Second Messanger Systems

Question 1

What occurs when epinephrine binds to beta-adrenergic receptor?

Answer 1

1. The occupied receptor causes replacements causes replacement of the GDP bound to Gs by GTP, activating Gs
2. Gs (a subunit) moves to Adenylyl Cyclase and activates it
3. Adenylyl cyclase catalyzes the formation of cAMP (and 5’-AMP)
4. PKA is activated by cAMP
5. Phosphorylation of cellular proteins by PKA causes the cellular response to epinephrine
6. cAMP is degraded, reversing the activation of PKA

Question 2

What are the changes in G-protein on formation of hormone-receptor complex?

Answer 2

1. Hormone binds to receptor
2. Exchange of GDP for GTP on Ga. dissociation of B y-subunits
3. Activation of Adenylate cyclase by Gsa-GTP
4. Ga has intrinsic GTPase and dissociates from adenylate cyclase
5. Gas-GDP reassociates with By(beta gamma)-subunits

Gsa- GTP is active

Ga subunit has intrinsic GTPase activity

Gsa-GDP is inactive

Question 3

How is protein kinase A?

Answer 3

Epinephrine or Norepinephrine bind to B-adrenergic receptor

Glucagon binds to glucagon receptor

Gsaos activated which activates adenylate cyclase, adenylate cyclase converts ATP to increase cAMP

Activates Protein kinase A

Question 4

What are the steps in adenylate cyclase activation?

Answer 4

1. Hormone binds to G-protein coupled receptor
   
   • The inactivation G protein is bound to GDP
2. Activated receptor interacts with G-protein causing Ga-subunit to release GDP and bind GTP ; Ga subunit-GTP bound and By(beta gamma ) dimer dissociate
3. GTP bound Ga-subunit activates adenylate cyclase
4. Adenylate cyclase catalyzes the conversion of ATP to cAMP (second messenger)
5. cAMP binds to regulatory subunits of protein Kinase A; catalytic kinase subunits are active
6. Catalytic kinase subunits transfer phosphate from ATP to Ser or Thr residues of protein substrates (enzymes) - Covalent modification of enzymes
7. Phosphorylation of enzymes can activate or inhibit enzymes —> Regulation metabolic pathways

Question 5

What is the termination of signal adenylate cyclase

Answer 5

1. Intrinsic GTP —> GDP+Pi GTPase activity of G-a subunit (intrinsic timer)
2. Phosohodiesterase enzyme hydrolyzes cAMP to AMP
3. Hormone dissociates from receptor

Caffeine and theophylline inhibit cyclic nucleotide phosphidiesterase and prolong effects of cAMP

Question 6

What are the enzyme regulatory mechasnisms ?

Answer 6

• Availability of substrates (minutes)
• Allosteric activation/inhibition of enzymes (minutes)
• Covalent modification of enzymes (minutes to hours ) -mediated via Protein kinase A
• Induction (up-regulation) or repression (down-regulation) of enzyme synthesis (hours to days)

Question 7

What are the cAMP effects on PKA?

Answer 7

cAMP Exerts effects via activation PKA:Rapid effect (sounds to minutes)-covalent modification of pre-existing enzymes

cAMP/PKA also exerts effects via gene regulation through CREB: response relatively slow -hours to days

Question 8

How does cAMP have an effect on gene expression?

Answer 8

CREB- cAMP response element binding protein

CRE- cAMP Response element

Gs activates Adenylate cyclase leads to increase cAMP. cAMP leads to protein kinase A. CREB and PKA leads to CREB-P

CREB-P interacts with CRE in DNA to affect gene expression

Question 9

Describe a-2 adrenergic receptors

Answer 9

• Epinephrine binds to a2-adrenergic receptors activates Gia
• Inhibits Adenylate cyclase
• Reduces intracellular cAMP levels
• Compare a2 and B

