Deck 10: From Dna to Protein: Gene Expression

A) promoter.
B) poly C center.
C) poly A tail.
D) 5' cap.
E) minor groove.

A) the same gene governs all the steps in a particular biological pathway.
B) different genes can govern different individual steps in the same biological pathway.
C) different genes govern the same step in a particular biological pathway.
D) all biological pathways are governed by different genes.
E) genes do not govern steps in biological pathways,but proteins do.

A) Doing nothing.
B) Engineering a gene that codes for the enzyme that converts tyrosine to phenylalanine
C) Engineering a gene that codes for the enzyme that converts homogentistic acid to phenylalanine
D) Reducing the level of protein synthesis from a gene that codes for the enzyme that converts phenylalanine to tyrosine
E) Engineering a gene that codes for the enzyme that converts phenylalanine to tyrosine

A) Proteins made up of two or more chains
B) Splicing
C) Introns
D) Nonsense mutations
E) Garrod's inborn errors of metabolism

A) one
B) three
C) four
D) five
E) six

A) changes the shape of the bacterial cell walls.
B) blocks glycolysis.
C) inhibits protein synthesis.
D) degrades DNA.
E) blocks the input of nutrients.

A) A DNA template
B) RNA polymerase
C) A primer
D) Appropriate ribonucleoside triphosphates
E) All of the above are required.

A) Proteins encode information that is used to produce other proteins of the same amino acid sequence.
B) RNA encodes information that is translated into DNA,and DNA encodes information that is translated into proteins.
C) Proteins encode information that is translated into RNA,and RNA encodes information that is transcribed into DNA.
D) DNA encodes information that is translated into RNA,and RNA encodes information that is translated into proteins.
E) DNA encodes information that is translated into proteins and RNA.

A) Strain 5 cannot grow on substance A.
B) Strain 5 cannot grow on substance D.
C) Strain 5 has a defect in the enzyme that converts substance B to substance C.
D) Strain 5 has a defect in the enzyme that converts substance B to substance D.
E) Strain 5 has a defect in the enzyme that converts substance C to substance B.

A) polysaccharide.
B) lipid.
C) protein.
D) nucleic acid.
E) carbohydrate/lipid mixture.

A) The mutant phenotype arises from a change in the protein's amino acid sequence.
B) More than half the typical amount of homogentisic acid oxidase is needed to break down the toxin by-product.
C) Having half the typical amount of homogentisic acid oxidase is sufficient to break down the toxin by-product.
D) Homogentisic acid oxidase occurs early in the metabolic pathway.
E) Homogentisic acid oxidase occurs late in the metabolic pathway.

A) aminoacyl tRNA synthetases.
B) transfer RNAs.
C) ribosomal RNAs.
D) messenger RNAs.
E) ribosomes.

A) A,B,C,D
B) A,C,B,D
C) B,A,C,D
D) C,B,A,D
E) C,A,B,D

A) DNA
B) Polysaccharides
C) tRNA
D) Proteins
E) Lipids

A) DNA
B) mRNA
C) tRNA
D) Proteins
E) Lipids

A) a DNA molecule is synthesized from an RNA template.
B) ribonucleoside triphosphates are assembled into an RNA molecule without a template.
C) an RNA molecule is synthesized from a DNA template.
D) a protein is synthesized with information from a messenger RNA.
E) a single-stranded DNA molecule is replicated.

A) coding;the same
B) coding;complementary
C) coding;reverse
D) template;the same
E) template;complementary

A) Individuals with the disease have low levels of homogentistic acid.
B) Individuals with the disease often have dark or black urine.
C) The disease is due to a recessive allele at a single gene.
D) The disease is an example of Garrod's inborn errors of metabolism.
E) The disease arises from an improperly functioning enzyme.

A) Not all genes code for enzymes.
B) One gene codes for one enzyme.
C) All mutations of the same gene have the same phenotypic effect.
D) Not all genes code for polypeptides.
E) Proteins can code for DNA.

A) terminator sequence.
B) stop codon.
C) termiproteator.
D) hairline slip.
E) series of As.

A) a protein;a ribosome
B) a protein;the promoter
C) DNA;a ribosome
D) DNA;the promoter
E) RNA;DNA

A) 1;0
B) 1;2
C) 2;1
D) 2;2
E) 3;1

A) proteins.
B) carbohydrates.
C) lipids.
D) nucleic acids.
E) amino acids.

A) directing the polymerases to the appropriate place on the DNA for transcription to begin.
B) the splicing of introns out of the DNA.
C) allowing transcription to stop at the appropriate spot.
D) catalyzing the synthesis of a protein.
E) providing information to orient RNA polymerase.

A) retroviruses.
B) introns.
C) exons.
D) transcripts.
E) puffs.

