Deck 13: Viruses, Viroids, and Prions

A) attachment
B) uncoating
C) biosynthesis
D) penetration
E) release

A) They are chemically simple.
B) They are filterable.
C) They cause diseases similar to those caused by chemicals.
D) They cannot reproduce themselves outside a host.
E) They are not composed of cells.

A) provirus.
B) infectious protein.
C) capsid without nucleic acid.
D) complete, infectious virus particle.
E) infectious piece of RNA without a capsid.

A) the period during replication when virions are not present.
B) when the burst time takes an unusually long time.
C) attachment of a phage to a cell.
D) lysis of the host cell due to a phage.
E) phage DNA is incorporated into host cell DNA.

A) animal cell cultures
B) culture media
C) embryonated eggs
D) laboratory animals
E) bacterial cultures

A) RNA
B) DNA polymerase
C) lysozyme
D) PrPSc
E) DNA

A) A prophage is phage DNA inserted into a bacterial chromosome.
B) A prophage may result in new properties of the host cell.
C) Prophage genes are repressed by a repressor protein coded for by the prophage.
D) A prophage can ʺpopʺ out of the chromosome.
E) The prophage makes the host cell immune to infection by other phages.

A) penetration
B) adsorption
C) release
D) biosynthesis
E) uncoating

A) They bind to receptors on the host cell surface.
B) They are composed of carbohydrate-protein complexes.
C) They may cause hemagglutination.
D) They are found only on nonenveloped viruses.
E) They are used for attachment.

A) DNA or RNA.
B) RNA.
C) viroids.
D) Capsomeres.
E) DNA.

A) a
B) b
C) c
D) d
E) All of the structures are complex viruses.

A) the virus remains in equilibrium with the host without causing a disease.
B) host cells are transformed.
C) host cells are gradually lysed.
D) the disease process occurs gradually over a long period.
E) viral replication is unusually slow.

A) cell lysis.
B) rash.
C) plaque.
D) pock.
E) phage.

A) morphology
B) size
C) number of capsomeres
D) biochemical tests
E) nucleic acid

A) Viruses are not composed of cells.
B) Viruses are filterable.
C) Viruses are obligate intracellular parasites.
D) Viruses do not have any nucleic acid.
E) Viruses do not reproduce.

A) acquisition of new characteristics by the host cell.
B) phage conversion.
C) specialized transduction.
D) immunity to reinfection by any phage.
E) immunity to reinfection by the same phage.

A) It can give infected pathogens the genetic information for toxin production.
B) It is a ʺsilentʺ infection; the virus does not replicate.
C) Lytic cycle may follow lysogeny.
D) Prophage is inserted into the host genome.
E) It causes lysis of host cells.

A) continuous cell lines always have to be re-isolated from animal tissues.
B) continuous cell lines are derived from primary cell lines.
C) viruses can be grown in continuous cell lines.
D) continuous cell lines are from human embryos.
E) continuous cell lines can be maintained through an indefinite number of generations.

A) bacteriophage.
B) prion.
C) papovavirus.
D) viroid.
E) retrovirus.

A) a
B) b
C) c
D) d
E) e

A) 2; 3; 4; 1
B) 4; 3; 2; 1
C) 3; 4; 1; 2
D) 4; 1; 2; 3
E) 1; 2; 3; 4

A) Viruses contain DNA or RNA but never both.
B) Viruses contain a protein coat.
C) Viruses have genes.
D) Viruses use their own catabolic enzymes.
E) Viruses use the anabolic machinery of the cell.

A) has the same genetic information and ecological niche.
B) has the same morphology and nucleic acid.
C) infects the same cells and cause the same disease.
D) cannot be defined.

A) have no effect on the host cell.
B) cause acute infections.
C) are genetically unstable.
D) cause tumors to develop.
E) are lytic viruses that kill the host cell.

A) tRNA.
B) lysozyme.
C) nucleotides.
D) amino acids.
E) ATP.

A) assembly of viral components.
B) replication of viral nucleic acid.
C) adsorption to specific receptors.
D) injection of naked nucleic acid into the host cell.
E) lysis of the host cell.

A) budding.
B) transduction.
C) penetration.
D) abduction.
E) lysogeny.

A) presence of pili on the host cell wall.
B) enzymatic activity of a host cell.
C) host cellʹs ability to phagocytize viral particles.
D) presence of receptor sites on the cell membrane.
E) type of viral nucleic acid.

A) togavirus
B) retrovirus
C) picornavirus
D) herpesvirus
E) papovavirus

A) a
B) b
C) c
D) d
E) e

A) nucleotides.
B) DNA polymerase.
C) RNA polymerase.
D) tRNA.
E) None of the answers are correct; all of these are supplied by the host animal cell.

A) Rhabdoviridae and Herpesviridae.
B) Herpesviridae and Retroviridae.
C) Hepadnaviridae and Retroviridae.
D) Retroviridae and Picornaviridae.
E) Herpesviridae and Poxviridae.

A) penetration
B) uncoating
C) attachment
D) synthesis of double-stranded DNA
E) synthesis of +RNA

A) latent viruses.
B) lytic viruses.
C) slow viruses.
D) phages.
E) unconventional viruses.

A) finding oncogenes in viruses.
B) some liver cancer patients having had hepatitis.
C) cancer following injection of cell-free filtrates.
D) the presence of antibodies against viruses in cancer patients.
E) treating cancer with antibodies.

A) cold sores.
B) mumps.
C) subacute sclerosing panencephalitis.
D) smallpox.
E) influenza.

A) penetration
B) attachment
C) biosynthesis
D) release
E) uncoating

A) The virus is infecting cells and then releasing only small amounts of virus.
B) The virus is incorporating its nucleic acid with that of the patientʹs cells.
C) The virus is slowly killing the patientʹs cells.
D) The virus is causing the death of the infected cells in the patient.
E) The virus is not killing any cells in the host.

A) Hepadnaviridae.
B) influenzavirus.
C) bacteriophage families.
D) Herpesviridae.
E) Retroviridae.

A) synthesis of viral proteins
B) synthesis of + strand RNA
C) penetration and uncoating
D) synthesis of - strand RNA
E) attachment

A) ease of virus transmission
B) attachment spikes
C) worldwide distribution of the virus
D) a segmented genome
E) different virus subtypes

A) synthesis of DNA
B) synthesis of - strands of RNA
C) synthesis of viral proteins
D) synthesis of + strands of RNA
E) None of the answers is correct.

A) envelope proteins
B) spike proteins
C) capsid proteins
D) DNA polymerase
E) lysozyme

A) Oncogenes; transformation
B) Segmented genomes; reassortment
C) T antigens; lysis
D) Glycoprotein spikes; syncytia formation
E) Herpes viruses; lesions

A) reverse transcriptase
B) lysozyme
C) ATP synthase
D) RNA-dependent RNA polymerase
E) DNA-dependent DNA polymerase