Deck 8: Transcription, Translation, and Bioinformatics

A) start
B) regulate
C) stop
D) speed up
E) slow down

A) 1-3 seconds.
B) 10-30 seconds.
C) 1-3 minutes.
D) 1-3 hours.
E) 1-3 days.

A) Transcription; translation
B) Holoenzyme; core
C) Translation; transcription
D) Core; holoenzyme
E) Ribosome; rRNA

A) stress-response genes.
B) motility and chemotaxis genes.
C) "housekeeping" genes.
D) heat shock-induced genes.
E) genes for nitrogen metabolism.

A) AUG
B) UCA
C) UAC
D) UGA
E) UAG

A) -10 and -35 sequences
B) binding of RNA polymerase to the beginning of the gene
C) melting of the helix
D) binding of sigma factor to promoter followed by binding of core RNA polymerase
E) base pairing of the first nucleotide of the RNA

A) proteases.
B) polymerases.
C) ribosomes.
D) ribozymes.
E) RNases.

A) streptomycin
B) actinomycin D
C) chloramphenicol
D) rifampin
E) tetracycline

A) sequences that are rarely found in nature.
B) the sequence with the most likely base (or bases) at each position.
C) hairpins in RNA to slow down or stop transcription.
D) sequences to which ribosomes bind.
E) primer sequences used to initiate transcription.

A) a type I secretion system.
B) RNA polymerase.
C) a ribosome.
D) aminoacyl-tRNA synthetase.
E) sigma factor and RNA polymerase.

A) phosphate; hydroxyl
B) C; GGA
C) G; CCA
D) A; TTA
E) C; AAT

A) streptomycin.
B) rifamycin.
C) erythromycin.
D) rifampin.
E) actinomycin D.

A) A
B) B
C) C
D) D
E) -35

A) stem and loop and stretches of uridines
B) stem and loop only
C) GC-rich region near the 3¢ terminus
D) GC-rich region near the 3¢ terminus followed by four to eight uridines
E) stem and loop followed by a GC-rich region

A) A
B) B
C) C
D) D
E) -35

A) GLU-LEU-CYS-MET-GLY-SER-MET-CYS
B) MET-GLY-SER-MET-CYS
C) MET-HIS-GLY-PHE-TYR-VAL
D) MET-CYS-ILE-LEU-GLY-THR-TYR
E) ASP-VAL-TYR-LEU-GLY-TYR-VAL-LEU

A) RNA; transformation
B) protein; transcription
C) DNA; transcription
D) RNA; transcription
E) protein; transposition

A) tRNA
B) tmRNA
C) mRNA
D) sRNA
E) catalytic RNA

A) The RNA polymerase holoenzyme binds.
B) GTP hydrolysis catalyzes bubble formation.
C) The promoter unwinds.
D) The first rNTP is usually a purine.
E) Position +1 marks the start of the gene.

A) are part of tRNA.
B) are sequences of DNA three nucleotides long.
C) are identical RNA sequences.
D) are complementary RNA sequences.
E) interact with tmRNA in order to function.

A) chloramphenicol.
B) streptomycin.
C) puromycin.
D) tetracycline.
E) erythromycin.

A) genes
B) proteins
C) polymerases
D) ribosomes
E) RNases

A) 16 RNAs and a variety of proteins.
B) an 80S (30S + 50S) component made of RNA and proteins.
C) 80S subunits along with several RNAs and at least 50 proteins.
D) two subunits made of three RNAs and at least 50 proteins.
E) three subunits containing both RNA and proteins.

A) ribozymes
B) aminoacyl-tRNA
C) peptidyl
D) proteases
E) polymerases

A) mRNA
B) rRNA
C) sRNA
D) tmRNA
E) tRNA

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

A) cistronic
B) transfer
C) polygenic
D) ribosomal
E) small

A) sRNAs
B) degrons
C) TolC proteins
D) release factors
E) ubiquitins

A) 5S RNA
B) 16S RNA
C) 23S RNA
D) tRNA
E) mRNA

A) clpX tags the peptide for destruction.
B) sspB tags the peptide for destruction.
C) tmRNA then destroys the peptide.
D) tmRNA ubiquitinates the peptide.
E) sspB recognizes a proteolysis tag and delivers the peptide to clpX for degradation.

