Deck 11: Transcription in Eukaryotes

A) trans-acting transcription factors
B) cis-acting transcription factors
C) trans-acting DNA sequences
D) cis-acting DNA sequences

A) regulatory proteins
B) RNA polymerase
C) promoters
D) operators

A) be transcribed by RNA Polymerase III
B) leave its chromosome territory to associate with a transcription factory
C) become dimethylated on Lys9 of histone H3
D) become covalently attached to the nuclear matrix

A) They serve as the recruitment site for RNA polymerase II.
B) They serve as the recognition site for general transcription factors.
C) They all contain a TATA box.
D) They become nonfunctional when moved even a short distance from the start oftranscription.

A) the TATA-binding proteins (TBP)
B) general transcription factors plus RNA polymerase
C) general transcription factors
D) regulatory transcription factors

A) Enhancers are transcription factors; promoter-proximal elements are DNA sequences.
B) Enhancers enhance transcription; promoter proximal-elements inhibit transcription.
C) Enhancers are part of the core promoter; promoter-proximal elements are regulatory sequences distinct from the core promoter.
D) Enhancers are at considerable distances from the core promoter; promoter-proximal elements are close to the core promoter.

A) They contain a consensus sequence called a TATA box.
B) They are found in a variety of locations and are functional in any orientation.
C) They are located only in introns.
D) They are located only in 5?-flanking regions.

A) The ability of the TATA-binding protein (TBP) to recognize the promoter.
B) The ability of RNA polymerase II to associate with the general transcription factors.
C) The ability of RNA polymerase II to initiate transcription.
D) The ability of enhancers to influence transcription.

A) enhancer
B) insulator
C) locus control region
D) matrix attachment region

A) inclusion of matrix attachment regions (MARs)
B) inclusion of insulator elements
C) inclusion of a strong promoter
D) inclusion of a G-less cassette

A) locus control region
B) coding region
C) matrix attachment region
D) promoter

A) promoter and silencer
B) promoter and enhancer
C) promoter and locus control region
D) silencer and enhancer

A) DNase I is an enzyme.
B) DNase I will digest DNAs from all species equally effectively.
C) DNase I preferentially digests DNA not associated with protein.
D) DNase I cuts at specific DNA recognition sequences.

A) The beta-globin and vitellogenin promoters are equally sensitive to DNase I treatment.
B) The beta-globin and vitellogenin promoters are equally resistant to DNase I treatment.
C) The beta-globin promoter is much more sensitive to DNase I treatment.
D) The vitellogenin promoter is much more sensitive to DNase I treatment.

A) general transcription factors
B) mediators
C) histones
D) elongation factors

A) TFIID
B) THIIE
C) TFIIF
D) TFIIH

A) phosphorylation of the RNA polymerase II (RNA pol II) C-terminal domain (CTD).
B) dephosphorylation of the RNA pol II CTD.
C) acetylation of the RNA pol II CTD.
D) deacetylation of the RNA pol II CTD.

A) TFIID
B) TFIIE
C) TFIIF
D) TFIIH

A) spliceosome
B) enhancer
C) Mediator
D) SWI/SNF

A) generate an RNA product of defined length
B) pause RNA polymerase at a defined site in a template
C) induce RNA polymerase backtracking
D) A and B

A) The different cells contain different sets of enhancers and promoter-proximal elements.
B) The different cells contain different sets of transcription factors.
C) The different cells contain different sets of cell-type-specific genes.

A) it is a DNA-binding domain that directly contacts DNA in the major groove
B) is a stretch of amino acids that fold into a long alpha-helix with leucines in every seventh position
C) it facilitates dimerization of two similar polypeptide chains
D) it is not as common as the zinc finger motif

A) chromodomain
B) zinc finger
C) helix-turn-helix
D) basic helix-loop-helix

A) It would activate the transcription of genes normally activated by Fork head.
B) It would activate the transcription of genes normally activated by Sp1.
C) It would activate the transcription of genes normally activated by both Fork head and Sp1.
D) It would not activate the transcription of any genes.

A) in vitro run-off assay
B) fluorescence recovery after photobleaching (FRAP)
C) X-ray crystallography
D) electromobility shift assay (EMSA)

A) Each Hox gene has a 180 base pair sequence called the homeobox.
B) In both fruit flies and mammals, the order of the Hox genes on the chromosomecorrelates with where they are expressed in embryos.
C) In fruit flies the order of Hox genes on the chromosome correlates with where they are expressed in embryos; in mammals there is no correlation.
D) The expression of the Hox genes is sequential, moving in order along the chromosome.

A) neutralizing positive charges on lysines of histones
B) increasing the negative charge on glutamic acids of histones
C) modifying the base sequence of the promoter
D) adding bulky methyl groups to lysines and arginines of histones

A) Many coactivators function as chromatin modification complexes.
B) Many coactivators function as chromatin remodeling complexes.
C) All coactivators increase transcriptional activity.
D) All coactivators bind DNA directly.

A) The "enhanceosome" model requires the involvement of both promoter proximal elements and the core promoter, whereas the "hit and run" model only involves promoter proximal elements.
B) The "enhanceosome" model requires that a stable transcriptional activation complex assembles in an ordered fashion, whereas the "hit and run" model suggests that such complexes are formed stochastically.
C) The "enhanceosome" model requires synergy between multiple transcriptional (co)activators, whereas the "hit and run" model allows that each transcriptional regulatory protein may function independently.
D) The "enhanceosome" model only applies to genes that undergo developmental regulation, whereas the "hit and run" model only applies to genes that undergo dynamic regulation even in a terminally differentiated cell.

A) nucleosome sliding
B) replacement of a core histone with a variant histone
C) nucleosome displacement
D) remodeled nucleosomes

A) SWI/SNF, histone acetyltransferase (HAT) complex, preinitiation complex
B) HAT complex, SWI/SNF, preinitiation complex
C) preinitiation complex, SWI/SNF, HAT complex
D) the order of recruitment is gene-specific.

A) FACT
B) SWI/SNF
C) Sonic hedgehog
D) Polycomb

A) in vitro run-off assay
B) fluorescence recovery after photobleaching (FRAP)
C) X-ray crystallography
D) electromobility shift assay (EMSA)

A) promoter clearance
B) transcript elongation
C) proofreading and backtracking
D) nucleotide translocation

A) TFIIS
B) FACT
C) HDAC
D) Elongator

A) The nuclear localization sequence of the protein to be imported binds to importin.
B) The nuclear localization sequence of the protein is removed once the protein enters the nucleus.
C) The energy for import is provided by the small GTPase Ran.
D) Import may occur against a concentration gradient.

A) occurs by diffusion through the nuclear envelope.
B) is mediated by structures embedded in the nuclear envelope called nuclear pore complexes.
C) is mediated by structures embedded in the nuclear envelope called nuclear localization sequences.
D) occurs by active transport through phospholipid-lined channels in the nuclear envelope.

A) causes disassembly of import complexes, but is required for the assembly of export complexes.
B) causes assembly of import complexes, but is required for the disassembly of export complexes.
C) is present in equal concentrations in the nucleus and cytoplasm.
D) is required to provide energy for cargo recognition and docking.

A) GTP to GDP
B) GDP to GTP
C) GDP to GMP
D) GMP to GDP

A) the receptor-hormone dimer must dissociate to form a monomer.
B) the receptor-hormone complex must become water soluble by binding to a carrier molecule.
C) the receptor-hormone complex must be transported through the nuclear pore complex.
D) the receptor-hormone complex must be activated by a signaling cascade.