Deck 6: Viruses

A) Icosahedral
B) Complex
C) Asymmetrical
D) Filamentous
E) Viroid

A) capsid
B) neck
C) tail fibers
D) envelope
E) tegument

A) phase-contrast microscopy
B) scanning electron microscopy
C) cryo-electron microscopy
D) negative stain
E) bright field microscopy

A) capsid
B) genome
C) envelope
D) neck
E) tail fibers

A) Viral
B) Viroid
C) Bacterial
D) Virion
E) Prion

A) icosahedral
B) filamentous
C) asymmetrical
D) complex
E) helical

A) helical
B) filamentous
C) rectangular
D) triangular
E) asymmetrical

A) Plaques
B) Viruses
C) Genomes
D) Proteomes
E) Burst size

A) It is encased by an envelope of membrane.
B) It fuses with the host cell membrane during infection.
C) It has progeny that bud out of the host cell.
D) It generates a rash of red spots on the skin of infected patients.
E) It is never fatal.

A) 4
B) 6
C) 8
D) 10
E) 20

A) prions
B) viroids
C) viruses
D) bacteria
E) virions

A) prion
B) viroid
C) virus
D) virion
E) bacterial

A) in the capsid
B) between the capsid and envelope
C) in the envelope
D) in the nucleus
E) in the spikes

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

A) icosahedral
B) filamentous
C) complex
D) bacteriophage
E) asymmetrical

A) It may cause human pneumonia.
B) It is as large as some bacteria.
C) It conducts DNA repair.
D) It conducts protein folding by chaperones.
E) It contains reverse transcriptase.

A) plasmid
B) bacterial chromosome
C) envelope
D) ribosome
E) viral genome

A) RNA
B) protein
C) DNA
D) capsid
E) envelope

A) tissue culture
B) lawn
C) soft agar
D) plaque
E) host

A) 5
B) 6
C) 7
D) 8
E) 9

A) Phage DNA is injected into the bacterial cell.
B) The phage DNA integrates into the bacterial chromosome.
C) Many copies of phage DNA are made.
D) The phage DNA is transcribed, and the resulting mRNA is translated to make capsid proteins.
E) All of the above steps are part of the life cycle of a lytic phage.

A) Annapolis
B) Baltimore
C) Orono
D) Augusta
E) Portland

A) an envelope
B) a neck
C) tail fibers
D) a ghost
E) temperate

A) They have an RNA genome.
B) They do not make a DNA intermediate.
C) Some have a viral reverse transcriptase.
D) Some use a host reverse transcriptase.
E) They consist of human and plant pathogens.

A) It enters the host cell with the viral genome.
B) It remains on the outside of the host cell.
C) It enters the host cell separately from the viral genome.
D) It is released to attach to and inject another host cell.
E) It becomes part of the host cell membrane.

A) DNAs
B) RNAs
C) proteins
D) capsids
E) host range

A) temperate
B) lysogen
C) oncogene
D) lytic
E) prophage

A) lytic
B) temperate
C) viroid
D) asymmetrical
E) oncogenic

A) Homologs
B) Open reading frames
C) Proteomes
D) Orthologs
E) Lysogenic

A) type of genetic material
B) virion structure
C) shared hosts
D) transcriptional strategy
E) replicase gene sequence

A) bacterial gene
B) bacterial enzyme
C) piece of phage DNA
D) inactive viral RNA
E) cascade protein

A) Resistance to phages can occur through mutations.
B) Bacterial restriction endonucleases can cleave viral RNA genome.
C) The clustered, regularly interspaced short palindromic repeats inserted in the bacterial genome facilitate cleavage of specific phage DNA.
D) Bacterial restriction endonuclease system cleaves DNA lacking appropriate methylation patterns.
E) Resistance to phages can occur through altered host receptor proteins.

A) Genera
B) Families
C) Species
D) Orders
E) Classes

A) genome
B) envelope
C) capsid
D) tegument
E) neck

A) only have eight genes
B) have an RNA genome
C) contain reverse transcriptase
D) have a segmented genome
E) have a circular chromosome

A) lytic number
B) burst size
C) lysogenic number
D) temperate number
E) release number

A) a DNase that digests host genome
B) an RNase that digests viral genome
C) a protease that digests viral capsids
D) the capsids required to produce mature viral particles
E) the ribosomes required for translation of viral mRNA

A) positive-sense (+)
B) negative-sense (-)
C) all
D) double-stranded
E) prion

A) monomeric
B) monophyletic
C) monogrammed
D) monosyllabic
E) monolithic

A) picornaviruses
B) papillomaviruses
C) oncogenic viruses
D) lentiviruses
E) pararetroviruses

A) It is the causative agent of AIDS.
B) It makes a DNA copy of its RNA genome.
C) Reverse transcriptase is translated from an early gene.
D) The virion contains two copies of the HIV genome.
E) The viral RNA is copied into double-stranded DNA.

A) latent infection
B) lytic infection
C) persistent infection
D) transformation
E) acute infection

A) eclipse period
B) latent period
C) rise period
D) burst period
E) lag period

A) tropism
B) host range
C) virulence
D) burst size
E) plaque

A) hosts never come down with illness when infected by persistent viruses
B) persistent viruses could encode growth factors beneficial to infected hosts
C) persistent viruses shorten hosts' generation time, resulting in hosts that outcompete their competitors
D) persistent viruses could encode toxins that kill off competing bacteria
E) persistent viruses could improve hosts' efficiency in uptake of nutrients

A) receptors
B) membranes
C) envelopes
D) vectors
E) hosts

A) envelope
B) capsid
C) genome
D) receptor
E) burst

A) latent infection
B) lytic infection
C) persistent infection
D) transformation
E) oncogenic infection

A) human papillomavirus (HPV)
B) human immunodeficiency virus (HIV)
C) gonorrhea
D) syphilis
E) chlamydia