Deck 28: Regulation of Gene Expression

A)In some operons (e.g. ,the his operon),attenuation may be the only regulatory mechanism.
B)Sequences of the trp operon leader RNA resemble an operator.
C)The leader peptide acts by a mechanism that is similar to that of a repressor protein.
D)The leader peptide gene of the trp operon includes no Trp codons.
E)The leader peptide is an enzyme that catalyzes transcription attenuation.

A)attenuator.
B)inducer.
C)mRNA.
D)repressor.
E)suppressor tRNA.

A)all constitutive enzymes are synthesized at the same rate,but are not degraded equally.
B)their promoters have different affinities for RNA polymerase holoenzyme.
C)some constitutively expressed genes are more inducible than others.
D)some constitutively expressed genes are more repressible than others.
E)the same number of mRNA copies are made from each gene but are translated at different rates.

A)assists RNA polymerase binding to the lac promoter.
B)is inhibited by a high level of cAMP.
C)occurs in the lac repressor region.
D)occurs only when glucose is present in the growth medium.
E)prevents the repressor from binding to the lac operator.

A)Attenuation is the only mechanism used to regulate the trp operon.
B)One of the enzymes in the Trp biosynthetic pathway binds to the mRNA and blocks translation when tryptophan levels are high.
C)The leader peptide plays a direct role in causing RNA polymerase to attenuate transcription.
D)Trp codons in the leader peptide gene allow the system to respond to tryptophan levels in the cell.
E)When tryptophan levels are low,the trp operon transcripts are attenuated (halted)before the operon's structural genes are transcribed.

A)Glucose in the growth medium decreases the inducibility by lactose.
B)Glucose in the growth medium does not affect the inducibility by lactose.
C)Glucose in the growth medium increases the inducibility by lactose.
D)Its expression is regulated mainly at the level of translation.
E)The lac operon is fully induced whenever lactose is present.

A)a mutation in the repressor gene that strengthens the affinity of the repressor for the operator.
B)a mutation in the repressor gene that weakens the affinity of the repressor for the operator.
C)a mutation in the repressor gene that weakens the affinity of the repressor for the inducer.
D)binding of the repressor to the operator.
E)the presence of glucose in the growth medium.

A)can adjust transcription of the structural genes upwards when tryptophan is present.
B)can fine-tune the transcription of the operon in response to small changes in Trp availability.
C)is a mechanism for inhibiting translation of existing (complete)trp mRNAs.
D)results from the binding of the Trp repressor to the operator.
E)results from the presence of short leader peptides at the 5' end of each structural gene.

A)helix-turn-helix.
B)homeobox.
C)homeodomain.
D)leucine zipper.
E)zinc finger.

A)group of related triplet codons.
B)network of operons with a common regulator.
C)operon that is subject to regulation.
D)protein that regulates gene expression.
E)ribosomal protein that regulates translation.

A)A promoter may be present on either side of a gene or in the middle of it.
B)All promoters have the same sequence that is recognized by RNA polymerase holoenzyme.
C)Every promoter has a different sequence,with little or no resemblance to other promoters.
D)Many promoters are similar and resemble a consensus sequence,which has the highest affinity for RNA polymerase holoenzyme.
E)Promoters are not essential for gene transcription,but can increase its rate by two- to three-fold.

A)unchanged.
B)increased.
C)always decreased.
D)only decreased in the absence of Trp.
E)Cannot be determined from the information given.

A)Ala,Asn,Glu
B)Arg,Gln,Leu
C)Asn,Gln,Trp
D)Asn,Glu,Lys
E)Glu,Lys,Pro

A)A - T
B)G - C
C)T - A
D)C - G
E)All of the above

A)A - T
B)G - C
C)T - A
D)C - G
E)All of the above

A)binds to RNA polymerase when tryptophan is present.
B)binds to the trp operator in the absence of tryptophan.
C)binds to the trp operator in the presence of tryptophan.
D)is a DNA sequence.
E)is an attenuator.

A)cause activator proteins to bind DNA sites.
B)cause repressor proteins to bind DNA sites.
C)directly bind to DNA sites.
D)prevent activator proteins from binding to DNA sites.
E)release repressor proteins from DNA sites.

A)( $\beta$ -barrel)
B)Helix-turn-helix
C)Homeodomain
D)Leucine zipper
E)Zinc finger

A)CRP protein binds to the lac operator.
B)CRP protein displaces the Lac repressor from the lac promoter.
C)the repressor is bound to the lac operator.
D)RNA polymerase binds the lac promoter and transcribes the lac operon.
E)the operon is fully induced.

A)associating with polymerase holoenzyme to help it remove LexA from operator.
B)bending LexA operator DNA to force dissociation of LexA repressor.
C)binding to LexA protein to weaken directly its affinity for operator sites.
D)causing self-cleavage of LexA,thus inactivating its binding to operator.
E)competitively binding to LexA operators and serving as an activator.

A)TATA box
B)TATA binding protein
C)CTD of RNA polymerase
D)TFIIH
E)Modification and remodeling enzymes

A)Large polycistronic transcripts are common.
B)Most regulation is positive,involving activators rather than repressors.
C)Transcription and translation are mechanistically coupled.
D)Transcription does not involve promoters.
E)Transcription occurs without major changes in chromosomal organization.

A)SWI/SNF chromatin remodeling proteins
B)Histone acetyltransferases
C)Histone methylases
D)Histone deacetylases
E)Alterations in histone content

A)Unipotent cells can develop into only one type of cell or tissue.
B)Pluripotent cells can develop into a complete organism.
C)Multipotent bone marrow cells can develop into different types of blood cells.
D)Totipotent cells can develop into any kind of tissue.
E)Totipotent,unipotent,multipotent,and pluripotent are all types of stem cells.

A)Gap genes
B)Homeotic genes
C)Maternal genes
D)Segment polarity genes
E)Segmentation genes

A)inhibiting transcription
B)inhibiting translation
C)inhibiting splicing
D)degradation of the mRNA
E)inhibiting polyadenylyation

A)Gap genes
B)Homeotic genes
C)Maternal genes
D)Segment polarity genes
E)Segmentation genes

A)Basal transcription factors
B)Coactivators
C)Repressors
D)TATA-binding proteins
E)Transactivators

A)are transcribed during egg production;their mRNAs lie dormant in the egg until it is fertilized.
B)determine the number of body segments that will form.
C)are expressed late and determine the detailed structure of each body segment.
D)generally have no introns.
E)are not translated into proteins.

A)Access to eukaryotic promoters is restricted by the structure of chromatin.
B)Most regulation is positive,involving activators rather than repressors.
C)Larger and more multimeric proteins are involved in regulation of eukaryotic transcription.
D)Transcription and translation are separated in both space and time.
E)Strong promoters in eukaryotes are generally fully active in the absence of regulatory proteins.

A)Small RNAs can disrupt local hairpins that prevent ribosome binding.
B)Small RNAs require a protein chaperone to facilitate RNA-RNA base pairing.
C)Riboswitches are often found in the 5-untranslated region of genes.
D)Each riboswitch can bind an assortment of small metabolites.
E)Riboswitches can affect either transcription of translation.

A)unchanged.
B)only increased in the presence of Trp.
C)always increased.
D)decreased.
E)Cannot be determined from the information given.

A)Coactivator
B)Corepressor
C)Enhancer
D)Inducer
E)Transactivator

A)Cell surface receptors
B)Hormone-receptor complexes
C)Specific DNA sequences
D)Transcription activation and repression
E)Zinc fingers