Deck 11: Regulation of Gene Expression

A) A constitutive gene and an activator
B) A transcription factor and a constitutive gene
C) A repressor and an activator
D) A promoter and a repressor
E) A promoter and an activator

A) Presence of $\beta$ -galactoside transacetylase at a high concentration when $\beta$ -galactoside is present at a low concentration
B) Production of $\beta$ -galactoside transacetylase at very low levels in the absence of lactose
C) Production of $\beta$ -galactoside transacetylase at very low levels when glucose is abundant
D) Production of $\beta$ -galactoside transacetylase at high levels when lactose is at a high concentration and glucose is not available
E) Presence of both $\beta$ -galactoside transacetylase and $\beta$ -galactoside in very low concentrations

A) a promoter and an operator.
B) an operator and three structural genes.
C) three structural genes and a promoter.
D) a promoter,an operator,and three structural genes.
E) a promoter,a director,and two structural genes.

A) inhibits the synthesis of needed enzyme(s).
B) stimulates the synthesis of needed enzyme(s).
C) binds to the promoter and prevents the repressor from binding to the operator.
D) binds to the operator and prevents the repressor from binding at this site.
E) binds to the termination codons and allows protein synthesis to continue.

A) the gene is never transcribed.
B) the gene is always transcribed.
C) the binding of an activator stimulates transcription.
D) transcription can be turned off when a repressor binds to the DNA near the promoter.
E) a transcription factor is required in order for the gene to be transcribed.

A) The level of transcription
B) The level of processing mRNA
C) The level of mRNA stability
D) The level of translation
E) The level of protein export

A) Both glucose and lactose are at high concentrations.
B) Both glucose and lactose are at low concentrations.
C) The operator has a mutation.
D) The promoter has a mutation.
E) One of the structural genes has a mutation.

A) extremely low;high
B) extremely low;extremely low
C) high;extremely low
D) high;high
E) high;variable

A) inducible
B) activated
C) repressible
D) constitutive
E) transcription factor

A) A mutation that lowers the efficiency of a repressor of the gene
B) A mutation that lowers the efficiency of an activator of the gene
C) A mutation that increases the efficiency of a repressor of the gene
D) A mutation that mutates an activator for the gene such that promoter recognition decreases
E) A mutation that mutates a repressor for the gene such that promoter recognition increases

A) They generally live in static environments.
B) The most efficient means of regulation of gene expression in these organisms is usually at the posttranslational level.
C) By making certain proteins only when needed,they save energy and other resources.
D) They lack the ability to react to their environment through gene expression.
E) They lack the ability to regulate their gene expression.

A) selective blocking of transcription.
B) translation of the mRNA.
C) inhibition of the protein.
D) degradation of the protein.
E) transcription of the gene.

A) protein;DNA
B) protein;RNA
C) promoter;a protein
D) gene;DNA
E) gene;RNA

A) All transcription factors are repressors.
B) All transcription factors are activators.
C) A promoter is a transcription factor.
D) A transcription factor can be an activator or a repressor.
E) A transcription factor can be both an activator and a repressor.

A) Cyclic AMP,CREB,protein kinase A
B) Cyclic AMP,protein kinase A,CREB
C) CREB,cyclic AMP,protein kinase A
D) CREB,protein kinase A,cyclic AMP
E) Protein kinase A,CREB,cyclic AMP

A) $\beta$ -Galactoside permease
B) $\beta$ -Galactoside transferase
C) $\beta$ -Galactoside transacetylase
D) $\beta$ -Galactosidase
E) Lactase

A) a transcription factor.
B) encoded by a constitutive gene.
C) encoded by an inducible gene.
D) part of an operon.
E) part of a replicon.

A) the total levels of CREB increased.
B) the total levels of CREB decreased.
C) the total levels of CREB remained the same.
D) levels of phosphorylated CREB increased.
E) levels of phosphorylated CREB decreased.

