Functions/Dysfunctions Of Protein Processing

Question 1

A protein is synthesized from the __________ to _______________

Answer 1

N-terminus

C-terminus

[sequentially adding aa’s to the C-terminus of the growing peptide chain

Question 2

True or false: the mRNA sequence will be complementary to the coding strand

Answer 2

False, the mRNA will be identical, but replace the Ts with Us

Question 3

How many codons code for amino acids?

Answer 3

61, 3 are stop codons that terminate translation

Question 4

What is the start codon?

Answer 4

AUG - codes for methionine

[fMet in prokaryotes]

Question 5

Why is the genetic code considered unambiguous and degenerate?

Answer 5

Unambiguous - each codon codes for only 1 aa

Degenerate - each amino acid can be coded for by more than one codon (exceptions = Met, Trp)

Question 6

What type of mutation is this and what is the effect on the resulting protein?

New codon –> same amino acid

Answer 6

Silent; no effect on protein

Question 7

What type of mutation is this and what is the effect on the resulting protein?

New codon –> new aa

Answer 7

Missense; variable effect on protein

Question 8

What type of mutation is this and what is the effect on the resulting protein?

New codon –> stop codon

Answer 8

Nonsense; nonfunctional protein

Question 9

What type of mutation is this and what is the effect on the resulting protein?

1+ nucleotides deleted or inserted

Answer 9

Frameshift; nonfunctional protein

Question 10

Sickle cell anemia results from what type of mutation?

Answer 10

Missense mutation of 6th codon in allele of gene for human beta-globin, from GAG to GTG (substitutes Val for Glu)

The mutation alters the conformation of HbA, causing it to aggregate and form rigid rod-like structures which deform RBCs into sickle like shape

Question 11

Duchenne Muscular Dystrophy results from what type of mutation?

Answer 11

Large in-frame and out of frame deletions to the dystrophin gene, leading to partially or non-functioning dystrophin protein

Leads to muscle wasting and wheelchair confinement by age 12, death by respiratory failure within 10 years

Muscle is replaced with fat and fibroid, elevated CK

Question 12

What post translational modifications occur to pre-mRNA and what is the purpose of these?

Answer 12

5’ cap and polyA tail

Makes mRNA more soluble for transport to cytoplasm for translation

Question 13

Each type of tRNA carries only one __________ amino acid, which is determined by its ___________ sequence

Answer 13

Activated; anticodon

Question 14

Amino acid activation is catalyzed by _____________ ___________, which requires ______ high energy bonds from ATP

Answer 14

Aminoacyl-tRNA synthetase; 2

Question 15

tRNA has an anticodon sequence that allows pairing with the mRNA codon, and transfers the activated amino acid on the ______ end of the correct tRNA

Answer 15

3’

Question 16

How many aminoacyl tRNA synthetases are there?

Answer 16

20, one for each amino acid

Question 17

What are the 2 uses of aminoacyl-tRNA synthetase?

Answer 17

Transfers AMP to the amino acid to form enzyme-bound aminoacyl-AMP

Transfers the aminoacyl group to the tRNA to activate the aa

Question 18

There are 2 subunits to a ribosome that assemble around the mRNA: the _______ subunit positions the mRNA and the _______ removes each amino aicd and adds it to the growing peptide chain

Answer 18

Small; large

Question 19

Compare/contrast the different ribosome structures in prokaryotes vs. eukaryotes

Answer 19

Prokaryotes = 70S (50S and 30S)

Eukaryotes = 80S (60S and 40S)

Question 20

The ribosomal complex consists of 3 sites. At which site is the aminoacyl-tRNA attached to the growing peptide chain?

Answer 20

Peptidyl (P) site

Question 21

The ribosomal complex consists of 3 sites. At which site does the mRNA codon accept the aminoacyl-tRNA?

Answer 21

Acceptor (A) site

Question 22

The ribosomal complex consists of 3 sites. At which site does the tRNA sit prior to exiting the ribosome?

