RNA

Question 1

RNA subtypes

Answer 1

mRNA: Largest
tRNA: transfers mRNA info to aa chain; smallest
rRNA: part of ribosome, binds aa together; most abundant

hnRNA: heterogeneous nuclear RNA

Question 2

Sites of RNA synthesis

Answer 2

Nucleoplasm: mRNA, tRNA
Nucleolus: rRNA

Question 3

Start codon

Answer 3

AUG – methionine

prokaryotes –formyl-methionine

Question 4

Stop codons

Answer 4

UGA
UAA
UAG

Question 5

Operon

Answer 5

Structural genes transcribed (coding region) + promoter region + all regulatory regions (enhancers and repressors)

Question 6

Transcription factors

Answer 6

Bind to promoter region (-75 CCAAT box, -25 Hogness/TATA box, and -10 Pribnow/TATAAT box) in order for transcription to take place

Question 7

Operator region

Answer 7

Binds repressor (stops transcription) or inducer (starts transcription), located between promoter and start site

Question 8

Response elements

Answer 8

Enhancer region and repressor region
Increase or decrease rate of transcription when bound by protein factors
Location may be close to, far from, or within the promoter region

Question 9

Common structural motifs

Answer 9

Helix-loop-helix
Helix-turn-helix
Zinc finger
Leucine zipper

Question 10

Lac operon

Answer 10

Excess glucose and excess lactose: operon OFF, CAP not bound

• lactose binds to lac repressor, changes shape and causes it to dissociate from DNA
• if lactose absent, lac repressor is bound

Excess glucose, absent lactose: Operon OFF both – lac repressor bound and CAP not bound

Absent glucose causes CAP to bind

Absent glucose, absent lactose: Operon OFF, lac repressor bound

Absent glucose, excess lactose: Operon ON, RNA polymerase binds and RNA transcribed

CAP: catabolite activating protein – TF

Question 11

Termination of prokaryotic RNA transcription

Answer 11

Rho factor of E coli – RNA-dependent ATPase) – energy of ATP knocks RNA poly off template

GC-rich DNA -> GC same strand binding forms stem-loop (hairpin) in RNA -> pause in RNA poly-> weak RNA bonds -> separation of RNA poly

Question 12

RNA processing and splicing

Answer 12

Allows it to leave nucleus

Cap 5’ end: 7-methyl-guanosine by SAM (s-adenosyl-methionine)

Poly-A 3’ end – by poly-A polymerase (signal AAUAAA)

Remove interons – euk: splicosomes remove interons, spice together exons

Question 13

Eukaryotic RNA polymerases

Answer 13

RNA poly 1: rRNA
RNA poly 2: mRNA
RNA poly 3: tRNA

(order of use)

Question 14

Alpha-amantin

Answer 14

Mushroom toxin inhibits RNA poly II

Causes hepatotoxicity, liver failure

Question 15

Prokaryotic RNA polymerase

Answer 15

Single RNA poly

Inhibited by rifampin

Question 16

Rifamin – 4 Rs

Answer 16

Rifampin
RNA poly inhibitor
Red secretions
Revs up CYP450

Question 17

Protein translation

Answer 17

mRNA -> ribosome -> protein and rRNA

Question 18

Ribosomal subunits

Answer 18

Euk: 60S + 40S = 80S (Even)

PrOk: 50s (has 23 rRNA molecule) + 30s = 70S (Odd)

Question 19

Initiation of protein synthesis in prokaryote

Answer 19

Initiation factors IF-1, -2, -3

Assist in assembly of small ribosomal subunits (30S) to first tRNA – fMET

IF2 binds 30S then fMET tRNA binds at the P site (subsequent bind at the A site)

50S hydrolyses GTP on IF2 -> energy release
-50S attaches to 30S = 70S prok ribosome

Question 20

Linezolid action

Answer 20

Binds 50S, inhibits initiation of prok ribosome

Question 21

Tetracycline action

Answer 21

Late – prevents tRNA from binding A site

Question 22

Elongation

Answer 22

2nd step of protein synthesis

EF (elongation factors) required for subsequent tRNA to bind A site
Energy from GTP

50 S has peptidyl transferase activity – transfers aa from P site to aa on A site
-in 23 s rRNA in prok

Translocation – ribosome complex moves down mRNA 3 nt

• > tRNA shift to next site: A-> P, P->E, E-> out to be recharged
• requires EFG in prok and EF2 in euk

Stop codon : UGA, UAA, UAG terminates

Question 23

Chloramphenicol action

Answer 23

Inhibits 23S rRNA – blocking peptidyl transferase activity

Question 24

Antibiotics inhibiting 50S translocation step

Answer 24

Streptogramins
Lincomycin
Clindamycin
Macrolides

Question 25

Termination

Answer 25

3rd step of protein synthesis

don’t match tRNA
release factor binds to mRNA
-hydrolyses GTP
-releases polypeptide from ribosome
-subunits/complex disassociates

Question 26

Post translational modification possibilities

Answer 26

C- or N- terminal trimed

Covalent modifications: add molecule
-glycosylation, hydroxylation, phosphorylation

disulfide bonds

protein folding

• primary structure aa sequence
• secondary structure – alpha helix/beta pleated sheet
• tertiary/quaternary structure- folding