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Deck 13: RNA Processing and Post-Transcriptional Gene Regulation

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Question
The ovalbumin gene is much longer than the mRNA produced by this gene. What causes this discrepancy?

A) The exons have been removed during mRNA processing.
B) The DNA represents a double-stranded structure and the RNA is single stranded.
C) There are more amino acids coded for by the DNA than the mRNA.
D) The introns have been removed during mRNA processing.
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Question
RNA splicing is the process by which introns are removed from a primary RNA transcript at precisely defined splice points. Which statement is not true about introns?

A) Introns are that are joined together after splicing.
B) Introns are usually nonfunctional and are degraded, but some introns encode functionalRNA products
C) Introns are transcribed along with the exons.
D) Introns are larger on average than exons.
Question
Some introns contain termination codons yet they do not interrupt the coding of a particular protein. Why?

A) The translation machinery recognizes and skips over introns.
B) These triplets cause frameshift mutations, not termination.
C) More than one termination codon is needed to stop translation.
D) Splicing occurs before translation.
Question
Group I intron self-splicing relies on

A) An external guanosine nucleotide as a cofactor.
B) A bulged internal guanosine nucleotide.
C) An external adenosine nucleotide as a cofactor.
D) A bulged internal adenosine nucleotide.
Question
The first nucleophilic attack in group II intron splicing is initiated by a

A) An external guanosine nucleotide as a cofactor.
B) A bulged internal guanosine nucleotide.
C) An external adenosine nucleotide as a cofactor.
D) A bulged internal adenosine nucleotide.
Question
The second transesterification step for group I and group II intron self-splicing is initiated by the

A) 3' end of the intron
B) 5' end of the intron
C) 3' end of the upstream exon
D) 5' end of the upstream exon
Question
Archael introns are

A) self-splicing.
B) spliced by an endoribonuclease.
C) spliced by the spliceosome.
D) require an external guanosine nucleotide as a cofactor.
Question
Which statement is true regarding eukaryotic nuclear tRNA genes?

A) There are no intron-containing nuclear tRNA genes in eukaryotes.
B) All eukaryotic nuclear tRNA genes contain at least one intron.
C) One of two classes of eukaryotic nuclear tRNA genes has introns.
D) Only yeast and plant nuclear tRNA genes have introns.
Question
Select three posttranscriptional modifications often seen in the maturation of nuclear pre-mRNA in eukaryotes.

A) 5'-capping; 3'-poly(A) tail addition; splicing
B) 3'-capping; 5'-poly(A) tail addition; splicing
C) 5'-capping, removal of exons; insertion of introns
D) 3'-capping, insertion of introns; 5'-poly(A) tail addition
Question
During maturation of nuclear pre-mRNA in eukaryotes, capping takes place at the

A) 5' end of the primary RNA transcript.
B) 3' end of the primary RNA transcript
C) 2' end of the primary RNA transcript
D) At either the 5' or 3' end, depending on the particular primary RNA transcript
Question
The 7-methylguanosine cap structure, the ribose of guanosine is connected to the 5' end of the mRNA by

A) phosphates
B) sulfates
C) glycerol
D) ethylene
Question
Which is not a function of the 7-methylguanosine cap?

A) protection from exonucleases
B) promoting mRNA nuclear export
C) stimulation of RNA polymerase elongation
D) stimulation of translation
Question
The process of polyadenylation is accomplished by

A) reverse transcriptase
B) the CTD domain
C) primase
D) poly(A) polymerase
Question
Which is not required for efficient mRNA polyadenylation?

A) a polyadenylation sequence in the mRNA
B) poly(A)-binding proteins
C) Xrn2 exonuclease
D) poly(A) polymerase
Question
To ensure that RNA polymerase is only released after it has transcribed a gene to its end, termination is mechanistically linked to

A) 5' capping
B) excision of the lariat RNA
C) alternative splicing
D) 3' end formation
Question
RNA polymerase is thought to be disengaged from the DNA template by

A) the Xrn2 exonuclease
B) cleavage and polyadenylation specific-factor (CPSF)
C) poly(A) polymerase
D) the spliceosome
Question
Nuclear pre-mRNA introns are

A) self-splicing
B) removed by an endoribonuclease
C) removed by the spliceosome
D) require an external guanosine nucleotide as a cofactor.
Question
RNA splicing of nuclear pre-mRNA involves removal of

A) introns from a primary RNA transcript by a series of two transesterification reactions.
B) exons from a primary RNA transcript by a series of two transesterification reactions.
C) introns from a primary RNA transcript by a series of polyadenylation reactions.
D) exons from a primary RNA transcript by a series of polyadenylation reactions.
Question
The spliceosome is composed of

A) U1, U2, U3, U4, and U5 snRNPs
B) five different U-rich snRNAs and more than 200 proteins
C) small ribosomal RNAs and associated proteins
D) more than 200 proteins
Question
Which snRNPs are thought to contribute to the catalysis of pre-mRNA splicing?

