1. Characterizing and Classifying Viruses, Viroids, and Prions
Chapter 13
Characterizing and Classifying Viruses, Viroids, and Prions

2. Characteristics of Viruses
Minuscule, acellular infectious agent having either DNA or RNA
Causes many infections of humans, animals, plants, and bacteria
Causes most of the diseases that plague the industrialized world
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3. Characteristics of Viruses
Cannot carry out any metabolic pathway
Neither grow nor respond to the environment
Cannot reproduce independently
Recruit the cell’s metabolic pathways to increase their numbers
No cytoplasmic membrane, cytosol, organelles (with one exception)
Have extracellular and intracellular state
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4. 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 provides protection and recognition sites for host cells
Intracellular State
Capsid removed
Virus exists as nucleic acid
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5. Figure 13.1 Virions-overview

6. Characteristics of Viruses
Genetic Material of Viruses
Show more variety in nature of their genomes than do cells
Primary way scientists categorize and classify viruses
May be DNA or RNA, but never both
dsDNA, ssDNA, dsRNA, ssRNA
Linear and segmented or single and circular
Much smaller than genomes of cells
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7. Figure 13.2 The relative sizes of genomes
Partial genome of E. coli
Viral genome

8. Characteristics of Viruses
Hosts of Viruses
Most viruses infect only particular host’s cells
Affinity of viral surface proteins for proteins on host cell
May be so specific they infect only particular kind of cell in a particular host
Generalists – infect many kinds of cells in many different hosts
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9. Figure 13.3 Hosts of viral infections-overview

10. Figure 13.4 Sizes of selected virions
E. coli (bacterium) (1000 nm  3000 nm)
Red blood cell (10,000 nm in diameter)
Bacterial ribosomes (25 nm)
Smallpox virus (200 nm  300 nm)
Poliovirus (30 nm)
Bacteriophage T4 (50 nm  225 nm)
Bacteriophage MS2 (24 nm)
Tobacco mosaic virus (15 nm  300 nm)

11. Characteristics of Viruses
Capsid Morphology
Capsids
Provide protection for viral nucleic acid
Means of attachment to host’s cells
Composed of proteinaceous subunits called capsomeres
Capsomere made of single or multiple types of proteins
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12. Characteristics of Viruses
Viral Shapes
Three basic shapes
Helical
Polyhedral
Complex
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13. Figure 13.5 The shapes of virions-overview

14. Figure 13.6 Bacteriophage T4-overview

15. Characteristics of Viruses
The Viral Envelope
Acquired from host cell during viral replication or release
Envelope is portion of membrane system of host
Composed of phospholipid bilayer and proteins
Some proteins are virally coded glycoproteins (spikes)
Envelope’s proteins and glycoproteins often play role in host recognition
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16. Figure 13.7 Enveloped virion-overview

17. Table 13.2 Families of Human Viruses

18. Dependent on hosts’ organelles and enzymes to produce new virions
Viral Replication
Dependent on hosts’ organelles and enzymes to produce new virions
Lytic replication
Replication cycle usually results in death and lysis of host cell
Stages of lytic replication cycle
Attachment
Entry
Synthesis
Assembly
Release
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19. Viral Replication ANIMATION Viral Replication: Overview 19
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20. Figure 13.8 The lytic replication cycle in bacteriophages-overview
Attachment
Bacteriophage genome
Entry
Tail sheath
Outer membrane
Peptidoglycan
Cytoplasmic membrane
Bacterial chromosome
Entry
Attachment
Phage DNA
Lytic replication cycle of bacteriophage
Bacterial chromosome degraded
Release
Synthesis
Phage proteins
Assembly
Assembly
Base
Tail
Sheath
DNA
Capsid
Mature head
Tail fibers
Mature virion

21. Figure 13.9 Pattern of virion abundance in lytic cycle
Burst size
Number of infective virions in medium (log scale)
Release of virions by lysis
Entry
Synthesis and assembly
Time (minutes)
Attachment
Burst time

22. Viral Replication ANIMATION Viral Replication: Virulent Bacteriophages
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23. Viral Replication Lysogeny Modified replication cycle
Infected host cells grow and reproduce normally for generations before they lyse
Temperate phages
Prophages – inactive phages
Lysogenic conversion results when phages carry genes that alter phenotype of a bacterium
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24. Figure 13.10 Bacteriophage lambda

25. Figure 13.11 The lysogenic replication cycle in bacteriophages: phage lambda and E. coli
Attachment
Entry
Prophage in chromosome
Lambda phage
Lytic cycle
Lysogeny
Synthesis
Release
Replication of chromosome and virus; cell division
Assembly
Induction
Further replications and cell divisions

26. Viral Replication
ANIMATION Viral Replication: Temperate Bacteriophages
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27. Replication of Animal Viruses
Viral Replication
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
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28. Replication of Animal Viruses
Viral Replication
Replication of Animal Viruses
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
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29. Figure 13.12 Three mechanisms of entry of animal viruses-overview

30. Replication of Animal Viruses
Viral Replication
Replication of Animal Viruses
Synthesis of animal viruses
Requires different strategy depending on its nucleic acid
DNA viruses often enter the nucleus
RNA viruses often replicate in the cytoplasm
Must consider
How mRNA is synthesized
What serves as template for nucleic acid replication
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31. Figure 13.13 Synthesis of proteins and genomes in animal RNA viruses-overview

