Acetylcholine

Acetylcholine (ACh) is a simple molecule synthesized from choline and acetyl-CoA through the action of choline acetyltransferase. Neurons that synthesize and release ACh are termed cholinergic neurons. When an action potential reaches the terminal button of a presynaptic neuron a voltage-gated calcium channel is opened. The influx of calcium ions, Ca²⁺, stimulates the exocytosis of presynaptic vesicles containing ACh, which is thereby released into the synaptic cleft. Once released, ACh must be removed rapidly in order to allow repolarization to take place; this step, hydrolysis, is carried out by the enzyme, acetylcholinesterase. The acetylcholinesterase found at nerve endings is anchored to the plasma membrane through a glycolipid.

ACh receptors are ligand-gated cation channels composed of four different polypeptide subunits arranged in the form [(a2)(b)(g)(d)]. Two main classes of ACh receptors have been identified on the basis of their responsiveness to the toadstool alkaloid, muscarine, and to nicotine, respectively: the muscarinic receptors and the nicotinic receptors. Both receptor classes are abundant in the human brain. Nicotinic receptors are further divided into those found at neuromuscular junctions and those found at neuronal synapses. The activation of ACh receptors by the binding of ACh leads to an influx of Na⁺ into the celland an efflux of K⁺, resulting in a depolarization of the postsynaptic neuron and the initiation of a new action potential.
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Cholinergic Agonists and Antagonists

Numerous compounds have been identified that act as either agonists or antagonists of cholinergic neurons. The principal action of cholinergic agonists is the excitation or inhibition of autonomic effector cells that are innervated by postganglionic parasympathetic neurons and as such are refered to as parasympathomimetic agents. The cholinergic agonists include choline esters (such as ACh itself) as well as protein- or alkaloid-based compounds. Several naturally occurring compounds have been shown to affect cholinergic nerons, either positively or negatively.

The responses of cholinergic neurons can also be enhanced by administration of cholinesterase (ChE) inhibitors. ChE inhibitors have been used as components of nerve gases but also have significant medical application in the treatment of disorders such as glaucoma and myasthenia gravis as well as in terminating the effects of neuromuscular blocking agents such as atropine.

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Natural Cholinergic Agonist and Antagonists

	Source of Compound	Mode of Action
Agonists
Nicotine	Alkaloid prevalent in the tobacco plant	Activates nicotinic class of ACh receptors, locks the channel open
Muscarine	Alkaloid produced by Amanita muscaria mushrooms	Activates muscarinic class of ACh receptors
a-Latrotoxin	Protein produced by the black widow spider	Induces massive ACh release, possibly by acting as a Ca2+ ionophore
Antagonists
Atropine (and related compound Scopolamine)	Alkaloid produced by the deadly nightshade, Atropa belladonna	Blocks ACh actions only at muscarinic receptors
Botulinus Toxin	Eight proteins produced by Clostridium botulinum	Inhibits the release of ACh
a-Bungarotoxin	Protein produced by Bungarus genus of snakes	Prevents ACh receptor channel opening
d-Tubocurarine	Active ingredient of curare	Prevents ACh receptor channel opening at motor end-plate

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Catecholamines

The principal catecholamines are norepinephrine, epinephrine and dopamine. These compounds are formed from phenylalanine and tyrosine. Tyrosine is produced in the liver from phenylalanine through the action of phenylalanine hydroxylase. The tyrosine is then transported to catecholamine-secreting neurons where a series of reactions convert it to dopamine, to norepinephrine and finally to epinephrine (see Specialized Products of Amino Acids).

Catecholamines exhibit peripheral nervous system excitatory and inhibitory effects as well as actions in the CNS such as respiratory stimulation and an increase in psychomotor activity. The excitatory effects are exerted upon smooth muscle cells of the vessels that supply blood to the skin and mucous membranes. Cardiac function is also subject to excitatory effects, which lead to an increase in heart rate and in the force of contraction. Inhibitory effects, by contrast, are exerted upon smooth muscle cells in the wall of the gut, the bronchial tree of the lungs, and the vessels that supply blood to skeletal muscle.

In addition to their effects as neurotransmitters, norepinephrine and epinephrine can influence the rate of metabolism. This influence works both by modulating endocrine function such as insulin secretion and by increasing the rate of glycogenolysis and fatty acid mobilization.