A) U1 and U2 snRNPs
B) U2 and U4 snRNPs
C) U5 and U6 snRNPs
D) U2 and U6 snRNPs
Question
The mechanism for nuclear pre-mRNA splicing is similar to the splicing mechanism of

A) Group I introns
B) Group II introns
C) Archael introns
D) nuclear tRNA introns
Question
It was once assumed that a count of the number of protein-coding genes in an organism would provide a reasonable estimate of the total number of gene products. This is now known to be incorrect, largely due to the discovery of widespread:

A) chromatin modification control
B) transcriptional initiation control
C) alternative splicing
D) translational control
Question
One way to detect alternative splicing of a given gene is to compare:

A) the relative rate of transcription of the alternatively spliced gene withanother gene
B) the sequence of the alternatively spliced gene to that of another gene.
C) the size and sequence of different pre-mRNAs transcribed from this gene.
D) the size and sequence of mature mRNAs produced from this gene.
Question
There is evidence supporting

A) that the spliceosome assembles in a step-wise fashion as the splicing reaction occurs
B) that the splicosome exists as a "pre-assembled" macromolecular complex
C) that the order of snRNP binding to a pre-mRNA varies between specific transcripts
D) A and B
Question
Which factors bind to pre-mRNA splice sites first?

A) U1 and U2AF
B) U2 and a DEXH helicase
C) U4/U6/U5
D) hnRNP proteins
Question
For some pre-mRNAs, splicing is regulated by

A) RNA polymerase stalling
B) splicing enhancer sequences
C) localization of the pre-mRNA to subnuclear "speckles"
D) transcription termination
Question
When an exon from one pre-mRNA joins to an exon from another pre-mRNA the process is called

A) trans-splicing
B) cis-splicing
C) alternative splicing
D) RNA editing
Question
RNA editing is a widespread mechanism for post-transcriptional modification of the base sequence of mRNA. In humans, RNA editing

A) is mediated by guide RNAs and a multiprotein complex called the "editosome" that inserts or deletes uridines.
B) occurs by deamination of adenosine to inosine, or cytidine to uridine.
C) is mediated by small nucleolar RNAs and base modification enzymes.
D) is mediated by the U12-type intron splicing pathway.
Question
RNA editing is a widespread mechanism for post-transcriptional modification of the base sequence of mRNA. In trypanosomes, RNA editing

A) is mediated by guide RNAs and a multiprotein complex called the "editosome" that inserts or deletes uridines.
B) occurs by deamination of adenosine to inosine, or cytidine to uridine.
C) is mediated by small nucleolar RNAs and base modification enzymes.
D) is mediated by the U12-type intron splicing pathway.
Question
The enzyme ADAR (adenosine deaminase acting on RNA) functions in

A) RNA interference
B) RNA editing
C) alternative splicing
D) formation of an alternative mRNA cap structure
Question
MicroRNAs are processed by the enzymes _______ and ______. One strand of the microRNA is loaded into a silencing complex named _________. The microRNAs target mRNA for ___________ or ___________.

A) RISC, Dicer, Drosha, mRNA degradation, translational repression
B) Drosha, Dicer, RISC, mRNA degradation, translational repression
C) Drosha, Dicer, RISC, alternative splicing, RNA editing
D) RISC, Dicer, Drosha, alternative splicing, RNA editing
Question
RNA interference is the process of

A) gene silencing at the transcriptional level.
B) gene silencing at the level of RNA splicing.
C) gene silencing at the post-transcriptional level.
D) gene silencing at the post-translational level.
Question
RNA interference is thought to have evolved to

A) downregulate cancer-causing genes
B) promote transposition
C) prevent spurious recombination
D) defend against viruses
Question
The target mRNA for a particular miRNA is cleaved by

A) RNA-directed RNA polymerase
B) Dicer
C) Drosha
D) RISC
Question
Which component of the RNAi pathway confers inheritance of siRNA-induced silencing?

