Deck 20: Dna Replication, repair, and Recombination

A) father and son
B) parent and children
C) parent and daughter
D) mother and daughter

A) DNA polymerase
B) DNA primase
C) DNA polymerization
D) DNA Pol III

A) They are not synthesized simultaneously.
B) One strand is synthesized , whereas the other is .
C) They are synthesized through Okazaki fragments.
D) They are synthesized using RNA polymerases.

A) Pol I
B) Pol II
C) Pol III
D) Pol IV

A) a RNA primer.
B) the magnesium ion.
C) uracils, always.
D) amino acids, always.

A) Gyrase adds the RNA primer and helicase removes it.
B) Helicase unwinds DNA and gyrase relieves the torsional strain.
C) Helicase synthesizes DNA and gyrase prevents helicase from dissociating.
D) Gyrase synthesizes RNA primers and helicase.

A) proofreading
B) exonuclease activity
C) convert RNA to DNA
D) convert DNA to RNA

A)
B)
C)
D)

A) entire; a required element of
B) partial; a required element of
C) entire; not required for
D) partial; not required for

A) a single intermediate density.
B) a lower density.
C) only the higher density.
D) one high density and one low density strand.

A) remains intact to make a new DNA duplex.
B) is broken into fragments.
C) is separated into single strands before replications.
D) can only be replicated once.

A) there are no hydrogen bonds that line up between the mismatches.
B) the active site does not fit mismatches well.
C) the mismatched pairs make covalent bonds instead of hydrogen bonds.
D) the DNA primer does not allow for mismatched pairs.

A) for DNA replication to start on a single strand.
B) for DNA replication to start on the double strand.
C) DNA to break into half to start replication.
D) DNA to unwind completely to start replication.

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

A) Pol I, Pol III, and Pol $\delta$
B) Pol I, Pol II, and Pol III
C) Pol I, Pol II, and Pol $\delta$
D) Pol I, Pol III, and Pol $\varepsilon$

A) very slow polymerization rate (1-2 nucleotides) to prevent mistakes
B) DNA translation
C) unlimited processivity
D) checking for exonuclease activity

A) primase.
B) polymerase.
C) replisome.
D) DNA gyrase.

A) Pol I
B) Pol II
C) Pol III
D) Pol

A) stabilize the positive charges on
B) act as a nucleophile to attack the
-phosphoryl group in
C) stabilize the negative charges on
D) protonate

A) new DNA strand.
B) old DNA strand.
C) RNA primer.
D) primase.

A) eliminating the need for unwinding the DNA.
B) providing more replication origins.
C) using multiple primases.
D) only replicating part of the DNA in one cycle.

A) DNA makes too many copies in the cell.
B) DNA synthesis does not occur.
C) DNA damage is not corrected.
D) Death of a cell occurs.

A) remove the telomeres
B) reverse transcription of the telomeres
C) bind to single-strand DNA to prevent refolding
D) shorten the DNA strand after each replication

A) G₁ phase
B) S phase
C) G₂ phase
D) after zygote formation

A) causes an abasic site to form.
B) produces photoproducts.
C) causes protein misfolding.
D) produces methylated thymidine.

A) DnaC would not be able to bind to DnaB.
B) DnaB would not bind to primase.
C) The genome would not be unwound.
D) Pol III would not be able to bind to the DNA.

A) three 13-bp repeats and four 9-bp repeats with enriched G-C base pairs.
B) three 13-bp repeats and four 9-bp repeats with enriched A-T pairs.
C) 20 subunits of A-T pairs.
D) the RNA primer.

A) synthesize primers for leading strand synthesis.
B) synthesize primers for lagging strand synthesis.
C) bind to single-stranded DNA to prevent reannealing.
D) synthesize new DNA on leading and lagging strand.

A) DNA synthesis would restart on the same strand.
B) DNA synthesis would be enhanced.
C) The chromosome would be shortened every subsequent replication.
D) The chromosome would be elongated every subsequent replication.

A) deamination of cytosine
B) deamination of uracil
C) methylation of adenine
D) methylation of tyrosine

A) Cells would die sooner.
B) Cells would have increased synthesis.
C) The rate of synthesis would increase.
D) Cells would live indefinitely.

A) nonbasic
B) abasic
C) dibasic
D) deaminated

A) breaking the single-strand DNA and preventing further synthesis.
B) forcing the primase to dissociate.
C) blocking the opening of helicase.
D) methylating the DNA strand.

A) keep the torsional strain reduced.
B) add the RNA primer.
C) keep the Pol III complex associated with the DNA.
D) separate the DNA into a single strand.

