Deck 17: DNA Replication, repair, and Recombination

A)origin of replication.
B)terminator sites.
C)initiator proteins.
D)minichromosome maintenance proteins.
E)helicase loaders.

A)due to exposure to certain chemicals or radiation.
B)spontaneously.
C)during DNA replication.
D)during transcription.
E)during DNA replication,spontaneously,or due to exposure to certain chemicals or radiation.

A)tautomeric shift
B)double-stranded DNA breaks
C)pyrimidine dimer addition
D)deletion of large sections of DNA
E)the re-replication of highly repetitive DNA sequences

A)requires a type of RNA polymerase.
B)is partially regulated by promoter/terminator sites.
C)proceeds by making two continuous strands.
D)is not edited once polymerization has occurred.
E)is conservative.

A)excision repair.
B)recombination.
C)transcription.
D)translation.
E)unwinding.

A)increasing the likelihood of depurination.
B)causing double-stranded breaks in the DNA sugar-phosphate backbone.
C)causing mispairing during DNA replication.
D)causing pyrimidine dimers.
E)increasing the likelihood of depurination or causing mispairing during DNA replication.

A)spontaneous hydrolysis reactions between DNA and water.
B)intercalating agents.
C)the addition of DNA adducts.
D)tautomeric shift.
E)spontaneous hydrolysis reactions between DNA and water or the addition of DNA adducts.

A)5' → 3' direction; the 3'-hydroxyl
B)5' → 3' direction; the 3'-phosphate
C)3' → 5' direction; the 5'-hydroxyl
D)3' → 5' direction; the 5'-phosphate
E)5' → 3' direction or 3' → 5' direction; both

A)the hydrolysis of the phosphate bonds of ATP by an accessory protein that is part of the DNA polymerase holoenzyme.
B)the hydrolysis of the phosphate bonds of ATP or GTP,depending on the form of DNA polymerase.
C)the hydrolysis of the phosphate bonds of the deoxynucleoside triphosphates that are being added to the new DNA chain.
D)the formation of the covalent bond between the phosphate of the nucleoside and the hydroxyl group.
E)the hydrolysis of the RNA primers used in DNA replication.

A)all of the DNA in the heavy (N¹⁵)band.
B)all of the DNA in the light (N¹⁴)band.
C)all of the DNA at a point midway between the heavy and light bands.
D)half of the DNA in the light band,the other half in the heavy band.
E)None of these are correct.

A)analog incorporation.
B)pyrimidine dimer formation.
C)intercalation of the bases.
D)direct transition of the bases.
E)deamination.

A)is synthesized in the 5' → 3' direction; the new DNA is synthesized in the 3' → 5' direction
B)is synthesized in the 3' → 5' direction; the new DNA is synthesized in the 5' → 3' direction
C)does not require an RNA primer; an RNA primer is required
D)is synthesized as a continuous chain; the new DNA is formed in a series of short,discontinuous fragments
E)is synthesized in a series of short,discontinuous fragments; the new DNA is synthesized as a continuous chain

A)DNA polymerase I
B)primase
C)helicase
D)single-strand binding proteins
E)telomerase

A)relies on DNA polymerases to correct all mutations.
B)relies on completely different mechanisms.
C)is accomplished by multiple specialized pathways.
D)can only repair abnormal nucleotides such as pyridine dimers and depurinated bases.
E)is very ineffective.

A)conservative.
B)dispersive.
C)semiconservative.
D)irregular.
E)None of these selections apply.

A)pyrimidine dimer formation.
B)depurination.
C)tautomeric shift.
D)double-stranded DNA breaks.
E)deletion mutations.

A)spontaneous deamination reactions convert cytosine to uracil at a fairly high rate.
B)uracil is more sensitive to ultraviolet (UV)damage.
C)uracil is more susceptible to depurination.
D)uracil can only bind with ribose,not deoxyribose.
E)thymine is less likely to undergo spontaneous deamination than uracil.

A)tautomeric shift.
B)double-stranded DNA breaks.
C)thymine dimer addition.
D)base analogue addition.
E)DNA intercalation.

A)thymine.
B)guanine.
C)adenine.
D)uracil.
E)None of these are correct.

A)are error prone.
B)may join nonhomologous ends of DNA together.
C)are part of the SOS repair system.
D)may use homologous DNA to repair the damage.
E)are error prone and may join nonhomologous ends of DNA together or use homologous DNA to repair the damage.

A)base excision repair pathway.
B)SOS repair pathway.
C)nonhomologous end-joining pathway.
D)nucleotide excision repair pathway.
E)synthesis-dependent strand annealing pathway.

A)the transposase gene flanked by inverted repeat sequences.
B)a mobile gene flanked by inverted repeat sequences.
C)the transposase gene only.
D)several genes,such as antibiotic resistance genes,flanked by transposase genes.
E)several genes,including transposase,flanked by inverted repeat sequences.

A)mismatched base pairs.
B)structurally damaged bases.
C)double-stranded DNA breaks.
D)thymine dimers.
E)DNA recombination.

A)mismatch repair
B)base excision repair
C)SOS repair
D)nucleotide excision repair
E)All DNA repair systems are equally prone to error.

A)correct base mismatches in newly synthesize DNA.
B)fix double-strand DNA breaks.
C)remove intercalating agents.
D)remove modified or depurinated bases.
E)remove intercalating agents and modified or depurinated bases.

A)increase the rate of mutation under stressful conditions.
B)aid in repairing DNA damage caused by stressful conditions.
C)halt DNA replication and cell division.
D)increase homologous recombination and genetic diversity.
E)explain why some plants can't withstand drought conditions.

A)correct base mismatches in newly synthesized DNA.
B)fix double-strand DNA breaks.
C)avoid deletion or insertion of bases.
D)remove modified or depurinated bases.
E)avoid deletion or insertion of bases and remove modified or depurinated bases.

A)base excision repair pathway.
B)SOS repair pathway.
C)nonhomologous end-joining pathway.
D)nucleotide excision repair pathway.
E)synthesis-dependent strand annealing pathway.

A)sister chromatids are always identical.
B)homologous recombination is prone to errors,potentially causing permanent genetic mutations.
C)strand invasion may introduce new genes onto the damaged chromosome.
D)homologous chromosomes may carry different alleles of the same gene.
E)the Holliday junction may migrate,resulting in loss of genetic material.

A)helicase.
B)scaffold proteins.
C)chromatin remodeling proteins.
D)replisomal proteins.
E)helicase and scaffold proteins.

A)5' to 3' exonuclease activity of DNA polymerase
B)3' to 5' exonuclease activity of DNA polymerase
C)5' to 3' endonuclease activity of DNA polymerase
D)3' to 5' endonuclease activity of DNA polymerase
E)RNA polymerase

A)replicons.
B)multireplication forks.
C)helicase loaders.
D)ARS elements.
E)None of these answers are correct.

A)required to resolve a Holliday junction.
B)involved in the movement of mobile genetic elements in prokaryotic and eukaryotic genomes.
C)found only in prokaryotic transposons.
D)required for synthesis-dependent strand annealing to repair double-stranded DNA breaks.
E)necessary for replicative transposition but not conservative transposition.

A)DNA polymerase I
B)DNA gyrase
C)single-strand binding proteins
D)DNA ligase
E)telomerase

A)alpha
B)beta
C)delta
D)epsilon
E)gamma