Lecture 7: Post-translational control

Question 1

What is RNA editing?

Answer 1

• Occurs in eukaryotic genes (e.g. tRNA, rRNA, mRNA n miRNA)
• Also found in archaeal n bacterial systems
• In trypanosomes there is extensive RNA editing of some kinetoplast genes.
• In vertebrates RNA editing occurs in the nucleus
• In cephalopods, RNA editing also occurs in

Question 2

Describe the trypansoma brucei’s mitochondrial DNA

Answer 2

• Mixture of maxicircles (~23kb: copy number, ~50)
  
  • Heterogenous set of minicircles (~1kb: copy number 5k-10k)
    Cateanated/interlocked to form aplanar network that resembles chain mail

Question 3

What is the structure of the maxicircle gene?

Answer 3

• 23kb
  
  • Variable region
  • Conserved region
    ○ 2 of them encode ribosomal RNAs
    ○ Extensively edited genes
  • Genes w limited editing (cytochrome B, cytochrome oxidase II)
  • Remainder of the genes aren’t edited, just expressed
  • 12 ORF are edited to be translatable

Question 4

Why do mitochondria of trypanosomes and plants utilize extensive RNA editing?

Answer 4

• Mitochondria of trypanosomes and plants use a primitive genetic system, derfvied from the RNA world -> offers few opportunities for other forms of transcriptional control.
  
  • Extensive editing is regulated to produce different mRNAs under different conditions, using different minicircles to provide different gRNAs.
  • Is RNA editing a primitive way to change the expression of genes?
  • Is it a relic, perhaps, of mechanisms that operated in the early RNA world?.
  • Different gRNA can be expressed, depending on the environment

Question 5

How do trypanosomes modify their RNA transcripts?

Answer 5

• Each circle encodes guide RNA (gRNA)
  
  • gRNA binds to 3’ of primary transcription
    ○ Every loop is a site where on the gRNA, there is an A
  • Information from gRNA is copied to mRNA
    ○ Requires specialized proteins that can recognize addition/deletion site
    ○ Break either strand, add in U/take U out of mRNA
    ○ RESULT: mRNA w Us inserted n deleted
  • Editing provides anchor site for gRNA 2
  • gRNA 2 encoded on a different minicircle
  • gRNA 2 acts as a template for the addition/deletion of Us in the primary transcript
    RESULT: fully edited mRNA

Question 6

How are some maxicircles extensively edited?

Answer 6

• More bases added than there were in the original transcript
  
  • Addition leads to formation of start codon AUG n stop codon uAG
  • In between, continuous ORF of triplets
  • Maxicircle genes are encrypted n hv to be decrypted before message can be read

Question 7

What is mammalian nuclear APOBEC-mediated mRNA editing?

Answer 7

• Cytosine deaminated to generate uracil
  ○ Change of amine group to oxygen
  Editing can alter protein sequences -> alter protein function

Question 8

What does an editosome consist of?

Answer 8

○ A cytidine deaminase activity is involved – APOBEC (ApoB mRNA editing enzyme catalytic subunit)
○ Another protein, ACF (APOBEC Complementation Factor) is also required
○ Both recognize sequences flanking the C to be edited

Question 9

What is the function of the APOBEC editosome?

Answer 9

• ApoB is required for uptake n cholesterol transport
  ○ Editing site: Exon 26 (CAA)
  
  • LIVER
    ○ No editing in the liver [differential control of ApoBEC, if not expressed in the liver, no editing]
    ○ Expression of ApoB- 100 (protein 100kd in size)
    § Lipid associated
    § Binds to LDL receptors
  • INTESTINE
    ○ Strong expression of APOBEC -
    ○ APOBEC recognizes editing site in exon 26 -> converts to stop codon (UAA)
    ○ RESULT: truncated version of ApoB (ApoB-48)
    ○ Lipid associated
    ○ Does not bind to LDL receptors
    TLDR: one gene two functions separated by cell specific expression

Question 10

What is mammalian nuclear ADAR-mediated mRNA editing?

Answer 10

• Deaminate adenosine to inosine
  
  • Protein required: adenosine deaminase acting on RNA (ADAR)
  • Inosine is a guanosine mimic
  • Native sequence
    ○ AAG UCA
    ○ Lys Ser
  • Edited sequence
    ○ IAG UCI
    ○ Glu Ser
  • ADAR recognizes dsRNA
  • Requires a fold back in mRNA (i.e. stem loop structure of complementary bases in the RNA)
  • Convert specific adenines to inosines
  • I is translated as G.
    ○ If the editing site is in an exon, this can change the protein sequence.
  • I mimics G.
    ○ If the editing site is in an intron, it can create new splice sites. (Lecture 6: the 5’ splice site is exon|GU: the 3’ splice site is AG|exon).
    Thus, ADAR can regulate both protein function and alternative splicing.

Question 11

What are Alu elements?

Answer 11

• Class of primate-specific retrotransposons ~300 bases long
  
  • Sub-group of SNEs
  • More than 1m Alu dispersed in our genomes (~11% of our genome) -> opportunity to derive dsRNA.

Question 12

Why would there be inverted repeats in mRNA?

