Deck 15: Genes and How They Work

A)codons.
B)nucleotides.
C)proteins.
D)histones.
E)complementary bases.

A)replication
B)transcription
C)initiation
D)condensation

A)termination
B)translation
C)splicing
D)capping
E)elongation

A)mRNA.
B)tRNA.
C)snRNA.
D)rRNA.
E)miRNA.

A)introns
B)exons
C)codons
D)spacers
E)spliceosomes

A)ribosomes.
B)Golgi bodies.
C)lysosomes.
D)centrosomes.
E)mitochondria.

A)mRNA splicing
B)translation
C)transcription
D)gene sequencing
E)termination

A)proteins
B)nucleotides
C)codons
D)amino acids

A)thymine
B)cytosine
C)guanine
D)uracil

A)alleles
B)codons
C)genes
D)polypeptides

A)nucleotides
B)amino acids
C)polypeptides
D)fatty acids

A)transcription
B)translation
C)replication
D)posttranscriptional modification

A)nucleotides.
B)nucleic acids.
C)amino acids.
D)genes.
E)codons.

A)Watson and Crick.
B)Griffith.
C)Garrod.
D)Franklin.
E)Beadle and Tatum.

A)expression
B)replication
C)modification
D)regulation

A)coding
B)noncoding
C)template
D)complementary

A)protein
B)ribosomal
C)translation
D)genetic
E)amino acid

A)5' cap
B)introsome
C)ribosome
D)spliceosome
E)3' poly-A tail

A)initiation site
B)primer
C)inducer
D)promoter
E)transcription bubble

A)replication
B)sequencing
C)transcription
D)translocation
E)translation

A)codons.
B)anticodons.
C)exons.
D)introns.
E)templates.

A)in the nucleoid.
B)on ribosomes.
C)on the plasma membrane.
D)on mesosomes.
E)on chromosomes

A)tRNA.
B)release factors.
C)anticodons.
D)translation terminators.
E)aminoacyl-tRNA synthetases

A)DNA.
B)the large ribosomal subunit.
C)mRNA.
D)tRNA.
E)the spliceosome.

A)the holoenzyme.
B)the core polymerase.
C)RNA polymerase II.
D)RNA polymerase III.
E)the sigma subunit.

A)anticodons.
B)introns.
C)exons.
D)nucleosomes.
E)noncodons.

A)There is no punctuation or spacing between codons.
B)Nucleotides are always read in groups of three.
C)Every codon codes for one amino acid.
D)Some amino acids are specified by more than one codon.
E)The genetic code is almost universal,but not quite.

A)transcription.
B)initiation.
C)replication.
D)translocation.
E)activation.

A)a small ribosomal subunit.
B)mRNA.
C)tRNA charged with N-formylmethionine.
D)RNA polymerase.
E)initiation factors.

A)RNA and DNA.
B)RNA and proteins.
C)RNA and sugars.
D)DNA and proteins.
E)nucleosomes and RNA.

A)hydrogen
B)hydrophobic
C)terminal
D)phosphodiester
E)peptide

A)intron.
B)exon.
C)codon.
D)initiation factor.
E)anticodon.

A)one
B)two
C)three
D)four
E)64

A)removal of exons from the pre-mRNA.
B)addition of a 5' cap.
C)addition of a 3' poly-A tail
D)pre-mRNA splicing by the spliceosome.

A)on the plasma membrane.
B)inside the nucleus.
C)on ribosomes.
D)on the nuclear membrane.
E)on spliceosomes.

A)E
B)P
C)A
D)termination
E)release

A)on the surface of the nuclear membrane.
B)on ribosomes.
C)on spliceosomes.
D)inside the nucleus.
E)on the surface of the plasma membrane.

A)four
B)12
C)16
D)61
E)64

A)aminoacyl-tRNA synthetases.
B)hydrogen bonds.
C)anticodons.
D)deactivating enzymes.
E)initiation factors.