A) Dicer
B) RISC (RNA induced silencing complex)
C) RdRP (RNA-directed RNA polymerase)
D) Drosha
Question
The targets of a microRNA are usually

A) viral mRNAs
B) bacterial dsRNAs
C) tissue-specific genes
D) "housekeeping" genes
Question
The nuclear exosome

A) degrades aberrant mRNAs
B) cleaves dsRNA into siRNAs
C) promotes nuclear export of mature mRNA complexes
D) facilitates spliceosome assembly
Question
Which aspect of an mRNA's life cycle serves as a key mRNA quality control mechanism?

A) 3' end cleavage
B) transcription termination
C) nuclear export
D) splicing
Question
Nuclear basket proteins Mlp1 and Mlp2 act as

A) nuclear exosomes
B) a sorting filter for unspliced transcripts
C) splicing factors
D) miRNA exportins
Question
When mRNAs lacking a poly(A) tail compete with polyadenylated mRNAs for
Limiting translational machinery

A) the polyadenylated mRNA is translated more efficiently.
B) the mRNA lacking a poly(A) tail is translated more efficiently.
C) the mRNAs are translated equally efficiently.
D) the efficiency of translation depends on the sequence of the mRNA, not the poly(A) tail.
Question
Failure of the ribosome to remove an exon-exon junction complex (EJC) leads to

A) degradation by nuclear exosomes
B) translation of the mRNA
C) storage of the mRNA in the cytoplasm
D) nonsense-mediated mRNA decay
Question
Describe the original observations that indicated the existence of "split genes."
Question
Define the terms "intron" and "exon."
Question
What is a snRNP ("snurp")?
Question
Discuss how the discovery of intron-encoded small nucleolar RNAs (snoRNAs) has added to the challenge of cloning "genes".
Question
Draw a diagram of the steps involved in self-splicing of an RNA containing a group I intron.
Question
You are characterizing an RNA transcript that contains an intron. List the key features you would need to analyze to determine whether the RNA is self-splicing and, if it is self-splicing, to classify the intron as a group I or group II intron.
Question
What is unusual about the phosphodiester bond forming a lariat intron?
Question
Compare and contrast the key features of "homing" and "retrohoming" by mobile group I and II introns, respectively.
Question
Diagram the Archael intron splicing pathway. Include a rough sketch of the conserved secondary structure of an archael intron.
Question
Diagram the tRNA splicing pathway of plants and fungi.
Question
a) Name the domain of RNA polymerase II that coordinates cotranscriptional processing of nuclear pre-mRNA. b) Name the post-translational modification that is required for function of this domain. c) Name the class of enzyme that carries out the post-translational modification in (b).
Question
Diagram a model showing how nuclear pre-mRNA processing is coupled to transcription.
Question
Diagram the structure of the 7-methylguanosine cap structure with sufficient detail to show how the cap is added in the "wrong" direction to the initial nucleotide of the mRNA.
Question
Describe and give the results of an experiment that showed that the carboxyl terminus of the RNA polymerase II carboxyl-terminal domain (CTD) is necessary and sufficient to enhance splicing.
Question
Diagram a two-step model for transcription termination in eukaryotes.
Question
Draw a diagram of the polyadenylation complex and the polyadenylation process.
Question
A friend of yours has been diagnosed with oculopharyngeal muscular dystrophy. Explain the genetic basis for this disease.
Question
Describe the composition and structure of the spliceosome, based on cryoelectron microscopy and biochemical analysis. Relate the structure to function.
Question
Suggest how DEXH/D-box RNA helicases might facilitate splicing.
Question
Describe and show the results of an experiment that demonstrates that U1 snRNP is the first snRNP to bind to the pre-mRNA.
Question
What process is thought to be defective in spinal muscular atrophy?
Question
Describe and show the results of an experiment to demonstrate that the survival of motor neurons (SMN) protein colocalizes with coilin in Cajal bodies.
Question
A friend of yours has been diagnosed retinistis pigmentosa. Explain the genetic basis for this disease.
Question
What are SR proteins and where are they located within cells?
Question
Is the spliceosome a ribozyme? Describe experimental evidence for the catalytic activity of U2 and U6 snRNAs.
Question
Define the term "alternative splicing." Describe a specific example of alternative splicing.
Question
Is alternative splicing within human genes common or uncommon? Explain your answer.
Question
Use a diagram to compare and contrast discontinuous group II trans-splicing with spliced leader trans-splicing. Discuss how the discovery of discontinuous group II trans-splicing in particular has added to the challenge of cloning "genes".
Question
When the genome of the only characterized member of the kingdom Nanoarchaeota (Nanoarchaeum equitans) was sequenced, it appeared to be missing genes encoding several tRNAs, yet the tRNAs themselves were all present in the organism. Provide an explanation.
Question
Define the term "RNA editing" and explain why its discovery shook the central dogma of molecular biology.
Question
Diagram the general mechanism for RNA editing in trypanosomes. You do not need to show a complete sequence for the pre-mRNA.
Question
In what cellular compartment does editing take place in trypanosomes? Are all the components required for editing produced in this compartment? Explain your answer.
Question
Diagram the process of apolipoprotein B (CU editing) in humans.
Question
Besides CU editing, what other type of editing occurs in humans?
Question
What unusual feature was revealed by X-ray crystallographic analysis of the structure of the adenosine deaminase ADAR?
Question
Describe evidence for a model in which a defect in RNA editing contributes to the onset of amyotrophic lateral sclerosis.
Question
You discover that a single gene can produce two different proteins. Provide possible explanations for your observation.
Question
Describe some of the experiments that led to the discovery of miRNAs in the nematode worm, Caenorhabditis elegans.
Question
Define the term RNA interference (RNAi). Compare and contrast key features of small interfering RNAs (siRNAs) and micro RNAs (miRNAs).
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Deck 13: RNA Processing and Post-Transcriptional Gene Regulation
1
The ovalbumin gene is much longer than the mRNA produced by this gene. What causes this discrepancy?