The catecholamines bind to two different classes of receptors termed the a- and b-adrenergic receptors. The catecholamines therefore are also known as adrenergic neurotransmitters; neurons that secrete them are adrenergic neurons. Norepinephrine-secreting neurons are noradrenergic. The adrenergic receptors are classical serpentine receptors that couple to intracellular G-proteins. Some of the norepinephrine released from presynaptic noradrenergic neurons recycled in the presynaptic neuron by a reuptake mechanism.

Catecholamine Catabolism

Epinephrine and norepinephrine are catabolized to inactive compounds through the sequential actions of catecholamine-O-methyltransferase (COMT) and monoamine oxidase (MAO). Compounds that inhibit the action of MAO have been shown to have beneficial effects in the treatment of clinical depression, even when tricyclic antidepressants are ineffective. The utility of MAO inhibitors was discovered serendipitously when patients treated for tuberculosis with isoniazid showed signs of an improvement in mood; isoniazid was subsequently found to work by inhibiting MAO.
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Serotonin

Serotonin (5-hydroxytryptamine, 5HT) is formed by the hydroxylation and decarboxylation of tryptophan (see Specialized Products of Amino Acids). The greatest concentration of 5HT (90%) is found in the enterochromaffin cells of the gastrointestinal tract. Most of the remainder of the body's 5HT is found in platelets and the CNS. The effects of 5HT are felt most prominently in the cardiovascular system, with additional effects in the respiratory system and the intestines. Vasoconstriction is a classic response to the administration of 5HT.

Neurons that secrete 5HT are termed serotonergic. Following the release of 5HT, a portion is taken back up by the presynaptic serotonergic neuron in a manner similar to that of the reuptake of norepinephrine.

The function of serotonin is exerted upon its interaction with specific receptors. Several serotonin receptors have been cloned and are identified as 5HT₁, 5HT₂, 5HT₃, 5HT₄, 5HT₅, 5HT₆, and 5HT₇. Within the 5HT₁ group there are subtypes 5HT_1A, 5HT_1B, 5HT_1D, 5HT_1E, and 5HT_1F. There are three 5HT₂ subtypes, 5HT_2A, 5HT_2B, and 5HT_2C as well as two 5HT₅ subtypes, 5HT_5a and 5HT_5B. Most of these receptors are coupled to G-proteins that affect the activities of either adenylate cyclase or phospholipase Cg. The 5HT₃ class of receptors are ion channels.

Some serotonin receptors are presynaptic and others postsynaptic. The 5HT_2A receptors mediate platelet aggregation and smooth muscle contraction. The 5HT_2C receptors are suspected in control of food intake as mice lacking this gene become obese fromincreased food intake and are also subject to fatal seizures. The 5HT₃ receptors are present in the gastrointestinal tract and are related to vomiting. Also present in the gastrointestinal tract are 5HT₄ receptors where they function in secretion and peristalsis. The 5HT₆ and 5HT₇ receptors are distributed throughout the limbic system of the brain and the 5HT₆ receptors have high affinity for antidepressant drugs.
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GABA

Several amino acids have distinct excitatory or inhibitory effects upon the nervous system. The amino acid derivative, g-aminobutyrate, also called 4-aminobutyrate, (GABA) is a well-known inhibitor of presynaptic transmission in the CNS, and also in the retina. The formation of GABA occurs by the decarboxylation of glutamate catalyzed by glutamate decarboxylase (GAD). GAD is present in many nerve endings of the brain as well as in the b-cells of the pancreas. Neurons that secrete GABA are termed GABAergic.

GABA exerts its effects by binding to two distinct receptors, GABA-A and GABA-B. The GABA-A receptors form a Cl^- channel. The binding of GABA to GABA-A receptors increases the Cl^- conductance of presynaptic neurons. The anxiolytic drugs of the benzodiazepine family exert their soothing effects by potentiating the responses of GABA-A receptors to GABA binding. The GABA-B receptors are coupled to an intracellular G-protein and act by increasing conductance of an associated K⁺ channel.
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Michael W. King, Ph.D / IU School of Medicine / mking@medicine.indstate.edu

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Last modified:   Thursday, 10-May-01 10:13:43