Quiz 10

Question 1

1. Understand what RNA processing includes

Answer 1

• Splicing
• 5’ cap addition
• polyadenylation.

Question 2

definition of an exon

Answer 2

• Sequences that are translated into protein

Question 3

definition of an intron

Answer 3

• intervening sequences that interrupt exons.

Question 4

3. Know what R looping experiments are used for

Answer 4

• RNA hybridized to its DNA template and the product is examined by electron microscopy.

Question 5

how R looping experiments led to the identification of introns.

Answer 5

• These experiments revealed introns in adenovirus

- RNA-DNA hybrid was interrupted by 3 ss DNA loops that represented introns

Question 6

4. Know what hnRNA is and where it is found in the cell.

Answer 6

• hnRNA: heterogeneous nuclear RNA, a class of large nuclear RNAs
• located in the nucleus.
• It is a precursor to mRNA
• hnRNA turns over very rapidly
• Converted into smaller RNAs very quickly.

Question 7

5. In splicing of eukaryotic mRNA, know the significance of the GU…..AG splice site signals and the A at the branch point. Be able to recognize at 5’ splice site, 3’ splice site and branch site within an intron.

Answer 7

• 5’ splice site - GU
• 3’ splice site - AG
• A - located 13-22 nucleotides upstream from 3’ splice site

Question 8

6. Know the two step splicing mechanism.

Answer 8

• Formation of the lariat-shaped intermediate:
  forms when 2’ hydroxyl group of an adenosine nucleotide in the middle of the intron attacks phosphodiester bond between first exon and G at beginning of intron
• forms lariat and simultaneously separates first exon from the intron
• 3’ hydroxyl group left at end of first exon attacks the phosphodiester bond linking intron to second exon
• This forms the exon-exon phosphodiester bond and releases the intron, in lariat form, at the same time

Question 9

7. Be able to identify the two phosphodiester linkages that are lost and the two that are formed in the splicing of eukaryotic mRNA.

Answer 9

• Phosphodiester bonds lost between the two exons binding to the one intron
• Phosphodiester bond formed between the two exons and a bond in intron forming a lariat structure.

Question 10

8. Understand what happens to the splicing pattern of a transcript when a branch site is mutated or deleted.

Answer 10

• Mutant 1: remove a region 35-70 bp upstream of intron 3’ splice site
• Mutant 2: insert extra DNA segment between this special sequence and exon 2
• Mutant 3: place special sequence within exon 2

Question 11

Result of Mutant 1: remove a region 35-70 bp upstream of intron 3’ splice site

Answer 11

• Result: splicing is blocked, suggesting that it is important for splicing

Question 12

Result of Mutant 2: insert extra DNA segment between this special sequence and exon 2

Answer 12

• Result: different AG used

- 1st AG downstream of special sequence (with inserted DNA)

Question 13

Result of Mutant 3: place special sequence within exon 2

Answer 13

• Result: 1st AG downstream of new special sequence used as a 3’ splice site

Question 14

9. Understand what the spliceosome is

Answer 14

the spliceosome is a ribonucleoprotein complex consisting of a number of subunits and requires ATP for assembly.

Question 15

10. Understand the involvement of 5’-2’ phosphodiester linkages in splicing of eukaryotic mRNA.

Answer 15

• an intron is removed as a lariat structure in which the 5’ G of the intron is joined in a unusual 2’-5’-phosphodiester bond to an adenosine near the 3’ end of the intron.
• The adenosine is called the branch point because it forms an RNA branch in the lariat structure

Question 16

1. Understand what the spliceosome consists of and what each contain

Answer 16

• the spliceosome consists of 5 ribonucleoprotein complexes called snRNPs.
• These contain snRNAs that help catalyze the splicing reactions.

Question 17

2. Know what the U1 snRNA base pairs with.

Answer 17

• U1 snRNA base pairs with the 5’ splice site.

- It is not sufficient but it is necessary

Question 18

3. Understand how compensatory mutations in a snRNA can be used to show its interaction with sequences within a pre-mRNA.

