Virology

🦠Virology Unit 7 – Animal Viruses – Overview and Key Families

Animal viruses are microscopic parasites that infect and replicate within animal cells. They consist of genetic material encased in a protein coat, lacking cellular structures and independent metabolism. These viruses cause various diseases in animals and humans. Animal viruses exhibit diverse structures, genomes, and replication strategies. They are classified based on their genetic material, capsid shape, and presence of an envelope. Understanding their lifecycle, transmission, and host interactions is crucial for developing effective prevention and control measures.

What Are Animal Viruses?

  • Obligate intracellular parasites that infect animal cells and tissues
  • Consist of genetic material (DNA or RNA) encapsulated by a protein coat (capsid)
  • Require host cell machinery for replication and propagation
  • Cause a wide range of diseases in animals, including humans (influenza, rabies, HIV)
  • Exhibit diverse morphologies, genome structures, and replication strategies
  • Lack cellular structure and independent metabolism, relying entirely on host cells
  • Evolve rapidly due to high mutation rates and short generation times
    • Allows for quick adaptation to new hosts and evasion of immune responses

Viral Structure and Classification

  • Virion, the complete infectious particle, comprises genetic material, capsid, and sometimes an envelope
  • Capsid, composed of proteins, protects the viral genome and facilitates cell entry
    • Icosahedral capsids have 20 triangular faces (adenoviruses, herpesviruses)
    • Helical capsids form a spiral structure around the nucleic acid (influenza virus, measles virus)
  • Enveloped viruses have an additional lipid bilayer derived from the host cell membrane (HIV, influenza virus)
  • Viral genomes can be DNA or RNA, single-stranded (ss) or double-stranded (ds), and linear or circular
  • Baltimore classification system categorizes viruses based on genome type and replication strategy
    • Seven groups: dsDNA, ssDNA, dsRNA, (+)ssRNA, (-)ssRNA, ssRNA-RT, and dsDNA-RT viruses
  • Viruses are also classified into families, genera, and species based on shared characteristics and evolutionary relationships

Lifecycle of Animal Viruses

  • Attachment: Viral surface proteins (spikes, fibers) bind to specific receptors on the host cell surface
  • Entry: Viruses penetrate the cell membrane through endocytosis or membrane fusion
  • Uncoating: Viral capsid disassembles, releasing the genome into the cytoplasm or nucleus
  • Replication: Viral genome is transcribed and replicated using host cell machinery and viral enzymes
    • DNA viruses typically replicate in the nucleus, while RNA viruses replicate in the cytoplasm
  • Assembly: Newly synthesized viral components are packaged into progeny virions
    • Capsid proteins self-assemble around the viral genome
    • Enveloped viruses acquire their lipid bilayer by budding through host cell membranes
  • Release: Mature virions are released from the host cell through lysis or budding, ready to infect new cells

Key Families of Animal Viruses

  • Herpesviridae: Large, enveloped dsDNA viruses that establish latent infections (herpes simplex virus, varicella-zoster virus)
  • Poxviridae: Large, complex dsDNA viruses that replicate entirely in the cytoplasm (smallpox virus, monkeypox virus)
  • Adenoviridae: Non-enveloped dsDNA viruses with icosahedral capsids, causing respiratory and gastrointestinal infections
  • Picornaviridae: Small, non-enveloped (+)ssRNA viruses (poliovirus, rhinovirus, foot-and-mouth disease virus)
  • Orthomyxoviridae: Enveloped (-)ssRNA viruses with segmented genomes (influenza viruses)
  • Paramyxoviridae: Enveloped (-)ssRNA viruses causing respiratory infections (measles virus, mumps virus)
  • Retroviridae: Enveloped ssRNA-RT viruses that integrate into the host genome (HIV, feline leukemia virus)
    • Reverse transcriptase converts the viral RNA genome into DNA for integration and replication

