Mechanisms of Translation

Question 1

Overview

Answer 1

• mRNA threads through subunit interface + is decoded
• 3 tRNA binding sites (A,P,E)
• Antibiotics

Question 2

Recognition of the tRNA + mechanism for correct amino acid

Answer 2

• Apart from tRNA initiator, all aminoacyl tRNAs interact w/ the ribosome + elongation factors in the same way
• 2o structure (RNA PolIII, 5’ end removed by RNase P, CCA added to 3’, short intron removed, bases modified)
• 3o structure (Non Watson-crick bp, triple base interaction, type I and II)

Question 3

Charging tRNAs

Answer 3

• Aminoacyl tRNA synthetase recognise both aa + tRNA

- Each tRNA has own E

Question 4

Mis-charging

Answer 4

• Mutating genes for tRNA → aa linked to wrong tRNA
• Mutations = in anticodon, D loop or acceptor stem of tRNA
• Freq of error rate = 10^-4 → 2 recognition steps
• 2 steps as recognition of aa by synthetase involves non-covalent interaction btw aa + E but some only differ by 1 methyl
• 2 steps separated by irreversible step to make frequency multiplicative

Question 5

Example - isoleucine tRNA synthetase

Answer 5

1. Isoleucine binding in 1st step: binding of Ile + forming Ale-adenylate 10^2 x better than Val binding
2. Rate of hydrolysis in 2nd: valyl-adenylate hydrolysed by E ↑ faster than isoleuc-adenylate, x proceed to tRNA

Question 6

Comparison of 30S + 50S subunits

Answer 6

• RNA domain fits together that determines 50S
• In AS + 30S interaction face = no proteins, ribozyme
• +vely charged tails on 12 proteins make interaction w/ RNA, stab
• 50S = monolithic

Question 7

Experimental evidence

Answer 7

• Free cell system, buffer and varying conc of soluble extract
• Yields ribosome carrying polyPhe-tRNA, ribosomes washed
• Incubated w/ puromycin
• 50% of ribosome release 14C labelled polyPhe-PM → ribosome itself forms peptide bond, x need E-supplying material
• Then was ribosome, add GTP, remove PM
• Remaining 50% of ribosome release 14C-Phe transferred → ribosomes have PM-reactive site + PM unreactive site

Question 8

Association of soluble factors to aa-tRNA

Answer 8

• Non-ribosomal = EFT/EFG
• EFT = EfTu (binds GTP) + EfTs (GEF, removes GDP from EfTu)
• EfTu = ↑ abundant, affinity is higher for GDP, only EfTu-GTP complexes w/ aatRNA

Question 9

Matching codon to anticodon

Answer 9

• Correct = 6 H bonds, incorrect = 5
• ‘wobble interaction’, even in correct orientation = imperfect
• G=U = acceptable at 3rd but not 1/2nd
• Wobbles take up ↑ space but little difference in binding E

Question 10

Different conformations of tRNA

Answer 10

• Ternary complex
• A*/T conformation (both cognate and non-cognate)
• A/T (only cognate, 30o bend in tRNA)

Question 11

How does the ribosome maintain accuracy?

Answer 11

• Mutations in ribosomal protein (S4,55+12 = close to decoding site)
• S4/5 = ram mutation, faster than WT
• S12 = Str mutation, slower than WT
• Ribosome has 2 conformations (open conf, E site is strong, A weak, alternative = opposite)
• Only cognate tRNAs cause closure of 30S

Question 12

Overall structure + maintaining accuracy

Answer 12

• Ribosomes decode mRNA codons by selecting aa-tRNAs delivered by Ef-Tu
• Both cognate + near cognate explore A of open 30S
• Initial codon-independent binding of ternary complex, codon recognition, GTPase activation
• G530 stabilises codon activation helix, step-wise latching of decoding centre, 30S closes, Ef-Tu docks w/ SRL, EfTu activated, accommodation of aa-tRNA
• Near-cognate x induce G530 latch, favours open 30S
• A minor interactions at pos I stabilise non-cognate W-C in enol tautomer