A) replication
B) transcription
C) translation
D) degradation
E) conjugation

A) tells the DNA polymerase to stop replicating the chromosome.
B) tells the RNA polymerase to stop transcribing the chromosome.
C) tells the tRNA to stop transcribing the DNA.
D) tells the ribosome to stop translating the mRNA.
E) signals the end of the operon.

A) RNA polymerase binds to begin transcription.
B) a ribosome binds so that it can initiate translation.
C) DNA polymerase binds to begin chromosome replication.
D) the tRNA binds to the mRNA in translation.
E) DNA polymerase begins synthesis of the Okazaki fragments on the lagging strand.

A) adenylation.
B) phosphorylation.
C) acetylation.
D) removal of formylmethionine.
E) ubiquitination.

A) tRNA
B) mRNA
C) rRNA
D) sRNA
E) tmRNA

A) proton motive force.
B) ATP hydrolysis.
C) GTP hydrolysis.
D) phosphoenolpyruvate hydrolysis.
E) No energy source is required.

A) the use of an acetyltransferase to destroy activity.
B) immediate metabolization to gain ATP.
C) efflux pumps to move it out of the cell.
D) the use of phosphotransferases to chemically modify the antibiotic.
E) mutations in genes for the bacterial target so antibiotics can no longer bind.

A) There is more than one kind of amino acid in proteins.
B) More than one rRNA can bind to the ribosome at the same time.
C) A codon is composed of more than one nucleotide.
D) More than one codon can specify the same amino acid.
E) All products of translation contain a certain minimum number of mistakes, called mutations.

A) beta-sheet to alpha-helix; a promoter to initiate transcription
B) alpha-helix to beta-sheet; a promoter to initiate translation
C) beta-sheet to alpha-helix; RNAP and thus being able to bind ribosomal protein
D) alpha-helix to beta-sheet; RNAP and thus being able to bind ribosomal protein
E) beta-sheet to alpha-helix; RNAP to initiate translation

A) export
B) import
C) translocation
D) transport
E) secretion

A) destroying damaged proteins so the amino acids can be recycled.
B) refolding proteins damaged by heat so they function again.
C) secreting damaged proteins into the periplasm.
D) labeling damaged proteins for destruction by clp proteases.
E) adding N-formylmethionine to damaged proteins.

A) archaea; exon removal
B) bacteria; splicing
C) eukaryote; splicing
D) bacteria; exon removal
E) eukaryote; exon removal

A) trigger factor
B) GroES
C) GroEL
D) Clp protease
E) DnaK

A) paralog.
B) orthologs.
C) open reading frames (ORFs).
D) introns.
E) aligned sequences.

A) membrane; periplasm
B) membrane; periplasmic space and lipopolysaccharide
C) membrane; periplasmic space and peptidoglycan
D) lipopolysaccharide; periplasmic space and peptidoglycan
E) lipopolysaccharide; peptidoglycan

A) Genes encoding enzymes for fermentation and production of butyrate have been found.
B) The genome is similar to other bacteria and thus the media for those other bacteria can now be used.
C) Bioinformatics has indicated genes for metabolism of sugars that can now be added to the growth medium.
D) Bioinformatics has revealed that this bacterium can make its own amino acids and thus they are not needed in the growth medium.
E) Bioinformatics has revealed that biosynthetic genes for certain amino acids and vitamins are absent. Now these can be added to growth medium and the bacterium will grow.

A) nucleus.
B) inner membrane.
C) cell wall.
D) periplasmic space.
E) outer membrane.

A) secretion recognition particle; refolding
B) secretion ribosomal particle; refolding
C) signal recognition particle; refolding
D) secretion ribosomal particle; secretion
E) signal recognition particle; secretion

A) in the 30S ribosomal subunit
B) in the 50S ribosomal subunit
C) at the N-terminal end of a protein
D) at the C-terminal end of a mRNA
E) upstream of the promoter

A) homologs.
B) orthologs.
C) paralogs.
D) homogenous.
E) synonymous.

A) GroEL and GroES.
B) DnaK and DnaJ.
C) clpAP protease.
D) Sec A.
E) ubiquitin.

A) annotation
B) bioinformatics
C) open reading frames (ORFs)
D) sequence homology
E) computer analysis

A) serve as a secretion system and a chaperone.
B) mark proteins for destruction.
C) secrete proteins to the periplasm.
D) anchor proteins in the cytoplasmic membrane.
E) form -S-S- bonds needed for protein structure.