Deck 21: Rna Synthesis, processing, and Gene Silencing

A) eukaryotes separate transcription and translation with a nucleus.
B) prokaryotes are often polycistronic.
C) eukaryotes are multicellular organisms.
D) prokaryotes do not add a poly(A) tail.

A) transfer RNA
B) ribosomal RNA
C) small nuclear RNA
D) messenger RNA

A) small nuclear RNA.
B) short interfering RNA.
C) ribosomal RNA.
D) long nc RNA.

A) be a component in protein synthesis, regulate protein synthesis, and be synthesized and function in cell nucleus.
B) catalyze its own synthesis.
C) contain a ribose sugar backbone.
D) be stable to hydrolysis.

A) can fold and hydrogen bond with itself, DNA, proteins, or small molecules to adopt largely modified tertiary structures.
B) is less capable of forming stable H-bonds than DNA.
C) is often shorter than DNA.
D) is largely composed of a phosphate backbone.

A) tRNA
B) siRNA
C) mRNA
D) rRNA

A) short interfering RNA.
B) TERC RNA.
C) small nucleolar RNA.
D) messenger RNA.

A) poly(A) tails
B) exons
C) polycistrons
D) introns

A) presence of simpler nucleotides.
B) presence of a OH group.
C) presence of a OH group.
D) lack of thymine nucleotides.

A) 10; 90
B) 90; 10
C) 50; 10
D) 25; 2

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

A) the tips of chromosomes.
B) the transcription of genomic DNA.
C) the splicing of used mRNA.
D) an infection of viral RNA.

A) splicing by RNaseP enzymes.
B) immediate translation during transcription.
C) addition of 7-methylguanylate cap.
D) removal of exons.

A) RNaseP
B) snRNA
C) reverse transcriptase
D) ribozyme

A) rRNA
B) tRNA
C) mRNA
D) siRNA

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

A) transfer RNA
B) messenger RNA
C) small nuclear RNA
D) micro RNA

A) differentiate the mRNA from the tRNA.
B) facilitate binding and translation by the ribosome.
C) increase mRNA splicing efficiency.
D) signify the start and end of the gene sequence.

A) RNA is single stranded, whereas proteins are not.
B) RNA can H-bond with itself, whereas proteins cannot.
C) RNA mutations can lead to nonfunctioning proteins, whereas protein mutations do not.
D) RNA adopts less defined tertiary structures than proteins.

A) largely conserved.
B) distinct for each gene.
C) capable of binding different promoters.
D) strong binders of DNA polymerase.

A) a primer
B) RNA polymerase
C) initiation factor
D) a ribonucleotide triphosphate (NTP)

A) DNA promoters and RNA polymerase
B) RNA promoters and DNA
C) DNA and RNA
D) transcription factors

A) is a ribozyme.
B) contains as many as five protein subunits in the final functional enzyme.
C) synthesizes all RNA types.
D) has a common core structure resembling that of prokaryotic RNA polymerase.

A) weak promoter
B) -10 and -35 box
C) TATA box
D) strong promoter

A) DNA sequence.
B) promotor region of a gene.
C) location of a gene in DNA.
D) location of a DNA binding protein on DNA.

A) are located before the transcription start site.
B) bind transcription factors.
C) are located after the transcription start site.
D) assist in activating transcription.

A) DNA promoter regions
B) RNA polymerases
C) transcription factors
D) receptor proteins

A) -35 box
B) -5 and -35 box
C) -10 and -35 box
D) -10 box

A) are typically found after the transcription start site.
B) have a single sequence and bind one RNA polymerase type.
C) may bind to both transcription factors and RNA polymerases.
D) are all controlled by a ubiquitous
Factor.

A) They are composed of an analogous
Core.
B) There is a single enzyme type per organism.
C) They make copies of RNA from either DNA or RNA templates.
D) They have the same number of cofactors in prokaryotes and eukaryotes.

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

A) leading
B) coding
C) lagging
D) template

A) gel electrophoresis
B) polymerase chain reaction
C) plasmid ligation
D) cloning

A) require multiple DNA binding regions.
B) are largely conserved across the genome.
C) can stimulate DNA polymerases by direct binding.
D) control translational as well as transcriptional events.

A) can bind to different transcription factors.
B) have a DNA sequence that is significantly different from that of other common promotors.
C) can be easily bound to
Factors.
D) give weak DNA footprinting signals.

A) exons of protein-coding genes.
B) introns of protein-coding genes.
C) non-functional rRNA.
D) protein-coding mRNA.

A) bind tightly to the transcription factors.
B) have
Factors that are larger, more stable proteins.
C) generally result in a higher rate of transcription.
D) are less common in prokaryotes.

A) in the to direction
B) with to phosphodiester linkages
C) in the to direction
D) It depends on whether the sense or antisense strand is transcribed.

A) cuts DNA whenever DNA binding proteins are present.
B) cuts double-stranded DNA by cutting phosphodiester bonds.
C) cuts DNA binding proteins.
D) makes an RNA copy of DNA.