Answer 18

• Disruption of base pairs and introduction of new potential base pairs will weaken the overall base pairing
• The number of contiguous base pairs is lower.
• Compensatory mutations restore base pairing and may or may not restore splicing

Question 19

4. Know how an RNase protection assay works and can be used to identify splicing patterns of mRNAs.

Answer 19

• Synthesize in vitro transcript that is radioactively labeled and allow it to hybridize to RNA.
• RNase digests single-stranded RNA and dsRNA is detected

Question 20

5. Understand what the U6 snRNA interacts with.

Answer 20

• the U6 snRNA interacts with the 5’ splice site of eukaryotic mRNAs.
• In complexes with both the substrate and the lariat, binds both before and after the initial step
• Also base pairs with U4

Question 21

6. Know what U2 base pairs with.

Answer 21

• base pairing between U2 and U6 help to form a structure that forms the active site of the spliceosome.
• U2 also base pairs with the branch site.
• U6-substrate complex and U6-lariat complex can be detected experimentally

Question 22

7. Understand what U4 snRNA interacts with

Answer 22

• U4 snRNA interacts with the consensus branch sequence in pre-mRNAs.

Question 23

8. Know what U2 base pairs with prior to splicing

Answer 23

• U2 also base pairs with U6 prior to splicing.

Question 24

9. Understand what U5 binds to during the second step of splicing

Answer 24

• U5 binds to the 3’ end of the first exon and the 5’ end of the second exon
• to bring the splice sites together during the second step of splicing.

Question 25

10. Know what happens between U4 and U6

Answer 25

- U4 dissociates from U6 after splicing is underway - must be removed before U6 can interact with U2 to form an active spliceosome. - Some U6 bases that participate in base pairing with U4 to form stem I are also involved in the essential base pairing to U2

Question 26

11. What was the surprising observation made by Tom Cech and his group that led to a Nobel Prize?

Answer 26

- RNA itself catalyzed its own splicing (self-splicing introns)

Question 27

12. Understand the similarities between Group II self-splicing introns and the spliceosome.

Answer 27

- Group II use a lariat intermediate - similar to nuclear mRNA splicing - U5 loop = domain ID - positions exons 1 and 2 for splicing - U6 region that base pairs with the 5’-splice site substitutes = domain IC - U2-U6 helix I = domain V - U2 branchpoint helix - domain VI - In both cases, base pairing around the branchpoint A causes it to bulge out to form the branch

Question 28

13. Know how snRNAs function as ribozymes

Answer 28

- snRNAs likely catalyze the splicing reactions in the spliceosome and, in this way, function as ribozymes.

Question 29

14. Understand the concept of the "ribozyme" as an RNA molecule with catalytic activity.

Answer 29

Ribozymes are catalytic RNA that are capable of carrying out enzymatic reactions

Question 30

15. Know the RNA world hypothesis.

Answer 30

- Evolution of self-replicating systems. - RNAs catalyzed biological reactions, cleavage, and self replication - In a world before proteins with 20 amino acids added versatility

Question 31

1. Understand how splice site selection is regulated

Answer 31

- splice site selection is regulated by controlling where a spliceosome forms. - A cell can regulate the quality and quantity of splicing and thereby regulate gene expression.

Question 32

2. Understand the role of the protein U2AF in splicing.

Answer 32

U2AF is the splicing factor involved in 3’-splice site recognition

Question 33

3. Understand the roles of the branch point binding protein in splicing.

Answer 33

- Branch point binding protein (BBP) helps define the intron and helps bring 2 ends of the intron together for splicing

Question 34

Understand the roles of SC35 in splicing.

Answer 34

- SC35 is a member of a group of RNA-binding proteins called SR proteins - contains domains that are rich in serine and arginine - it is a commitment factor that helps select splicing sites for the spliceosome

Question 35

4. Understand how different mRNAs can result from the transcription of a single gene by alternative splicing.

Answer 35

- Alternative splicing generates 2 or more alternative RNAs that encode different proteins

Question 36

5. What percentage of transcripts are subject to alternative splicing in humans?

Answer 36

- at least 40% of transcripts have the potential for alternative splicing.

Question 37

6. Know what alternative splicing can do.

Answer 37

- alternative splicing can result in the production of more than one protein from a single gene.

Question 38

7. Understand the variable splice sites in transcripts.

Answer 38

- can have variable 5’ splice sites that are spliced to a common 3’ splice site - can have variable 3’ splice sites that are spliced to a common 5’ splice site; - have exons that are sometimes skipped - can have mutually exclusive exons - can have introns that are used only under certain circumstances.

Question 39

8. Understand the difference between splice sites that match the consensus sequence versus splice sites that diverge from the consenus.

Answer 39

- splice sites that match the consensus sequence are less likely to undergo alternative splicing compared to splice sites that diverge from the consensus.