Answer 22

Empty (E) site

[aka Exit site]

Question 23

Translation occurs in the 5’ to 3’ direction and consists of what 3 general steps?

Answer 23

Initiation
Elongation
Termination

Question 24

What are the initiation sequences in prokaryotes vs. eukaryotes?

Answer 24

P = Shine-Dalgarno sequence (AGGAGG)

E = 5’cap, 3’polyA tail, Kozak sequence, and ATP dependent mRNA scan

[the initiation site determines the reading frame for the whole length of the mRNA]

Question 25

The pre-initiator complex consists of:

an initiator tRNA to which _____ is bound, which attaches to the P site of a small subunit (_______________ tRNA in prokaryotes and ____________ tRNA in eukaryotes)

mRNA strand with ______ start codon

Other initiation factors (____ in prokaryotes, _____ in eukaryotes)

The large subunit is then added to complete the complex, which is driven by hydrolysis of ______.

Answer 25

GTP; N-formyl-methionyl tRNA; methionyl

AUG

IF; eIF

GTP

Question 26

How can prokaryotic vs. eukaryotic translation be determined in a figure?

Answer 26

If the mRNA does not have a 5’ cap or polyA tail, it is prokaryotic

Question 27

During elongation, the polypeptide chain is extended by the catalytic action of the ribosome:

Loading of an aminoacyl tRNA onto the ribosome, its anticodon base pairs with codon positioned on A site

Prior to loading, the aminoacyl tRNA is attached to GTP-bound ___________ _____________

Loading of tRNA is accompanied by _______ ___________ and release of GDP-bound EF from aminoacyl tRNA

Peptide bond formation is catalyzed by __________ __________

Answer 27

Elongation factor (EF)

GTP hydrolysis

Peptidyl transferase

Question 28

What are 4 the prokaryotic elongation inhibitors?

Answer 28

Tetracycline
Chloramphenicol
Clindamycin
Erythromycin

Question 29

______________ is a prokaryotic elongation inhibitor the inhibits peptidyl transferase in prokaryotes and mitochondria

Answer 29

Chloramphenicol

Question 30

_____________ is a prokaryotic elongation inhibitor that binds to the small 30S subunit, blocking entry of aminoacyl tRNA to the ribosomal complex

Answer 30

Tetracycline

Question 31

______________ and ___________ are prokaryotic elongation inhibitors that bind to large 50S subunit and block translocation of the ribosome

Answer 31

Clindamycin; erythromycin

[note that erythromycin is commonly used to treat pertussis]

Question 32

What are the 4 eukaryotic elongation inhibitors?

Answer 32

Cyclohexamide
Diphtheria toxin
Shiga toxin
Ricin

Question 33

Which eukaryotic elongation inhibitor inactivates GTP-bound eEF-2, interfering with ribosomal translocation?

Answer 33

Diphtheria toxin

Question 34

Which eukaryotic elongation inhibitor inhibits peptidyl transferase?

Answer 34

Cyclohexamide

Question 35

Which eukaryotic elongation inhibitors bind to large 60S subunit and block entry of aminoacyl tRNA to ribosomal complex?

Answer 35

Shiga toxin and Ricin

Question 36

Which elongation inhibitor causes premature chain termination in both prokaryotes and eukaryotes?

Answer 36

Puromycin

[resembles the 3’ end of the aminoacyl tRNA, enters A site and adds to growing chain, leads to premature release, mroe resistant to hydrolysis, stops the ribosome]

Question 37

What are the 3 stop codons?

Answer 37

UAA
UAG
UGA

Question 38

Termination is triggered when a stop codon resides in the ____ site, and ______ ________ are loaded

Answer 38

A
Release factors (RFs)

This triggers peptidyl transferase to cleave the ester bond between the C terminus of the chain and the tRNA

Question 39

What is the last event prior to dissociation of the ribosomal complex?

