A partial agonist has:

High affinity with low intrinsic activity

High affinity with no intrinsic activity

Low affinity with high intrinsic activity

Low affinity with low intrinsic activity

Which of the following statements best describes the mechanism of action of insulin on target cells?

Insulin binds to a transmembrane receptor on the outer surface of the plasma membrane, activating the tyrosine kinase in the cytosolic domain of the receptor.

Insulin binds to a receptor on the outer surface of the plasma membrane, activating adenylate cyclase through the Gs protein.

Insulin binds to a cytoplasmic receptor and is transferred as a hormone receptor complex to the nucleus to modulate gene expression.

Insulin enters the cell and causes the release of calcium ions from intracellular stores.

Which of the following hormones uses cGMP as a second messenger?

Atrial natriuretic peptide (ANP)

A primigravida at 38 weeks of gestation has gone into labor. Oxytocin was started to augment labor. The second messenger system through which oxytocin acts is:

Phospholipase C (IP3/DAG pathway)

Membrane Receptors and Signal Transduction | Membrane Biochemistry

Receptor Basics - Lock & Key Chat

Receptor: Cellular protein binding specific ligands (hormones, neurotransmitters, drugs).
Binding Models:
- Lock & Key: Rigid, complementary shapes.
- Induced Fit: Ligand binding alters receptor shape (more accurate).
Key Properties:
- Affinity: Binding strength. ↓$K_d$ (dissociation constant) = ↑affinity.
- Specificity: Distinguishing between ligands.
- Efficacy: Ability to activate receptor & elicit response.
Ligand Actions:
- Agonist: Activates receptor (affinity + efficacy).
  - Full: Max effect.
  - Partial: Submaximal effect.
- Antagonist: Blocks receptor (affinity, no efficacy).
- Inverse Agonist: Produces effect opposite to agonist.

⭐ Many therapeutic drugs function by targeting receptors as agonists or antagonists.

GPCR Signaling - G-Protein Gala

GPCRs: Largest family, 7-TM helices. Mediate diverse signal responses.

Mechanism:
- Ligand binding → GPCR conformational change.
- GPCR activates heterotrimeric G-protein (α, β, γ).
- Gα exchanges GDP for GTP → Dissociates from Gβγ.
- Gα-GTP & Gβγ modulate effectors.
- Termination: Gα GTPase activity (GTP→GDP); reassociation.
Major G-Protein Families & Effectors:
- Gs (Stimulatory): Activates Adenylyl Cyclase (AC) → ↑cAMP → PKA. 📌 Stimulates Adenylyl Cyclase.
- Gi (Inhibitory): Inhibits AC → ↓cAMP. 📌 Inhibits Adenylyl Cyclase.
- Gq/11: Activates Phospholipase C (PLC) → PIP2 to IP3 & DAG. IP3 → ↑$Ca^{2+}$; DAG → PKC. 📌 Quts PIP2.

⭐ Cholera toxin ADP-ribosylates Gsα (active) → ↑cAMP → diarrhea. Pertussis toxin ADP-ribosylates Giα (inactive) → ↑cAMP → whooping cough.

RTKs & Ion Channels - Kinase Kickstart & Ion Influx

Receptor Tyrosine Kinases (RTKs)
- Mechanism: Ligand binding → Dimerization of receptors → Autophosphorylation of tyrosine residues → Recruits SH2-domain proteins (e.g., Grb2) → Activates downstream MAPK, PI3K-Akt pathways.
- Key Examples: Insulin R, EGF R, PDGF R.
- Functions: Regulates crucial cell processes: growth, proliferation, differentiation, survival, metabolism.
- 📌 Mnemonic: Receptors That Kinase (phosphorylate) Tyrosine.
Ligand-gated Ion Channels (Ionotropic Receptors)
- Mechanism: Ligand binds to receptor → Conformational change → Channel pore opens → Specific ion flux ($Na^+$, $K^+$, $Ca^{2+}$, $Cl^-$) → Rapid change in membrane potential → Fast cellular response (e.g., neurotransmission).
- Key Examples: Nicotinic AChR, GABA-A R, NMDA R.
- Functions: Key for rapid neurotransmission, muscle cell excitation, sensory transduction.

Membrane receptors and signal transduction

⭐ Insulin receptor (RTK): intrinsic tyrosine kinase activity. Activation recruits IRS, promotes GLUT4 translocation for glucose uptake.

Signal Pathways & Clinical - Pathway Powwow & Rx Relevance

Key Second Messengers:
- $Ca^{2+}$/Calmodulin: Muscle contraction, secretion.
- $IP_3$/DAG: From $PIP_2$ (PLC). $IP_3 \rightarrow Ca^{2+}$ release; DAG $\rightarrow$ PKC activation.
- Nitric Oxide (NO): Activates guanylyl cyclase $\rightarrow$ ↑cGMP (vasodilation).
Signal Amplification: Cascades (e.g., one receptor $\rightarrow$ many G-proteins).
Signal Termination:
- Ligand dissociation.
- Gα GTP hydrolysis.
- Phosphodiesterases (PDEs) degrade cAMP/cGMP.
- Receptor downregulation.
Clinical/Rx Examples:
- β-blockers: GPCR antagonists (hypertension).
- Sildenafil: PDE5 inhibitor $\rightarrow$ ↑cGMP (erectile dysfunction).
- Lithium: Modulates $IP_3$ pathway (bipolar disorder).
⭐ Cholera toxin: ADP-ribosylates Gαs $\rightarrow$ persistent ↑cAMP $\rightarrow$ severe diarrhea.
- Pertussis toxin: ADP-ribosylates Gαi $\rightarrow$ ↑cAMP (whooping cough). 📌 Gs 's'timulatory ON (Cholera), Gi 'i'nhibitory OFF (Pertussis) $\rightarrow$ both ↑cAMP.

High‑Yield Points - ⚡ Biggest Takeaways

GPCRs, largest family, use heterotrimeric G-proteins: Gαs → ↑cAMP (PKA); Gαq → IP3/DAG (PKC).

Adenylyl cyclase forms cAMP; phosphodiesterases degrade it.

Phospholipase C produces IP3 (↑Ca²⁺) & DAG (PKC activation).

Receptor Tyrosine Kinases (RTKs) (e.g., insulin receptor) autophosphorylate, activating MAPK or PI3K/Akt pathways.

JAK-STAT pathway for cytokine receptors involves Janus Kinases (JAKs) and STATs.

Key second messengers: cAMP, cGMP, Ca²⁺, IP3, DAG.