Virology

avatar
Created by
Asia

Subdecks (1)

Cards (161)

  • What is a virus?
    Obligate intracellular parasite
    Needs a host cell to survive
    Lacks organellesno nucleus, mitochondria, ribosomes etc
    Extremely small filterable agents − Range from 18230 nm
    Need electron microscope to visualise
    Some viruses can remain viable in the environment for a long time e.g. months but they cannot replicate outside of the cell
    Viruses are much smaller than bacteria and parasites/protozoa
     
  • Virus Nomenclature:
    Family name= End in –viridae
    Genus name= Ends in –virus
    Virus species = A group of viruses sharing the same genetic information and ecological niche
    Can be further divided into types and subtypes
    E.g. Rhabdoviridae, Lyssavirus, Rabies Lyssavirus
  • Some ds and ss RNA can be segmented
    more than 1 molecule of genomic material, so rather than having all the RNA encoded onto one molecule, it’s on multiple.
    Allows the virus to increase its genetic capacity as RNA is typically fragile.
    As size of RNA gets bigger it may become more susceptible to degradation but If the genetic information is then on several smaller segments, the chances of the virus keeping those smaller segments intact is greater. It allows viruses to increase their genome size so they can code for more proteins without the risk of their genomic information becoming degraded.
  • Some ds DNA viruses can be circular. Even those that are linear have mechanisms to make them adopt a circular configuration as this is important for replication.
  • All DNA viruses are monopartite (all viral genes on a single segment)
  • DNA viruses are all mostly DS
  • there's little diversity in structure with the DNA viruses
  • most RNA viruses are SS
  • SS RNA viruses can either have a positive or negative sense
  • all DS RNA viruses are segmented
  • Segmentation of RNA viruses
    Allows virus to increase its diversity very rapidly (reassortment)
  • all viruses have a capsid
  • Icosahedral Capsid (Parvoviridae and Adenoviridae)
    Twelve vertices
    20 triangular sides (facets)
    Composed of capsomers (basic structural building block of the capsid)
    penton capsomers (5)
    hexon capsomers (6)
  • Penton capsomers (5)
    • Found at the vertex (pointy bits/corners?) of the capsid
    • 12 present – one at each vertex
    • Has 5 neighbouring capsomers
    Hexon capsomers (6)
    • Has 6 neighbouring capsomers
    • Number present in capsid varies depending on size
    • Found in spaces between the penton capsomers
  • most viruses with a Icosahedral Capsid structure do not have an envelope
  • Biological Properties of Viruses:
    Can vary depending on
    Whether the virus has an envelope
    Structure and composition of its genomic material (RNA viruses are more variable than DNA)
  • Genome composition of a virus affects its biological properties
    DNA viruses are more stable, show very little variation
    RNA viruses are more variable
    RNA polymerase is error prone and has no proof reading
    Can adapt easily to new environments (jump species/zoonotic)
    Some RNA viruses are segmented and so can reassort or swap genes (cover this in more detail in the sessions on influenza viruses)
  • Virus Envelope proteins
    Contain receptors that allows the virus to attach and then enter the host cell
    Are targets of the humoral and cellular immune response
    Antibodies will recognise these surface exposed viral proteins
    Interact with the capsid during virus assembly
  • Non-Structural Viral Proteins
    Are not structural components of the virus particle
    Made in the virus-infected cell following infection:
    Often enzymes involved in viral replication
    Proteases
    Helicases
    Polymerase (can be a structural protein!)
    Protein primers for nucleic acid replication
    Can be proteins that help the virus avoid the host immune response
    Targets of the host cellular response (T cell epitopes)
  • Naked viruses can be transmitted inside vesicles (so sometimes have an envelope!):
    • Some RNA viruses can be transmitted as virus clusters inside vesicles
    • Rotavirus and noroviruses are transmitted as clusters
    • Vesicles remain intact (?) and they pass through the GI tract to the intestines
    • vesicles are used to transmit the naked viruses from one one host to another
  • Entry of Herpes Simplex Virus - Cell membrane fusion
    • An enveloped virus
    • Initial binding glycoprotein B or glycoprotein C to heparin sulphate (a complex carbohydrate expressed on the surface of many cell types)
    • Attachment of glycoprotein D to
    • HveA (lymphocytes, epithelial cells, fibroblasts)
    • Nectin 1 & 2 (neurons, epithelial cells, fibroblasts)
    • Fusion of the viral envelope with cell membrane
    • Uses multiple types of spike glycoproteins to bind and enter different types of cells
  • Entry of Human Immunodeficiency Virus - Cell membrane fusion
    • Binding of HIV gp120 (HIV Spike protein) to CD4+ T cells
    • Induces conformational change in gp120
    • Enables binding of gp120 to CCR5 or CXCR4
    • Causes the gp120 trimer to break apart
    • Allows gp41 to be pulled towards the cell membrane
    • Fusion of gp41 with cell membrane
    • Releases nucleocapsid into the cytoplasm
    • Nucleocapsids are targeted to nucleus
  • Entry of influenza virus - Receptor mediated endocytosis
    • Binding of haemagglutinin (HA) to sialic acid receptor
    • Internalisation in clathrin coated pit
    • Movement into endocytotic vacuole which fuse with lysosomes
    • Low pH triggers conformational change in HA trimer
    • Exposes fusion domain which allows fusion of viral membrane and endosome membrane