A) The exons have been removed during mRNA processing.
B) The DNA represents a double-stranded structure and the RNA is single stranded.
C) There are more amino acids coded for by the DNA than the mRNA.
D) The introns have been removed during mRNA processing.
The introns have been removed during mRNA processing.
2
RNA splicing is the process by which introns are removed from a primary RNA transcript at precisely defined splice points. Which statement is not true about introns?

A) Introns are that are joined together after splicing.
B) Introns are usually nonfunctional and are degraded, but some introns encode functionalRNA products
C) Introns are transcribed along with the exons.
D) Introns are larger on average than exons.
Introns are that are joined together after splicing.
3
Some introns contain termination codons yet they do not interrupt the coding of a particular protein. Why?

A) The translation machinery recognizes and skips over introns.
B) These triplets cause frameshift mutations, not termination.
C) More than one termination codon is needed to stop translation.
D) Splicing occurs before translation.
Splicing occurs before translation.
4
Group I intron self-splicing relies on

A) An external guanosine nucleotide as a cofactor.
B) A bulged internal guanosine nucleotide.
C) An external adenosine nucleotide as a cofactor.
D) A bulged internal adenosine nucleotide.
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k this deck
5
The first nucleophilic attack in group II intron splicing is initiated by a

A) An external guanosine nucleotide as a cofactor.
B) A bulged internal guanosine nucleotide.
C) An external adenosine nucleotide as a cofactor.
D) A bulged internal adenosine nucleotide.
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Unlock for access to all 94 flashcards in this deck.
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6
The second transesterification step for group I and group II intron self-splicing is initiated by the

A) 3' end of the intron
B) 5' end of the intron
C) 3' end of the upstream exon
D) 5' end of the upstream exon
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7
Archael introns are

A) self-splicing.
B) spliced by an endoribonuclease.
C) spliced by the spliceosome.
D) require an external guanosine nucleotide as a cofactor.
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Unlock for access to all 94 flashcards in this deck.
Unlock Deck
k this deck
8
Which statement is true regarding eukaryotic nuclear tRNA genes?

A) There are no intron-containing nuclear tRNA genes in eukaryotes.
B) All eukaryotic nuclear tRNA genes contain at least one intron.
C) One of two classes of eukaryotic nuclear tRNA genes has introns.
D) Only yeast and plant nuclear tRNA genes have introns.
Unlock Deck
Unlock for access to all 94 flashcards in this deck.
Unlock Deck
k this deck
9
Select three posttranscriptional modifications often seen in the maturation of nuclear pre-mRNA in eukaryotes.

