viral response and resistance to intra-cellular viral replication NK Cells • Activated by IFN and IFN; become cytotoxic for virallyinfected cells • Also activated by IL-12 - produced in response to viral infection Humoral Immunity & Anti-Viral Responses Antibody-mediated Anti-viral Responses • Prevent initial infection or reinfection • Less effective against intracellular viral infections • Less effective against viral DNA incorporated into host genome Secretory IgA - Blocks viral binding to target cells General Immunoglobulin Isotypes • Block Fusion Between Virus Envelop and Host Cell Membrane • Enhance phagocytosis by opsonization of viral particles IgM - Agglutinates viral particles IgM and IgG - Activates Complement • Opsonization by Complement Fragment C3b for phagocytosis • Lysis of virus envelop by membrane attack complex Cell-Mediated Immunity & Anti-Viral Responses Interferon • From TH1 Helper T-Cells or Tc • Direct Anti-viral Action Cytoxic T-Cells (CTLs) • Kill virus-infected cells; Eliminates source of additional virus • Presentation of Viral Peptides by MHC-Class I Proteins • Virus-specific T-cell Clones; Can confer specific immunity by passive (adoptive) transfer to unifective recipient NK Cells and Macrophages • Antibody recognition of virus antigens on cell surface • Kill by ADCC (Antibody-dependent Cell-mediated Cytotoxicity) Activated TH1 Cells • IFN, IL-2, TNF attack virus directly or indirectly • IFN has direct anti-viral effects • IL-2 Recruits Tc to become Effector CTL Mechanisms of Anti-viral Immunity p. 449 Interferon Inhibition Of Viral Replication In Virally-infected Cells Degrades RNA needed for viral replication Shuts down protein synthesis needed for viral replication Viral Evasion of Host Responses: Effects on Infected Cells Block Intra-cellular Effects of IFN and IFN • Blocks intra-cellular effects on PKR - RNA-dependent protein kinase • By hepatitis C virus Inhibition of Antigen-Presentation in Virally-infected Cells • • • • By Herpes Simplex 1 and 2 (HSV1 and HSV2) Early Proteins Inhibits TAP (Transporter Associated with Antigenic Protein) Blocks delivery of Antigenic Peptide to MHC-Class I Protein No presentation to CD8+ CTL Down-regulation (Shutting Down) of Class I MHC Proteins • CMV (Cytomegalo Virus) and Adeno Viruses Block Class II MHC Protein • Blocks Antigen-specific Anti-viral Helper T-Cells • By CMV, Measles, HIV Viral Evasion: Direct Viral Effects Inhibition of Complement Pathways • Vaccinia and HSV Antigenic Variation (Mutations in Virus Surface Proteins) • Rhino Viruses (Common Cold viruses) • Influenza • HIV Generalized Host Immuno-Suppression • Direct Effects on Macrophages and Lymphocytes Destruction of Immune Cells Alteration of Cell function • CMV, HIV, and EBV (Epstein-Barr Virus) • Paramyxo (Mumps) Virus; Measles Virus Cytokine-based Effects by Virus • Production of IL-10 Mimic by EBV • Suppresses TH1 Subset • Reduces Levels of TNF and IFN, and IL-2 Pathogenicity of Influenza Virus Host Range: • • • • Mammals, Birds Can cross species barriers Duck influenza can infect pigs Pig influenza can infect humans Can produce extensive antigenic reassortments - "antigenic shift" Subject to Point Mutations in Hemagglutin (Binds to Host-Cell Sialic Acid) - "Antigenic Drift" Host resistance based on Ab to Hemagglutin is by-passed Influenza Pandemics • • Killed 20 Million - Post World War I (1918 - 1919) Largely Young Adults Lower prior exposure and cross-reactive immunity? More extensive exposure to infected persons? Over-aggressive inflammatory immune response? Diagram of Influenza Virus Structure Figure 17-3 Kuby- Immunology 4th Edition p. 429 Dimensions in Cell Biology & Microbiology 100 um (100 microns) • 0.1 mm • Diameter of human hair 10 um (10 microns) • Diameter of a red cell • 10 Red cell diameters = one human hair diameter 1 um (1 micron) • One-tenth the diameter of a red cell • One-hundredth the diameter of a human hair • 1000 nm (1000 nano-meters) 100 nm (0.1 um or 0.1 microns) • One-hundredth the diameter of a red cell • One-thousandth the diameter of a human hair • Size of an enveloped RNA or Enveloped DNA Virus Structure of Influenza Virus RNA Virus • • • • RNA Genome in nucleocapsid of Matrix proteins 8 Different Strand of Single-Stranded (ss) RNA RNA associated with Viral nucleoproteins and RNA polymerase Codes of 10 different viral proteins Enveloped RNA Virus • 100 nm Diameter (100 nano-meters - See "Dimensions" Graphic) • Host-derived plasma membrane (buds from infected host cell) • Contains Viral protein spikes Neuraminidase (for viral release from host membrane sialic acid groups) Hemagglutinin (for viral attachment to target cell) Diagram of Influenza Virus Structure Figure 17-3 Kuby- Immunology 4th Edition p. 429 Host Response to Influenza Virus Humoral Immune Response to Influenza Virus • • • • • Antibody Strain-Specific for Virus