Protein Homeostasis

Question 1

What does it mean that the genetic code is specific, universal, and degenerate?

Answer 1

Specific: 1 codon => 1 amino acid

Universal: Approximately the same in all organisms

Degenerate: Codons are redundant–multiple codons can encode the same AA via 3rd base wobble. These different codons are used with different frequencies and regulate translation rate as the minor use codons are present in lower abundance/concentration

Question 2

What is a reading frame?

Answer 2

The way in which an mRNA is divided into triplets for translation

Question 3

Describe the structure of an aminoacyl-tRNA.

Answer 3

Stem loop cloverleaf structure forms due to base pairing between complementary antiparallel strands.

• Anticodon loop
• 2 other loops important for recognition

The amino acid is attached to the 3’ end of the tRNA via an acyl linkage connected to CCA.

Question 4

How are aminoacyl tRNA’s synthesized?

Answer 4

Each amino acid has a specific amino acid tRNA sythetase that links the amino acid to the tRNA, requiring 2 ATP equivalents.

Question 5

Describe the structure of the ribosome.

Answer 5

70 structural proteins + catalytic rRNA

Large and small subunits

3 tRNA binding sites: E, P, A

Question 6

How do the ribosome, mRNA, and tRNAs assemble?

Answer 6

1. eIF2 ternary complex formation
   - Initiator tRNA binds GTP-eIF2 (eukaryotic initiation factor 2)
2. 43S complex formation
   - tRNA-eIF2 complex binds to the P site of the 40S (small) ribosomal subunit
3. mRNA activation
   - mRNA 5’ cap binds cap binding protein (CBP)
   - CBP has many 20 subunits including eIF4E
   - binding recruits more initiation factors
   - poly-A tail binds the cap forming a circle
4. 48S complex formation
   - mRNA-CBP associates with tRNA-40S complex
5. Scanning for start codon
   - RNA helicase unwinds secondary structure from 5’ -> 3’ and scans for a start codon
   - requires ATP
6. Start codon recognition
   - eIF2 conformation change and GTP hydrolysis
   - eIF2 dissociates
7. 60S subunit binds to tRNA in P site with GTP hydrolysis and remaining initiation factors displaced
8. 80S initiation complex is assembled.

Question 7

How do eukaryotic and prokaryotic translation differ?

Answer 7

Prokaryotes: translation is co-transcriptional

Eukaryotes: transcription and translation are spatially and temporally separated

Question 8

How is cap-independent translation initiated?

Answer 8

Found often in viruses (decapping enzymes) but also sometimes in vertebrates

IRES = internal ribosome entry site for internal start codons
- stem loop structure; all initiation machinery assembles here

Question 9

What are the steps of elongation?

Answer 9

1. Random association of tRNAs with mRNA in the A site
2. Proofreading by EF1a-GTP
   - If proper pairing, tRNA lingers
   - GTP hydrolysis by EF1a
3. Hydrolysis of AA-tRNA bond
   - AA on P site tRNA transfered to A site AA
   - peptidyl transferase
4. Translocation
   - Ribosome moves along mRNA, moving new chain to P site
   - Old tRNA released
   - Requires EF2-GTP

Growing chain emerges via channel in large subunit and is folded

Question 10

What are the energy requirements for elongation?

Answer 10

2 ATP to charge each tRNA
2 GTP to add each AA

50 kDa protein (~450 AA) = 1800 ATP

Question 11

How is translation terminated?

Answer 11

1. Release factor binds a stop codon in the A site
2. Termination via hydrolysis:
   - polypeptide chain released from E site
3. Ribosomal dissociation

Question 12

What are polyribosomes?

Answer 12

During translation in the cytosol, after one ribosome moves from the initiation region another ribosome can bind. mRNAs usually have multiple ribosomes translating, > 80 nt apart.

In the ER, only 1 ribosome per mRNA because an SRP binds to the 5’ cap for translocation

Question 13

How does heme regulate globin mRNA translation?

Answer 13

Hemoglobin = 2 a-globin + 2 B-globin + heme. Syntheses must be coupled to avoid energy waste and ROS production.

Heme regulated inhibitor kinase:

• activated by low heme => phosphorylates eIF2 => inhibits protein synthesis
• inactivated by high heme

Question 14

What are ferritin and transferrin receptor and how do iron levels regulate their translation?

Answer 14

Transferrin receptor

• transports extracellular Fe to cytosol
• 3’ stem loop; if exposed -> endonucelolytic cleavage and mRNA degradation

Ferritin

• binds cytoplasmic Fe
• 5’ stem loop; if blocked translation is blocked

Cytosolic aconitase = cytosolic enzyme that binds stem loops in the absence of Fe. In the presence of Fe, binds Fe.

Iron starvation: ferritin translation blocked, transferrin receptor mRNA protected

Excess iron: ferritin translation ok, transferrin receptor mRNA degraded

Question 15

How is mRNA stability determined?

