Deck 10: Analyzing Genomic Variation

A) beta-galactosidase.
B) a random region of DNA.
C) the cis-acting regulatory DNA sequence.
D) X-gal.
E) the coding region of the gene being studied.

A) the DNA sequences that are important for regulating gene expression levels.
B) the effects on cell function of expression of heterologous proteins.
C) colorimetric assays.
D) protein-protein interactions.
E) Western blots.

A) promoter
B) terminator
C) enhancer
D) regulator
E) initiator

A) They contain the TATA box regulatory element.
B) They may be located upstream of a TATA box.
C) They can be more than 10 kilobases from the gene they regulate.
D) They may increase or decrease gene transcription levels.
E) They may contain multiple regulatory elements.

A) an antibody that recognizes specific chromatin structures
B) an antibody that recognizes a nucleosome
C) an antibody that recognizes a transcription factor of interest
D) an antibody that recognizes the DNA cis-element of interest
E) an antibody that recognizes the promoter of interest

A) kinase activity
B) DNA binding
C) mRNA splicing
D) DNA replication
E) methylation

A) ABP
B) Zinc-finger
C) Basolateral
D) Leucine zipper
E) Medial cleft

A) the reporter gene
B) cis-acting DNA elements
C) X-gal coding sequence
D) RNA polymerase II gene
E) the introns of the reporter gene

A) transcriptional machinery controls compaction and decompaction of chromatin.
B) the mRNA produced can undergo alternative splicing.
C) both prokaryotic and eukaryotic proteins have identical affinities for DNA.
D) both are contained within the cell nucleus.
E) both are regulated by attachment of proteins to DNA adjacent to the gene being transcribed.

A) DNA polymerases.
B) tumor suppressors.
C) enhancers.
D) transcription factors.
E) promoter elements.

A) dsRNA
B) mRNA
C) tRNA
D) snRNA
E) rRNA

A) repressor.
B) activator.
C) promoter.
D) enhancer.
E) initiator.

A) cross-reacting.
B) cis-acting.
C) trans-acting.
D) origins of transcription.
E) transcription factors.

A) Promoter elements
B) Terminator elements
C) Enhancer elements
D) Regulator elements
E) Initiator elements

A) DNA pol II.
B) DNA pol III.
C) RNA pol I.
D) RNA pol II.
E) RNA pol III.

A) TATAs
B) DNA-BPs
C) TAFs
D) Jun and Fos
E) Sxl and string

A) termination of replication.
B) transport of mRNA to the cytoplasm.
C) initiation of transcription.
D) alternative splicing.
E) regulation of translation.

A) initiator.
B) activator.
C) repressor.
D) enhancer.
E) super-repressor.

A) repress transcription initiation of a particular gene.
B) assist in associating RNA polymerase with the promoter element.
C) increase transcription by binding enhancer sequences.
D) activate RNA synthesis at origins of replication.
E) regulate activity of DNA polymerase II.

A) Genomic imprinting
B) Spermatogenesis
C) Heterodimerization
D) Homodimerization
E) Gender-specific RNA stability

A) hyperactivation of transcription.
B) suppression of progression through metaphase.
C) DNA replication.
D) transcriptional silencing.
E) reduced cell size.

A) they are free of histones.
B) they are maintained as chromatin.
C) the nuclei in which they are contained enter prophase.
D) a cell is in G₀.
E) found at a recombination hotspot.

A) The repressor associates with a promoter element,blocking RNA polymerase from binding promoter element.
B) The repressor binds to the activation domain of an activator,eliminating its ability to increase transcription.
C) The repressor binds to DNA-binding domain of an activator,eliminating its ability to associate with enhancer.
D) The repressor binds to a DNA sequence in an enhancer,eliminating access to sequence by activator.
E) The repressor binds to RNA polymerase II,blocking its ability to associate with promoter element.

A) No transcription occurs in this region of the chromosome.
B) The chromatin is in an open state and available for transcription.
C) Transcription terminates at this site.
D) It indicates a region devoid of (lacking)genes.
E) The DNA is highly methylated.

