Deck 14: DNA Structure, Replication, and Organization

A)thymine ​
B)cytosine
C)each of cytosine and guanine
D)each of thymine and guanine
E)guanine

A)protein; amino acids ​
B)DNA; amino acids
C)protein; nucleotides
D)DNA; nucleotides
E)RNA; nucleotides

A)amino acids ​
B)lipids
C)nucleotides
D)sugars
E)peptides

A)hydrophobic interaction
B)phosphodiester bond
C)hydrogen bond
D)peptide bond
E)ionic bond ​

A)most of the radioactive protein was inside the bacteria ​
B)most of the radioactive DNA was inside the bacteria
C)both radioactive DNA and protein were inside the bacteria
D)neither radioactive DNA nor protein were inside the bacteria
E)entire viruses were inside the bacteria

A)Bacteria had incorporated radioactive proteins into their DNA. ​
B)Bacteria and viral progeny had incorporated ³²P into their DNA.
C)Viral progeny had used the ³²P to build new viral proteins.
D)Bacteria had incorporated radioactive proteins into their cell membranes.
E)​ ³² P was left outside the cell during viral infection.

A)a polysaccharide capsule
B)a phospholipid
C)protein
D)RNA
E)DNA

A)The S strain bacteria come back to life. ​
B)The R strain bacteria are killed, and the S strain bacteria remain dead.
C)The R strain bacteria are transformed into S strain bacteria.
D)The S strain bacteria are transformed into R strain bacteria.
E)The R strain bacteria are killed, and the S strain bacteria come back to life.

A)RNA; protein ​
B)protein; DNA
C)phospholipids; protein
D)protein; phospholipids ​
E)DNA; protein

A)none
B)about 1/4
C)about 1/2
D)about 3/4
E)all

A)a six-carbon sugar, a phosphate group, and one of twenty amino acids ​
B)a five-carbon sugar, a nitrogenous base, and one of twenty amino acids
C)a five-carbon sugar, a phosphate group, and one of four nitrogenous bases
D)a six-carbon sugar, a nitrogenous base, and one of four amino acids
E)a five-carbon sugar, a phosphate group, and one of four amino acids

A)protein, DNA, and RNA ​
B)protein and RNA only
C)DNA only
D)protein, lipids, and RNA
E)lipids and DNA only

A)protein
B)deoxyribonucleic acid
C)ribonucleic acid
D)glycoprotein
E)polypeptide

A)DNA only ​
B)RNA and protein
C)protein, phospholipid, and DNA
D)DNA and protein
E)protein, phospholipid, DNA, and RNA

A)86; 14 ​
B)14; 36
C)36; 36
D)14; 86
E)36; 14

A)Okazaki fragments ​
B)pentose-phosphate backbones
C)nucleic acids
D)phosphate bases
E)nitrogenous bases

A)presence of nuclein (DNA)in white blood cells ​
B)role of DNA in cells
C)chemical components of DNA
D)three-dimensional structure of DNA
E)location of DNA in cells

A)replication
B)transformation
C)crossing-over
D)excision repair
E)ligation

A)it contains 47% A and T bases
B)there are more pyrimidines than purines
C)there are more purines than pyrimidines
D)it contains 53% A and T bases
E)there are no genes in this stretch of DNA

A)thymine and cytosine ​
B)adenine and cytosine
C)adenine and guanine
D)thymine and adenine
E)guanine and thymine

A)proofreads the newly synthesized DNA ​
B)relieves over-twisting ahead of the DNA replication fork
C)rewinds the newly synthesized DNA strands into a double-stranded helix
D)unwinds the double-stranded DNA helix
E)binds DNA polymerase to the template strand

A)Two hydrogen bonds bind A and T; three hydrogen bonds bind G and C. ​
B)Two hydrogen bonds bind A and C; three hydrogen bonds bind T and G.
C)Two hydrogen bonds bind G and C; three hydrogen bonds bind A and T.
D)Two hydrogen bonds bind A and T, and two hydrogen bonds bind G and C.
E)Three hydrogen bonds bind A and C, and three hydrogen bonds bind T and G.