    • Release of nucleocapsids into cytoplasm
  • Uncoating
    • Release of viral nucleic acid from viral capsid
    • Process is variable: For some viruses
    • nucleic acids may still be in a nucleoprotein complex
    • the capsid is only partially disintegrated
  • Routes of Virus Entry and Mechanisms of Spread:
    Must overcome innate defences to enter body
    Both physical & immunological
    Many viruses enter via mucosal surfaces
    Different viruses adopt different strategies
    Some viruses may use several entry routes
    e.g. Foot and Mouth Disease Virus inhaled (most common) or ingested
    Entry route may differ in different host species
    e.g. Influenza: Faecal-oral in wild birds and respiratory in humans
  • How do viruses enter the body & initiate infections?
    Skin
    Respiratory tract
    Alimentary tract (GI tract)
    Urogenital tract
    Eye
    Viruses attach to cells at these locations by attaching to receptor molecules on certain cells
  • Mechanisms of Spread
    Some viruses remain localised at the site of infection
    Influenza virus in the respiratory tract
    Rotavirus in the alimentary tract
    Replication occurs in epithelium at initial infection site.
    Cell-to-cell spread occurs, but virus does not disseminate to other tissues
    Usually acute (short incubation period, short duration)
    Site of shedding = site of entry
  • Respiratory Tract - Defences
    • Specialised ciliated epithelium & mucus: MUCOCILIARY ESCALATOR (in Upper Respiratory Tract (URT) and bronchi)
    • Filters out large particles (particles <5uM can enter terminal airways and alveolar)
    • Sneezing & coughing
    • Innate immunological defences (e.g. alveolar macrophages, complement, cytokines, natural killer cells)
  • Respiratory Tract - Virus entry
    Via aerosolized droplets expelled by an infected individual
    Spread by coughing or sneezing
    Contact with saliva from an infected individual
  • Examples of viruses entering via respiratory route
    Influenza
    Foot and Mouth Disease Virus
    Rhinovirus (common cold)
  • Gastrointestinal (GI) Tract - Defences
    Low pH in stomach (Denatures protein and kills most microorganisms)
    Bile and proteolytic enzymes in intestines
    High pH in the duodenum (rapid change)
    Mucous
  • Gastrointestinal (GI) Tract - Virus Entry + examples
    Oral route (ingestion)
    Examples of viruses entering via the GI tract
    Rotavirus
    Norovirus
  • Spread via blood stream (Viraemia) to other tissues
    Some viruses can spread to distant sites
    Virus reaches blood via lymphatic system
    Primary viraemia (clinically silentincreases virus levels allowing infection of distant organs)
    Secondary viraemia (virus replication in other organs leads to high concentrations of virus in circulation)
    Infection spreads to more sites
    Allows entry and exit routes from host to differ
    Usually have longer incubation period (more severe pathology)
    Greater involvement of adaptive immune responses and IgG
  • Spread via the Central Nervous System (CNS)
    Entry: Bite of a rabid animal or contamination of scratch wounds by virus-infected saliva.
    Rabies replicate in peripheral tissues (striated or connective tissue) at site of infection
    Can remain at site of infection for days/weeks or longer
    Virus enters peripheral nerves. (Infects unmyelinated nerve endings in muscle)
    Spreads to CNS and enters brain (causes behaviour changes)
    Migrates to salivary glands (replicates) and excreted in saliva
    No viraemia
    Also allows rabies to evade immune system
  • Virus Tropism
    Specificity of a virus for a particular host, tissue or cell
    Determines the host range of virus
    For virus infection to occur, the cell must be:
    Susceptible
    Appropriate cell surface receptors for entry (susceptibility)
    Permissive
    Able to support replication of the virus
    May need particular cellular proteins to complete infection
    May need to be in a particular cell type
    E.g. Canine parvovirus needs rapidly dividing cells
  • Virus Tropism
  • Factors affecting Tropism
    Not just receptors that determine tropism
    Cells need to be susceptible (able to support replication of the virus)
    Other factors that can determine tropism:
    Cellular protease can activate fusion
    Protease cleavage by digestive enzymes
    Temperature of replication
    pH Lability of viruses
    Anatomical Barriers
  • Cellular protease can activate fusion
    • Some enveloped viruses require proteolytic cleavage of envelope glycoprotein for activation of fusion domain
    • Fusion of the two membranes (which is needed for cell entry) is dependent on cleavage by specific proteases, if the cell in the endosome doesn't have those proteases, then we're not going to get a effective infection, as without the proteases, the virus gets trapped in the endosome and will be degraded within that cell
  • Protease cleavage by digestive enzymes
    Reoviruses are activated into infectious virions by cleavage with digestive enzymes
    Cleavage of VP4 spike to form VP8 and VP5
    Conformational change permitting virus to bind to M cells in the gut
    retroviruses need this proteolytic cleavage to generate their receptors
  • Temperature of replication
    Some viruses are temperature sensitive, even if they can get into the cells, if the temperature is not right for them, they're not going to replicate
    Most human viruses replicate at 37°C
    Upper respiratory tract has a lower temp – about 33°C
    Rhinoviruses replicate efficiently at 33°C but poorly at 37°C
    This limits their ability to spread beyond the upper respiratory tract