All GRE Subject Test: Biology Resources
Example Questions
Example Question #3 : Dna, Rna, And Proteins
Several enzymes are required for DNA replication. What is the class of enzymes that is required for unwinding the DNA at the replication fork?
Telomerase
Topoisomerase
DNA helicase
DNA polymerase
DNA helicase
DNA helicases use ATP to break the hydrogen bonds that separate complementary strands of DNA. During DNA replication, DNA helicases move along the DNA backbone with the replication fork and are responsble for unwinding the DNA at the fork.
Example Question #183 : Gre Subject Test: Biology
Which of the following proteins is not necessary during DNA replication?
Single-strand binding proteins
Helicase
RNA polymerase
DNA polymerase
RNA polymerase
RNA polymerase is an enzyme that transcribes RNA from DNA; it is not essential for DNA replication. This enzyme is easy to confuse with primase, whose primary function is to synthesize the RNA primers necessary for replication. DNA polymerase add nucleotides during replication, synthesizing the daughter strand from the parental template. Helicase is responsible for separating double-stranded DNA. Single-strand binding proteins are needed to keep DNA from reannealing after it has been denatured by helicase.
Example Question #2 : Understanding Dna Replication
Which statement correctly describes the process of DNA replication?
New DNA is replicated from parental template strands and an enzyme cuts the new strands away from the old strands
The original molecule is separated and each daughter molecule will have one old DNA strand and a new DNA strand
The old DNA strands stay together and are replicated to form an entirely new DNA molecule
Parent DNA strands are cut into pieces and the segments are replicated and combined to form two new DNA molecules
The original molecule is separated and each daughter molecule will have one old DNA strand and a new DNA strand
DNA replicates in a semiconservative process. Parental strands are used as templates to synthesize daughter strands, which remain adhered to the parental template creating hybrid molecules of old and new DNA.
The original DNA molecules is "unzipped" by helicase to create the replication fork. DNA polymerase then begins to recruit nucleotides to bind to the exposed template, building the new DNA strand along the parental strand.
Example Question #1 : Understanding Dna Replication
Which of the following proteins is known for its ability to break hydrogen bonds?
Topoisomerase
DNA helicase
Primase
DNA ligase
DNA helicase
Before replication, the DNA helix must be unwound so that the strands can be replicated by DNA polymerase. This unwinding is accomplished by DNA helicase, which interferes with the hydrogen bonds between nucleotide pairs. This intervention creates a small separation between the two strands, known as the replication fork. DNA polymerase binds to the replication fork and recruits nucleotides to build the new DNA strand.
Topoisomerase is responsible for cleaving phosphodiester bonds in order to release torsional tension in the DNA backbone. DNA ligase synthesizes phosphodiester bonds, both on the daughter strand of DNA and in the regions cleaved by topoisomerase. Primase is responsible for synthesizing RNA primers that serve to help recruit and bind DNA polymerase in the replication fork.
Example Question #3 : Understanding Dna Replication
__________ is a protein that synthesizes RNA primers on __________ during DNA replication.
RNA polymerase . . . the lagging strand
Primase . . . the lagging strand
RNA polymerase . . . both the leading and lagging strands
Primase . . . both the leading and lagging strands
Primase . . . both the leading and lagging strands
In order for DNA polymerase to begin synthesizing base pairs, an RNA primer is needed to assist the binding of DNA polymerase to the DNA template strand. This primer is synthesized by the enzyme primase. Because DNA polymerase always needs an RNA primer before it can bind, primase must synthesize RNA primers on both the leading and lagging strands.
RNA polymerase transcribes molecules of RNA from DNA sequences during transcription, and is not involved in DNA replication.
Example Question #2 : Understanding Dna Replication
Which of the following is not true of DNA replication?
The lagging strand is synthesized in short fragments, directed away from the replication fork
The DNA must be denatured at the replication fork
Replication occurs during prophase of mitosis
Replication occurs in the 5' to 3' direction
Replication occurs during prophase of mitosis
DNA replication occurs during the S phase of the cell cycle, significantly before prophase of mitosis. During prophase chromosomes are condensed into easily segregated forms, but replication has already occurred. The S phase is the intermediate period of interphase in the cell cycle. The G2 phase follows the S phase, and is subsequently followed by the M phase (mitosis).
The short fragments synthesized on the lagging strand are known as Okazaki fragments. DNA replication does occur in the 5' to 3' direction; this is also the reason that the lagging strand must be synthesized away from the replication fork. DNA is denatured (separated) at the replication fork by an enzyme known as helicase, which breaks the hydrogen bonds between base pairs to allow DNA polymerase and other replication proteins to bind to single-strand DNA.
Example Question #3 : Understanding Dna Replication
Which prokaryotic polymerase is primarily responsible for filling in DNA nucleotides into the gap created by the removal of RNA primers?
DNA polymerase III
RNA polymerase
DNA polymerase I
DNA polymerase II
Reverse transcriptase
DNA polymerase I
DNA polymerase I replaces the RNA primer gap with DNA nucleotides. This polymerase is unique in that it has 5' 3' exonuclease activity. This RNA primer is created by primase, it is removed and replaced with DNA by DNA polymerase I, and the remaining nick is sealed by DNA ligase. Bacterial DNA polymerase III, in contrast, is the main polymerase for bacterial elongation. The function of DNA polymerase II is not completely understood. The remaining answer choices are not involved in prokaryotic DNA replication.
Example Question #1 : Dna Replication And Repair
Which of the following is not true of DNA repair?
DNA repair cannot occur during replication
Several DNA polymerases contain an exonuclease function
Irreparable DNA damage may activate pathways that lead to apoptosis
p53 is a protein responsible for activating many DNA repair pathways
DNA repair cannot occur during replication
DNA repair can, and does, occur during replication. An easy example of this is the proofreading function of several DNA polymerases. This function is carried out due to the enzymes containing an exonuclease function that allows them to excise incorrect base pairs. p53 is an incredibly important protein that is expressed heavily when DNA damage is detected. It is responsible for activating both DNA repair pathways and apoptotic pathways, preventing the cell from passing replication and cell cycle checkpoints. If the DNA damage is irreparable, the cell may undergo apoptosis.
Example Question #1 : Understanding Dna Repair
Upon double-stranded DNA break, the cell can search the genome for a homologous sequence to serve as a template for repairing the damaged sequence. What is this process known as?
Non-homologous end joining
Homology directed repair
Directed reversal
Base excision repair
Crossing over
Homology directed repair
The correct answer is homology directed repair. Using flanking homologous regions upstream and downstream of the double stranded break, the cell is able to determine the precise sequence that is in the damaged region and repair that sequence.
Example Question #2 : Understanding Dna Repair
Which of the following enzymes is responsible for catalyzing the formation of phosphodiester bonds in single- and double-stranded DNA breaks?
DNA polymerase I
Endonuclease
DNA polymerase III
DNA ligase
Exonuclease
DNA ligase
DNA ligase catalyzes the formation of phosphodiester bonds between the elements of the DNA backbone. DNA polymerases function in replication of DNA, whereas exonucleases and endonucleases break apart DNA strands by disrupting phosphodiester bonds.
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