A)hydrogen bonds ​
B)ionic bonds
C)hydrophobic interactions
D)phosphodiester bonds
E)covalent bonds

A)the number of nucleotides within genes remains constant
B)half of the DNA in a cell comes from one parent and the other half from the other parent.
C)the same process of DNA replication is used by all organisms
D)the total amount of DNA within an individual remains the same
E)each new DNA molecule is composed of one old strand and one new strand

A)5'-TCATGG-3' ​
B)3'-TCATGG-5'
C)3'-CTGCAA-5'
D)3'-AGTACC-5'
E)5'-TTGCAG-3'

A)archaea and bacteria only ​
B)archaea, bacteria, and eukaryotes
C)archaea and eukaryotes only
D)none of these groups
E)bacteria and eukaryotes only

A)creating cuts in the DNA to relieve over-twisting and strain ahead of the replication fork ​
B)binding DNA polymerase to hold it tightly to the template DNA
C)unwinding the DNA double helix to expose the template strands for replication
D)binding the newly synthesized DNA to re-twist it into a double helix after replication
E)reading the DNA template and synthesizing a complementary strand of DNA

A)nitrogenous bases; hydrogen ​
B)RNA fragments; noncovalent ​
C)DNA and RNA fragments; covalent
D)DNA fragments; peptide
E)DNA fragments; covalent  ​

A)is constant
B)is narrower where adenine is present than where cytosine is present
C)is wider where purines are present than where pyrimidines are present
D)varies randomly
E)is wider where pyrimidines are present than where purines are present

A)Purines are derived from a pair of fused C-N rings, while pyrimidines are derived from a single C-N ring.
B)Pyrimidines are derived from a pair of fused C-N rings, while purines are derived from a single C-N ring. ​
C)Purines have a carbon-containing ring, while pyrimidines have a nitrogenous ring.
D)Pyrimidines have a carbon-containing ring, while purines have a nitrogenous ring.
E)Purines are found only in DNA, while pyrimidines are found only in RNA.

A)topoisomerase; 3 ¢ hydroxyl group ​
B)primase; 3 ¢ hydroxyl group
C)primase; 5 ¢ hydroxyl group
D)DNA polymerase; 5 ¢ phosphate group
E)DNA polymerase; 3 ¢ hydroxyl group ​

A)deoxyribose sugar, ribose sugar ​
B)adenine, thymine
C)cytosine, guanine
D)hydroxyl group, phosphate group
E)phosphate group, hydroxyl group

A)either entirely old DNA strands or entirely new DNA strands
B)one old DNA strand and one new DNA strand
C)entirely new DNA
D)some DNA helix regions from old DNA alternating with some DNA regions from new DNA
E)two strands that are each a mix of old and new DNA

A)the 5' end of one strand is directly paired with the 5' end of the other strand ​
B)since the double helix twists, it is not perfectly parallel
C)one strand has a negative charge and the other strand has a positive charge
D)the 5' end of one strand is directly paired with the 3' end of the other strand
E)both strands have a negative charge

A)The lagging strands contain more short DNA segments than the leading strand, which are joined together by DNA ligase.
B)The lagging strand is synthesized more slowly, and DNA ligase speeds up the DNA polymerase.
C)The lagging strand synthesizes DNA in the 3' 5' direction.
D)The lagging strand requires DNA ligase to couple the RNA primer to the Okazaki fragments.
E)DNA ligase performs the function of RNA primase on the lagging strand.

A)synthesizes a short RNA segment to begin DNA replication ​
B)adds nucleotides to the 5' end of an existing strand to synthesize a new DNA strand
C)adds nucleotides to the 3' end of an existing strand to synthesize a new DNA strand
D)seals nicks between adjacent segments of DNA
E)unwinds the DNA double helix at the origin of replication

A)molecular scale models of nucleotides ​
B)X-ray diffraction
C)computer-assisted graphics
D)electron microscopy
E)light microscopy

A)thymine and cytosine ​
B)adenine and cytosine
C)adenine and guanine
D)thymine and adenine
E)guanine and thymine

A)DNA replication is semiconservative
B)DNA replication is conservative
C)DNA replication is dispersive
D)DNA replication is either semiconservative or dispersive
E)DNA replication is either semiconservative or conservative

A)the 5' 3' direction for the leading strand and the 3' 5' direction on the lagging strand
B)either the 5' 3' direction or the 3' 5' direction on both strands, depending on where replication begins
C)the 5' 3' direction only
D)the 3' 5' direction for the leading strand and the 5' 3' direction on the lagging strand
E)the 3' 5' direction only

A)circular; one ​
B)circular; more than one
C)linear; more than one
D)linear; one
E)linear; no

A)they are sterile
B)their cells have no proofreading abilities during DNA replication
C)Okazaki fragments produced during DNA replication cannot be joined
D)they easily develop skin cancer when exposed to sunlight
E)their telomeres are shorter than average

A)10 to 100
B)100,000 to 1,000,000
C)1,000 to 10,000
D)10,000,000 to 100,000,000
E)100,000,000 to 1,000,000,000

A)unwinding of the DNA double helix
B)hydrolysis of pyrophosphate
C)breaking hydrogen bonds between base pairs
D)DNA helicase
E)forming hydrogen bonds between base pairs