A) Myc has a higher affinity for Max than Max has for Max.
B) Myc more tightly associates with DNA,thus recruiting Max monomers to the enhancer.
C) The enhancer element being regulated only associates with Myc/Max heterodimers.
D) Max is rapidly degraded in the presence of Myc.
E) Myc/Myc homodimers are rapidly degraded in the presence of Max.

A) monomers.
B) oligomers.
C) heterodimers.
D) homodimers.
E) diplomers.

A) mRNA folding.
B) transcriptional silencing.
C) transcriptional activation.
D) basal transcription.
E) initiation of replication.

A) enhancer trap.
B) replication origin.
C) Mendelian enhancer.
D) mutant chromosome.
E) epigenetic condition.

A) transcriptosome
B) regulosome
C) nucleosome
D) enhanceosome
E) spliceosome

A) Jun/Jun
B) Fos/Jun
C) Max/Max
D) Myc/Myc
E) Myc/Max

A) hyperoxidation.
B) methylation.
C) dephosphorylation.
D) phosphorylation.
E) integration.

A) mediate the physical association of two polypeptides.
B) anchor transcriptional activator proteins to enhancer sequences.
C) release leucines from misfolded transcription factors.
D) integrate leucines and isoleucines into newly translated transcriptional activators.
E) open up proteins after transcription.

A) in G₀.
B) virally infected.
C) proliferating.
D) cancerous.
E) dormant.

A) sax
B) max
C) sxl
D) myc
E) SIR

A) unable to undergo transcription.
B) associated with DNA polymerase.
C) unable to undergo replication.
D) of the Z-DNA form.
E) free of associated proteins.

A) Deregulators
B) Depleters
C) Regulators
D) Repressors
E) TBPs

A) transcriptional repressor.
B) promoter element.
C) enhancer element.
D) transcriptional activator.
E) RNA polymerase.

A) increasing basal transcription rates.
B) decreasing basal transcription rates.
C) increasing transcription of a few genes,while not influencing most others.
D) decreasing transcription of a few genes,while not influencing most others.
E) increasing transcription of some genes and decreasing transcription of others.

A) associating with Ras to form heterodimers.
B) forming Myc-Myc homodimers.
C) associating with Max to form heterodimers.
D) dissociating with Fos Jun heterodimers.
E) enhancing formation of Max-Max homodimers.

A) sxl functions as a repressor of male-specific dosage-compensation genes.
B) recessive mutations indicate an increase in sxl activity.
C) these mutations are the result of a loss of both X chromosomes.
D) sxl is required for transcription of male-specific genes.
E) recessive mutations are always lethal.

A) Monozygotic twins have identical CpG methylation patterns
B) CpG methylation patterns are more similar in dizygotic twins than in monozygotic twins
C) Twin studies are not useful in methylation because environment overwhelms heritability in epigenetics
D) Dizygotic twins have identical CpG methylation patterns
E) CpG methylation patterns are more similar in monozygotic twins than in dizygotic twins

A) lack of an open reading frame (ORF).
B) 5' GTP cap and 3' poly A tail.
C) stem-loop structures.
D) translation on ribosomes.
E) RNA pol II promoter.

A) dephosphorylation
B) phosphorylation
C) degradation
D) sensitization
E) deamination.

A) the binding of transcription factors may change
B) the posttranslational modification may change
C) the ubiquitination of the protein may change
D) the half-life of the mRNA may change
E) the rate of transcription may be decreased

A) it is recessive to all other alleles
B) it is metastable
C) it is an epiallele
D) it is caused by a retrotransposon
E) it is responsible for phenotypic variation

A) It is transcribed by RNA polymerase II.
B) It is exported from the nucleus.
C) It contains stem-loop structures.
D) It may contain introns.
E) It is a substrate for Drosha in animal cells.

A) ubiquitination
B) methylation
C) phosphorylation
D) dephosphorylation
E) covalent attachment of small molecules to protein.

A) RISC
B) Drosha
C) RNA polymerase I
D) Dicer
E) pre-miRNA.