A) 5'-capping; 3'-poly(A) tail addition; splicing
B) 3'-capping; 5'-poly(A) tail addition; splicing
C) 5'-capping, removal of exons; insertion of introns
D) 3'-capping, insertion of introns; 5'-poly(A) tail addition
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k this deck
10
During maturation of nuclear pre-mRNA in eukaryotes, capping takes place at the

A) 5' end of the primary RNA transcript.
B) 3' end of the primary RNA transcript
C) 2' end of the primary RNA transcript
D) At either the 5' or 3' end, depending on the particular primary RNA transcript
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11
The 7-methylguanosine cap structure, the ribose of guanosine is connected to the 5' end of the mRNA by

A) phosphates
B) sulfates
C) glycerol
D) ethylene
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k this deck
12
Which is not a function of the 7-methylguanosine cap?

A) protection from exonucleases
B) promoting mRNA nuclear export
C) stimulation of RNA polymerase elongation
D) stimulation of translation
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13
The process of polyadenylation is accomplished by

A) reverse transcriptase
B) the CTD domain
C) primase
D) poly(A) polymerase
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k this deck
14
Which is not required for efficient mRNA polyadenylation?

A) a polyadenylation sequence in the mRNA
B) poly(A)-binding proteins
C) Xrn2 exonuclease
D) poly(A) polymerase
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15
To ensure that RNA polymerase is only released after it has transcribed a gene to its end, termination is mechanistically linked to

A) 5' capping
B) excision of the lariat RNA
C) alternative splicing
D) 3' end formation
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k this deck
16
RNA polymerase is thought to be disengaged from the DNA template by

A) the Xrn2 exonuclease
B) cleavage and polyadenylation specific-factor (CPSF)
C) poly(A) polymerase
D) the spliceosome
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17
Nuclear pre-mRNA introns are

A) self-splicing
B) removed by an endoribonuclease
C) removed by the spliceosome
D) require an external guanosine nucleotide as a cofactor.
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Unlock for access to all 94 flashcards in this deck.
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k this deck
18
RNA splicing of nuclear pre-mRNA involves removal of

A) introns from a primary RNA transcript by a series of two transesterification reactions.
B) exons from a primary RNA transcript by a series of two transesterification reactions.
C) introns from a primary RNA transcript by a series of polyadenylation reactions.
D) exons from a primary RNA transcript by a series of polyadenylation reactions.
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k this deck
19
The spliceosome is composed of

A) U1, U2, U3, U4, and U5 snRNPs
B) five different U-rich snRNAs and more than 200 proteins
C) small ribosomal RNAs and associated proteins
D) more than 200 proteins
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20
Which snRNPs are thought to contribute to the catalysis of pre-mRNA splicing?

A) U1 and U2 snRNPs
B) U2 and U4 snRNPs
C) U5 and U6 snRNPs
D) U2 and U6 snRNPs
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21
The mechanism for nuclear pre-mRNA splicing is similar to the splicing mechanism of

A) Group I introns
B) Group II introns
C) Archael introns
D) nuclear tRNA introns
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k this deck
22
It was once assumed that a count of the number of protein-coding genes in an organism would provide a reasonable estimate of the total number of gene products. This is now known to be incorrect, largely due to the discovery of widespread:

A) chromatin modification control
B) transcriptional initiation control
C) alternative splicing
D) translational control
Unlock Deck
Unlock for access to all 94 flashcards in this deck.
Unlock Deck
k this deck
23
One way to detect alternative splicing of a given gene is to compare:

A) the relative rate of transcription of the alternatively spliced gene withanother gene
B) the sequence of the alternatively spliced gene to that of another gene.
C) the size and sequence of different pre-mRNAs transcribed from this gene.
D) the size and sequence of mature mRNAs produced from this gene.
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k this deck
24
There is evidence supporting

A) that the spliceosome assembles in a step-wise fashion as the splicing reaction occurs
B) that the splicosome exists as a "pre-assembled" macromolecular complex
C) that the order of snRNP binding to a pre-mRNA varies between specific transcripts
D) A and B
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25
Which factors bind to pre-mRNA splice sites first?

