Protein Synthesis

Question 1

Structure of tRNA

Answer 1

75 bases
50% bases base paired
10% modified bases

Acceptor stem, T loop, anticodon loop, D loop, variable loop

Question 2

D Loop

Answer 2

Interacts with the synthetase enzymes

Question 3

Acceptor Stem

Answer 3

Site of amino acid charging by the synthetase enzymes

Always has conserved sequence: CCA

Question 4

T Loop

Answer 4

Interacts with 5S rRNA, helps position tRNA in the ribosome

Question 5

How are bacterial tRNAs synthesized?

Answer 5

• Multimeric: 2 or more tRNAs in a transcript, which are processed to monomeric precursors; may also be embedded in rRNA transcripts
• cleaved by RNases at 5’ and 3’ ends
• bases modified
• CCA added to 3’ end by tRNA nucleotidyl transferase (if not present already)

Question 6

Processing of prokaryotic tRNA transcripts (multimers)

Answer 6

1. 5’ end cleavage by RNase
2. 3’ end cleavage by RNase
3. Bases modified
4. CCA added

Question 7

Eukaryotic

Answer 7

Made as monomeric precursors
Leader sequence on 5’ end is cleaved off
There is an intron by the anticodon which masks it –> tRNA cannot be used until fully processed/modified

Removal of tRNA intron involves endonuclease cleavage and ATP-dependent ligation

Question 8

Prokaryotic Ribosome

Answer 8

50S- 23S + 5S rRNA
30S- 16S rRNA

70S

Question 9

Eukaryotic Ribosome

Answer 9

60S- 28S + 5.8S rRNA
40S- 18S rRNA

80S

Question 10

Processing rRNA

Answer 10

Transcribed by Pol I- moderately repetitive sequences
Self splicing ribozymes (no need for snRNPs)
Pol II brings in 5S rRNA

Question 11

Where in the cell do ribosomal subunits self assemble from rRNAs and ribosomal proteins?

Answer 11

Nucleolus

Question 12

Wobble sequence

Answer 12

Base pairing between codon/anticodon in 5’ and middle codon bases must be perfect

Some flexibility in 3’ base of codon (5’ anticodon)

Question 13

What does bacterial protein synthesis require?

Answer 13

mRNA (read 5’ –> 3’)

Ribosomes (subunits assemble on the mRNA)

Protein factors for initiation elongation, and termination

Activated tRNAs: one or more for each amino acid

Unique tRNA for initiation (f-met-tRNA)

Question 14

Which translational protein factors require GTP energy?

Answer 14

IF2-GTP: to bind Met-tRNA

EF-Tu-GTP: Delivery of aminoacyl tRNA to ribosomes
EF-G-GTP: Translocation factors
RF-3-GTP: Release of complete polypeptide chain

eiF2-GTP (eukaryotes): Helps bind Met-tRNA

Question 15

What does it mean that tRNA are adaptor molecules?

Answer 15

Bind both amino acids and mRNA codons

Question 16

Function of aminoacyl tRNA synthetases

Answer 16

Activation of amino acids prior to tRNA attachment

Question 17

2 steps in Amino Acid activation

Answer 17

Amino acid + ATP —-> aminoacyl adenylate: synthetase + PPi

Aminoacyl adenylate: synthetase + tRNA —> aminoacyl-tRNA: synthetase + AMP

SUM: AA + ATP + tRNA —> AA-tRNA + AMP + PPi

1) both carried out by aminoacyl tRNA synthetase
2) Synthetase specific for a given amino acid (ie: alanine tRNA synthetase)

Question 18

How does synthetase control accuracy?

Answer 18

1) Each synthetase must recognize R group on amino acid AND some part of the nucelotide sequence of the corresponding tRNA (either anticodon, specific sequence on acceptor stem, sequences somewhere else on the molecule)
2) Each synthetase has an activation site (for activation and attachment) and a hydrolytic site to correct errors
3) The aa-tRNA complex that leaves the synthetase will be used in protein synthesis with no further means of correcting errors

Question 19

How many energy bonds cleaves during aa activation?

Answer 19

Two high energy bonds cleaved/ aa activated- protein synthesis requires energy

1) cleavage of ATP
2) subsequent hydrolysis of pyrophosphate

Question 20

Initiation of protein synthesis in prokaryotes

Answer 20

1) Formyl group added to met. Complex of initiator tRNA bound to fmet and IF2-GTP

Question 21

First Codon in Prokaryotes

Answer 21

AUG

Question 22

How to locate first codon (P)

Answer 22

Shine Dalgarno sequence

Question 23

First amino acid (P)

Answer 23

IF2-GTP

Question 24

Initiation factor (P)

Answer 24

IF2-GTP

Question 25

Small subunit binding codon (P)

Answer 25

AUG

Question 26

Ribosome assembly codon (P)

Answer 26

AUG

Question 27

Elongation (P)

Answer 27

EF-Tu-GTP, peptidyl transferase, EF-G-GTP cycle

Question 28

Termination (P)

