Deck 11: Gene Expression: From Transcription to Translation

A)a gene carries the information to build lipids
B)a gene carries the information to build carbohydrates
C)a gene carries the information for the construction of a particular enzyme
D)a gene is made of RNA
E)a gene is made of DNA

A)DNA-dependent DNA polymerase
B)DNA-dependent RNA polymerase
C)RNA-dependent RNA polymerase
D)RNA-dependent DNA polymerase
E)ribonuclease

A)urine turning dark upon exposure to the air
B)mental retardation
C)paralysis
D)urine smelling and tasting like maple syrup
E)high fevers

A)terminator
B)operator
C)promoter
D)enhancer
E)silencer

A)0
B)+1
C)-1
D)+2
E)-2

A)the One Gene - One Enzyme hypothesis
B)the One Gene - One Polypeptide hypothesis
C)the One Polypeptide - One Enzyme hypothesis
D)the One Polypeptide - One Gene hypothesis
E)the One Gene - Two Gene hypothesis

A)Charles Darwin
B)Archibald Garrod
C)George Beadle
D)Vernon Ingram
E)James Watson

A)an RNA having a sequence complementary to the mRNA of the targeted protein
B)an RNA having the sequence of the mRNA that encoded the protein being targeted
C)a small RNA with a clover shape
D)an RNA with catalytic activity
E)an RNA generally found in ribosomes that forges the peptide bond

A)deadly diseases
B)inborn errors of transcription
C)homogentisms
D)errors
E)inborn errors of metabolism

A)nitrogenous bases
B)deoxyribonucleoside triphosphates (dNTPs)
C)ribonucleoside triphosphates (NTPs)
D)ribose sugars
E)ribosomes

A)phenylalanine
B)tyrosine
C)homogentisic acid
D)asparagine
E)pantothenic acid

A)The enzyme does not work in reverse.
B)Polynucleotides are too stable to depolymerize.
C)H bonds holding the strands together are too strong.
D)Nucleic acid synthesis is coupled to the highly exergonic pyrophosphate hydrolysis.
E)There is a large uptake of free energy.

A)familiar sequences
B)conserved sequences
C)consensus sequences
D)avatars
E)consensons

A)Pribnow box,TATAAT,transcription
B)Pribnow box,TTGACA,transcription
C)Pribnow box,TATAAT,translation
D)Portnoy box,TATAAT,transcription
E)Portnoy box,TATAAT,translation

A)mustard gas
B)irradiation with ultraviolet light
C)fluorescent dyes
D)ethidium bromide
E)Coomassie blue

A)It was totally wrong.
B)Genes can be spliced differently to generate a variety of related polypeptides.
C)Enzymes sometimes consist of more than one polypeptide,each of which is coded for by its own gene.
D)Enzymes actually code for genes.
E)Polypeptides code for genes.

A)Transcription begins.
B)The core enzyme continues synthesis.
C)The core enzyme discontinues synthesis.
D)Transcription terminates.
E)The core enzyme backs up 25 nucleotides.

A)3' to 5' direction
B)5' to 3' direction
C)N-terminal to C-terminal direction
D)C-terminal to N-terminal direction
E)N-terminal to 3' direction

A)tightly
B)loosely
C)angularly
D)rapidly
E)linearly

A)tRNA precursors
B)mRNA precursors
C)rRNA precursors
D)snoRNA precursors
E)mature snRNAs

A)tandem array with spacers
B)continuous genes
C)tandem array without spacers
D)4 introns between each protein
E)quartile array with duplex spacers

A)migrates more rapidly through a field of force during centrifugation
B)migrates less rapidly through a field of force during centrifugation
C)migrates more rapidly through a field of force during gel filtration
D)migrates more rapidly through a field of force during SDS polyacrylamide gel electrophoresis
E)migrates less rapidly through a field of force during SDS polyacrylamide gel electrophoresis

A)terminators
B)nucleoli
C)nucleosomes
D)ribostores
E)telomeres

A)45S RNA
B)28S RNA
C)18S RNA
D)5)8S RNA
E)65S RNA

A)endosome
B)exosome
C)nucleosome
D)heliosome
E)degradosome

A)less than 20%
B)more than 90%
C)more than 80%
D)exactly 75%
E)36.5%

A)sedimentation unit
B)transcription unit
C)translation unit
D)coding unit
E)transcriptosome

A)It is near the longest nascent transcripts.
B)It is near the middle of the Christmas tree.
C)It is near the shortest nascent transcripts.
D)It is always 40 µm from the center of the Christmas tree.
E)It is near the centromere.