A) U1 and U2AF
B) U2 and a DEXH helicase
C) U4/U6/U5
D) hnRNP proteins
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26
For some pre-mRNAs, splicing is regulated by

A) RNA polymerase stalling
B) splicing enhancer sequences
C) localization of the pre-mRNA to subnuclear "speckles"
D) transcription termination
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27
When an exon from one pre-mRNA joins to an exon from another pre-mRNA the process is called

A) trans-splicing
B) cis-splicing
C) alternative splicing
D) RNA editing
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28
RNA editing is a widespread mechanism for post-transcriptional modification of the base sequence of mRNA. In humans, RNA editing

A) is mediated by guide RNAs and a multiprotein complex called the "editosome" that inserts or deletes uridines.
B) occurs by deamination of adenosine to inosine, or cytidine to uridine.
C) is mediated by small nucleolar RNAs and base modification enzymes.
D) is mediated by the U12-type intron splicing pathway.
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Unlock for access to all 94 flashcards in this deck.
Unlock Deck
k this deck
29
RNA editing is a widespread mechanism for post-transcriptional modification of the base sequence of mRNA. In trypanosomes, RNA editing

A) is mediated by guide RNAs and a multiprotein complex called the "editosome" that inserts or deletes uridines.
B) occurs by deamination of adenosine to inosine, or cytidine to uridine.
C) is mediated by small nucleolar RNAs and base modification enzymes.
D) is mediated by the U12-type intron splicing pathway.
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Unlock Deck
k this deck
30
The enzyme ADAR (adenosine deaminase acting on RNA) functions in

A) RNA interference
B) RNA editing
C) alternative splicing
D) formation of an alternative mRNA cap structure
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k this deck
31
MicroRNAs are processed by the enzymes _______ and ______. One strand of the microRNA is loaded into a silencing complex named _________. The microRNAs target mRNA for ___________ or ___________.

A) RISC, Dicer, Drosha, mRNA degradation, translational repression
B) Drosha, Dicer, RISC, mRNA degradation, translational repression
C) Drosha, Dicer, RISC, alternative splicing, RNA editing
D) RISC, Dicer, Drosha, alternative splicing, RNA editing
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32
RNA interference is the process of

A) gene silencing at the transcriptional level.
B) gene silencing at the level of RNA splicing.
C) gene silencing at the post-transcriptional level.
D) gene silencing at the post-translational level.
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Unlock Deck
k this deck
33
RNA interference is thought to have evolved to

A) downregulate cancer-causing genes
B) promote transposition
C) prevent spurious recombination
D) defend against viruses
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Unlock for access to all 94 flashcards in this deck.
Unlock Deck
k this deck
34
The target mRNA for a particular miRNA is cleaved by

A) RNA-directed RNA polymerase
B) Dicer
C) Drosha
D) RISC
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Unlock Deck
k this deck
35
Which component of the RNAi pathway confers inheritance of siRNA-induced silencing?

A) Dicer
B) RISC (RNA induced silencing complex)
C) RdRP (RNA-directed RNA polymerase)
D) Drosha
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36
The targets of a microRNA are usually

A) viral mRNAs
B) bacterial dsRNAs
C) tissue-specific genes
D) "housekeeping" genes
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Unlock Deck
k this deck
37
The nuclear exosome

A) degrades aberrant mRNAs
B) cleaves dsRNA into siRNAs
C) promotes nuclear export of mature mRNA complexes
D) facilitates spliceosome assembly
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k this deck
38
Which aspect of an mRNA's life cycle serves as a key mRNA quality control mechanism?

A) 3' end cleavage
B) transcription termination
C) nuclear export
D) splicing
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Unlock Deck
k this deck
39
Nuclear basket proteins Mlp1 and Mlp2 act as

A) nuclear exosomes
B) a sorting filter for unspliced transcripts
C) splicing factors
D) miRNA exportins
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Unlock Deck
k this deck
40
When mRNAs lacking a poly(A) tail compete with polyadenylated mRNAs for
Limiting translational machinery

A) the polyadenylated mRNA is translated more efficiently.
B) the mRNA lacking a poly(A) tail is translated more efficiently.
C) the mRNAs are translated equally efficiently.
D) the efficiency of translation depends on the sequence of the mRNA, not the poly(A) tail.
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Unlock for access to all 94 flashcards in this deck.
Unlock Deck
k this deck
41
Failure of the ribosome to remove an exon-exon junction complex (EJC) leads to