Question 13

Decoding

Answer 13

• Binding of aa complex to ribosome surface is weak, binding E of codon/anticodon critical for cognate vs non cognate
• Non cognate diffuse away
• G530, A1492/3 change position if P/A empty
• Interactions: A minor at pos I (A forms 4 H bonds w/ G-C, perfect geometry)
• A minor at 1 w/ wobble (A forms 2 H bonds w/ G-U, different geometry)

Question 14

Summary of decoding

Answer 14

• P/A kink, DC restricted allows geometry of nucl 1+ 2 of codon
• No restraint on 3
• G-U in pos 1 or 2 creates repulsion unless Enol tautomer
• Mutations can occur if make more space w/ mutations so accommodate wobble e.g. paromycin opens A site

Question 15

Domain closure

Answer 15

• 30S domain closure needs W-C bp at pos 1+2 anticodon
• G530 has 2 structures: semi-on (forms H bond w/ codon-anticodon) on (3A movement, H bond formed at A1492 at 2+3)
• Near cognate, G530 x stabilises codon-anticodon
• Sometimes G530 stabilises Watson crick like codon anticodon helix → miscoding
• Cognate: samples 30S → shoulder moves → Ef-Tu docks at SRL → GTPase active → G530 in semiON, → ON
• Near cognate: ternary complex samples A site of open 30S subunit w/o inducing 30S rearrangements

Question 16

Selection and accommodation

Answer 16

• 30S works w/ 50S to ensure accommodation of cognate aa-tRNA in P + move tRNA
• Using FRET, work constant of 2 steps
• Shoulder lifted + stabilised on binding cognate tRNA during selection
• Fastening cognate tRNA A site → additional intersubunit bridge
• L25 holds tRNA in A site (x near-cognate)
• ## Near-cognate produces distorted protein extensions in A site

Question 17

Proofreading

Answer 17

• Entire anticodon loop monitored by nuc. from 16S rRNA + 23S rRNA
• Elbow region scanned by rRNA + ribosomal protein determines whether to accom. acceptor tRNA

Question 18

Decoding centre activates Ef-Tu accomodation

Answer 18

• G530 shifts to ‘latch’ to decoding centre → 30S closure
• Accom = movement of aa-tRNA after Ef-Tu release into peptidyl transferase centre, CCA moves 100A
• Puromycin stab decoding centre
• 23S RNA active-site residues adopt different conformation depending on A site occupancy (w/o substrate, ribosome protects P site)

Question 19

Peptidyl transferase reaction

Answer 19

• Need Eftu.GDP to be dissociated from the ribosome (x need E)
• Catalytic centre of ribosome = just RNA, enhances peptide
• 4x10^6 rate enhancement
• Proton-shuttling via P-site adenosine 2’OH of A76
• Antibiotics

Question 20

Translocation

Answer 20

• Due to peptide bond leaving deactyl tRNA in P site + lengthened tRNA in A
• EFG needed, binds A site
• EFG mimics ternary complex
• EFG departure leaves bs preformed for acceptance of ternary complex
• peptidyl tRNA moves A→P, deaceylated tRNA moves p→E
• New codon in A site
• Ribosome can bind another EfTu.GDP but x another EfTu
• Need to break H bonds btw tRNA-mRNA in A site
• EFG catalyses tRNA translocation by disrupting interactions btw decoding centre + codon-anticodon duplex

Question 21

Exit tunnel

Answer 21

• Stretches from peptidyl transferase + ends back of large subunit
• SRP interacts w/ protein at end of tunnel
• Around 100A long, accommodates diameter of a helix
• Co-translational proteins bind
• Antibiotics

Question 22

Initiation

Answer 22

• 70S initiates
  1. Vacant 30S binds IF3 + 2, IF1 blocks A site, A1492/3 buried in/btw IF1/2
  2. fMet tRNA recruited, binds close to IF2
  3. mRNA binds, need correct Aug for initiator, 2o affects rate
  5. 2o unfolded facilitated by IF2-GTP
  6. Isomerisation of 30S allows P codon-anticodon interaction
  7. 30S docked by 50S
  8. GTPase of IF2 activated, GTP hydrolysed
  9. IF3 + 1 dissociate, IF2 undergoes conf change
  10. FMet-tRNA adjusted on ribosome occupying P/1
  11. Pi dissociates from IF2-GDP, helix-exit transition in switch II
  12. IF2 leaves
  13. Ef-Tu-GTP complex binds 70S, delivers ribosomal A site aminoacyl tRNA
• Fmet tRNA bound in P site of 50S donates formyl-meth to A site bound aminoacyl - tRNA

