Virology Viruses • Cause many infections of humans, animals, plants, and bacteria • Cannot carry out any metabolic pathway • Neither grow nor respond to the environment • Cannot reproduce independently • Obligate intracellular parasites • Are however considered “alive” by most scientists • Cannot be seen by light microscopy Characteristics of Viruses • Virus – miniscule, acellular, infectious agent having one or several pieces of either DNA or RNA • No cytoplasmic membrane, cytosol, organelles • Have extracellular and intracellular state Characteristics of Viruses • Extracellular state – Called virion – Protein coat (capsid) surrounding nucleic acid – Nucleic acid and capsid also called nucleocapsid – Some have phospholipid envelope – Outermost layer (capsid or envelope) provides protection and recognition sites for host cells • Intracellular state – Capsid removed – Virus exists as nucleic acid How Viruses Are Distinguished • • • • • • *Type of genetic material they contain Kinds of cells they attack Size of virus Nature of capsid coat Shape of virus Presence or absence of envelope Genetic Material of Viruses • May be DNA or RNA; never both • May be linear and composed of several segments or single and circular • Much smaller than genomes of cells Hosts of Viruses • Most only infect particular kinds of host’s cells – Due to affinity of viral surface proteins or glycoproteins for complementary proteins or glycoproteins on host cell surface • Generalists • Bacteriophage (phage) HIV Tobacco mosaic virus bacteriophages Sizes of Viruses Figure 13.4 Capsid Morphology • Capsids – protein coats that provide protection for viral nucleic acid and means of attachment to host’s cells – capsomeres Shapes of viruses Also bullet and thread shapes Complex Viruses Figure 13.6a The Viral Envelope • Acquired from host cell during viral replication or release • Composed of phospholipid bilayer and proteins; some proteins are virally-coded glycoproteins (spikes) – play role in host recognition Nucleic acid • • • • Genome Used to replicate within the host DNA or RNA Can be ss, ds, linear, circular, segmented (pieces) • DNA – ss or ds • RNA – positive (+) sense, negative (-) sense, ds Viral classification • Originally by type of host or host structures • Biochemical and molecular now • Don’t use kingdom, phylum… Viral Replication • Dependent on host’s organelles and enzymes to produce new virions • Cycles vary between bacteriophages and animal viruses • Replication cycle usually results in death and lysis of host cell (hence lytic cycle, lytic phages, virulent phages) • Stages of lytic replication cycle – Attachment – Entry/Penetration – Synthesis – Assembly/Maturation – Release Lytic Replication of Bacteriophages Lysozyme – phage tails Figure 13.8 Lytic Replication of Bacteriophages Lysozyme Figure 13.8 Lytic Phage Replication Cycle Figure 13.9 Lysogeny (Temperate phages) Figure 13.11 • Lysogenic conversion – prevents entry of another virus into a bacteria that is already infected by another phage of the same type – Can be infected however by virus of different type – Medical importance - toxins Bacterium Phage Gene Product Phenotype Vibrio cholerae CTX phage cholerae toxin cholera Escherichia coli lambda phage shigalike toxin hemorrhagic diarrhea Clostridium botulinum clostridial phages botulinum toxin botulism (food poisoning) Corynebacterium diphtheriae corynephage betadiphtheria toxin diphtheria Streptococcus pyogenes T12 erythrogenic toxins scarlet fever Replication of Animal Viruses • Same basic replication pathway as bacteriophages • Differences result from – Presence of envelope around some viruses – Eukaryotic nature of animal cells – Lack of cell wall in animal cells Attachment of Animal Viruses • Chemical attraction • Animal viruses do not have tails or tail fibers • Have glycoprotein spikes or other attachment molecules that mediate attachment Entry and Uncoating of Animal Viruses Figure 13.12a, b Synthesis of Animal Viruses • Each type of animal virus requires different strategy depending on its nucleic acid Synthesis in DNA viruses • Replicate their DNA in the host cell nucleus with the aid of viral enzymes • Synthesize new viral parts in cytoplasm with host enzymes • Parts then move to nucleus to combine with new DNA to make complete virions – Exception Poxviruses assemble in cytoplasm • ssDNA viruses – must make complement strand before proceeding to replicate RNA animal viruses • (+) sense RNA viruses – (+) strand acts as mRNA and viral proteins made immediately after penetration and uncoating – Nucleus not involved – RNA-dependent RNA polymerase makes (-) strand RNA (antisense strand) to act as template for more (+) strand RNA – Assembly in cytoplasm • (-) sense RNA viruses – RNA-dependent RNA polymerase uses (-) sense RNA to make (+) sense RNA which acts as mRNA to make viral parts – New (-) sense RNA made to package into new virions – Assembly in cytoplasm • Retroviruses – two copies of (+) sense RNA don’t act as mRNA – Reverse transcriptase – turn the RNA into ssDNA, which is then replicated to dsDNA – dsDNA moves to nucleus and turns into provirus in host cell chromosome – Can