A) 3'-GUC…CCA-5'
B) 5'-GUC…CCA-5'
C) 3'-CAG…GGU-5'
D) 5'-CAG…GGU-3'
E) 5'-CAG…GGT-3'

A) 5'-AUGCCU…CCA-3'
B) 5''-ATGCCT…CCA-3'
C) 3'-AUGCCU…CCA-5'
D) 3'-UACGGA…GGU-5'
E) 3'-TACGGA…GGT-5'

A) CE
B) ABD
C) BAD
D) ABDCE
E) ABCDE

A) 5'-to-3';5'-to-3'
B) 5'-to-3';3'-to-5'
C) 3'-to-5';5'-to-3'
D) 3'-to-5';3'-to-5'
E) 5'-to-5';3'-to-3'

A) spliced out of the original transcript.
B) spliced together from the original transcript.
C) spliced to introns to form the final transcript.
D) usually much larger than introns.
E) larger than the original coding region.

A) 5'-GUCUAUGCAUUA-3'
B) 5'-GTCTATGCATTA-3'
C) 5'-CAGATACGTAAT-3'
D) 5'-CAGAUACGUAAU-3'
E) 3F'-GUCUAUGCAUUA-5'

A) more;the number of copies made
B) less;the proofreading system
C) more;excision repair
D) less;the number of copies made
E) more;the proofreading system

A) within the promoter.
B) on RNA polymerase.
C) at splice sites.
D) in a ribosome.
E) at the consensus sequences.

A) The increased efficiency of proofreading repair in transcription and the large numbers of RNA sequences produced
B) The increased efficiency of proofreading repair in transcription and the reduced lifespan of RNA sequences
C) The reduced lifespan of RNA sequences and the large numbers of RNA sequences produced
D) The large numbers of RNA sequences produced and the fidelity function
E) The fidelity function and the increased efficiency of proofreading repair in transcription

A) single-stranded DNA.
B) double-stranded DNA.
C) triple-stranded DNA.
D) single-stranded RNA.
E) double-stranded RNA.

A) 5'-to-3';5'-to-3'
B) 3'-to-5';3'-to-5'
C) 5'-to-3';3'-to-5'
D) 3'-to-5';5'-to-3'
E) 5'-to-5';3'-to-3'

A) Some promoters are more efficient than others at initiating transcription.
B) Various proteins can bind to the promoter.
C) Promoters provide information that orients RNA polymerase to the strand of the DNA it should use as a template.
D) A promoter is a DNA sequence.
E) Bacterial genes lack promoters.

A) CE
B) ABD
C) BAD
D) ABDCE
E) ABCDE

A) 5'-GTCTATGCATTA-3'
B) 5'-CAGATACGTAAT-3'
C) 3'-GTCTATGCATTA-5'
D) 3'-CAGATACGTAAT-5'
E) 5'-GUCUAUGCAUUA-3'

A) One that removes 6 nucleotides from a sequence
B) One that adds 8 nucleotides to a sequence
C) One that removes 2 nucleotides from a sequence
D) One that adds 14 nucleotides to a sequence
E) One that adds 5 nucleotides to a sequence

A) peptide bonds.
B) hydrogen bonds.
C) disulfide bridges.
D) phosphodiester bonds.
E) glycosidic linkages.

A) It protects mRNA from being digested by enzymes.
B) It is added to the pre-mRNA during transcription.
C) It is a chemical modification of GTP.
D) It assists in transport of mRNA from the nucleus to the cytoplasm.
E) All of the above are true;none is false.

A) 5'-ATC-3'.
B) 5'-AUC-3'.
C) 5'-UAG-3'.
D) 5'-TAG-3'.
E) 5'-CAU-3'.

A) 190
B) 440
C) 600
D) 1,320
E) 1,800

A) A defect in the addition of the poly A tail on the pre-mRNA
B) A defect in a spliceosome
C) A defect in nucleic acid hybridization
D) Overactive termination
E) A defect in the promoter

A) 5'-GCA-3'.
B) 5'-GCG-3'.
C) 5'-GCU-3'.
D) 5'-GCC-3'.
E) The anticodon could pair with all of the above.

A) The codons CCU and CCC both code for the amino acid proline.
B) The codon CAG could code for two different amino acids.
C) The codons CUU and CCU code for different amino acids.
D) In some protists,UAG encodes for glutamine rather than functioning as a stop codon.
E) In nearly all organisms,UUU codes for phenylalanine.

A) chemically converted the amino acid on a charged tRNA.
B) manipulated the anticodon of a charged tRNA.
C) manipulated the anticodon of an uncharged tRNA.
D) chemically changed the aminoacyl-tRNA synthetase.
E) charged a tRNA molecule with two different amino acids.

A) missense
B) nonsense
C) ambiguous
D) silent
E) frame-shift

A) 8
B) 16
C) 24
D) 32
E) 64

A) Eukaryotes,archaea,and bacteria each evolved the genetic code independently.
B) The common ancestor of eukaryotes and archaea evolved the genetic code independently from the one evolved by bacteria.
C) The common ancestor of eukaryotes and bacteria evolved the genetic code independently from the one evolved by archaea.
D) The common ancestor of archaea and bacteria evolved the genetic code independently from the one evolved by eukaryotes.
E) The genetic code evolved in the common ancestor of all known life.

