Deck 9: The Molecular Biology of Translation

A)the genetic code is overlapping.
B)the genetic code is nonoverlapping.
C)the genetic code is redundant.
D)there are 20 amino acids.
E)the genetic code is triplet.

A)one codon.
B)one nucleotide.
C)two nucleotides.
D)two codons.
E)three codons.

A)polymerase chain reaction
B)gel electrophoresis
C)two-dimensional gel electrophoresis
D)CsCl gradient ultracentrifugation
E)cryo-EM

A)5′ - ATG CGA TTT GGG TGC TAG - 3′
B)5′ - AUG CGA UUU GGG UGC UAG - 3′
C)5′ - AUG CGA UUU GGG UGC - 3′
D)5′ - CTA GCA CCC AAA TCG CAT TAG - 3'
E)3′ - GGA CAU AGG UAC GUG GGU UUA GCG UAA UCC UG - 5′

A)UUC and UUG
B)UCC and UAC
C)CGA and AGA
D)AGG and AGC
E)AAG and AAC

A)deleting 2 bases
B)adding 1 base
C)deleting 1 base or adding 1 base
D)deleting 1 base or adding 3 bases
E)deleting 1 base or adding 2 bases

A)peptidyl transferase
B)DNA polymerase I
C)DNA polymerase III
D)aminoacyl synthetase
E)aminoacyl peptidase

A)methionine (Met).
B)N-formylmethionine (fMet).
C)acetylated.
D)IF-1.
E)added using ATP as the energy source.

A)is a purine-rich consensus sequence found in the 5′ UTR of the mRNA.
B)is a pyrimidine-rich consensus sequence found in the 3′ UTR of the mRNA.
C)is a purine-rich consensus sequence found in the 16S rRNA subunit.
D)is a region of the tRNA molecule involved in formation of charged tRNAs.
E)is a consensus sequence involved in the termination of translation.

A)a charged tRNA with the anticodon TAG
B)a charged tRNA with the anticodon ATC
C)an uncharged tRNA
D)a release factor
E)Nothing binds to a stop codon,which is why the peptide is released.

A)formation of the preinitiation complex
B)formation of the initiation complex
C)scanning
D)ribosome assembly
E)translocation of the ribosome in the 3′ direction

A)5′ - AUG CAG AUA GCG UGC UAG - 3′
B)5′ - AUG AAG UUA GCG UGC UAG - 3′
C)5′ - AUG CAG UAA GCG UGC UAG - 3′
D)5′ - AUG CAG UUA UUG UGC UAG - 3′
E)5′ - AUG CAG UUA GCG UGC AAG - 3′

A)promoters
B)Shine-Dalgarno sequences
C)Kozak sequences
D)mRNAs
E)polypeptide-producing sequences

A)5′-Met-Arg-Phe-Gly-Stop-3′
B)C-Met-Arg-Leu-Glu-N
C)N-Met-Arg-Phe-Gly-Cy-C
D)N-Met-Asp-Phe-Gly-Trp-C
E)N-Arg-Phe-Gly-Stop-C

A)The tRNA will fit into the A site but will not release the peptide at the P site.
B)The tRNA will not be recognized by tRNA synthetase and cannot be charged.
C)The tRNA will be charged with the wrong amino acid.
D)The tRNA will not be able to undergo traditional complementary base pairing.
E)There will be no effect on function,so long as the anticodon region is intact.

A)The true start codon is the first ATG encountered downstream of the Shine-Dalgarno sequence.
B)The initiation complex moves the small ribosomal subunit through the 5′ UTR,scanning for the start AUG.
C)The preinitiation complex moves the ribosome through the 3′ UTR,scanning for the Kozak sequence.
D)The true start codon is the first ATG encountered downstream of the Kozak sequence.
E)The true start codon is the formyl-ATG,which will encode for fMet in the protein.

A)hydrogen bonds and disulfide bonds that maintain the shape of the tRNAs
B)complementary base pairing between amino acids and tRNA
C)complementary base pairing between tRNA and mRNA
D)ionic bonds between the small and large subunits of the ribosome
E)hydrogen bonding between the ribosomal subunits and the mRNA

A)5′ - AUG CAA UUA GCG UGC UAG - 3′
B)5′ - AUG CAG UUA GCA UGC UAG - 3′
C)5′ - AUG CAG UUG GCG UGC UAG - 3′
D)5′ - AUG CAA UUA GCG UGU UAG - 3′
E)5′ - AUG CAC UUA GCA UGC UAG - 3′

A)It is likely nonfunctional,since bacteria use posttranslational cleavage of fMet to make functional proteins.
B)It will show improper protein sorting and will likely remain in the ER.
C)It will be not be able to be chemically modified,so it will be sent to the Golgi for secretion.
D)It will be a functional bacterial protein,since all functional proteins must begin with fMet.
E)It will likely form a disulfide bond with a second peptide chain,forming a protein complex.