Answer 12

If 1 Alu element inserts into gene n the other inserts in the opposite direction -> complementarity in mRNA -> allows ADAR to bind

Question 13

What is the value of ADAR-mediated RNA editing?

Answer 13

• It may have evolved as a defence system to inactivate retroviruses/ retrotransposons.
  
  • Enhances genome plasticity (new proteins, alternative splicing).
  • ADAR can also recognise DNA:RNA hybrids and has a role in DNA repair.
  • There are three ADAR gene isoforms in us, and in mice, with different targets.
  • Neurobiology link?
    ○ Mice lacking ADAR1 have frequent epileptic seizures, and die soon after weaning
    ○ Flies lacking ADAR display neurodegeneration
    ○ Glutamate receptor expression depends on ADAR1 activity
    Serotonin receptors are expressed from edited transcripts

Question 14

How is mRNA edited for nuclear transport?

Answer 14

• As introns are removed, spliceosome deposits exon junction complex (EJC) at sites upstream of exon fusion site
  ○ Upstream of the exon/intron are 2 exon borders
  ○ ECJs are important bc they interact w SR proteins
  
  • At a late stage in splicing, a nuclear export receptor complex is transferred from the CTD of Pol II.
  • This provides a nuclear export signal (NES).
  • mRNA is not naked
    Clothed with proteins and is a complex compacted particle of RNA and proteins – it is a messenger RNA particle (mRNP).

Question 15

How does nuclear export of mRNA occur?

Answer 15

• The NER targets the nuclear pore, and the mRNP is threaded through.
  
  • SR proteins are removed
  • The CBC is removed and replaced by eukaryotic Initiation Factor 4E (eIF4E, LF104 lecture 15) and circularised with eIF4G.
    ○ eIF4G interacts w PABP -> pseudo circularization of mRNP
    NER is returned to the nucleus.

Question 16

What are miRNAs?

Answer 16

• Small non-coding regulatory RNAs processed from dsRNA precursors
• GC-rich -> strong base pairing to make stable structures
• Internal loops at the end
• 2 bp overhang

Question 17

Why is miRNA of high importance?

Answer 17

Regulates gene expression might be as important as that of transcription factors.

Question 18

What is involved in the biogenesis of miRNA?

Answer 18

• Canonical pathway
  ○ Downstream Pol II promoter might find miRNA precursors
  ○ Sometimes found in clusters transcribed together
  
  • Non-canonical pathway
    ○ miRNA encoded in an intron (mirtron)
    ○ Splice miRNA out -> mirtron lariat + mRNA
    ○ Lariat has to be debranched n base-paired
  • Canonical pathway can now fuse w the non-canonical pathway [similar structures]
  • Pri-mRNAs interact w Drosha
    ○ Drosha: RNAse III family member
    ○ Makes specific cuts at cleavage sites
    RESULT: pre-miRNA

Question 19

How are pre-miRNAs exported from the nucleus?

Answer 19

• Processed pre-miRNAs do not have a 5’ cap, nor a poly-(A) tail
  
  • Exportin binds to pre-miRNA [2 base overhang at the 3’ end of the pre-miRNA is recognized by exportin 5]
  • Associates w Ran-GTP which allows export thru the nucleus where the complex falls apart cytosolically
  • Releases pre-miRNA into cytosol
  • Recognized by another RNAse III
    All other components are recycled back into the nucleus

Question 20

How is RISC formed?

Answer 20

• Dicer is a cytosolic RNAse III family member
  
  • Dicer binds to terminal loop n removes it
  • RESULT: mature duplex w guide n passenger strand
  • Hsp90 n Hsp70 (cytosolic chaperones) targets Argonaute (AGO)
    ○ Binds -> alters conformation -> open conformation
  • Open conformation can accept miRNA
  • miRNA interacts w open form of AGO -> passenger strand degraded
  • RESULT: RISC (RNA-induced silencing complex)
    ○ Regulatory complex that can regulate the expression of other genes

Question 21

What is the role of RISC?

Answer 21

• RISC reduces expression of target mRNA by:
  ○ Rapid degradation of the mRNA (efficient)
  ○ Inhibition of translation (less efficient)
  
  • Extensive base pairing to target mRNA
    ○ AGO slices mRNA in 2 -> 2 sites for nucleases to attack
    ○ Recruit deadenylate
    ○ Rapid mRNA degeneration
  • Less extensive match to target mRNA
    ○ No slicing
    ○ RISC complex acts as a physical barrier to ribosome -> reduces efficiency of translation

Question 22

What are some examples of miRNA action?

Answer 22

• Neural stem cell differentiation controlled by NumbI protein
  ○ miR-184 is antagonistic to NumbI
  ○ Shuts down normal expression -> regenerates stem cell identity -> stops differentiation
  
  • Muscle development
    ○ Pax7 which drives differentiation
    ○ miR-1 n miR-206 inhibit Pax7
    ○ RESULT: increased differentiation of muscle cells
    ○ Reduction in stem cell identity
  • Concentrations of these antagonistic miRNAs determine cell fate

Question 23

What can happen when miRNAs go wrong?

Answer 23

• Dysregulation of protein expression
  
  • Cancer
  • Neurological defects, behavioural effects
  • Infertility
    Dicer is inactivated in fertilized eggs -> blocks the generation of all miRNAs at this developmental stage