Question 10

Describe the affect of bacterial toxins on Ga subunits by covalent modifications

Answer 10

-ADP-ribosylation (addition of ADP-ribose)—> inactivation or proteins

• Cholera toxin ADP-ribosylates Gas—> Continuously active Gas
  
  • Intrinsic GTPase activity of Gas destroyed, Gas locked in GTP-bound state
  • Increased cAMP in intestinal mucosal cells
  • Opening of CFTR—> loss of electrolytes and water —> Severe watery diarrhea
• Pertussis toxin ADP-ribosylates Gai —> Continuously inactive Gai
  
  • Increased cAMP in respiratory-tract cells
  • Respiratory distress, and whooping cough

Diphtheria toxin ADP-ribosylates eEF-2

Some pathogenic E. coli toxin also ADP ribossylates Gsa

Question 11

How does a-1 adrenergic receptors work?

Answer 11

Epinephrine/norepinephrine binds to a-1 receptor

Activates Gqa

Activates Phospholipase C

Forms second messengers

• IP3
• Ca2+
• DAG

The activates PKC

Question 12

What does Phospholipase C do?

Answer 12

Cleaves PIP2 to generate IP3 and DAG

Question 13

Explain in detail the phosohoinositide system

Answer 13

Second messengers: IP3, DAG, Ca2+

1. Epinephrine binds to a-1 receptor
2. Activates Gqa which binds to GTP (in exchange for GDP)
3. Gqa-GTP activates Phospholipase C
4. PLC cleaves PIP2 to IP3 and DAG
5. IP3 causes Ca2+ release from endoplasmic reticulum
6. DAG and Ca2+ activate Protein kinase C fir cellular responses
   
   • PKC requires DAG, Ca2+ and phospholipids (membrane)

Cholinergic muscuranic receptors activate Phospholipase C isoforms to form IP3,DAG and Ca2+

Question 14

What does cGMP do?

Answer 14

Second messenger in smooth muscle relaxation, platelet aggregation and in visual system

Question 15

Describe guanylate cyclase

Answer 15

Two forms

• Membrane bound guanylate cyclase (binds to signals outside cell and prod7ce cGMP inside cell)
  
  • Activated by atrial natriuretic peptide)
• Cytosolic guanylate cyclase (activated by NO)

G-protein isn’t involved

Question 16

Explain nitric oxide (NO)

Answer 16

Syntgesized by arginine

• NO (gas) synthesized in endothelial cells (capillaries) diffuses to vascular smooth muscle where it activates cytosolic guanylate cyclase
• cGMP levels increase within smooth Muscle cells
• Activates protein kinase G which phosphorylates various proteins
• Vasvular smooth muscle relaxation by leading to phosphorylate myosin light chain kinase and inhibits it
• Less phosphorylation of myosin light chains(vasodilation)

Question 17

What regulates vasodilation?

Answer 17

G-protein and NO woke together to regulate vasodilation

Involvement of several intracellular messengers to regulate vasodilation (IP3, Ca2+, NO, cGMP)

Question 18

Explain the regulation of vasodilation

Answer 18

1. Activation of cholinergic (Muscuranic) receptors in the endothelium by acetylcholine
2. Activation of Phospholipase C (isoenzyme) results in release of IP3 —> and increases intracellular calcium
3. Calcium binds to calmodulin—> activates NO synthase, producing. NO in endothelial cells
4. NO gas diffuses to adjacent smooth muscle cells and activates soluble guanylate cyclase
5. Increases cGMP
6. Activation of PKG and subsequent muscle relaxation

Question 19

Explain NO as a chemical

Answer 19

Endogenous vasodilator (aka endothelium-derived relaxing factor)

Drugs like nitroglycerin and nitrates (anti angina/anti hyper intensive)

• nitroglycerin/nitrates metabolized to NO
• Angina (chest pain) is due to less myocardial oxygen supply
• NO causes vasodilation of coronary blood vessels; systemic blood vessels and reduce cardiac load
• Used as vasodilator