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Viruses

Viruses. Viruses contain DNA or RNA And a protein coat Some are enclosed by an envelope Some viruses have spikes. Figure 13.1. Viruses. Host range is the spectrum of host cells that a virus can infect. Most viruses infect only specific types of cells in one host

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Viruses

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  1. Viruses • Viruses contain DNA or RNA • And a protein coat • Some are enclosed by an envelope • Some viruses have spikes Figure 13.1

  2. Viruses • Host range is the spectrum of host cells that a virus can infect. • Most viruses infect only specific types of cells in one host • Host range is determined by specific host attachment sites and cellular factors

  3. Viral Structure • Virion is a fully developed, infectious viral particle composed of • Capsid or protein coat • Nucleic acid core • Envelope (not present on all viruses) • The arrangement capsid can be used to classify viruses into several different morphological types.

  4. Helical Viruses Figure 13.4a, b

  5. Polyhedral Viruses Figure 13.2a, b

  6. Complex Viruses Figure 13.5a

  7. Viral Taxonomy • Family names end in -viridae • Genus names end in -virus • Order names end in –ales • Viral species: A group of viruses sharing the same genetic information and ecological niche (host). • Common names are used for species • Subspecies are designated by a number

  8. Viral Taxonomy • Herpesviridae • Herpesvirus • Human herpes virus 1, HHV 2, HHV 3 • Retroviridae • Lentivirus • Human Immunodeficiency Virus 1, HIV 2

  9. Growing Bacterial Viruses • Viruses must be grown in living cells. • Plaque Assay is used to quantitate virus. • Bacteriophages form plaques when grown on agar. • Plaques are cleared areas in the bacterial lawn. Figure 13.6

  10. Growing Animal Viruses • Animal viruses may be grown in: • Living animals • Embryonated eggs. Figure 13.7

  11. Growing Animal Viruses • Animal and plants viruses may be grown in cell culture. • Primary Cell lines tend to die out after a few generations. • Continuous cell lines may be maintained indefinitely. Figure 13.8

  12. Virus Identification • Cytopathic effects • Serological tests • Detect antibodies against viruses in a patient • Use antibodies to identify viruses in neutralization tests, viral hemagglutination, and Western blot • Nucleic acids • RFLPs • PCR

  13. Virus Identification Figure 13.9

  14. Multiplication of Bacteriophages • Lytic cycle Phage causes lysis and death of host cell • Lysogenic cycle Prophage DNA incorporated in host DNA

  15. Multiplication of Bacteriophages (Lytic Cycle) • Attachment Phage attaches by tail fibers to host cell • Penetration Phage lysozyme opens cell wall, tail sheath contracts to force tail core and DNA into cell • Biosynthesis Production of phage DNA and proteins • Maturation Assembly of phage particles • Release Phage lysozyme breaks cell wall

  16. Multiplication of Bacteriophages (Lytic Cycle) Bacterial cell wall Bacterial chromosome Capsid DNA Capsid Sheath Tail fiber Tail 1 Attachment:Phage attaches to host cell. Base plate Pin Cell wall Plasma membrane 2 Penetration:Phage pnetrates host cell and injects its DNA. Sheath contracted Tail core 3 Merozoites released into bloodsteam from liver may infect new red blood cells Figure 13.10.1

  17. Multiplication of Bacteriophages (Lytic Cycle) Tail DNA 4 Maturation:Viral components are assembled into virions. Capsid 5 Release:Host cell lyses and new virions are released. Tail fibers Figure 13.10.2

  18. Viral Growth Curve Figure 13.11

  19. The Lysogenic Cycle Figure 13.12

  20. Specialized Transduction gal gene Bacterial DNA Prophage 1 Prophage exists in galactose-using host (containing the gal gene). Galactose-positive donor cell gal gene 2 Phage genome excises, carrying with it the adjacent gal gene from the host. 3 Phage matures and cell lyses, releasing phage carrying gal gene. gal gene 4 Phage infects a cell that cannot utilize galactose (lacking gal gene). Galactose-negative recipient cell 5 Along with the prophage, the bacterial gal gene becomes integrated into the new host’s DNA. 6 Lysogenic cell can now metabolize galactose. Galactose-positive recombinant cell Figure 13.13

  21. Multiplication of Animal viruses • Attachment Viruses attaches to cell membrane • Penetration By endocytosis or fusion • Uncoating By viral or host enzymes • Biosynthesis Production of nucleic acid and proteins • Maturation Nucleic acid and capsid proteins assemble • Release By budding (enveloped viruses) or rupture

  22. Attachment, Penetration, and Uncoating Figure 13.14

  23. Release of an enveloped virus by budding Figure 13.20

  24. Multiplication of DNA Virus Papovavirus 1 Virion attaches to host cell 7 Virions are released Host cell DNA Capsid 2 DNA Virion penetrates cell and its DNA is uncoated Cytoplasm 6 Virions mature Capsid proteins mRNA 5 Late translation; capsid proteins are synthesized 3 Early transcription and translation; enzymes are synthesized 4 Late transcription; DNA is replicated Figure 13.15