Question 40

9. Know the role of cis-acting enhancers

Answer 40

- cis-acting enhancers can help regulate the utilization of certain splice sites.

Question 41

10. Understand the function of cells expressing specific splicing factors.

Answer 41

- cells express specific splicing factors that regulate the splicing pattern of certain pre-mRNAs in specific ways.

Question 42

11. Understand the sex determination pathway

Answer 42

- the sex determination pathway consists of several alternative splicing steps. - Loss of function mutations are lethal in females and do not affect males - Gain of function mutations are lethal in males and do not affect females. - All due to the role of Sxl in dosage compensation

Question 43

12. Know the default sex determination pathway

Answer 43

- the default sex determination pathway is the male pathway in fruit flies.

Question 44

13. Know what the X:A ratio does

Answer 44

- initiates the female sex determination pathway in fruit flies through a female-specific early promoter that is ON is females and OFF in males.

Question 45

14. Understand the importance of the sex-lethal protein in flies.

Answer 45

- the Sex-lethal protein in flies is an RNA binding protein that binds to, and regulates its own splicing pattern by preventing splicing to the male-specific exon.

Question 46

15. Know the level of regulation of initiation and maintenance of the sex determination pathway.

Answer 46

- the initiation of the sex determination pathway in flies is regulated at the transcriptional level - maintenance of the pathway is regulated by alternative splicing.

Question 47

16. Understand the roles of the Doublesex zinc finger transcription factor in the sex determination pathway of flies.

Answer 47

- Specify different aspects of male differentiation

Question 48

16. Understand the roles of the Fruitless zinc finger transcription factor in the sex determination pathway of flies.

Answer 48

Controls most steps of male courtship behavior. | Specifies aspects of sexual differentiation responsible for male sexual behavior

Question 49

1. Know what capping does

Answer 49

Capping adds a special blocking nucleotide (a cap) added to the 5’-end of a pre-mRNA

Question 50

Know what polyadenylation is

Answer 50

polyadenylation is a string of AMPs (poly[A]) added to the 3’-end of a pre-mRNA.

Question 51

2. Understand that the 5’ cap has 4 functions:

Answer 51

- To protect mRNAs from degradation - To enhance the translatability of mRNAs - most important - To enhance the transport of mRNAs from the nucleus to the cytoplasm - To enhance the splicing efficiency of mRNAs.

Question 52

3. Understand when the 5’ cap is added.

Answer 52

- the 5’ cap is added early, before the pre-mRNA chain is about 30 base pairs long. - The 5’ cap is added by the condensation of a molecule of GTP w/ triphosphate at the 5’ end of the transcript

Question 53

4. Know the average size of a poly A tail

Answer 53

- the average size of a poly A tail is about 250 nucleotides.

Question 54

5. Understand when the poly A tail is added.

Answer 54

- the poly A tail is added post-transcriptionally and not encoded in the DNA.

Question 55

Know the evidence that poly A is added post transcriptionally:

Answer 55

- poly(A) digested quickly with an enzyme that degrades RNAs from 3’ - Located at the 3’ end of messages - Genome do not have run of T’s long enough to encode polyA tail - No T’s at ends of thousands of sequenced genes - Actinomycin D inhibits DNA-directed transcription, does not inhibit polyadenylation

Question 56

6. Understand what poly(A) polymerase does

Answer 56

- poly(A) polymerase (PAP) is the enzyme in the nucleus that adds AMP residues to mRNA precursors. - It is found on hnRNA

Question 57

7. Know the function of the poly A tail

Answer 57

- the poly A tail protects mRNAs from degradation and stimulates translation.

Question 58

8. Know what poly(A)-binding protein I does

Answer 58

- poly(A)-binding protein I binds to the poly A tail and enhances the efficiency of translation.

Question 59

9. Understand how poly A+ mRNA forms polysomes more successfully than poly A- mRNA and is, therefore, translated more efficiently.

Answer 59

- mRNA with >1 ribosome translating it = polysome - Poly(A)+ showed the greatest increase in polysome formation - as poly(A) grows from 15 to 30 nt and a more gradual increase as more A’s added - Enhancement of translatability by poly(A) seems to be more important than mRNA stabilization

Question 60

10. Understand the relationship between the transcript and poly(A) polymerase

Answer 60

- The transcript does not have to be completely synthesized before poly(A) polymerase adds A’s to its 3’-end - polyadenylation and transcription termination are not necessarily linked.