A) Any particular tRNA binds to one and only one amino acid.
B) tRNAs bind physically to mRNA.
C) The three-dimensional structure of tRNA results from hydrogen bonding between complementary bases.
D) tRNAs interact with ribosomes.
E) During elongation,the anticodon of an incoming tRNA first binds to the codon at the P site.

A) 190
B) 460
C) 600
D) 1,320
E) 1,800

A) A pre-RNA strand is longer than the corresponding mature mRNA.
B) A pre-RNA strand is shorter than the corresponding mature mRNA.
C) The nucleotides of a pre-RNA strand are in a different order from those of the corresponding mature mRNA.
D) A mature mRNA strand contains more introns than the corresponding pre-RNA.
E) Introns scramble the order of genes.

A) 20
B) 23
C) 45
D) 61
E) 64

A) missense codons.
B) start codons.
C) stop codons.
D) promoters.
E) initiator codons.

A) 120
B) 180
C) 360
D) 1,080
E) 2,160

A) A silent mutation
B) A deletion mutation
C) A frame-shift mutation
D) A nonsense mutation
E) A missense mutation

A) 5';3'
B) 5';5'
C) 5';2'
D) 3';5'
E) 3';3'

A) are transcription factors.
B) are responsible for the wobble phenomenon.
C) charge tRNAs.
D) are responsible for the fidelity function.
E) bind tRNA to rRNA.

A) A site;3'-to-5'
B) A site;5'-to-3'
C) N terminus;3'-to-5'
D) C terminus;3'-to-5'
E) N terminus;5'-to-3'

A) glycation.
B) glycosylation.
C) phosphorylation.
D) proteolysis.
E) exonuclease digestion.

A) Any component of the ribosome
B) The structure formed when multiple peptide chains are gathered together
C) Any RNA with catalytic ability
D) The structure formed when tRNAs are charged
E) Any RNA-DNA hybrid

A) accepted;the large
B) rejected;the small
C) rejected;the large
D) rejected;both
E) accepted;the small

A) amino acid;consistent
B) tRNA;inconsistent
C) mRNA;inconsistent
D) tRNA;consistent
E) amino acid;inconsistent

A) a protein release factor.
B) a polysome.
C) a signal sequence.
D) a spliceosome.
E) directing factors.

A) protein;large
B) protein;small
C) RNA;large
D) RNA;small
E) sugar;large

A) glycation.
B) glycosylation.
C) phosphorylation.
D) proteolysis.
E) exonuclease digestion.

A) the structure formed when a polypeptide is glycosylated.
B) a signal sequence.
C) the structure formed when multiple peptide chains are gathered together.
D) a protein release factor.
E) the structure formed when multiple ribosomes are translating an mRNA molecule.

A) small proteins;translation
B) proteins and small RNAs;translation
C) proteins and tRNAs;transcription
D) proteins and mRNAs;translation
E) mRNAs and tRNAs;translation

A) A
B) N
C) E
D) T
E) P

A) the large ribosomal subunit.
B) a specialized segment of DNA.
C) a specialized segment of RNA.
D) the initiation complex.
E) initiation factors.

A) on the mRNA interacts with a receptor protein on the membrane.
B) on the ribosome interacts with a receptor protein on the membrane.
C) at the amino terminus of the protein being synthesized interacts with a receptor protein on the ribosome.
D) on the protein being synthesized interacts with a signal recognition particle and both bind to the endoplasmic reticulum.
E) on the mRNA passes through a pore in the membrane.

A) A,E,P
B) P,E,A
C) E,P,A
D) P,A,E
E) A,P,E

A) increasing peptidyl transferase activity.
B) binding a protein release factor,causing hydrolysis of the bond between the polypeptide chain and the tRNA.
C) binding a signal sequence,causing hydrolysis of the bond between the polypeptide chain and the tRNA.
D) interfering with the working of the ribosome,leading to the ribosome's secretion of protein release factors.
E) decreasing peptidyl transferase activity.

A) is the site of mRNA attachment.
B) is the site where all ribosomes bind.
C) is the site of translation of membrane-bound and exported proteins.
D) produces tRNAs.
E) brings together mRNA and tRNA.

A) Bacterial and eukaryotic ribosomes differ in their specific proteins and RNAs.
B) Bacteria and eukaryotic tRNAs bind different amino acids.
C) Tetracyclines cannot enter the nucleus of eukaryotic cells.
D) Tetracyclines cannot enter the ER of eukaryotic cells.
E) Tetracyclines are destroyed by enzymes found only in eukaryotes.

A) It is always the first amino acid in a new polypeptide chain in eukaryotes.
B) It is always the first amino acid in mature proteins in eukaryotes.
C) In a modified form,it is the first amino acid in a new polypeptide chain in bacteria.
D) Transfer RNAs that bind to start codons are charged with methionine.
E) It is encoded by the start codon.