A)Because the 5' base on the tRNA anticodon has some flexibility (wobble); thus,some tRNA anticodons can pair with more than one mRNA codon.
B)Although 61 different codons code for amino acids,any given cell contains fewer than 61.
C)Because the 5' base on the mRNA codon has some flexibility (wobble); thus,some mRNA codons can pair with more than one tRNA anticodon.
D)Because each amino acid is coded for by just one codon.

A)releasing a tRNA molecule from the ribosome.
B)joining an amino acid to a tRNA molecule.
C)joining an amino acid to the next amino acid in the chain.
D)joining a tRNA molecule to the ribosome.
E)moving the ribosome along the mRNA molecule.

A)poly-A polymerase.
B)mRNA.
C)tRNA.
D)the ribosome.
E)the template strand of DNA.

A)the transcription bubble is formed
B)RNA polymerase binds to the promoter
C)the DNA double helix is unwound
D)RNA polymerase synthesizes a short primer
E)transcription factors bind to the TATA box sequence

A)3' UAGCGAGG 5'
B)3' TAGCGAGG 5'
C)5' UAGCGAGG 3'
D)5' TAGCGAGG 3'
E)5' AUCGCUCC 3'

A)RNA synthetase
B)RNA polymerase II
C)RNA polymerase III
D)transcription factors
E)RNA polymerase

A)start codon
B)stop codon
C)promoter
D)release factor
E)transcription factor

A)proteins→ RNA→ DNA.
B)RNA→ DNA→ proteins.
C)DNA→ proteins→ RNA.
D)DNA→ RNA→ proteins.

A)in the cytoplasm.
B)at the ribosome.
C)inside the nucleus.
D)as they pass through the nuclear membrane.
E)at the transcription bubble.

A)DNA
B)RNA polymerase
C)miRNA
D)rRNA
E)tRNA

A)AUG CGU.
B)ATG CGT.
C)UAC GCA.
D)UAG CGU.

A)The product of translation,called the primary transcript,is cut and some pieces are joined back together to form the mature mRNA.
B)The product of transcription,called the primary transcript,is cut and some pieces are joined back together to form the mature tRNA.
C)The product of transcription,called the secondary transcript,is cut and some pieces are joined back together to form the mature mRNA.
D)The product of transcription,called the primary transcript,is cut and some pieces are joined back together to form the mature mRNA.
E)The product of transcription,called the primary transcript,is cut and all pieces are joined back together to form the mature mRNA.

A)A lariat would not form.
B)snRNPs would not base-pair with the 5' end of the intron.
C)A 3' poly A tail would not be added to the transcript.
D)A 5' cap would not be added to the transcript.

A)In prokaryotes,translation of the mRNA begins before transcription is complete.In eukaryotes,transcription and modification of the mRNA is completed before translation begins.
B)In prokaryotes,genes are transcribed directly into polypeptides.In eukaryotes,genes are transcribed into RNA which is used to assemble polypeptides.
C)In prokaryotes,translation occurs before genes are transcribed into mRNA.In eukaryotes,genes are transcribed into mRNA which is then translated into polypeptides.
D)In prokaryotes,introns are removed before genes are transcribed into mRNA.In eukaryotes,introns are removed after genes are transcribed into mRNA.

A)a promoter.
B)enzymes.
C)a primer.
D)a DNA template strand.

A)There is some flexibility in pairing between the 5' base of the codon and the 3' base of the anticodon.
B)There is some flexibility in pairing between the middle base of the codon and the middle base of the anticodon.
C)There is some flexibility in pairing between the 3' base of the codon and the 5' base of the anticodon.
D)There is some flexibility in pairing between all 3 bases of the codon and all 3 bases of the anticodon.

A)snRNPs.
B)miRNAs.
C)SRP RNAs.
D)the lariat.
E)the branch point.

A)DNA
B)RNA polymerase
C)mRNA
D)rRNA
E)tRNA

A)THE FAT RAT ATE THE RED CAT
B)THE CAT ATE THE RED RAT
C)THE FAC ATA TET HER EDR AT
D)THE FAT CAT ATE THE RED RAT

A)two
B)three
C)four
D)one
E)64

A)The inversion would probably have no effect on gene expression.
B)The gene would not be transcribed because it would be oriented in the wrong direction.
C)The gene would be transcribed in the 3' to 5' direction.
D)The gene would be transcribed normally but the mRNA would be translated in the 3' to 5' direction.