Hemagglutinin in Virus Envelop Prevents Virus Binding to Host Target Cell Antibodies Block Binding Cleft in HA for Host Cell Membrane Sialic Acid Antibody titer peaks within a few days after infection Decreases for six months Plateaus and persists for several years Antigenic Shift involving entire viral single-stranded RNA's incorporation and increase in infectivity of newly arising influenza strain. Antigenic Drift involves point mutations in Hemagglutinin or Neuraminidase allowing for viral escape from antibody inhibition. Host Protection from Influenza Infection • • • • Antibody prevents reinfection by same strain of Influenza Antigenic drift of viral HA requires re-vaccination for newly emergent or reemerging strains Serum antibody not required for recovery after infection CTL's may play a role in responses after infection p. 453 p. 453 p. 452 Sequence variations in 10 different proteins in three different strains of influenza type A viruses. (HA = Hemagglutinin; NA = Neuraminidase; M = matrix protein; N and P are nucleoproteins) p. 453 http://www.youtube.com/watch?v=Rpj0emEGShQ Flu Attack! How A Virus Invades Your Body From NPR: Robert Krulwich and Others The following slides are Turning Point Fillin-the-Blank question. Please clear your desk and respond. No talking or other kinds of consultation, please. 17% Rank 1 17% 17% 17% 17% 17% Responses 2 3 4 5 6 Other 1 2 3 4 5 6 17% Rank 1 2 17% 17% 17% 3 4 17% 17% Responses 3 4 5 6 Other 1 2 5 6 Go to Last Two Slides for Course Evaluation In there is no time for Anti-bacterial Immunity Bacterial Infection and Pathogenicity Bacterial Entry Points (Non-immunological Barriers) • Gastro-intestinal, Respiratory, Genito-urinary epithelial linings • Epidermal Barriers - Entry by Wounding or Animal and Plant Vectors Steps in Bacterial Infection • Attachment to Target Cells Surface Pili on Bacteria Adhesion Molecules • Proliferation • Invasion of Host Tissues • Toxin-induced Damage to Host Functions (Bacterial Exotoxins) Bacterial Pathogenicity • • • • • Bacterial Cell Wall Endotoxins Bacterial Exotoxins Pathological Host Responses Bacterial Mimics of Host Antigens Intra-cellular Bacterial Infections and Damaging Host Responses Host Response to Extra-cellular Bacterial Challenge & Infection Blocking Bacterial Attachment to Target Cells • Secretory Antibody (IgA) Removal of Bacteria • • • Complement Pathways - Direct destruction of Bacterium, or Attracts PMN's for Anti-bacterial action, or Targets bacterium for Phagocytosis Antibody-dependent "Classical" Complement Response -Opsonization and phagocytosis - Inflammatory mediators (PMN Attraction and degranulation) - Bacterial Membrane lysis Antibody-independent "Alternative" Complement Pathway - Opsonization and phagocytosis (*as for classical complement pathway) - Inflammatory mediators (PMN Attraction and degranulation)* Agglutination of bacteria by poly-valent antibody Antibody-dependent phagocytosis of bacteria Neutralization of Bacterial Exotoxins • Antibodies to bacterial exotoxins p. 456 Host Response to Intra-cellular Bacterial Challenge & Infection T-Cell Mediated DTH (Delayed-type Hypersensitivity) • Cytokines • Inflammatory mediators • PMN and Macrophage responses NK Cell Cytotoxicity of Bacterially-Infected Cell Pathogenicity due to host Responses • Granulomas in tuberculosis and leprosy Granuloma (tubercule) in pulmonary tuberculosis Kuby -Immunology Figure 17-9 4th Ed., p.436 Bacterial Evasion of Host Responses Host Responses Affecting Bacterial Attachment • Digestion of IgA - by Neisseria gonorrhoeae, and Neisseria meningitis -by hemophillus influenzae • Antigenic drift in bacterial attachment pili proteins Responses Affecting Bacterial Proliferation and Invasion • Inactivation of complement components • Induction of apoptosis in host response cells • Escape intra-cellular destruction in lysosomes Prevent lysomal membrane fusion with phagosome Block action of lysosomal oxidative components -Listeria moncytogenes -Mycobacterium avium p. 457 Cryptococcus gattii (respiratory and brain fungus): Emerging 2013, Western Canada Added in 7th edition The next slide will allow you to grade this course from A to F. The slide is set to anonymous so we won’t know who says what. 1. (A) It is excellent. 2. (B) It is pretty good. Above average. 3. (C) It is average. 4. (D) It is disappointing. Pretty bad. 5. (F) This course is terrible. This poll is set to anonymous. Based on the Scale of A to F detailed in the previous slide I give this a course a (an) using 1 = A etc. 1. (A) It is excellent. 2. (B) It is pretty good. Above average. 3. (C) It is average. 4. (D) It is disappointing. Pretty bad. 5. (F) This course is terrible. le . te rri b g. P rs e is tin 5. (F )T hi sc ou sa isa pp oi n ti )I ti sd (D )I re t.. ve ra ge . v. .. Ab o (C go od . re tty 3. 4. 2. (B )I ti sp 1. (A )I ti se xc el le nt . 20% 20% 20% 20% 20%