A)within their own genes
B)within the exons of other genes
C)within the telomeres
D)within the intervening sequences of other genes
E)within the intervening sequences of their own genes

A)hnRNAs
B)snoRNAs
C)mRNAs
D)rRNAs
E)hmRNAs

A)dysplasia
B)keratinosis
C)dyskeratosis
D)lupus erythematosus
E)dyspareunia

A)at the gene's 3' end
B)within the coding section of the gene rather than in the 5' flank
C)at the 5' end of the gene
D)far downstream of the gene
E)far upstream of the gene

A)spacelies
B)nontranscribed spacers
C)nontranslated spacers
D)untranslated spacers
E)naked genes

A)highly repetitive DNA
B)moderately repetitive DNA
C)unique sequence DNA
D)single copy DNA
E)single-stranded DNA

A)in larger RNAs in the cytoplasm
B)in smaller RNAs in the mitochondria
C)in smaller RNAs in the cytoplasm
D)in larger RNAs in the mitochondria
E)in moderately sized RNAs in the Golgi complex

A)tDNA
B)transferase
C)rDNA
D)t clusters
E)tDNase

A)exons,structural genes
B)introns,ribosome assembly and function
C)exons,ribosome assembly and function
D)introns,structural genes
E)introns,RNA synthesis

A)pseudouridine residues and thymidine residues
B)thymidine residues and methylated nucleotides
C)pseudouridine residues and methylated nucleotides
D)pseudouridines and pseudocytosines
E)methylated nucleotides and pseudocytosines

A)posttranslationally
B)pretranscriptionally
C)posttranscriptionally
D)postmitotically
E)premitotically

A)RNA activation
B)RNA ascension
C)RNA silencing
D)RNA sussuration
E)RNA quieting

A)It cleaves the target mRNA.
B)It stabilizes the target mRNA.
C)It destabilizes the target mRNA's binding to its associated proteins.
D)It guides the RISC that cleaves the target mRNA to that target mRNA due to its complementarity to that molecule.
E)It activates the RISC complex ribonuclease.

A)stop,deficiency,phenotype
B)enhance,deficiency,phenotype
C)stop,deficiency,genotype
D)enhance,overexpression,phenotype
E)stop,overexpression,genotype

A)They contain a continuous nucleotide sequence encoding a specific polypeptide.
B)They are found in the cytoplasm and inside the Golgi complex.
C)They are attached to ribosomes when they are translated.
D)Most have a significant noncoding segment that does not direct assembly of amino acids.
E)Eukaryotic mRNAs have special modifications at their 5' and 3' termini.

A)RNA polymerase I
B)RNA polymerase II
C)RNA polymerase III
D)reverse transcriptase
E)general transcription factors

A)the active strand
B)the passenger strand
C)the siRNA strand
D)the pedestrian strand
E)the silencer strand

A)transcription
B)alternative splicing
C)transposition
D)hybridization
E)exon shuffling

A)on the N-terminal end of the largest RNA polymerase II subunit
B)on the central 20 amino acids of the largest RNA polymerase II subunit
C)on the 3' end of the largest RNA polymerase II subunit
D)on the 5' end of the largest RNA polymerase II subunit
E)in the carboxyl-terminal domain (CTD)of the largest RNA polymerase II subunit

A)langolier
B)lanyard
C)lariat
D)lasso
E)elsesser

A)The same transcription factors are required for the accurate initiation of transcription of a diverse array of genes in a wide variety of different organisms.
B)The same transcription factors are required for the accurate initiation of translation of a diverse array of genes in a wide variety of different organisms.
C)The same transcription factors are required for the accurate termination of transcription of a diverse array of genes in a wide variety of different organisms.
D)The same transcription factors are required for the accurate termination of translation of a diverse array of genes in a wide variety of different organisms.
E)They are called "general" because they outrank "major."

A)splicer
B)acrosome
C)spliceosome
D)splicing body
E)splice engine

A)3'
B)5'
C)N-terminal
D)C-terminal
E)internal

A)dsRNAs are not produced by the cell's normal genetic activities.
B)dsRNAs are produced by the cell's normal genetic activities.
C)dsRNAs adversely affect mitochondria.
D)dsRNAs could cause degradation of nuclear DNA.
E)dsRNAs have a very abnormal interaction with proteins.

