Deck 16: Protein

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

A) All are hydrophilic amino acids
B) All have A as the second nucleotide in their codon
C) All have U as the second nucleotide in their codon
D) All have only one codon
E) Both (A) and (B) are correct

A) GAU to GUU
B) GAA to GUA
C) GAG to GAU
D) GUU to GAA
E) CAG to GAG

A) 5'-GCT-3' to 5'-GCA-3'
B) 5'-AGC-3' to 5'-TGC-3'
C) 5'-AGC-3' to 5'-UGC-3'
D) 5'-AGU-3' to 5'-UGU-3'
E) 5'-TCG-3' to 5'-TCC-3'

A) I only
B) II and III
C) III only
D) I and II
E) III and IV

A) a start and stop codon
B) homology with other species
C) placement on a genome map
D) presence of transposable elements
E) absence of highly repetitive sequences

A) they are aromatic amino acids
B) they are the sulfur containing amino acids
C) they are neutral polar amino acids
D) they occur very infrequently in proteins
E) none of the above

A) '-UCA-3'
B) 5'-UCG-3'
C) 5'-ACU-3'
D) 5'-GUA-3'
E) 5'-GCU-3'

A) UGG
B) TGG
C) CCA
D) Cannot be determined from the given data.
E) None of the above is the correct sequence.

A) a cloverleaf shape with the anticodon and acceptor stem on "leaves" that are opposite each other
B) an L shape with the anticodon at one end of the L and the acceptor stem at the other
C) a large loop with the anticodon and 3' end in very close proximity to each other
D) an elongated cylinder shape with the anticodon and acceptor stem at opposite ends
E) since all tRNAs have very different three-dimensional structures, it is difficult to describe a general shape

A) aminoacyl-adenylate
B) aminoacyl-tRNA
C) aminoacyl-ADP
D) tRNA-adenylate
E) none of the above

A) valine does not fit into the binding site for isoleucine
B) only leucine and isoleucine can fit in the active site of the enzyme
C) before incorporation, the enzyme methylates valine to make it into an isoleucine
D) the enzyme contains a proofreading site that removes valine from the tRNA
E) none of the above

A) ester between AA carboxylate and tRNA 3' hydroxyl
B) mixed anhydride of AA carboxylate and tRNA 3'phosphate
C) phosphoramide of AA amine and tRNA 3'phosphate
D) mixed anhydride of AA carboxylate and tRNA 5' phosphate
E) phosphoramide of AA amine and tRNA 5' phosphate

A) 1
B) 2
C) 3
D) 4
E) 5

A) 1
B) 2
C) 3
D) 4
E) 5

A) 1
B) 2
C) 3
D) 4
E) 5

A) 1/2
B) 1/3
C) 1/4
D) 1/5
E) 1/6

A) I only
B) I and III
C) I, III and IV
D) II, III and IV
E) I, II and III

A) the strength of even weak interactions of the amino acid within its catalytic binding site
B) the topography of the enzymes' proofreading sites
C) recognition of the anticodon loop only
D) specific cations found in the catalytic binding site
E) Both (A) and (B) are correct

A) mRNA and rRNA
B) tRNA and mRNA
C) tRNA and rRNA
D) all of the above
E) none of the above

A) I and II
B) III and IV
C) I, III and IV
D) II and III
E) IV only

A) N-formylthreonine
B) N-formylmethionine
C) N-formylaspartate
D) N-formylglutamine
E) N-formylcysteine

A) Watson-Crick sequence
B) Meselson-Stahl sequence
C) Hershey-Chase sequence
D) Avery-MacLeod sequence
E) Shine-Dalgarno sequence

A) initial tRNA with the initiation codon
B) initial tRNA with the ribosomal A site
C) mRNA with 23S rRNA of the ribosome
D) mRNA with 16S rRNA of the ribosome
E) mRNA with initial tRNA

A) IF-1; IF-2
B) IF-1; IF-3
C) IF-2; IF-1
D) IF-2; IF-3
E) IF-3; IF-1

A) a sequence similar to the Shine-Dalgarno sequence is located
B) the 5'cap binds just beyond the P site of the ribosome
C) the fMet-tRNA is able to locate the initiation codon before binding to the ribosome
D) when the mRNA circularizes, the poly(A) tail enables location of the initiation codon
E) the first AUG codon is found when the 40S subunit scans the mRNA from the 5' end

A) the formation of the first peptide bond, when the amino N of amino acid 2 attacks the carboxyl C of methionine
B) the formation of the first peptide bond, when the amino N of methionine attacks the carboxyl C of amino acid 2
C) binding of eIF-2 or IF-2 to amino acid 2
D) translocation of the ribosome to place empty tRNAmet into the E site
E) binding of EF-G to tRNA-amino acid 2

A) tRNAmet
B) the tRNA held in the E site after translocation
C) the tRNA held in the E site before translocation
D) the tRNA held in the P site after translocation
E) the tRNA held in the A site after translocation

A) proofreading
B) transpeptidation
C) translocation
D) aminoacyl-tRNA binding to the ribosomal A site
E) none of the above

A) entrance site; exit site
B) 50S subunit; 30S subunit
C) C-terminus; N-terminus
D) N-terminus; C-terminus
E) peptidyl site; aminoacyl site

A) a
B) b
C) c
D) d

A) translocation; the EF-Tu-tRNA complex
B) transpeptidation; the EF-Tu-GDP complex
C) transferase; an uncharged tRNA
D) transduction; an aminoacyl-tRNA
E) none of the above

A) in prokaryotes requires a single release factor RF-1, which is also a GTPase
B) in eukaryotes requires a single release factor eRF-1
C) in eukaryotes requires one of three release factors: RF-1, RF-2 or RF-3
D) none of the above

A) About 10% of cell proteins are completely synthesized and reside in the cytosol.
B) A single mRNA in the cytosol may have multiple ribosomes translating it at the same time.
C) Ribosomes that reside permanently on the rough ER translate only proteins destined for secretion from the cell.
D) Nascent proteins with a signal peptide at their amino terminus bind a signal recognition particle that binds an ER receptor.
E) Polysomes are multiple ribosomes translating the same mRNA.

A) the N-terminus binds SRP which delivers the ribosome and growing peptide to the ER
B) the N-terminus binds SRP which is then partially cleaved by a signal peptidase
C) the ribosome must be translocated into the ER prior to initiation of translation
D) the ribosome must be bound to the ER before translation begins
E) a chaperone protein embedded in the ER membrane binds the N-terminus

A) ubiquitin
B) trigger factor
C) chaperonin
D) heat shock protein
E) signal recognition particle

A) hydrophobic regions
B) acidic regions
C) basic regions
D) both acidic and basic regions
E) neutral polar regions

A) chloramphenicol
B) erythromycin
C) penicillin
D) puromycin
E) streptomycin

A) is specific for bacteria because it binds preferentially to the 50S ribosomal subunit, which is prokaryote-specific
B) is specific for bacteria because it binds preferentially to the 40S ribosomal subunit, which is prokaryote-specific
C) causes early termination of bacterial protein translation because it is an analog of release factor 3
D) causes early termination of bacterial protein translation because it is an analog of EF-Tu and translocation ceases
E) is not naturally-occurring

A) They are naturally occurring, commonly from plants
B) They are proteins that bind carbohydrates
C) They block protein synthesis in prokaryotes by binding to the 16S subunit of the ribosome
D) They depurinate ribosomal RNAs in prokaryotes
E) They are endoglycosylases that target ribosomal adenines