Answer 28

Stop codon/RF-GTP protein

Question 29

Shine Dalgarno Sequence

Answer 29

purine rich sequence: base pairs with 3’ end of 16S rRNA. Usually 7-10 bases upstream of AUG start codon

AUG start codon is not necessarily the 1st AUG, but the AUG closest to the Shine Dalgarno Sequence

Question 30

Elongation: Repeat of 3 Steps (P)

Answer 30

1) Codon-specific binding of the aminoacyl-tRNA to the A site of the ribosome mediated by EF-Tu-GTP

Question 31

Polyribosome

Answer 31

Complex of mRNA with multiple ribosomes called a polyribosome or polysome

Once the start codon is free, another round of initiation can begin –> many ribosomes can read mRNA at the same time

Question 32

Translation + Transcription

Answer 32

mRNA is read in translation from 5’ –> 3’ and is synthesized from 5’ –> 3’

Therefore can be translated while being synthesized

Question 33

Termination of Protein synthesis in prokaryotes

Answer 33

1) Stop codons: UAA, UAG, UGA appears in the A site
2) Stop codon recognized by RF1 and RF2 and they bind near the site so nothing else can come in
3) RF3-GTP binds ribosome
4) Hydrolysis of GTP
5) Cleavage of Ester bond (peptidyl transferase)
6) Release of protein, tRNA, mRNA, ribosomal subunits

Question 34

Tetracycline

Answer 34

Inhibitor of Protein Synthesis

Blocks binding of aminoacyl-tRNA to A-site of ribosome (prokaryotes only)

Question 35

Chloramphenicol

Answer 35

Inhibitor of Protein Synthesis

Resembles peptide bond; inhibits pepitdyl transferase activity (prokaryotes only)

Question 36

Initiation of Translation differences between Eukaryotes and Prokaryotes

Answer 36

• capped mRNA
• initiation factors: eIF for eukaryotic
• met-tRNA is not formylated
• Ribosomal subunit/met-initiator tRNA/factors scan along mRNA to find AUG start codon- no Shine Dalgarno

Question 37

First Codon (E)

Answer 37

AUG

Question 38

How is first codon located (E)

Answer 38

Kozak Sequence

Question 39

First amino acid (E)

Answer 39

Met

Question 40

Where does the small subunit bind to? (E)

Answer 40

At the cap

Question 41

Where does the ribosome assemble? (E)

Answer 41

AUG codon

Question 42

Where is termination? (E)

Answer 42

Stop Codon/ RF protein

Question 43

eIF4F

Answer 43

eIF4A-helicase
eIF4B- ATPase
eIF4E- binds eIF3 (on 40S ribosomal subunit)

cap binding proteins

Question 44

eIF4G

Answer 44

scaffold protein on the cap

Question 45

Kozak Sequence

Answer 45

Contains the first AUG after the AUG at the cap

Question 46

Eukaryotic Translation

Answer 46

1) 5’ cap interacts with the cap binding complex (A,B,E)
2) Presence of the eIF4F facilitates binding of the small-subunit tRNA
3) eIF4E facilitates binding of small subunit eIF3 initiator tRNA-eIF2-GTP (binds eIF3)
4) eIF4A (helicase), eIF4B (ATPase) move ahead to unwind secondary structure
5) small subunit eIF3-initiator tRNA eIF2 GTP scans the mRNA w/ the 40S subunit to find the AUG initiation codon (in Kozak consensus)
6) eIF5 then causes release of these accessory factors, GTP mediated re-organization and joining of the large subunit

Question 47

Loop structure on Eukaroytic mRNA

Answer 47

Facilitates ribosome recycling

Cap binding proteins interact with Poly A binding proteins

Question 48

HCV vs HIV

Answer 48

HCV

• RNA virus- flavivirus
• Infects liver cells
• uses host ribosomes to synthesize viral proteins but not into host DNA

HIV

• RNA virus- retrovirus
• infects human immune cells
• uses host DNA and genetic material to replicate

Question 49

Lifecycle of HCV

Answer 49

(+) RNA virus infects cells and conducts translation with RNA-dependent RNA polymerase

5A is a replication protein on cell ER
and 5B is a RNA-dependent RNA polymerase on cell ER

Using those proteins, create (-) RNA

Change back to (+) RNA

Now can infect other cells

Question 50

Ledipasvir

Answer 50

inhibits NS5A- replication complex protein

Question 51

Sofosbuvir

Answer 51

inhibits NS5B- RNA dependent RNA polymerase (

Question 52

If HCV RNA (+) is not capped, how can it be translated by the host ribosomes?

Answer 52

HCV IRES
Internal ribosome entry sequence
IRES is recognized by 40S subunit and eIF3 complex some how

Question 53

Ataluren-Facilitated Translation

Answer 53

Ataluren is a drug to help with CF mutation class 1 with shortened protein

Drug helps shift ribosome, tRNA-trp binds to stop codon –> still can get same length protein as opposed to before when the trp could not bind to stop codon