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Immune Responses to Viral Infections

Immune Responses to Viral Infections. Interferons. Proteins synthesized and secreted by cells in response to virus infection. A strong trigger for interferon production is dsRNA , which is produced , not only by dsRNA viruses, but also by ssRNA viruses as they replicate.

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Immune Responses to Viral Infections

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  1. Immune Responses to Viral Infections

  2. Interferons • Proteins synthesized and secreted by cells in response to virus infection. • A strong trigger for interferon production is dsRNA, which is produced, not only by dsRNA viruses, but also by ssRNAviruses as they replicate. • The roles of interferons are to protect adjacent cells from infection and to activate T cell-mediated immunity. • There are a number of types of interferon. • Alpha- and beta- (α- and β-) interferonsare produced by most cell types when they become infected with viruses. • After secretion, the interferon molecules diffuse to nearby cells, where they can trigger various anti-viral activities by binding to interferon receptors.

  3. Action of IFNs • Activation of genes that encode antiviral proteins, such as dsRNA-dependent protein kinase R and RNaseL. • Stimulation of production of major histocompatibility (MHC) class I molecules and proteasome proteins; these molecules enhance the presentation of viral peptides on the infected cell surface to T cells. • Activation of NK cells • Induction of apoptosis

  4. Immune Response to Virus The induction of Interferon (IFN)- and  virus Receptor-mediated entry into host cells Pathogen-associated molecular patterns Viral replication Viral PAMP dsRNA Unmethylated CpG TLR-3 TLR-9 Intracellular TLRs Induction of IFN-/ synthesis IFN-/ are type I interferons (many infected cells) IFN- is type II interferon (NK cells, TH1, CTL)

  5. Class switching to IgG2a is induced by IFN- during immune response to viral infection. TGF- IFN- IL-4 IL-4 LPS LPS Mouse IgH V(D)J 2a 3  1 2b    S I C S2a I2a C2a IFN- Induced by B cell activation and IFN- Active in B cell V(D)J 2a   2a (IgG2a) IgG2a facilitates ADCC by NK cells during viral infection. Antibody-Dependent Cell-Mediated Cytotoxicity (ADCC)

  6. Viral countermeasures against interferons • Many viruses produce proteins that inhibit either the production of interferons or their activities. • The NS1 protein of influenza A virus and the NS3-4A protein of hepatitis C virus block pathways involved in interferon production. • Some viruses, such as poliovirus, prevent the synthesis of interferons as a result of a general inhibition of cell gene expression.

  7. Cytokines activates NK cells. IL12, IL18 DCs, macrophage NK cells NK cell activation dsRNA Many cells IL15 IFN- Bone marrow stromal cells

  8. Natural killer (NK) cells • NK cells are present throughout the body, but mainly in the blood. • They recognize changes in the surface molecules of virus-infected cells as a result of infection, though they do not recognize specific antigens. • After recognizing virus-infected cells as target cells, NK cells are able to bind to them and kill them. • NK cells kill their target cells either by releasing perforins, which are proteins that are inserted into the plasma membrane of the virus-infected cell, or by inducing apoptosis. • Also, on binding to infected cells, NK cells release γ-interferon

  9. NK cell activity is regulated by stimulatory and Inhibitory receptors. NK cell inactive NK cell activated NK cell activated - + + Inhibitory receptor Stimulatory receptor Stimulatory ligand Self MHC I killing killing Normal cell Viral infection Upregulates Stimulatory ligands Viral infection Downregulates MHC I The missing-self hypothesis

  10. Inhibitory receptors Inhibitory receptors contain ITIM (immunoreceptor tyrosine-based inhibitory motif) in their cytoplasmic domains. [I/V]XYXXL: Y is the substrate of tyrosine kinases. Phosphorylated ITIM recruits phosphatases (SHP-1) that counteract the Phosphorylation cascade of signal transduction. ITIM Stimulatory receptors Stimulatory receptors contain short cytoplasmic domain without ITIM. The transmembrane domain associates with signal transduction molecules that contain ITAM (immunoreceptor Tyrosine-based activating motif) in the cytoplasmic domain. YXX[L/I]X6-9YXX[L/I]: Y is the substrate of typrosine kinases. Phosphorylated ITAM recruits and activates additional kinases for signal transduction. ITAM

  11. NK cells control viral infection in the first few days of immune response. Complete elimination of the infection requires adaptive immunity.

  12. Viral countermeasures against NK cells • The presence of HIV particles in the blood alters the expression of a number of molecules on the surface of NK cells. • This reduces the efficiency of NK cell activities, including the ability to kill virus-infected cells and to secrete γ-interferon.