  25. Pathways of Multiplication for RNA-Containing Viruses Figure 13.17

  26. Multiplication of a Retrovirus Capsid Reverse transcriptase DNA Virus Two identical + stands of RNA 1 Retrovirus penetrates host cell. Host cell DNA of one of the host cell’s chromosomes 5 Mature retrovirus leaves host cell, acquiring an envelope as it buds out. Reverse transcriptase 2 Virion penetrates cell and its DNA is uncoated Viral RNA Identical strands of RNA 4 Transcription of the provirus may also occur, producing RNA for new retrovirus genomes and RNA that codes for the retrovirus capsid and envelope proteins. Viral proteins RNA 3 The new viral DNA is tranported into the host cell’s nucleus and integrated as a provirus. The provirus may divide indefinitely with the host cell DNA. Provirus Figure 13.19

  27. Viruses and Cancer • Viruses have been shown to cause cancer. • Viruses integrate into host cell DNA, causing DNA damage. • Oncogenes are alterations to normal cellular DNA that lead to cancer development

  28. Cancer • Activated oncogenes transform normal cells into cancerous cells. • Oncogenes can be activated by a variety of agents. • Transformed cells have increased growth, loss of contact inhibition, tumor specific transplant and T antigens.

  29. Oncogenic Viruses • Oncogenic RNA viruses • Retroviridae • Viral RNA is transcribed to DNA which can integrate into host DNA • HTLV 1 • HTLV 2 • Oncogenic DNA Viruses • Adenoviridae • Heresviridae • Poxviridae • Papovaviridae • Hepadnaviridae

  30. Viral Infections • Latent Viral Infections • Virus remains in asymptomatic host cell for long periods • Cold sores, shingles • Persistent Viral Infections • Disease processes occurs over a long period, generally fatal • Subacute sclerosing panencephalitis (measles virus)

  31. Prions • Infectious proteins • Inherited and transmissible by ingestion, transplant, & surgical instruments • Spongiform encephalopathies: Sheep scrapie, Creutzfeldt-Jakob disease, Gerstmann-Sträussler-Scheinker syndrome, fatal familial insomnia, mad cow disease • PrPC, normal cellular prion protein, on cell surface • PrPSc, scrapie protein, accumulate in brain cells forming plaques

  32. Prions PrPSc PrPc 2 3 4 1 Lysosome Endosome 5 6 7 8 Figure 13.21

  33. Plant Viruses • Plant Viruses • Plant viruses enter through wounds or via insects • Viroids • Viroids are infectious RNA; potato spindle tuber disease Figure 13.22

  34. Virus Families • Single-stranded DNA, nonenveloped viruses • Parvoviridae • Human parvovirus • Fifth disease • Anemia in immunocompromised patients

  35. Double-stranded DNA, nonenveloped viruses • Mastadenovirus • Respiratory infections in humans • Tumors in animals

  36. Double-stranded DNA, nonenveloped viruses • Papillomavirus (human wart virus) • Polyomavirus • Cause tumors, some cause cancer

  37. Double-stranded DNA, nonenveloped viruses • Orthopoxvirus (vaccinia and smallpox viruses) • Molluscipoxvirus • Smallpox, molluscum contagiosum, cowpox

  38. Double-stranded DNA, nonenveloped viruses • Simplexvirus (HHV1 and HHV 2) • Varicellavirus (HHV 3) • Lymphocryptovirus (HHV 4) • Cytomegalovirus (HHV 5) • Roseolovirus (HHV 6) • HHV 7 • Kaposi's sarcoma (HHV 8) • Some herpesviruses can remain latent in host cells

  39. Double-stranded DNA, nonenveloped viruses • Hepadnavirus (Hepatitis B virus) • Use reverse transcriptase to produce DNA from mRNA

  40. Single-stranded RNA, + strand, nonenveloped • Enterovirus • Enteroviruses include poliovirus and coxsackievirus • Rhinovirus • Hepatitis A virus

  41. Single-stranded RNA, + strand, nonenveloped • Hepatitis E virus • Norovirus (Norwalk agent) causes gastroenteritis

  42. Single-stranded RNA, + strand, nonenveloped • Alphavirus • Alphaviruses are transmitted by arthropods; include EEE, WEE • Rubivirus (rubella virus)

  43. Single-stranded RNA, + strand, nonenveloped • Arbovirusescan replicate in arthropods; include yellow fever, dengue, SLE, and West Nile viruses • Hepatitis C virus

  44. Single-stranded RNA, + strand, nonenveloped • Coronavirus • Upper respiratory infections

  45. Single-stranded RNA, – strand, one RNA strand • Vesiculovirus • Lyssavirus (rabies virus) • Cause numerous animal diseases

  46. Single-stranded RNA, – strand, one RNA strand • Filovirus • Enveloped, helical viruses • Ebola and Marburg viruses

  47. Single-stranded RNA, – strand, one RNA strand • Paramyxovirus • Morbillivirus • Paramyxovirus causes parainfluenza, mumps and Newcastle disease

  48. Single-stranded RNA, – strand, one RNA strand • Hepatitis D virus • Depends on coinfection with Hepadnavirus

  49. Single-stranded RNA, – strand, multiple RNA strands • Influenzavirus (Influenza viruses A and B) • Influenza C virus • Envelope spikes can agglutinate RBCs

  50. Single-stranded RNA, – strand, multiple RNA strands • Bunyavirus (CE virus) • Hantavirus

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