32. Replication of Animal Viruses
Viral Replication
Replication of Animal Viruses
Assembly and release of animal viruses
Most DNA viruses assemble in nucleus
Most RNA viruses develop solely in cytoplasm
Number of viruses produced depends on type of virus and size and initial health of host cell
Enveloped viruses cause persistent infections
Naked viruses are released by exocytosis or lysis
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33. Figure 13.14 The process of budding in enveloped viruses
Enveloped virion
Budding of enveloped virus
Viral glycoproteins
Cytoplasmic membrane of host
Viral capsid

34. Figure 13.15 Pattern of virion abundance in persistent infections
Number of infective virions in medium
Synthesis and assembly
Release of virions
Entry
Time
Attachment

35. Viral Replication ANIMATION Viral Replication: Animal Viruses 35
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36. Replication of Animal Viruses
Viral Replication
Replication of Animal Viruses
Latency of animal viruses
When animal viruses remain dormant in host cells
May be prolonged for years with no viral activity
Some latent viruses do not become incorporated into host chromosome
Incorporation of provirus into host DNA is permanent
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37. The Role of Viruses in Cancer
Animal’s genes dictate that some cells can no longer divide or are prevented from unlimited division
Genes for cell division “turned off” or genes inhibiting division “turned on”
Neoplasia
Uncontrolled cell division in multicellular animal
Mass of neoplastic cells is tumor
Benign vs. malignant tumors
Metastasis
Cancers
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38. Figure 13.16 The oncogene theory of the induction of cancer in humans
Normal state:
DNA
Protooncogene
Gene for repressor
Represses
mRNA
Repressor
Result: No cancer
First “hit”:
Virus inserts promoter
DNA
Oncogene
Gene for repressor
Represses
mRNA
Repressor
Result: Still no cancer
Second “hit”:
Virus inserts into represssor gene
DNA
Oncogene
No repressor protein because gene is segmented
mRNA
Protein
Causes cell division
Result: Cancer

39. The Role of Viruses in Cancer
Environmental factors that contribute to the activation of oncogenes
Ultraviolet light
Radiation
Carcinogens
Viruses
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40. The Role of Viruses in Cancer
Viruses cause 20–25% of human cancers
Some carry copies of oncogenes as part of their genomes
Some promote oncogenes already present in host
Some interfere with tumor repression
Specific viruses are known to cause ~15% of human cancers
Burkitt’s lymphoma
Hodgkin’s disease
Kaposi’s sarcoma
Cervical cancer
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41. Culturing Viruses in the Laboratory
Culturing Viruses in Mature Organisms
In bacteria
In plants and animals
Culturing Viruses in Embryonated Chicken Eggs
Inexpensive, among the largest of cells, free of contaminating microbes, and contain a nourishing yolk
Culturing Viruses in Cell (Tissue) Culture
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42. Bacterial lawn Viral plaques
Figure Viral plaques in a lawn of bacterial growth on the surface of an agar plate
Bacterial lawn
Viral plaques

43. Injection into chorioallantoic membrane
Figure Inoculation sites for the culture of viruses in embryonated chicken eggs
Air sac
Injection into chorioallantoic membrane
Injection into chorioallantois
Injection into embryo
Injection into amnion
Injection into yolk sac

44. Culturing Viruses in the Laboratory
Culturing Viruses in Cell (Tissue) Culture
Consists of cells isolated from an organism and grown on a medium or in a broth
Two types of cell cultures
Diploid cell cultures
Continuous cell cultures
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45. Figure 13.19 An example of cell culture

46. Some consider them complex pathogenic chemicals
Are Viruses Alive?
Some consider them complex pathogenic chemicals
Others consider them the least complex living entities
Use sophisticated methods to invade cells
Have the ability to take control of their host cell
Are able to replicate themselves
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47. Other Parasitic Particles: Viroids and Prions
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
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48. Genome of bacteriophage T7 PSTV
Figure The RNA strand of the small potato spindle tuber viriod (PSTV)
Genome of bacteriophage T7
PSTV

49. Figure 13.21 One effect of viroids on plants

50. Other Parasitic Particles: Viroids and Prions
Characteristics of Prions
Proteinaceous infectious agents
Cellular PrP protein
Made by all mammals
Normal structure with -helices called cellular PrP
Prion PrP
Disease-causing form with -pleated sheets called prion PrP
Prion PrP changes shape of cellular PrP so it becomes prion PrP
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51. Other Parasitic Particles: Viroids and Prions
ANIMATION Prions: Overview
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52. Figure 13.22 The two stable, three-dimensional forms of prion protein (PrP)-overview

53. Other Parasitic Particles: Viroids and Prions
Characteristics of Prions
Normally, nearby proteins and polysaccharides force PrP into cellular shape
PrP mutations result in formation of prion Pr
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54. Other Parasitic Particles: Viroids and Prions
ANIMATION Prions: Characteristics
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55. Other Parasitic Particles: Viroids and Prions
Characteristics of Prions
Prion diseases
Fatal neurological degeneration, fibril deposits in brain, and loss of brain matter
Large vacuoles form in brain
Characteristic spongy appearance
Spongiform encephalopathies
Prions only destroyed by incineration or autoclaving in 1 N NaOH
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56. Figure 13.23 The brain of a sheep with the prion disease called scrapie
Vacuole

57. Other Parasitic Particles: Viroids and Prions
ANIMATION Prions: Disease
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