Answer 39

GTP hydrolysis

Question 40

The __________ pathway of protein sorting typically consists of proteins destined for the cytoplasm, mitochondria, nucleus, and peroxisomes. Synthesis usually begins and ends on ribosomes in the cytoplasm.

Answer 40

Cytoplasmic

Question 41

The __________ pathway consists of proteins destined for the ER, lysosomes, secretion, or membranes. The first 20 AA of the polypeptide contains an ER-targeting signal

Answer 41

Secretory

Question 42

If any protein lacks a translocation signal, it will remain in the _____________

Answer 42

Cytoplasm

Question 43

If there is an N-terminal hydrophobic alpha helix signal peptide, where is that protein destined to go?

Answer 43

Cytoplasmic pathway - mitochondria

Question 44

If there is a KKKRK translocation signal sequence, where is the protein destined to go?

Answer 44

Cytoplasmic pathway - nucleus

Question 45

If there is a C-terminal SKL translocation signal sequence, where is the protein destined to go?

Answer 45

Cytoplasmic pathway - Peroxisomes

Question 46

If there is a C-terminal KDEL retention signal, where is the protein destined to go?

Answer 46

Secretory pathway - ER lumen

[each protein in secretory pathway contains the N-terminal hydrophobic alpha-helix ER signal peptide]

Question 47

If there is a mannose 6-phosphate translocation signal, where is this protein destined to go? What pathological condition is associated with this?

Answer 47

Secretory pathway - Lysosomes

I-cell disease

[each protein in secretory pathway contains the N-terminal hydrophobic alpha-helix ER signal peptide]

Question 48

If there is a tryptophan-rich domain signal region and absence of retention motifs, where is the protein destined to go?

Answer 48

Secretory pathway - secretion

[each protein in secretory pathway contains the N-terminal hydrophobic alpha-helix ER signal peptide]

Question 49

If there is an N-terminal apolar region (stop-transfer sequence), where is the protein destined to go?

Answer 49

Secretory pathway - membranes

[each protein in secretory pathway contains the N-terminal hydrophobic alpha-helix ER signal peptide]

Question 50

What is the purpose of the N terminal hydrophobic alpha-helix on mitochondrial proteins?

Answer 50

Allows interaction with chaperone proteins (HSP70 family)

Translocation sequences for mitochondria are recognized by TIM and TOM

Question 51

Proteins in the secretory pathway contain an ER-targeting signal peptide with 1 or 2 basic amino acids like _______ or _______, and a 10-15 residue ____________ sequence

Answer 51

Lys; Arg

Hydrophobic

Question 52

With the secretory pathway, post-translational modifications occur in the ER and/or golgi. This occurs when the _________ wraps itself around the ribosome-mRNA-peptide complex, tethering to the membrane and temporarily halting translation.

Once the protein is directed into the ER lumen, translation resumes and is directed to the ____________ space.

Enzymes then cleave the _________ to release the protein

Answer 52

SRP (signal recognition particle)

Luminal

Signal

Question 53

I-cell disease, or Mucolipidosis II, is a severe form of _____________ storage disease where the tagging of lysosomal proteins with _________ is defective, resulting in high plasma levels of those enzymes.

Answer 53

Lysosomal

Mannose 6P

Question 54

What are the clinical manifestations of I cell disease?

Answer 54

By 6 months: failure to thrive, developmental delays, physical manifestations

Abnormal skeletal development, coarse facial features, restricted joint movement, stiff claw-shaped hands, dwarfism, clouding on corneas, hepatomegaly, splenomegaly, recurrent respiratory tract infections

Death usually by age 7 due to CHF or respiratory tract infection.

Question 55

________ proteins can spontaneously fold into native conformations, ________ proteins cannot due to risk of aggregation and proteolysis.

Answer 55

Small; large

Question 56

______________ are auxiliary proteins that protect the protein, and help it to fold into its proper tertiary structure

A subset of these proteins are called ____________, which are barrel-shaped compartments that admit unfolded proteins, and catalyze their folding in an ATP-dependent manner

Answer 56

Chaperones

Chaperonins

Question 57

What disease results from a mutation in the gene for the human B-globin, which alters the conformation of HbA, causing it to aggregate and form rigid, rod-like structures?

