Deck 12: Dna: the Carrier of Genetic Information

A) was the result of genetic mutation.
B) was an example of the genetic exchange known as transformation.
C) supported the case for proteins as the genetic material.
D) could not be reproduced by other researchers.
E) was an example of conjugation.

A) the same; uncomplementary
B) opposite; uncomplementary
C) parallel; uncomplementary
D) parallel; complementary
E) antiparallel; complementary

A) phosphodiester bonds of the DNA strand.
B) number of separate strands of DNA.
C) size of a particular chromosome.
D) specific nucleotide sequence of the DNA molecule.
E) number of bases in a DNA strand.

A) 5'- AGATCCG- 3'
B) 3' -AGATCCG- 5'
C) 5' -CTCGAAT- 3'
D) 3' - CTCGAAT- 5'
E) 3' - TCTAGGC- 5'

A) adenine and thymine.
B) cytosine and guanine.
C) sugar and phosphate.
D) base and sugar.
E) base and phosphate.

A) Crick and Wilkins
B) Watson and Crick
C) Franklin and Crick
D) Franklin
E) Watson, Crick, and Wilkins

A) the sequence of amino acids in protein molecules.
B) the sequence of nucleic acids in nucleic acid molecules.
C) the distances between atoms of molecules.
D) the type of chemical under investigation.
E) the wavelength of light emitted by chemicals.

A) Watson and Crick
B) Crick and Wilkins
C) Franklin
D) Franklin and Crick
E) Watson and Wilkins

A) DNA is capable of forming many different sequences.
B) DNA contains thymine instead of uracil.
C) DNA is double-stranded rather than single-stranded.
D) DNA is only found in eukaryotic cells.
E) DNA contains the sugar deoxyribose.

A) uracil
B) thymine
C) adenine
D) cytosine
E) guanine

A) a sugar.
B) a protein.
C) a pyrimidine.
D) a purine.
E) a nucleotide.

A) 1
B) 3
C) 4
D) 1 and 3
E) 3 and 4

A) Meselson and Stahl.
B) Watson and Crick.
C) Franklin and Wilkins.
D) Avery, MacLeod, and McCarty.
E) Hershey and Chase.

A) Nucleotides pair with those of the original strand to form a new strand.
B) Hydrogen bonds holding the two strands together are easy to break, allowing one strand to be a template.
C) A single strand of DNA is not able to serve as a template.
D) One strand of DNA directs the synthesis of a new strand on its partner.
E) Both the pairing of nucleotides and the breaking of hydrogen bonds.

A) It contains a large number of different nucleotides.
B) Its nucleotides can be arranged in a large number of possible sequences.
C) It is capable of assuming a wide variety of shapes.
D) The sugar and phosphates can be arranged in many different sequences.
E) The nucleotides can be altered to form many different letters in the sequence.

A) had the bases in the center of the molecule.
B) had the sugars and phosphates on the outside of the molecule.
C) was a very long molecule.
D) was made of 2 strands.
E) was a helix.

A) a hydrogen bond.
B) a phosphate.
C) a nucleotide.
D) a pyrimidine.
E) a protein.

A) DNA was injected into bacteria.
B) DNA and protein were injected into bacteria.
C) DNA remained on the outer coat of bacteria.
D) proteins were injected into bacteria.
E) proteins were responsible for the production of new viruses within the bacteria.

A) their presence within the nucleus.
B) their abundance within the cell.
C) the large number of possible amino acid combinations.
D) their ability to self replicate within the cytoplasm.
E) their ability to be exported from the cell.

A) the same RNA primer that began synthesis on the leading strand.
B) a DNA primer binding to the template DNA.
C) DNA polymerase binding to the template DNA.
D) a separate RNA primer.
E) a small DNA primer.

A) DNA helicase enzyme.
B) single-strand binding proteins.
C) DNA polymerases.
D) ATP.
E) GTP.

A) mRNA, tRNA, and rRNA molecules.
B) a wide variety of proteins.
C) DNA fragments.
D) two DNA molecules, each of which contains one new and one old DNA strand.
E) the enzymes needed for further processes, such as DNA polymerase.

A) is synthesized as a series of Okazaki fragments.
B) is synthesized as a complementary copy of the leading strand.
C) pairs with the leading strand by complementary base pairing.
D) is made up entirely of RNA primers.
E) is not synthesized until the synthesis of the leading strand is completed.

A) The linear DNA molecule is replicated from multiple origins of replication bidirectionally.
B) The linear DNA molecule is replicated from one origin of replication bidirectionally.
C) The circular DNA molecule is replicated from multiple origins of replication bidirectionally.
D) The circular DNA molecule is replicated from one origin of replication bidirectionally.
E) The circular DNA molecule is replicated from one origin of replication unidirectionally.