  13. APOBEC3 proteins • There are enzymes in the cells of humans and animals that can interfere with the replication of retroviruses. • Induce lethal mutations by deaminatingdeoxycytidine to deoxyuridineduring reverse transcription. • ApolipoproteinB mRNA-editing enzyme, catalytic polypeptide-like 3 proteins APOBEC3 • Several of these proteins in human cells can interfere with the replication of HIV. • Two of them (APOBEC3F and APOBEC3G) can be incorporated into HIV virions and taken into the next cell, where they can interrupt reverse transcription.

  14. Inactivating retrovirus by cytidine deamination Apobec-3 (A-H): homologous to AID. The seven apobec-3 genes are located in one cluster. Apobec-3B, F, G deaminates cytidines in reverse transcript during retroviral replication. RNA genome 3’ 5’ C C 5’ 3’ C cDNA reverse transcript HIV produces Vif protein to degrade apobec-3G. Apobec-3 3’ 5’ U U 5’ 3’ U cDNA mutated and nonfunctional

  15. Viral countermeasures against APOBEC3proteins • In the cytoplasm of an HIV-infected cell the virus protein Vif can bind APOBEC3G, triggering its degradation and hence preventing its incorporation into virions.

  16. Antibody Response to Viruses

  17. Antibody Responses Virus-specific antibody can coat both virionsand virus-infected cells, and this may lead to their destruction by a variety of mechanisms. A number of cell types in the immune system have receptors for the Fcregion of IgG, allowing these cells to attach to antibody-coated virions and cells. Cell types that have IgGFc receptors include neutrophilsand macrophages (these cell types are phagocytes and may phagocytose the antibody-coated materials; they may also kill cells without phagocytosing them) NK cells (these cells may kill virus-infected cells by insertion of perforins into their membranes). Activation of complement

  18. The effector functions of antibodies Antibodies to viruses can inhibit the infection of viruses to other cells and prevent the spread of infection. Antibodies can activate complement to lyse enveloped viruses. Opsonization can facilitate phagocytosis. Complement activation C3b and antibodies serve as opsonins for Phagocytosis. Crosslinking of antigens to form a aggregate (agglutination) IgM most effective

  19. Neutralization of infectivity • Which may occur by a variety of mechanisms. • Release of nucleic acid from virions. • In studies with several viruses, including poliovirus, it was found that antibodies can attach to virions, and then detach leaving empty capsids devoid of their genomes. • Prevention of virion attachment to cell receptors - Antibody bound to a virion may mask virus attachment sites. Not all virus attachment sites, however, are accessible to antibodies; those of most picornaviruses are in deep canyons • Release of virions that have attached to cell receptors. • Inhibition of entry into the cell. Antibody coating fusion proteins on an enveloped virion may inhibit fusion of the envelope with a cell membrane. • Inhibition of genome uncoating.

  20. T cell activation DCs can be directly infected by virus. If DCs are not infected by virus, DCs can still internalize viral antigens from the suroundings through phagocytosis, endocytosis and macropinocytosis. The antigens can be presented in the context of both class II and class I MHC through cross-priming. Lysis of infected cells DCs are activated by recognition of Viral PAMPs through TLRs. Secondary lymphoid tissues DC CTL CD8 T cell Ag-MHC I virus infection TH1 Ag-MHC II CD4 T cell IL12 IFN- Viral antigen Endocytosis Pinocytosis phagocytosis TH1 failitates CD8 T cell activation by producing IL2 and activation of DCs through CD40L-CD40

  21. B cell activation DC TH cells antibodies Viral antigen B cell activation B cell Natural antibody Seoncdary lymphoid tissues FDC Antigen-antibody complex B1 cells

  22. The viral antigens are displayed on the surface of infected cells in association with MHC class I molecules, flagging infected cells for destruction by cytotoxicT cells. • CytotoxicT cells can kill target cells by insertion of proteins (perforins) into their membranes or by inducing apoptosis.

  23. Viral countermeasures against cytotoxic T cells • Some viruses, such as herpesviruses, reduce the level of expression of MHC class I molecules at the surface of infected cells, thereby making it more difficult for cytotoxic T cells to recognize infected cells.

  24. Immunological memory • The quantity and quality of the adaptive immune response depends on whether or not the host is encountering the virus for the first time. • Some B cells and T cells can survive as memory cells long after the first or subsequent encounters. Memory cells have returned to a resting state, from which they can be reactivated if they encounter the same antigen again. • These cells are the basis of immunological memory, which can be formed as a result of a natural infection, but also as a result of encountering antigens in vaccines. • The outcome of infection of a vertebrate animal with a virus may depend on whether or not the host has immunological memory of the virus antigens. • If immunological memory is present then signs and symptoms of disease are likely to be less severe, or totally absent.

