Deck 19: Gene Mutation and Dna Repair

A) EMS
B) Nitrous acid
C) 5BU
D) Nitrogen mustards
E) Acridine dyes

A) Reduction
B) Increase
C) Gene expression would remain the same

A) Depurination
B) Tautomeric shifts
C) Deamination
D) Demethylation

A) DNA replication errors
B) Tautomeric shifts of nucleic acid bases
C) Aberrant recombination
D) UV light
E) Transposable elements

A) EMS
B) Nitrous acid
C) 5BU
D) 2-amino purine
E) Acridine dyes

A) Rates of spontaneous mutation per cell generation typically range from 10-5 to 10-9
B) Mutation rates are consistent across species
C) Mutation rates are not influenced by environmental conditions
D) Mutation rates are constant

A) An intragenic mutation that restores the inactive protein's structure
B) An intergenic mutation that increases the activity of a protein performing a different function as the mutated protein
C) An intergenic mutation that activates a transcription factor that increases the expression of a normal protein
D) A mutation that suppresses cell growth

A) GAA
B) CAG
C) ATG
D) CCC
E) Any codon containing three of the same bases

A) Transition
B) Transversion
C) Neither

A) 1.0 x 105
B) 1.0 x 10-5
C) 3.0 x 105
D) 3.3 x 10-5

A) Random mutation theory
B) Physical adaptation theory
C) Both theories
D) Neither theory

A) Depurination
B) A tautomeric shift
C) Deamination
D) None of the answers are correct

A) Physiological adaptation theory
B) Random mutation theory
C) Both theories
D) Neither theory

A) TNRE
B) Anticipation
C) Position effect
D) Genome mutations

A) Depurination
B) Tautomeric shifts
C) Deamination
D) Demethylation

A) Neutral
B) Beneficial
C) Deleterious
D) Conditional

A) Nonsense mutations
B) Up-promoter mutations
C) Intergenic suppressors
D) TNRE mutations
E) None of the answers are correct

A) Recombinational repair
B) Direct repair
C) Base excision repair
D) Mismatch repair
E) Nucleotide excision repair

A) Recombinational repair
B) Base excision repair
C) Mismatch repair
D) Nucleotide excision repair
E) Nonhomologous end joining (NHEJ)

A) Point mutations in promoters frequently occur by this mechanism
B) Translocations may result in a promoter that is normally used for one gene now controlling an entirely different gene.
C) Since this mechanism relies on recombination it relies on the positioning of one allele so that it is under the control of the other allele.
D) Translocations always result in a gene being recombined into an area of heterochromatin.

A) UvrA/UvrB
B) UvrC
C) UvrD
D) UvrE

A) Recombinational repair
B) Direct repair
C) Base excision repair
D) Mismatch repair
E) Nucleotide excision repair

A) Recombinational repair
B) Direct repair
C) Base excision repair
D) Mismatch repair
E) Nucleotide excision repair

A) Recombinational repair
B) Direct repair
C) Base excision repair
D) Mismatch repair
E) Nucleotide excision repair

A) Total number of colonies on a plate: 1500 Total number of resistant colonies on replica plate with T1: 150
B) Total number of colonies on a plate: 1500 Total number of resistant colonies on replica plate with T1: 1500
C) Total number of colonies on a plate: 500 Total number of resistant colonies on replica plate with T1: 1500
D) Total number of colonies on a plate: 1500 Total number of resistant colonies on replica plate with T1: 0

A) Depurination, deamination, errors in DNA replication
B) UV light, radiation, deamination, depurination
C) UV light, radiation, deamination, errors in replication
D) UV light, errors in DNA replication, deamination, depurination

A) the polymerase used in translesion synthesis has a pocket that can accommodate the lesions while DNA pol III's pocket cannot.
B) there is no real difference between the polymerases except that the translesional polymerase is not part of the replication complex.
C) the polymerase used in translesion synthesis has a pocket that cannot accommodate the lesions, that is part of the mechanism by which the lesions are removed.
D) the polymerase used to remove the lesion has a modified nucleotide binding pocket allowing for mispairing of nucleotides.

A) A
B) B
C) C
D) D

A) Silent
B) Missense
C) Nonsense
D) Insertion

A) The differences between gladiolas and snapdragons would most likely be silent mutations while those in beechdrops may be silent or missense
B) Since these three plants are not highly related the sequences for RuBisCO would be very different between them
C) The differences between gladiolas and snapdragons would most likely be in the second nucleotide of codons while beechdrops would have a higher number of mutations in the third nucleotide of the different codons
D) The differences between gladiolas and snapdragons would most likely be missense mutations while those in beechdrops may be silent or missense

A) an agent that can alter the structure of DNA and cause mutations.
B) a depurinated base.
C) a DNA polymerase without a 5' to 3' exonuclease.
D) a deaminated base.

A) bases are oxidized to a variety of different products which might pair with a different base than the original base would have.
B) thymine bases are dimerized which causes a break in the DNA which is not repaired correctly.
C) the reactive oxygen species stabilize different tautomeric forms of the bases causing inappropriate pairing.
D) guanine is depurinated by the reactive oxygen species and if it is not repaired can result in any base being inserted.