Transmission and Host Range

  • Animal viruses can be transmitted through various routes, depending on the virus and host
    • Respiratory droplets and aerosols (influenza virus, measles virus)
    • Fecal-oral route (rotavirus, norovirus)
    • Blood and body fluids (HIV, hepatitis B virus)
    • Vector-borne transmission by insects or ticks (dengue virus, Zika virus)
  • Host range is determined by the presence of specific receptors and cellular factors required for viral replication
    • Some viruses have a narrow host range, infecting only one or a few closely related species (measles virus, canine parvovirus)
    • Others have a broad host range, capable of infecting multiple species (rabies virus, West Nile virus)
  • Zoonotic viruses can cross species barriers and infect humans from animal reservoirs (SARS-CoV, Ebola virus)
    • Viral mutations and adaptations facilitate the emergence of new zoonotic threats

Pathogenesis and Disease

  • Viral pathogenesis involves the complex interactions between the virus and the host, leading to disease
  • Tissue tropism: Viruses preferentially infect and replicate in specific cell types or tissues
    • Respiratory viruses (influenza virus) target the epithelial cells of the respiratory tract
    • Neurotropic viruses (rabies virus) infect neurons and cause neurological disorders
  • Cytopathic effects: Viruses can directly damage or kill infected cells, disrupting tissue function
    • Cell lysis, apoptosis, or fusion can result from viral replication and release
  • Immune-mediated pathology: Host immune responses to viral infections can contribute to disease
    • Excessive inflammation and cytokine release (cytokine storm) can cause tissue damage
    • Autoimmune reactions triggered by viral antigens may lead to chronic conditions
  • Viral persistence: Some viruses can establish long-term or lifelong infections in the host
    • Latent infections (herpesviruses) involve periods of dormancy with occasional reactivation
    • Chronic infections (HIV, hepatitis C virus) involve continuous viral replication and presence

Diagnosis and Detection Methods

  • Clinical diagnosis based on symptoms, patient history, and physical examination
  • Laboratory tests confirm the presence of the virus or the host's immune response
    • Viral culture: Isolation and growth of the virus in cell culture or embryonated eggs
    • Antigen detection: Identification of viral proteins using immunoassays (ELISA, immunofluorescence)
    • Nucleic acid amplification tests (NAAT): Detection of viral genetic material using PCR or other amplification methods
      • Highly sensitive and specific, allowing for rapid diagnosis and quantification of viral load
    • Serological tests: Measurement of virus-specific antibodies (IgM, IgG) in the host's serum
      • Indicates current (IgM) or past (IgG) exposure to the virus
  • Imaging techniques (X-rays, CT scans) can reveal virus-induced pathology in affected tissues

Prevention and Control Strategies

  • Vaccination: Administration of vaccines to stimulate protective immunity against viral infections
    • Live attenuated vaccines contain weakened viruses that replicate without causing disease (measles, mumps, rubella vaccine)
    • Inactivated vaccines use killed viruses or viral components to elicit an immune response (influenza vaccine, polio vaccine)
    • Subunit and recombinant vaccines contain specific viral antigens produced through genetic engineering (hepatitis B vaccine)
  • Antiviral drugs: Medications that inhibit viral replication or block specific steps in the viral lifecycle
    • Nucleoside analogues (acyclovir) interfere with viral DNA synthesis
    • Protease inhibitors (lopinavir) prevent the cleavage of viral polyproteins
    • Entry inhibitors (enfuvirtide) block viral fusion and entry into host cells
  • Infection control measures: Practices aimed at preventing the spread of viral infections
    • Hand hygiene, respiratory etiquette, and personal protective equipment (gloves, masks)
    • Isolation and quarantine of infected individuals to limit transmission
    • Disinfection and sterilization of contaminated surfaces and medical equipment
  • Vector control: Strategies to reduce or eliminate the populations of insect vectors that transmit viruses
    • Insecticide spraying, bed nets, and environmental management to control mosquito populations (dengue, Zika)
  • Surveillance and monitoring: Continuous tracking of viral infections and outbreaks to guide public health interventions
    • Reporting of cases, identification of risk factors, and early detection of emerging threats
    • Genomic sequencing to monitor viral evolution and the emergence of new variants


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© 2024 Fiveable Inc. All rights reserved.
AP® and SAT® are trademarks registered by the College Board, which is not affiliated with, and does not endorse this website.