Question 23

Termination of translation

Answer 23

• Peptide elongated as peptidyl tRNA but cells have no peptidyl tRNA, released by hydrolysis
• Chain terminating codons in A site
• Protein factors release NfMet: RF1 recognises UAG/UAA, RF2 recognises UAA + UGA
• RF1/2 bind A site, peptide released via hydrolytic cleavage
• RF3 binds RF1/2 w/ GDP, GTP displaces GDP, RF3 released
• Release factors alter specificity of peptidyl transferase (in elongation, peptidyl transferase transfers peptide from ester linkage w/ tRNA to peptide w/ incoming NH2)
• Release factors have conserved GGQ, H bond distance from A76
• Upon recognition of stop, conserved Q in GGQ inserted into catalytic centre

Question 24

RF1-3

Answer 24

• RF1/2 stay on ribosome, need to be recycled
• RF3 froms complex w/ GDP or GTP
• RF3.GDP binds ribosome/RF1/2 complex weakly, GTP means binds tightly + displaces RF1/2
• Hydrolysis of GTP liberates RF3/GDP, ribosome release factor releases deacylated tRNA
• Efficiency of termination depends on nucleotide to the 3’ side of termination codon

Question 25

Rates + antibiotics

Answer 25

• Rate = important for accuracy
• Similarity btw eukaryotes + prokaryotes (all go into A site, long projection, molecular mimic)
• Puronycin = chain termination
• Fusidic acid = translocation

Question 26

Extra - summary

Answer 26

• Initiation needs 30S, 50S, IF1-3
• 30S carrying initiation factors binds initiation site → initiation complex
• IF-3 released so 50S joins 30S mRNA complex
• tRNA of 30S bacterial ribosomal subunit has a complementary sequence that bp SD during initiation
• NH2 of initiator tRNA has formulated methionine

Question 27

Extra - Fmet + IF2

Answer 27

• In initiation complex, small subunit alone is bound mRNA
• Initiation codon lies within P site carried by small subunit
• Large subunit binds, tRNA bs converted to P/A sites
• Initiation = when AUG/GUG lies within ribosome binding site, only initiator tRNA enters partial P site
• Accessory factors are critical
• All aminoacyl tRNAs associate w/ ribosome by binding to an accessory factor
• Ef-Tu places amino-acyl tRNA in A site, x bind fmet-tRNA

Question 28

Extra - Initiation in eukaryotic mRNA

Answer 28

• Small subunit 1st recognises 5’ end of mRNA, moves to initiation site where joined by larger
• 1st feature recognised = methylated 5’ cap
• 40S recognises 5’ then migrates along mRNA
• Melts 2o structure
• Migration stops when 40S encounters AUG start in right context

Question 29

Extra - elongation factors

Answer 29

• e1F2 + met-RNAi, e1F1,3 +A bind 40S → 43S preiniaiton complex
• e1F4A,B,E,G bind 3’ of mRNA → capping binding complex
• This complex associates w/ 3’ end of mRNA via e1FG
• 43S binds initiation factors at 5’ end of mRNA + scans for initiation codon
• 60S x work until E1F2/3 are released, facilitated by EIF5B
• Once ribosome assembled, aa-tRNA enters A site w/ help of Ef-Tu
• Dissoc once amino acyl tRNA in place
• Ef-Tu-GTP binds aa-tRNA → ternary complex
• Anticodon binds A site of 30S, codon-anticodon recognition triggers conf Δ
• Ef-Tu releases amino acyl site, amino acyl ends twins closed
• Peptide bond synthesis makes deacylated tRNA In P site + peptidyl tRNA in A
• Translocation

Question 30

Extra- elongation factors bind alternatively to ribosome

Answer 30

• Ef-Tu + Ef-G x bind at the same time
• Ef-Tu released before Ef-G binds, then Ef-G released before aa-tRNA-Ef-tu-GTP binds
• Structure of Ef-G mimics Ef-Tu bound to acceptor stem, compete for same bs?
• Re-orientation of Ef-G occurs at translocation
• Head of 30S swivels around neck when complete ribosome forms