A) More expression of an activator of the gene
B) More expression of an activator of a repressor of the gene
C) Less expression of a repressor of the gene
D) Less expression of an activator of a repressor for the gene
E) More expression of an activator of an activator for the gene

A) late genes.
B) viral RNA polymerase from earlier lytic cycles.
C) host DNA polymerase.
D) reverse transcriptase.
E) host RNA polymerase.

A) The host genes are turned off because the phage encodes repressors shutting off the host genes.
B) The host genes are turned off because the phage polymerase competes with the host polymerase.
C) The host genes are turned off because the phage interferes with activators required for production of host genes.
D) The shutdown of host gene expression occurs after transcription.
E) The shutdown of host gene expression occurs after translation.

A) They are produced only in the lysogenic phase.
B) They are produced only in the lytic phase.
C) They are the host genes shut down by the virus.
D) They are produced in the lysogenic and lytic phases.
E) They are short,unused pieces of RNA in the viral genome.

A) They are not cells.
B) They can regulate the movements of substances into and out of the cell.
C) They can reproduce outside living cells.
D) They are large and therefore easy to study.
E) They are the smallest life form.

A) on;on
B) on;off
C) off;on
D) off;off
E) None of the above;in both cases the presence or absence of the corepressor would dictate whether the genes are on or off.

A) inducible
B) repressible
C) structural
D) regulatory
E) Both a and c

A) arise from preexisting viruses.
B) replicate their DNA before they reproduce.
C) develop and reproduce only within the cells of hosts.
D) cannot replicate themselves.
E) replicate themselves by division,just as cells do.

A) transcribed.
B) transcribed and translated.
C) sequences of RNA that are spliced out.
D) transcribed and then removed.
E) neither transcribed nor translated.

A) The structural genes in the operon are either all on or all off at a given time.
B) They consist of a cluster of genes with a single promoter.
C) Their DNA is transcribed into a single molecule of mRNA.
D) They are the units of transcriptional regulation in prokaryotes.
E) A repressible operon is turned off unless needed.

A) cAMP
B) Lactose
C) Methionine
D) Tryptophan
E) CRP

A) repressible;inducer
B) repressible;transcription factor
C) inducible;inducer
D) inducible;corepressor
E) inducible;transcription factor

A) In transcriptional regulation,only the final product is regulated;thus,it is more efficient.
B) In allosteric regulation,the continued production of enzymes is energetically costly.In transcriptional regulation,it is possible to shut down the production of the enzymes.
C) Allosteric regulation is necessarily slower than transcriptional regulation.
D) Allosteric regulation requires cofactors that are not required by transcriptional regulation.
E) Transcriptional regulation can be inducible or repressible.

A) a plasmid that binds the enzymes for replication.
B) the mRNA that binds to a ribosome.
C) the DNA that binds RNA polymerase.
D) the mRNA that binds tRNAs.
E) the DNA that binds DNA polymerase.

A) They require RNA polymerase from the host bacterium in order to be transcribed.
B) Some of them stimulate the production of late genes.
C) At least one early gene produces the capsid proteins.
D) At least one early gene shuts down expression of the host genome.
E) They stimulate viral genome replication.

A) can control the operon only after it is activated by a corepressor.
B) can repress the transcription of the operon on its own.
C) is a molecule made from the operon.
D) binds to the mRNA.
E) must first be made negative to control the operon.

A) positive
B) inducible
C) repressible
D) negative
E) positive-negative

A) inducible
B) positive
C) negative
D) repressible
E) positive-negative

A) Both systems control primarily catabolic pathways.
B) In both systems,the final product of the pathway usually regulates transcription of the genes that will encode enzymes that produce it.
C) In both systems,the regulatory molecules function by binding to the operator.
D) Blocking transcription is the default state for both systems.
E) Both systems control primarily anabolic pathways.

A) The prokaryotic RNA polymerase can bind directly to DNA,whereas the eukaryotic polymerase cannot.
B) The eukaryotic RNA polymerase can bind directly to DNA,whereas the prokaryotic polymerase cannot.
C) Global gene regulation is absent in prokaryotes.
D) DNA-protein interactions are involved in gene regulation only in prokaryotes.
E) Sigma factors are absent in eukaryotes.