A) occurs in the same manner as prokaryotic transcription.
B) requires the complete unfolding of the gene into single-stranded DNA.
C) requires many more transcription factors than prokaryotic transcription.
D) uses RNA polymerase as well as helicase and primase.

A) DNAzymes.
B) ribozymes.
C) ligases.
D) transferases.

A) addition of a poly(A) tail.
B) removal of exons.
C) directing RNA to the cytoplasm.
D) product phosphorylation.

A) transferase
B) cleavage
C) hydrolysis
D) transesterification

A) intron cleaving versus exon ligating abilities
B) cis versus trans cleaving capabilities
C) linear versus lariat intron products
D) nucleophilic versus electrophilic hydroxyl attacks

A) cleavage of another identical RNA molecule
B) intermolecular cleavage of substrate
C) intramolecular cleavage
D) conserved activity of all enzymes

A) in the initiation phase
B) in the termination phase
C) before the elongation phase
D) during the elongation phase

A) small nuclear ribonucleoprotein
B) RNA only
C) protein
D) mRNA

A) is a cis-acting ribozyme.
B) resembles group II introns in its mechanism and product.
C) performs the same function in prokaryotes and eukaryotes.
D) is a protein enzyme.

A) association of a
Factor with the DNA.
B) RNA with GC stem loop structures.
C) a G-rich region on the DNA.
D) RNA polymerase without the elongation factor.

A) nuclear pore
B) nucleus
C) rough endoplasmic reticulum
D) cytoplasm

A) lack of need for a primer.
B) presence of a transcription bubble.
C) addition of a poly(A) tail.
D) direction of transcription on the DNA template.

A) extent of phosphorylation and dephosphorylation of the RNA polymerase.
B) presence of initiation, elongation, and termination factors binding to RNA polymerase.
C) unwinding the double-stranded DNA.
D) length of the RNA transcript.

A) They have conserved primary sequences.
B) They are not true catalysts.
C) They are transcription factors.
D) They have conserved secondary and tertiary structures.

A) ATP hydrolysis
B) metal ion cofactors
C) guanosine cofactor binding
D) external RNA substrate

A) self-operating enzymes.
B) enzymes that operate on a target molecule.
C) intermolecular-operating enzymes.
D) enzymes that operate on other enzymes.

A) 20; 80
B) 8; 17
C) 17; 20
D) 200; 1000

A) removal of exons.
B) addition of 7-methylguanylate cap.
C) addition of a poly(A) tail.
D) translation of the RNA transcript.

A) requirement for metal ion cofactors.
B) requirement for exogenous nucleoside binding.
C) DNA composition.
D) intron lariat structure.

A) stem-loop
B) hairpin
C) hammerhead
D) cloverleaf

A) the splicing of mRNA into alternative transcripts.
B) defense mechanisms against RNA viruses.
C) mechanisms inhibiting gene expression.
D) the modification of genes through RNA-mediated mutation.

A) snoRNA
B) siRNA
C) miRNA
D) rRNA

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

A) One is derived from the nucleus and one is derived from double-stranded RNA.
B) One regulates gene expression, whereas the other regulates protein synthesis.
C) One binds to mRNA and suppresses its translation and one binds to mRNA and signals degradation.
D) One binds to the DNA gene and inhibits transcription and one binds to the mRNA and signals degradation.

A) (1) poly(A) tail removal; (2) 7-methylguanosine cap removal; (3) RNA hydrolysis
B) (1) 7-methylguanosine cap removal; (2) RNA hydrolysis; (3) poly(A) tail removal
C) (1) 7-methylguanosine cap removal; (2) poly(A) tail removal; (3) RNA hydrolysis
D) (1) RNA hydrolysis; (2) Poly(A) tail removal; (3) 7-methylguanosine cap removal

A) RNAi
B) snoRNA
C) miRNA
D) siRNA

A) bind mRNA and facilitate the splicing reaction.
B) bind the small nuclear RNA.
C) carry the products from the nucleus to the cytoplasm.
D) bind proteins and hold the complex together.

A) template DNA; coding DNA
B) tRNA; mRNA
C) coding DNA; template DNA
D) mRNA; coding DNA

A) involved in stimulating gene expression.
B) derived from degraded mRNA.
C) expressed in the nucleus and is involved in regulating gene expression.
D) derived from degraded virus RNA strands.

A) poly(A) binding protein
B) exosome
C) CCR4
D) DCP1 and DCP2

A) terminating transcription at different stop codons.
B) splicing the mRNA with different exons.
C) adding the 7-methylguanosine cap at different sites.
D) alternate folding of mRNA.

A) RNA polymerase 1
B) guanine-N7 methyltransferase
C) GMP
D) snoRNA

A) cleavage stimulatory factor (CStF)
B) poly(A) polymerase
C) cleavage and polyadenylation specificity factor (CPSF)
D) poly(A) binding protein

A) RISC.
B) snoRNA.
C) exosome.
D) dicer.

A) methylation.
B) amination.
C) carboxylation.
D) hydroxylation.