A)short lengths of new DNA on the leading strand
B)RNA primers on the lagging strand
C)RNA primers on both the lagging and leading strand
D)short lengths of new DNA on the lagging strand
E)RNA primers on the leading strand

A)prokaryotic DNA associated with nonhistone proteins
B)eukaryotic DNA associated with histone proteins
C)prokaryotic DNA associated with histone proteins
D)eukaryotic DNA associated with nonhistone proteins
E)associated histone and nonhistone proteins

A)DNA polymerase ​
B)primase
C)telomerase
D)DNA ligase
E)helicase

A)The clone will be unable to grow. ​
B)When the clone matures, it will most likely have cancer.
C)The clone's cells may divide, but after a certain number of generations, cell division will stop.
D)The lack of telomerase should have no effect on the clone.
E)When the clone matures, it will most likely be sterile.

A)The leading strand would be synthesized, but not the lagging strand. ​
B)No part of the DNA replication process could occur.
C)The DNA helix would be unwound by helicase, but no new strands will be produced.
D)Both the leading and lagging strand would be synthesized, but pieces of discontinuous strands would not be joined together.
E)DNA replication would still proceed completely since RNA strands are not part of the final product of DNA replication.

A)parental histones are degraded and entirely replaced by new histones ​
B)DNA is permanently freed from histone binding
C)the histone proteins are also replicated
D)only some of the histone proteins are replicated
E)the number of histones that bind to each DNA molecule is halved

A)DNA ligase cannot join pieces at the end of a chromosome ​
B)RNA primers at the beginning of a new strand cannot be replaced with DNA
C)those ends are Okazaki fragments that are lost
D)cells do not need the DNA at the ends of chromosomes
E)the ends of chromosomes are made of protein, not DNA

A)in the middle of chromosomes ​
B)at replication origins
C)where DNA strands are joined together
D)within genes
E)at the ends of chromosomes

A)leading; opposite; continuous ​
B)lagging; same; discontinuous ​
C)leading; same; discontinuous
D)lagging; opposite; continuous
E)leading; same; continuous

A)two chromosomes linked together ​
B)RNA wrapped around an 8-protein histone complex
C)DNA wrapped around an 8-protein histone complex
D)DNA associated with the nuclear envelope
E)DNA replication enzymes associating to form the replisome

A)disassemble; reassemble
B)reassemble; disassemble
C)unwind DNA; disassociate
D)synthesize primers; proofread
E)cut DNA; ligate DNA

A)circular, one ​
B)circular, more than one
C)linear, more than one
D)linear, one
E)linear, no

A)DNA only ​
B)DNA, RNA, and protein
C)DNA and RNA
D)RNA and protein
E)DNA and protein

A)adds telomere repeats in some human cells ​
B)removes telomere repeats in all human cells
C)adds telomere repeats in all human cells ​
D)removes telomere repeats in some human cells
E)transcribes telomere repeats in some human cells

A)primase, DNA polymerase, and DNA ligase ​
B)DNA polymerase
C)DNA polymerase and DNA ligase
D)primase and DNA ligase
E)primase and DNA polymerase

A)none ​
B)one
C)two
D)three
E)four

A)mutations ​
B)nucleosomes
C)Okazaki fragments
D)DNA repairs
E)RNA primers

A)DNA replication occurred more frequently in individuals who exercised. ​
B)Cell division occurred more rapidly in individuals who exercised.
C)Telomerase activity was higher in individuals who exercised.
D)Telomerase activity was lower in individuals who exercised.
E)Fewer DNA replication errors occurred in individuals who exercised.

A)largely variable; the function of the sliding clamp is different in these organisms ​
B)largely variable; the function of the sliding clamp is similar in bacteria and archaea but different in eukaryotes
C)highly conserved; the sliding clamp is involved in different processes depending on the organism
D)highly conserved; the function of the sliding clamp is similar in these organisms
E)largely variable; the sliding clamp is not essential for DNA replication

A)maintain telomerase function ​
B)have longer telomeres than normal cells
C)eventually die due to shortening chromosomes
D)have circular chromosomes
E)cannot replicate their DNA

A)promote DNA replication only
B)inhibit DNA repair enzymes only
C)inhibit DNA replication only
D)promote DNA replication or inhibit DNA repair enzymes
E)inhibit DNA replication or DNA repair enzymes

A)unwind DNA ahead of the replication fork
B)anchor DNA polymerase to the template strand
C)remove DNA polymerase from the template strand
D)anchor primase to the template strand
E)bind to single stranded DNA to stabilize it before it is replicated