Medical Pharmacology Chapter 6: Autonomic Pharmacology: Cholinergic Drugs
Cellular Events following Cholinergic Receptor Activation
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Nicotinic Muscle Receptor
Response:
Membrane Depolarization leading to muscle contraction
Molecular Aspects:
Nicotinic (muscle) receptor's cation ion channel opening
Responses:
Depolarization: postsynaptic cell activation
Catecholamine secretion
Molecular Aspects
Nicotinic (muscle) receptor's cation ion channel opening
Response:
Depolarization (late EPSP)
Molecular Aspects
Stimulation of Phospholipase C (PLC) with formation of inositol-1,4,5 triphosphate (IP3 ) and diacylglycerol (DAG)resulting in increased cytosolic Ca2+
SA node
Responses: decreased phase 4 depolarization; hyperpolarization
Molecular Aspects: K+ channel activation through ß-gamma Gi subunits.
Atrium
Responses: decreased contractility; decreased AP duration
Molecular Aspects: Gi -mediated inhibition of adenylyl cyclase which decreases intracellular Ca2+ levels (reduces contractility);(Gi can inhibit directly Ca2+ channel opening)
AV node
Responses: decreased conduction velocity
Ventricle:
Responses: decreased contractility
Molecular Aspects: Gi -mediated inhibition of adenylyl cyclase which decreases intracellular Ca2+ levels (reduces contractility);(Gi can inhibit directly Ca2+ channel opening)
Adapted from Table 6-2: Lefkowitz, R.J, Hoffman, B.B and Taylor, P. Neurotransmission: The Autonomic and Somatic Motor Nervous Systems, In, Goodman and Gillman's The Pharmacologial Basis of Therapeutics,(Hardman, J.G, Limbird, L.E, Molinoff, P.B., Ruddon, R.W, and Gilman, A.G.,eds) The McGraw-Hill Companies, Inc.,1996, p119
Muscarinic Receptors: Second Messenger Systems
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Activation of IP3, DAG cascade
DAG may activate smooth muscle Ca2+ channels
IP3 releases Ca2+ from endoplasmic and sarcoplasmic reticulum
Increase in cGMP
Increase in intracellular K+ by cGMP-K+ channel binding
Inhibition of adenylyl cyclase activity (heart)
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Pappano, A.J. Cholinoceptor-Activating & Cholinesterase-Inhibiting Drugs, In Basic and Clinical Pharmacology, 7th Edition, (Katzung, B.G.,ed) Appleton & Lange, 1998, p. 93-94
Nitric Oxide and Muscarinic Receptor Activation
Activation of salivary gland and intestinal parasympathetic systems produce significant vasodilation.
This effect depends on nitric oxide (EDRF) release and subsequent guanylate cyclase activation. (NO binding to the heme group of guanylate cyclase).
Increased levels of cGMP results in stimulation of ion pumps which lower intracellular Ca2+ promoting relaxation.
Increased nitric oxide production may be mediated by:
Acetylcholine
Substance P
Bradykinin
Direct mechanical (shear forces) on endothelial membranes.
Nitric oxide synthase catalyzes the conversion of L-arginine and molecular oxygen to nitric oxide.
Three forms of nitric oxide synthase
Form 1 (constitutive): release nitric oxide over short time periods in response to increase in intracellular Ca2+ .
Form 2: responsible for Ca2+ - dependent nitric oxide neuronal release.
Form 3: induced following cytokine or endotoxin cellular activation. This form catalyzes nitric oxide synthesis for an extended time.
This form is Ca2+ - independent and is responsible for some pathophysiological responses to endotoxin (hypotension, e.g.).
1Granger,D.N., Regulation of Regional Blood Flow, In Essential Physiology,(Johnson, L.,ed) Lippincott-Ravin,1998, p. 231.
2Lefkowitz, R.J, Hoffman, B.B and Taylor, P. Neurotransmission: The Autonomic and Somatic Motor Nervous Systems, In, Goodman and Gillman's The Pharmacological Basis of Therapeutics, (Hardman, J.G, Limbird, L.E, Molinoff, P.B., Ruddon, R.W, and Gilman, A.G.,eds) The McGraw-Hill Companies, Inc.,1996, pp.136-137.
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