A)riboendonuclease
B)Dicer ribonuclease
C)deoxyribonuclease
D)RNA helicase
E)reverse transcriptase

A)a G protein
B)RNA polymerase II
C)RNA polymerase IV
D)peptidyltransferase
E)DNA helicase

A)days or weeks long
B)minutes long
C)seconds long
D)hours long
E)years long

A)RNA
B)proteins
C)polypeptides
D)DNA
E)both proteins and polypeptides

A)The ribonuclease slicer directs the RISC to the cleavage site.
B)The single-stranded siRNA is complementary to the target mRNA and directs the RISC to it.
C)The passenger strand acts like a guide to direct the RISC to the target.
D)The siRNA is complementary to the slicer ribonuclease.
E)The siRNA is magnetically attracted to the target mRNA.

A)CTD
B)tRNA
C)corticosteroid binding protein
D)TBP
E)PBT

A)poly(A)tail,methylated guanosine cap
B)poly(U)tail,methylated guanosine cap
C)methylated guanosine cap,poly(A)tail
D)poly(A)tail,sulfonated guanosine cap
E)methylated guanosine cap,poly(U)tail

A)in the stems
B)in the loops
C)at the 3' end
D)at the 5' end
E)in double-stranded regions

A)Drosha,pre-miRNA
B)Drosha,pri-miRNA
C)Dicer,pre-miRNA
D)Dicer,pri-miRNA
E)Slicer,pre-miRNA

A)piRNAs are longer than si/miRNAs.
B)The majority of mammalian piRNAs can be mapped to a small number of huge genomic loci,unlike si/mi RNAs.
C)The formation of piRNAs does not involve the formation of dsRNA precursors,unlike si/mi RNAs.
D)Formation of piRNAs does not involve cleavage by Dicer ribonuclease,but instead it depends on the endonuclease activity of the PIWI protein acting on a long,single stranded primary transcript.
E)All of these are correct.

A)the nucleus
B)the cytoplasm
C)the mitochondria
D)the plasma membrane
E)the lysosome

A)slicer
B)Mincer
C)an Argonaute protein
D)riscin
E)ribonuclease

A)20
B)3
C)64
D)61
E)21

A)RNA polymerase
B)reverse transcriptase
C)Dicer ribonuclease
D)DNA polymerase
E)Mincer ribonuclease

A)All proteins looked the same.
B)All proteins were made of amino acids.
C)He noted that the base composition of the DNAs of various bacteria varied greatly while the amino acid composition of their proteins varied very little overall.
D)He noted that the base composition of the DNAs of various bacteria varied little while the amino acid composition of their proteins varied greatly overall.
E)The code was non-overlapping.

A)DNA insertions
B)DNA deletions
C)chromosome rearrangements
D)RNA interference
E)genome editing

A)siRNA,DNA
B)siRNA,RNA
C)dsDNA,RNA
D)sgRNA,RNA
E)sgRNA,DNA

A)the 3' untranslated region of specific mRNAs produced by the organism
B)the 5' untranslated region of specific mRNAs produced by the organism
C)the promoter of specific genes
D)the poly(A)tail of specific mRNAs
E)the 5'-methylguanosine cap of the mRNA

A)Mutant proteins whose genes experience a change in only one nucleotide,have a corresponding change in 3 consecutive amino acids.
B)Mutant proteins whose genes experience a change in only one nucleotide,have a corresponding change in only 1 amino acid.
C)Mutant proteins are greatly increased in length relative to the gene coding for them.
D)Mutant proteins are greatly decreased in length relative to the gene coding for them.
E)Mutant proteins whose genes experience a change in only one nucleotide,have a corresponding change in 6 consecutive amino acids.

A)They aid in fertilization.
B)They may be the mechanism of defense against the movement of transposable elements in the female germ cell line.
C)They may be the mechanism of defense against the movement of chromosomes in the female germ cell line.
D)They play a role in the regulation of meiosis.
E)They play a role in the regulation of oogenesis.

A)exo-siRNAs
B)endo-siRNAs
C)endoRNAs
D)mamma-siRNAs
E)oo-siRNAs

A)regenerate
B)degenerate
C)overlapping
D)nonoverlapping
E)nonspecific

A)The genetic code is the same everywhere in the Universe.
B)All of the organisms on Earth use the same genetic code with only minor variations.
C)The genetic code is found in all organisms but varies extensively.
D)The genetic code is minimal.
E)The genetic code is multiphasic.

A)20
B)3
C)64
D)61
E)21

A)They bind to amino acids.
B)They bind to other tRNAs.
C)They bind to mRNAs.
D)They serve as potential recognition sites for various proteins.
E)They increase the buoyant density of tRNAs.

A)1
B)2
C)3
D)4
E)6

A)transcription
B)transition
C)transubstantiation
D)translation
E)transition state