A)AUA codes for isoleucine
B)AAA codes for phenylalanine
C)AAA codes for lysine
D)AAA codes for lysine and AUA codes for isoleucine
E)AAA codes for phenylalanine and AUA codes for isoleucine

A)no effect,since introns are not expressed
B)failure to form a lariat
C)failure of snRNPs to recognize the 5' end of intron
D)no exon shuffling
E)failure of snRNAs to combine with protein and form snRNPs

A)Only RNA polymerase adds new nucleotides to the 3' end of a growing chain.
B)Only RNA polymerase requires a primer.
C)Only DNA polymerase uses a template DNA strand to direct synthesis of a new nucleotide strand.
D)Only DNA polymerase has a proofreading ability.

A)missense mutation.
B)nonsense mutation.
C)frameshift mutation.
D)triplet repeat expansion mutation.

A)poly-A polymerase
B)RNA polymerase III
C)RNA polymerase II
D)RNA polymerase I

A)the core polymerase plus two alpha subunits.
B)the core polymerase plus two beta subunits.
C)the core polymerase plus two alpha subunits,two beta subunits,and a sigma subunit.
D)the core polymerase plus a sigma subunit.
E)two alpha subunits,two beta subunits,and two sigma subunits.

A)The gene that codes for this protein is not transcribed in the pancreas.
B)The transcript is immediately degraded in the pancreas.
C)The transcript receives a 5' cap in the pancreas.
D)Alternative splicing in the pancreas creates a protein missing the domain that the antibody recognizes.
E)The transcript receives a 3' poly-A tail in the pancreas.

A)Rewinding the DNA molecule would be inhibited.
B)Unwinding the DNA molecule would be inhibited.
C)The position of the 5' end of the RNA would be unstable,inhibiting elongation.
D)The position of the 3' end of the RNA would be unstable,inhibiting elongation.
E)The position of the 5' end of the RNA would be unstable,stimulating elongation.

A)It continues to be an accurate description of how genes work.
B)It is oversimplified,especially in eukaryotes.
C)It has been replaced by the more accurate "one-gene/one-enzyme" hypothesis.
D)It was true for fungi like Neurospora,but not for other species.

A)block transcription
B)degrade the mRNA after it is made
C)prevent translation of the mRNA
D)degrade the protein after it is made

A)Binding sites for both the holoenzyme and ATP are provided.
B)Both the location of the start site and the direction of transcription can be established.
C)Binding sites for both the core polymerase and holoenzyme are provided.
D)The transcription bubble can be properly formed.
E)It allows RNA polymerase to distinguish between the template strand and the coding strand of the DNA molecule.

A)A small deletion has removed the nucleotides that code for the signal sequence at the amino terminus of the protein.
B)A missense mutation has caused premature termination during translation of this protein.
C)A chromosomal segment that includes the gene for insulin has been inverted.
D)A two-base deletion near the middle of the gene has altered the reading frame during translation of the protein.
E)A missense mutation has altered the ribosome-binding sequence at the 5' end of the mRNA.

A)There are slight differences in the genetic code for prokaryotes and eukaryotes.
B)Unlike eukaryotes,which have three different RNA polymerases,prokaryotes have a single RNA polymerase.
C)Eukaryotic genes often contain introns while prokaryotic genes do not.
D)Eukaryotic transcripts have a 5' cap while prokaryotic transcripts do not.

A)binding of a transcription factor to the TATA box,followed by recruitment of additional transcription factors and recruitment of RNA polymerase II
B)binding of a transcription factor to the transcription bubble,followed by recruitment of additional transcription factors and recruitment of RNA polymerase III
C)binding of the sigma subunit to the start site followed by recruitment of RNA polymerase II
D)binding of RNA polymerase II to the TATA box,followed by recruitment of transcription factors
E)binding of the sigma subunit to promoter elements at -35 and -10,followed by recruitment of the core polymerase

A)transcription initiation.
B)transcription elongation.
C)transcription termination.
D)translation initiation.
E)translation termination.