Deck 8: Transcriptional Control of Gene Expression

A)serves as a promoter sequence for genes transcribed by RNA polymerase III.
B)is located approximately 100 base pairs upstream of the start site for mRNAs.
C)is present in all eukaryotic genes.
D)acts to position RNA polymerase II for transcription initiation.

A)fluorescent in situ hybridization
B)chromatin immunoprecipitation
C)immunocytochemistry
D)high-throughput DNA sequencing

A)allow translation to proceed.
B)terminate DNA replication.
C)initiate transcription.
D)terminate DNA replication and initiate transcription.

A)TFIID,TFIIB,Pol II,TFIIH
B)PolII,TFIID,TFIIB,TFIIH
C)TFIIB,PolII,TFIIH,TFIID
D)TFIID,TFIIH,TFIIB,PolII

A)express the lac repressor constitutively.
B)block the binding of RNA polymerase to the promoter.
C)express β-galactosidase constitutively.
D)prevent the inducer from binding to the repressor.

A)luciferase
B)green fluorescent protein
C) β-galactosidase
D)RNA polymerase 1

A)DNA affinity chromatography
B)polymerase chain reaction
C)reporter gene assay
D)DNAse 1 footprinting

A)CBP
B)CDK9
C)CREB
D)CTD

A)a TATA box.
B)an initiator element.
C)CpG islands.
D)an enhancer.

A)In bacteria,but not eukaryotes,there is a specific sequence that specifies where RNA polymerase binds and initiates transcription.
B)In eukaryotes,but not bacteria,transcription can be influenced by how effectively the DNA sequence of a promoter region interacts with histone octamers.
C)Transcription regulation is the most widespread form of control of gene expression in bacteria but not in eukaryotes.
D)Gene regulation is readily reversible in eukaryotes but not bacteria.

A)lac repressor binding blocks RNA polymerase from interacting with DNA at the start site.
B)lac repressor binding induces a DNase that cleaves the DNA at the transcription start site.
C)lac repressor binding causes a conformational change in RNA polymerase.
D)lac repressor binding induces a protease that degrades the sigma subunit of RNA polymerase.

A)is a region of DNA that is transcribed as a single mRNA encoding several proteins.
B)encodes for miRNAs.
C)contains a promoter unique for each individual gene in the operator.
D)none of the above

A)lac repressor
B)β-galactosidase
C)RNA polymerase
D)cAMP-CAP

A)The CTD is present in RNA polymerase I,II,and III.
B)The CTD can become phosphorylated.
C)The CTD is critical for viability.
D)The CTD of mammals contains more than 50 repeats of a heptapeptide.

A)RNA polymerase I.
B)RNA polymerase II.
C)RNA polymerase III.
D)RNA polymerase I and RNA polymerase III.

A)nucleosome
B)chromosome
C)enhanceosome
D)proteasome

A)a stretch of five leucine residues in a row.
B)a leucine residue at every seventh position.
C)a leucine residue complexed with a zinc ion.
D)an alternating leucine-alanine-proline structure.

A)binding to the TATA box
B)unwinding the DNA duplex
C)catalyzing the synthesis of RNA
D)all of the above

A)homeodomain
B)zinc-finger
C)helix-loop-helix
D)random-coil acidic domain

A)It acts as tumor suppressor.
B)It serves as a co-activator of transcription.
C)It has homology to DNA helicases.
D)It can stabilize DNA-histone interactions.

A)TATA box
B)enhancers
C)CpG islands
D)UAS (upstream activating sequences)

A)methylation of the silent-mating-type locus.
B)transcription of the gene at the MAT locus.
C)chromatin condensation at the silent mating type locus.
D)a recombination event known as gene conversion.

A)a radiolabeled DNA fragment
B)a polyacrylamide gel
C)a DNA binding protein
D)DNase I

A)is a DNA element that stimulates transcription of eukaryotic promoters.
B)binds to RNA polymerase and stimulates transcription.
C)acts as a binding site for RNA polymerase.
D)interacts with repressor proteins to enhance transcriptional repression.

A)DNA dyes stain heterochromatin more darkly than euchromatin.
B)The DNA of heterochromatin is more highly condensed than that of euchromatin.
C)Heterochromatin is associated with inactive genes.
D)Heterochromatin is more susceptible to DNaseI than is euchromatin.

A)can form a molecular bridge between activators of transcription and DNA replication machinery.
B)can function to maintain a promoter in a hypoacetylated state.
C)has histone acetylase activity.
D)none of the above

A)are always located within euchromatin.
B)are not located within nucleosomes.
C)often are methylated.
D)are not resistant to DNase I.

A)methylation.
B)acetylation.
C)phosphorylation.
D)ubiquitination.

A)in situ hybridization and a radioactive fragment of the DNA response element
B)fluorescence microscopy and a GFP-tagged receptor fusion protein
C)pulse-chase radiolabeling
D)none of the above

A)binding to specific cell-surface receptors.
B)phosphorylating a protein kinase.
C)binding to a nuclear receptor.
D)inhibiting a histone deacetylase.

A)variable region,DNA-binding domain,ligand-binding domain
B)acetylase domain,DNA-binding domain,ligand-binding domain
C)variable region,acetylase domain,ligand-binding domain
D)variable region,DNA-binding domain,acetylase domain

A)involves hormone receptors only found in the nucleus.
B)involves cytoplasmic hormone receptors that can move to the nucleus.
C)involves two ligase domains.
D)always activates transcription.

A)ATP hydrolysis is not required for initiation.
B)Pol III is responsible for synthesizing tRNAs and 5S-rRNA.
C)The promoter elements of tRNA genes lie entirely within the transcribed sequence.
D)all of the above

A)Retinoblastoma
B)Trithorax
C)Polycomb
D)Pax

A)retinoic acid receptor
B)acetylcholine receptor
C)glucocorticoid receptor
D)progesterone receptor

A)They have the ability to both silence and activate genes.
B)They can involve the methylation of cytosine bases.
C)They are linked to the acetylation of histones.
D)All of the above

A)micro RNAs (miRNA).
B)long non-coding RNAs (ncRNA).
C)messenger RNA (mRNA).
D)short RNA-directed methylation of histones and DNA.