Answer 15

5’ cap structure:

• prevents recognition by exonucleases
• decapping (by virus or cleavage from thermal instability) => rapid 5’ -> 3’ degradation

poly-A tail length:

• ~200bp bound with poly-A binding proteins
• gradual shortening: exposed regions between proteins will be randomly cleaved in the cytosol
• binding proteins cannot bind when tail < 30 => rapid 3’ -> 5’ degradation by exonucleases

Question 16

What are micro RNAs?

Answer 16

20-22bp ssRNAs homologous to RNAs

Bind mRNAs and modify translation depending on binding site

• initiation block: binding cap or start codon
• elongation block: cause ribosome drop off or proteolysis
• decapping
• deadenylation of tail

1 microRNA can regulate 100s of mRNAs; multiple microRNAs may regulate 1 mRNA

Question 17

How does mTOR regulate cell growth and proliferation?

Answer 17

mTOR = “master regulator” kinase

1. Growth factors and nutrient sensing activate mTOR
2. mTOR upregulates ribosome synthesis and (de)phosporylates ribosomal subunit proteins and initiation factors

Question 18

What is proteostasis?

Answer 18

Maintaining proper protein composition by balancing synthesis and stability

Molecular chaperones help with correct folding.

Degradation systems deal with improperly folded proteins.

Question 19

How does the ubiquitin proteasome system degrade proteins?

Answer 19

Ubiquitin proteasome = collection of proteases surrounded by caps

1. Tagging for degradation
   - E1 (only 1) activates the ubiquitin monomer, requiring ATP
   - Activated ubiquitin transferred to E2 (dozens), which binds E3.
   - E3 (100s–substrate specific) binds the substrate and transfers the ubiquitin from E2 to substrate
2. Recognition of poly-ubiquitin chain by proteasome caps
3. Cleavage of ubiquitin and polypeptide degraded to individual AAs

Question 20

What are the functions of lysosomes?

Answer 20

Digestion of macromolecules from phagocytosis, endocytosis, autophagy, or direct transfer using acid hydrolases

Destruction of microbes

Lysosomotropism of drugs

Question 21

How are misfolded ER proteins degraded?

Answer 21

ERAD = ER Associated Degradation

1. Misfolded protein carried thru ER lumen by chaperone to ER protein translocator
2. Sugars removed by N-glycanase
3. Ubiquination and degradation

Question 22

What is the unfolded protein response and when does it occur?

Answer 22

Lots of ERAD suggests a mutation and triggers unfolded protein response

Sensors for misfolded proteins in the ER lumen are kinases and transcription factors with cytosolic effects

Activation of genes to increase protein folding capacity of ER like chaperones and glucosyl transferases

Question 23

What is consumed via macroautophagy?

Answer 23

• virus
• protein aggregates
• organelles: degrade proteins to recycle AAs when there is a need for AAs

Question 24

What are the steps of macroautophagy?

Answer 24

1. Autophagy induction by LC3
2. Phagophore formation
3. Elongation of phagophore and engulfment
4. Autophagosome formation
5. Fusion with lysosome or early endosome to add hydrolases
6. Lysosomal degradation

Question 25

What is microautophagy?

Answer 25

Lysosomes engulf small amounts of cytoplasm: bulk or selectively (substrates bind hsc70, which binds to a receptor on the lysosome and is then engulfed)

Question 26

What is chaperone mediated autophagy?

Answer 26

Direct transfer of proteins into lysosomes:

1. Chaperone complex (including hsc70) recognizes KFERQ motif
2. Binding of LAMP2 receptor on lysosomal surgace
3. Unfolding and translocation of protein into lysosome

Question 27

What are the paths of protein degradation?

Answer 27

Ubiquitin proteasome system

ERAD and URP

Lysosomal degradation:

• macroautophagy
• microautophagy
• chaperone mediated autophagy

Question 28

What can cause misfolded proteins leading to aggregation?

Answer 28

• Mutations
• Defects in translation
• Environmental stress
• Aging

Question 29

What causes the formation of amyloid?

Answer 29

Nonphysiological proteolysis

Defective proteolysis

Mutations

Question 30

How is amyloid formed?

Answer 30

1. Proteins rich in a-helical structures misfold, forming antiparallel beta sheets.
2. Soluble oligomers of B-sheets aggregate forming protofibrils
3. Protofibrils aggregate into fibrils

Question 31

What diseases are related to protein aggregation and amyloid deposits?

Answer 31

ALS, Alzheimers, CJD, mad cow, scrapie, Parkinson’s (Lewy bodies), Huntington’s (intranuclear exclusions)

Question 32

What hypotheses exist about how protein aggregates affect cellular functions?

Answer 32

Depletion of normal protein => loss of function

Misfolded/aggregated protein and protein deposits => inflammation

Misfolded/aggregated protein and protein deposits => gain of toxin

Question 33

What are prions?

Answer 33

Infectious amyloid with self-seeding growth

Host-to-host, molecule-to-molecule, and cell-to-cell transmission

CJD, kuru, mad cow, scrapie, fatal familial insomnia, Gerstmann-Straussler-Scheinker