A) integrate its DNA into the host cell chromosome.
B) excise its DNA from the host cell chromosome.
C) lyse or cut open the host cell.
D) induce point mutations in the host cell.
E) activate the host cell DNA.

A) RNA sequences that bind to RNA polymerase.
B) proteins that bind to the DNA promoter sequence.
C) DNA sequences that regulate transcription.
D) polysaccharides that bind to the transcripts.
E) factors that bind to enhancers.

A) promoters.
B) inducers.
C) transcription factors present.
D) silencers.
E) enhancers.

A) arbovirus.
B) double-stranded DNA virus.
C) single-stranded DNA virus.
D) porcine virus.
E) retrovirus.

A) methylates the DNA
B) demethylates the DNA
C) changes the shape of the DNA
D) produces signals that attract other transcription factors
E) blocks the RNA polymerase binding site

A) Protein
B) Enzyme
C) DNA
D) Carbohydrate
E) Lipid

A) increases the stability of a specific mRNA.
B) stimulates transcription of a specific gene.
C) stimulates transcription of all genes.
D) stimulates splicing of a specific mRNA.
E) stimulates splicing of all mRNAs.

A) They are both retroviruses.
B) They both (at least initially)rely on the host RNA polymerase to transcribe their genes.
C) They both produce capsids.
D) They are both proviruses.
E) They can both replicate themselves outside a host cell.

A) activator sequence necessary for proper translation.
B) general transcription factor.
C) enhancer consensus sequence.
D) sequence close to the promoter region of many genes.
E) repressor sequence.

A) are located closer together on the chromosome.
B) do not alter their expression levels due to transcription factor binding.
C) are not coordinately regulated.
D) are located farther apart on the chromosome.
E) do not respond to changes in environmental conditions.

A) a transcription factor.
B) coordinated gene expression.
C) a strategy for increasing water intake.
D) a response resulting from a single transcription factor.
E) an inhibitory element.

A) TATA box.
B) enhancer.
C) operon.
D) promoter.
E) consensus sequence.

A) sequences bind the same groups of transcription factors.
B) genes are not regulated together.
C) genes have the dehydration response element (DRE).
D) genes are regulated by maternal effect transcription factors.
E) sequences code for homologous proteins.

A) A specific gene near the silencer will be transcribed all the time,even when it is not needed.
B) There will be a large decrease in transcription rates for most genes.
C) There will be a large increase in transcription rates for most genes.
D) The rate of transcription of a specific gene located near the silencer will be reduced,even when it is needed the most.
E) Transcription will be terminated prematurely.

A) is made of DNA.
B) binds to the enhancer region to block transcription.
C) is located both upstream and downstream from the promoter.
D) binds to the operator to block RNA polymerase.
E) binds to a repressor protein to reduce transcription rates.

A) a promoter.
B) an enzyme.
C) part of the TATA box.
D) a promoter and a transcription factor.
E) a protein and a transcription factor.

A) binding of RNA polymerase to the promoter.
B) binding of only one transcription factor.
C) capping of mRNA.
D) addition of a poly-A tail to mRNA.
E) blocking of the TATA box by a repressor.

A) It is the first transcription factor to bind to the TATA box.
B) Its shape changes after it binds to the TATA box.
C) Its binding to DNA changes the shape of the DNA.
D) It attracts other transcription factors to the transcription initiation complex.
E) It must bind RNA polymerase II before binding to the TATA box.

A) Groups of eukaryotic genes are likely to be regulated together,whereas each prokaryotic gene is usually regulated separately.
B) Groups of prokaryotic genes are likely to be regulated together,whereas each eukaryotic gene is usually regulated separately.
C) Prokaryotes have more classes of RNA polymerase than eukaryotes do.
D) Only prokaryotes have global gene regulation.
E) Only eukaryotes have global gene regulation.