Answer 57

Sickle cell anemia

Question 58

Alzheimer’s disease results from a mutation in the gene for __________ __________ __________, which predisposes it to misfold and aggregate to form neuritic plaques in the brain.

Supplementation with ____________ has recent clinical significance.

Answer 58

Amyloid precursor protein (APP)

Lysine

Question 59

What are prions?

Answer 59

Transmissible misfolded proteins that convert their properly folded host counterparts to the same misfolded structure that they posses

Cause diseases like CJD, Kuru, and Mad Cow

Question 60

What causes Huntington disease?

Answer 60

Mutation in the Huntington gene results in the expansion of CAG triplet repeats which results in a polyglutamine tract, resulting in an abnormal HTT protein. mHTT forms intramolecular H-bonds, which eventually misfold and aggregate

Question 61

_______________ disease results from mutated a-synuclein that aggregates to form insoluble fibrils called Lewy bodies

This is caused by an N-terminal apolar sequence (the functional form has ___________, and the __________ form has insoluble beta sheets.

Results in neuronal death in the midbrain, reducing the availability of _____________

Answer 61

Parkinson

Alpha-helix; fibril

Dopamine

Question 62

Proteolytic cleavage converts inactive forms (zymogens) to active enzymes by “unmasking” the active site. How does this apply to digestive enzymes?

Answer 62

Trypsinogen –> trypsin

Chymotrypsinogen –> chymotrypsin

Question 63

______________ is a post-translational modification where the N-terminus is bonded to an acetyl or long-chain acyl residue, or thioesterification with a long-chain acyl group

Affects N-terminus and Cys residues

Answer 63

Acylation

Question 64

______________ is a post-translational modification involving covalent linkage to an amine.

What residue does this affect?

Answer 64

Acetylation

Lysine

Question 65

______________ is a post-translational modification with a covalent bond to sugar residues and occurs in the ER as they are translated

What residues does this effect?

Answer 65

Glycosylation

O-glycosylation affects Ser, Thr

N-glycosylation affects Asn, Gln

Question 66

______________ is a post-translational modification where a phosphate is linked via formation of an ester bond between phosphate and an -OH of an amino acid

What residues are affected?

Answer 66

Phosphorylation

Ser, Tyr, Thr, Asp, His

Question 67

______________ is a post-translational modification with the addition of a -COOH group?

What residue is affected?

Answer 67

g-carboxylation

Glu

Question 68

______________ is a post-translational modification with the covalent modification with ubiquitin?

What residue is affected?

Answer 68

Ubiquitination

Lysine

Question 69

______________ is a post-translational modification with the addition of an -OH group?

What residues are affected?

Answer 69

Hydroxylation

Pro and Lys

Question 70

______________ is a post-translational modification where oxidation achieves covalent linkages of Cys residues?

Answer 70

Disulfide bonds

Question 71

______________ is a post-translational modification where an isoprenoid group such as farnesyl or geranyl-geranyl groups are added to cysteins in C-terminal CAAX or CC motifs?

Answer 71

Prenylation

Question 72

What post-translational modification is thought to play a role in diabetic cataract formation?

Answer 72

Glycosylation of lens crystallins

Question 73

What is the most common glycosylation?

Answer 73

N-linked: -NH of Asn

Question 74

Glycosylation occurs when a precursor oligosaccharide (14-residue) is synthesized on membrane-embedded dolichol, catalyzed by glycotransferases. These glycotransferases can be inhibited by antibiotic _____________

Answer 74

Tunicamycin

Question 75

What is the general result of disulfide bond formation on protein stability?

Answer 75

Makes them more stable, but can be reduced in certain conditions

Question 76

Where does the formation and reorganization of disulfide bonds occur?

Answer 76

In the ER lumen