remain for indefinite amount of time, passed to subsequent generations – Genome cannot be excised like prophages – Once activated, makes viral mRNA, and full length (+) sense RNA to package into virion (2 per new virion) • dsRNA viruses – (+) strand acts as mRNA template – Make more (-) strands (RNA-dependent RNA polymerase) – Assembly in cytoplasm, (+) and (-) strands come together to form viral genome, polymerase packaged with genome Synthesis of Animal Viruses Table 13.3 Assembly (maturation) and Release of Animal Viruses • Number of viruses produced and released depends on type of virus and size and initial health of host cell • Site of assembly varies by virus type • Enveloped viruses cause persistent infections • Naked viruses released by exocytosis or may cause lysis and death of host cell Release of Enveloped Viruses by Budding Budding may/may not kill cell Naked virions exocytosed Figure 13.13 Latency of Animal Viruses • When animal viruses remain dormant in host cells • May be prolonged for years with no viral activity, signs, or symptoms • Some latent viruses do not become incorporated into host chromosome • When provirus is incorporated into host DNA, condition is permanent; becomes permanent physical part of host’s chromosome – Site of integration can affect host cell Summary of Bacteriophage and Animal Virus Replication Table 13.4 Damage to host cells • Cytopathic effect – Virus-induced damage to cell, alters cell appearance • Shape, changes intracellularly (inclusion bodies), damage to organelles • Single cells merge into large giant cells (syncytia) The Role of Viruses in Cancer • Normally, animal’s genes dictate that some cells can no longer divide and those that can divide are prevented from unlimited division • Genes for cell division “turned off” or genes that inhibit division “turned on” • Neoplasia – uncontrolled cell division in multicellular animal; mass of neoplastic cells is tumor • Benign vs. malignant tumors – Metastasis – Cancers • Oncogenes – genes that promote neoplasia – In DNA viruses, part of viral genome needed to synthesize viral proteins is oncogene – In RNA viruses, viruses pick up “extra” genes from normal host cell during replication which are similar to oncogenes (proto-oncogenes) How Viruses Cause Cancer • Some carry copies of oncogenes as part of their genomes • Some stimulate oncogenes already present in host • Some interfere with tumor repression when they insert into host’s repressor gene • Several DNA and RNA viruses are known to cause ~15% of human cancers – Burkitt’s lymphoma – Hodgkin’s disease – Kaposi’s sarcoma – Cervical cancer Viruses and pregnancy • Teratogenesis – induction of defects during embryonic development (caused by teratogen) – Can cause more severe abnormalities if early in pregnancy – Can pass disease to unborn fetus Culturing Viruses in the Laboratory • In Whole Organisms – Bacteria – Plants and Animals • Embryonated Chicken Eggs • In Cell (Tissue Culture) Culturing Viruses in Bacteria Plaque assay PFU – plaque forming unit Lawn of bacteria Figure 13.16 Culturing Viruses in Embryonated Chicken Eggs Figure 13.17 Culturing Viruses in Cell (Tissue) Culture Figure 13.18 Gene therapy • In vitro • In vivo • Single-gene defects Characteristics of Viroids • Extremely small, circular pieces of RNA that are infectious and pathogenic in plants • Similar to RNA viruses, but lack capsid • May appear linear due to H bonding How viroids differ from viruses • Single circular RNA molecule with low molecular weight • Exist inside cells, usually in nucleoli, and particles of RNA w/o capsids or envelopes • Does not produce proteins from RNA • Viroid RNA always processed in host nucleus • Not apparent in infected tissues without the use of special techniques to identify nucleotide sequences in the RNA Characteristics of Prions • Proteinaceous infectious agents • Composed of single protein PrP • All mammals contain gene that codes for primary sequence of amino acids in PrP • Two stable tertiary structures of PrP – Normal functional structure with α-helices called cellular PrP – Disease-causing form with β-sheets called prion PrP • Prion PrP converts cellular PrP into prion PrP by inducing conformational change Characteristics of Prions • Normally, nearby proteins and polysaccharides force PrP into cellular shape • Excess PrP production or mutations in PrP gene result in initial formation of prion PrP • When prions present, they cause newly synthesized cellular PrP to refold into prion PrP Prion Diseases • All involve fatal neurological degeneration, deposition of fibrils in brain, and loss of brain matter • Large vacuoles form in brain; characteristic spongy appearance • Spongiform encephalopathies – BSE, CJD, kuru • Only destroyed by incineration; not cooking or sterilization Scrapie Prion-associated diseases • Scrapie • Common in several countries around the world, sheep, goats • Kuru • Once common in Papua New Guinea, now rare, humans • Cruetzfeldt-Jakob disease (CJD) • Worldwide, humans • Bovine spongiform enchephalopathy (BSE) or “mad cow disease” • Mainly Europe, UK, cattle • Feline spongiform encephalopathy (FSE) • UK, domestic cats