A) DNA polymerase
B) DNA helicase
C) RNA primer
D) primase
E) RNA polymerase

A) Because DNA polymerases can only add nucleotides to the 3' end of a polynucleotide strand.
B) Because the 3' end of the polynucleotide molecule is more electronegative than the 5'end.
C) Because that is the direction in which the two strands of DNA unzip.
D) Because that is the only direction that the polymerase can be oriented.
E) Because the chromosomes are always aligned in the 5'to 3' direction in the nucleus.

A) RNA polymerase.
B) DNA ligase.
C) DNA polymerase.
D) RNA ligase.
E) primase.

A) unwinding the DNA double strand to allow DNA polymerase access to the template DNA.
B) introducing nicks into the DNA double strand in order to prevent the formation of knots.
C) hydrolyzing ATP to facilitate DNA unwinding.
D) making short strands of RNA at the site of replication initiation.
E) forming a replication fork in the DNA double helix.

A) The linear DNA molecules are replicated from multiple origins of replication bidirectionally.
B) The linear DNA molecules are replicated from one origin of replication bidirectionally.
C) The circular DNA molecules are replicated from multiple origins of replication bidirectionally.
D) The circular DNA molecules are replicated from one origin of replication bidirectionally.
E) The linear DNA molecules are replicated from one origin of replication unidirectionally.

A) protosomes
B) topoisomerases
C) scaffolding proteins
D) chromatin
E) histones

A) topoisomerases
B) single-strand binding proteins
C) DNA polymerases
D) RNA polymerases
E) DNA ligases

A) DNA polymerase
B) DNA helicase
C) RNA primer
D) primosome
E) RNA polymerase

A) Chargaff and Hershey
B) Watson and Crick
C) Avery and Griffith
D) Meselson and Stahl
E) Watson, Crick, and Wilkins

A) primary strand.
B) first strand.
C) leading strand.
D) alpha strand.
E) lagging strand.

A) The translation of a DNA molecule into a complementary strand of RNA.
B) A DNA molecule consists of one parental strand and one new strand.
C) The number of DNA molecules is doubled with every other replication.
D) The replication of DNA never takes place with 100% accuracy.
E) The replication of DNA takes place at a defined period in the cell cycle.

A) the mutation is corrected by the DNA polymerase enzyme.
B) the mutation is ignored by the DNA polymerase enzyme.
C) the mutation is copied into one of the two daughter molecules.
D) the mutation is copied into both of the daughter molecules.
E) the replication is stopped.

A) density gradient centrifugation.
B) gel electrophoresis.
C) an electron microscope.
D) differential radioisotope labeling.
E) None of these.

A) is only seen in prokaryotic chromosomes.
B) is only seen in bacterial cells.
C) is a Y-shaped structure where both DNA strands are replicated simultaneously.
D) is a site where one DNA strand serves as a template, but the other strand is not replicated.
E) is created by the action of the enzyme RNA polymerase.

A) dispersive.
B) gradient.
C) semiconservative.
D) parental.
E) conservative.

A) the leading strand.
B) 3'.
C) Okazaki fragments.
D) polymerase.
E) a strand serving as a template.

A) It is a type of mismatch repair.
B) It involves a nuclease.
C) It involves a DNA polymerase.
D) It involves DNA ligase.
E) It is implicated in xeroderma pigmentosum.

A) leading fragments
B) Okazaki fragments.
C) replication forks.
D) nucleosomes.
E) DNA polymerases.

A) apoptosis.
B) reverse transcriptase.
C) primase.
D) telomerase.
E) DNA polymerase.

A) linking short DNA segments.
B) synthesizing the leading strand.
C) forming the replication fork.
D) initiating DNA synthesis.
E) unwinding the DNA double helix.

A) the cells underwent more cell divisions than normal.
B) the cells underwent fewer cell divisions than normal.
C) the cells died almost immediately.
D) the cells underwent gene expression more vigorously.
E) the cell cycle shortened.

A) linking short DNA segments.
B) synthesizing the leading strand.
C) forming the replication fork.
D) forming nucleosomes.
E) unwinding the DNA double helix.

A) have reduced levels of telomerase.
B) divide only 20 to 30 times.
C) have lost the ability to resist apoptosis.
D) can maintain telomere length as they divide.
E) lack telomeres.

A) Centromeres
B) Telomeres
C) Kinetochores
D) Primosomes
E) Nucleosomes