  25. Immune Response to Virus Innate immunity Virus Infected cells M, DC MHC I IL12, IL18 IFN- Stimulatory ligand IL15 Inhibit protein sythesis Apoptosis of infected cell NK cells IFN- Lysis of infected cell Activate antigen presentation Promote TH1 response

  26. Adaptive Immunity Virus DC B cell CD8 T cell CD4 T cell IL12 IFN- CTL TH1 Activated B cells IL2 Lysis of infected cell antibodies IFN- neutralization complement T cell proliferation Antigen Presentation IgG2a ADCC

  27. Latent viral infection Latent viruses do not replicate, do not cause disease, and are not detected by the immune system. These laten viruses are activated when immune system is weakened. Herpes simplex viruses establish latency in sensory neuron. environmental stress or decrease in immune function reactivate the virus to cause cold sores. Epstein-Barr virus (EBV, herpes virus) establish latency in B cells. It produces EBNA-1, which is needed for replication. But EBNA-1 inhibits proteasome processing and antigen presentation. Some of these infected cells can be transformed. When T cell function is compromised, they could develop into B cell lymphomas (Burkitt’s lymphoma).

  28. Mutation as evasion strategy Influenza virus H5N1, H1N1, etc

  29. Evasion by hiding Neurons produce very low levels of class I MHC. Viruses (Rabies virus) are not effectively recognized by T cells Destruction of Immune Cells HIV destroyes CD4 T cells. HBV kills CD8 effector T cells that are specific for HBV infected hepatocytes. Interference with cytokine function EBV, HCMV produces IL-10 like molecules to inhibit TH1 resposne. Some viruses express mimetics of IFN, IL2. Downregulation of class I MHC Inhibition of transcription, intererence with peptide transport by TAP, targeting of Newly synthesized class I MHC for degradation, and rapid turnover of surface expressed MHC.

  30. Superantigen Viral superantigen: mouse mammary tumor virus, rabies virus, Epstein-Barr virus Bacteria superantigen: staphylococcal enterotoxins (SEs, foodpoisoning) toxic shock syndrome toxin-1 (TSST-1, toxic shock syndrome) Superantigens crosslink class II MHC with TCR V chain. The interaction is independent of Peptide sequence. Each superantigen can bind 2-20% of all T cells. Superantigens are not processed and presented by MHC. Superantigens can cause massive activation of CD4 T cells, which release cytokines (IFN-, TNF-) and activate macrophages to release inflammatory cytokines (IL1, TNF-) These cytokines cause the toxic shock syndrome (similar to septic shock). The massive activation of CD4 T cells eventually lead to their death, and cause immunol suppression, which aid the propagation of pathogens.

  31. RNA silencing • RNA silencing, also known as post-transcriptional gene silencing or RNA interference (RNAi), is an intracellular process that is induced by dsRNA. • The process results in the destruction of mRNAs that have the same sequence as the inducing dsRNA; both cellular and viral mRNAs can be destroyed.

  32. Protein complex RISC: RNA-induced silencing complex siRNA: small interfering RNA

  33. Viral countermeasures against RNA silencing • Some plant viruses encode proteins that can suppress RNA silencing, for example the ‘helper component proteinase’ of potyviruses and the P19 protein of tombusviruses are strong suppressors of RNA silencing.

  34. Programmed cell death • Virus infection of a cell may initiate a process that causes the death of the cell before progeny virus has been produced, hence preventing the spread of infection to other cells. • In animal cells this suicide mechanism is known as apoptosis. • It is triggered, not only by virus infection, but also when the life-span of cells, such as epithelial cells, is complete. • Bacteria have developed similar mechanisms to protect the species from phage infection. The death of a host bacterium before any progeny phage has been produced protects other susceptible cells from infection. These mechanisms have been found in Escherichia coli and in many other species. • If a virus-infected cell successfully completes the process of programmed cell death then it altruistically commits suicide for the benefit of either a multicellular host or a population of unicellular hosts.

  35. Viral countermeasures against apoptosis • Many viruses have evolved mechanisms that can suppress apoptosis at a variety of points in the process, for example several DNA viruses encode proteins related to the cell BCL-2 proteins that control apoptosis. • These viral proteins block apoptosis, resulting in the survival of host cells and the completion of virus replication cycles.

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