A) Specific transcription factors are found only in multicellular animals,whereas general transcription factors are found in most eukaryotes.
B) Specific transcription factors are found only in multicellular plants,whereas general transcription factors are found in most eukaryotes.
C) Specific transcription factors bind regulatory sequences more tightly than general transcription factors do.
D) Specific transcription factors bind to regulatory sequences of fewer genes than general transcription factors do.
E) Specific transcription factors bind regulatory sequences less tightly than general transcription factors do.

A) binds to the enhancer region to block transcription.
B) is made of RNA.
C) binds to an activator protein to increase transcription rates.
D) is a carbohydrate.
E) is an enzyme.

A) different genomic imprinting in the two individuals.
B) different alternative splicing in the two individuals.
C) environmental differences that they experienced as adults.
D) different levels of histone acetyltransferase in the two individuals.
E) differences in their experiences in utero.

A) be able to decrease transcription of a gene.
B) be able to increase transcription of a gene.
C) be passed on from one generation to the next.
D) coordinate regulation across different genes.
E) produce microRNA.

A) DNA ligase
B) Maintenance methylase
C) Histone deacetylase
D) Maintenance deacetylase
E) DNA prophase

A) lighter;more
B) lighter;less
C) darker;more
D) darker;less
E) darker;just as

A) marks the parental origin of alleles.
B) explains why euchromatin and heterochromatin are different.
C) explains differences in the epigenomes of adult monozgotic twins.
D) alters the DNA sequence.
E) is not found in mammals.

A) methylation patterns become more similar over time.
B) methylation patterns become less similar over time.
C) the environment does not have a large influence on the epigenome.
D) methylation patterns do not change over time.
E) methylation patterns have no effect on gene expression.

A) more;increases
B) more;decreases
C) less;increases
D) less;has no effect on
E) less;decreases

A) methylation.
B) coordinate regulation.
C) alternative splicing.
D) induction.
E) demethylation.

A) a component of a cell's negative regulation against HIV.
B) a co-receptor that allows HIV to enter cells.
C) a protein used by HIV to evade host cell defenses.
D) a protein produced by HIV that interferes with transcription of host genes.
E) a protein used by host cells to promote HIV integration.

A) the cells are in meiotic prophase.
B) all of the chromatin in these cells is inactive.
C) the DNA in these cells has replicated itself.
D) the cells are not transcribing any genes.
E) the cells came from a female rat.

A) greater;an increase
B) greater;a decrease
C) reduced;an increase
D) reduced;no change
E) reduced;a decrease

A) more initiation of transcription.
B) less initiation of transcription.
C) the termination of more partial transcripts,and thus the making of fewer complete transcripts.
D) the termination of fewer partial transcripts,and thus the making of more complete transcripts.
E) a reduction in the stability of complete transcripts.

A) One type of epigenetic change occurs via DNA methylation.
B) One type of epigenetic change occurs via chromosomal protein alterations.
C) Epigenetic changes can lead to gene expression changes.
D) Epigenetic changes do not change the DNA sequence.
E) Epigenetic changes cannot be inherited.

A) no;Barr bodies do not form in males
B) one;the Barr body is the active X chromosome
C) one;the Barr body is the inactive X chromosome
D) two;these males have two X chromosomes
E) three;these males have three sex chromosomes

A) X chromosome inactivation.
B) cell death.
C) genomic imprinting.
D) posttranslational control of eukaryotic gene expression.
E) a stress response.

A) heavily;low to no
B) heavily;high
C) lightly;high
D) variably;high
E) lightly;low

A) A mutation that changes adenine to guanine
B) Methylation of a cytosine
C) The binding of a transcription factor to a sequence of DNA
D) The mutation of an activator binding site
E) The mutation of a repressor binding site

A) through alternative splicing.
B) through the attachment of ubiquitin.
C) through the alternation of nucleotides.
D) by acetylation and deacetylation.
E) through the insertion of nucleotides.

A) the small number of genes in the human genome.
B) why there are more mRNAs than there are human genes.
C) the great variety in proteins.
D) why different proteins can be made from the same genes.
E) All of the above

A) histone deacetylase
B) maintenance methylase
C) DNA methyltransferase
D) histone acetyltransferase
E) RNA polymerase