A) degradation by nuclear exosomes
B) translation of the mRNA
C) storage of the mRNA in the cytoplasm
D) nonsense-mediated mRNA decay
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42
Describe the original observations that indicated the existence of "split genes."
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43
Define the terms "intron" and "exon."
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44
What is a snRNP ("snurp")?
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45
Discuss how the discovery of intron-encoded small nucleolar RNAs (snoRNAs) has added to the challenge of cloning "genes".
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46
Draw a diagram of the steps involved in self-splicing of an RNA containing a group I intron.
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47
You are characterizing an RNA transcript that contains an intron. List the key features you would need to analyze to determine whether the RNA is self-splicing and, if it is self-splicing, to classify the intron as a group I or group II intron.
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48
What is unusual about the phosphodiester bond forming a lariat intron?
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49
Compare and contrast the key features of "homing" and "retrohoming" by mobile group I and II introns, respectively.
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50
Diagram the Archael intron splicing pathway. Include a rough sketch of the conserved secondary structure of an archael intron.
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51
Diagram the tRNA splicing pathway of plants and fungi.
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52
a) Name the domain of RNA polymerase II that coordinates cotranscriptional processing of nuclear pre-mRNA. b) Name the post-translational modification that is required for function of this domain. c) Name the class of enzyme that carries out the post-translational modification in (b).
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53
Diagram a model showing how nuclear pre-mRNA processing is coupled to transcription.
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54
Diagram the structure of the 7-methylguanosine cap structure with sufficient detail to show how the cap is added in the "wrong" direction to the initial nucleotide of the mRNA.
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55
Describe and give the results of an experiment that showed that the carboxyl terminus of the RNA polymerase II carboxyl-terminal domain (CTD) is necessary and sufficient to enhance splicing.
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56
Diagram a two-step model for transcription termination in eukaryotes.
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57
Draw a diagram of the polyadenylation complex and the polyadenylation process.
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58
A friend of yours has been diagnosed with oculopharyngeal muscular dystrophy. Explain the genetic basis for this disease.
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59
Describe the composition and structure of the spliceosome, based on cryoelectron microscopy and biochemical analysis. Relate the structure to function.
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60
Suggest how DEXH/D-box RNA helicases might facilitate splicing.
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61
Describe and show the results of an experiment that demonstrates that U1 snRNP is the first snRNP to bind to the pre-mRNA.
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62
What process is thought to be defective in spinal muscular atrophy?
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63
Describe and show the results of an experiment to demonstrate that the survival of motor neurons (SMN) protein colocalizes with coilin in Cajal bodies.
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64
A friend of yours has been diagnosed retinistis pigmentosa. Explain the genetic basis for this disease.
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65
What are SR proteins and where are they located within cells?
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66
Is the spliceosome a ribozyme? Describe experimental evidence for the catalytic activity of U2 and U6 snRNAs.
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67
Define the term "alternative splicing." Describe a specific example of alternative splicing.
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68
Is alternative splicing within human genes common or uncommon? Explain your answer.
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69
Use a diagram to compare and contrast discontinuous group II trans-splicing with spliced leader trans-splicing. Discuss how the discovery of discontinuous group II trans-splicing in particular has added to the challenge of cloning "genes".
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70
When the genome of the only characterized member of the kingdom Nanoarchaeota (Nanoarchaeum equitans) was sequenced, it appeared to be missing genes encoding several tRNAs, yet the tRNAs themselves were all present in the organism. Provide an explanation.
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71
Define the term "RNA editing" and explain why its discovery shook the central dogma of molecular biology.
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72
Diagram the general mechanism for RNA editing in trypanosomes. You do not need to show a complete sequence for the pre-mRNA.
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73
In what cellular compartment does editing take place in trypanosomes? Are all the components required for editing produced in this compartment? Explain your answer.
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74
Diagram the process of apolipoprotein B (CU editing) in humans.
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75
Besides CU editing, what other type of editing occurs in humans?
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76
What unusual feature was revealed by X-ray crystallographic analysis of the structure of the adenosine deaminase ADAR?
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77
Describe evidence for a model in which a defect in RNA editing contributes to the onset of amyotrophic lateral sclerosis.
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78
You discover that a single gene can produce two different proteins. Provide possible explanations for your observation.
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79
Describe some of the experiments that led to the discovery of miRNAs in the nematode worm, Caenorhabditis elegans.
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80
Define the term RNA interference (RNAi). Compare and contrast key features of small interfering RNAs (siRNAs) and micro RNAs (miRNAs).
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