A) oriC
B) DnaA
C) primase
D) SeqA

A) increased DNA replication
B) an alteration of the protein's coding sequence
C) prevention of further synthesis
D) cell death

A) remove the histones.
B) block further production of pre-RCs while converting pre-RC to RPC.
C) block further production of methylated DNA.
D) terminate synthesis.

A) keto group
B) amine
C) amide group
D) ester group

A) base substitution
B) abasic site
C) somatic
D) nucleotide deletions

A) phosphorylated.
B) methylated.
C) protonated.
D) ionized.

A) phosphorylated adenine
B) methylated guanine
C) pyrimidine dimers
D) mismatched bases

A) find the double-strand break
B) assist with strand invasion
C) repair pyrimidine dimers
D) synthesize new DNA bases

A) methylated riboflavin
B) reactive oxygen species
C) spontaneous deglycosylation
D) production of an abasic site

A) mismatch repair
B) abasic repair
C) base excision
D) nucleotide excision

A) base mismatch
B) abasic sites
C) pyrimidine dimers
D) phosphorylated base

A) removal and replacement of individual bases that have been damaged by various chemical reactions
B) repair of large lesions that distort DNA
C) removal of individual bases that have been phosphorylated
D) repair of small lesions that distort DNA

A) radical
B) excited
C) cation
D) anion

A) requires the presence of an intact sister chromatid as a template.
B) does not require the presence of a homologous template.
C) requires the cell to be in cell division.
D) requires the cell to be in the resting phase.

A) global genomic and mismatch
B) global genomic and base excision
C) transcription-coupled and partial genomic
D) transcription-coupled and global genomic

A) base excision
B) mismatch repair
C) DNA adenylation
D) DNA methylation

A) single-strand break
B) double-strand break
C) mismatched pairs
D) pyrimidine dimers

A) DNA photolyase system
B) nucleotide excision repair
C) base excision repair
D) DNA mismatch repair

A) N-7; nucleophilic; electrophilic
B) N-5; nucleophilic; electrophilic
C) N-7; electrophilic; nucleophilic
D) N-5; electrophilic; nucleophilic

A) recognizes the break
B) removes the methyl group from guanine
C) replaces the mismatched pair
D) absorbs light to become excited

A) degrading of the entire DNA strand to start over
B) base excision
C) mismatch repair
D) abasic repair

A) breast cancer.
B) lymphoma.
C) arthritis.
D) bone tumors.

A) Nothing, because ROS do not react with DNA.
B) G-C to T-A replacement
C) O-alkylation of thymine
D) single point excision

A) mismatched
B) methylated
C) those damaged by ROS
D) uracil

A) mismatch repair
B) direct repair pathway
C) base excision
D) nucleotide excision

A) quadruplex DNA.
B) duplex DNA.
C) DNA damage.
D) DNA pyrimidine duplexes.

A) integration of virus DNA into host DNA
B) production of new bacteriophage particles
C) cell death
D) formation of Holliday junctions

A) the organization of genes on the chromosome to change.
B) DNA repair to occur.
C) exchange of genetic information.
D) base excision to occur.

A) viruses being formed.
B) DNA combinations.
C) antibodies.
D) RNA combinations.

A) DNA that can move from one region to another.
B) RNA that can move from one region to another.
C) DNA that is easily transcribed.
D) DNA that is in need of repair.

A) start replication.
B) help with alignment of the viral DNA to the host DNA.
C) start a base mismatch repair sequence.
D) help with cell meiosis.

A) prevents new DNA from being replicated.
B) prevents HIV from binding to the cell.
C) allows DNA to repair itself after viral DNA is added.
D) allows DNA to be replicated at a slower rate.

A) DNA excision
B) single-strand
C) double-strand
D) mismatch

A) integration of virus DNA into host DNA
B) production of new bacteriophage particles
C) cell death
D) formation of Holliday junctions

A) G1
B) S
C) G2
D) meiosis

A) 10%
B) 25%
C) 50%
D) 100%

A) fusion of the cell membrane and viral envelope
B) release of viral DNA and synthesis of cDNA
C) protein synthesis and processing
D) budding of infectious virus

A) increased ability to form pyrimidine dimers.
B) decreased ability to repair single-strand DNA breaks.
C) decreased ability to repair double-strand DNA breaks.
D) increased ability to form methylated guanine.

A) DNA that goes through an RNA intermediate to be moved.
B) RNA that goes through a DNA intermediate to be moved.
C) DNA that needs to be excised.
D) DNA that is folded incorrectly.