Muscarinic inhibitory transmission in mammalian sympathetic ganglia mediated by increased potassium conductance

Muscarinic inhibitory transmission in mammalian sympathetic ganglia mediated by increased potassium conductance

Slow muscarinic inhibition may be a powerful influence on membrane properties in the peripheral and central nervous system. But the location of the muscarinic receptors in sympathetic ganglia, either on interneurones or on the postganglionic membrane, and the underlying mechanism of the inhibitory r...

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Bibliographic Details
Published in:Nature (London) Vol. 307; no. 5948; pp. 270 - 271
Main Authors: Cole, Alison E, Shinnick-Gallagher, Patricia
Format: Journal Article
Language:English
Published: London Nature Publishing 01-01-1984
Subjects:
Acetylcholine - pharmacology
Animals
Biological and medical sciences
Calcium - physiology
cholinergic transmission
Electric Conductivity
Fundamental and applied biological sciences. Psychology
Ganglia, Sympathetic - physiology
Neural Inhibition
Peripheral nervous system. Autonomic nervous system. Neuromuscular transmission. Ganglionic transmission. Electric organ
potassium
Potassium - physiology
Rabbits
Receptors, Muscarinic - physiology
sympathetic nervous system
Synaptic Transmission - drug effects
Vertebrates: nervous system and sense organs
Vertebrata
Mammalia
Synaptic transmission
Rabbit
Muscarinic receptor
Inhibition
Lagomorpha
Potassium
Sympathic nervous system
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Summary:Slow muscarinic inhibition may be a powerful influence on membrane properties in the peripheral and central nervous system. But the location of the muscarinic receptors in sympathetic ganglia, either on interneurones or on the postganglionic membrane, and the underlying mechanism of the inhibitory response, remains controversial. In mammalian sympathetic ganglia synaptic activation of muscarinic receptors located on inhibitory interneurones was thought to release catecholamines leading to a membrane hyperpolarization called the slow inhibitory postsynaptic potential, or s.-i.p.s.p.. However, the s.-i.p.s.p. in parasympathetic ganglia and in amphibian sympathetic ganglia is due to direct monosynaptic activation of muscarinic receptors, accompanied by an increased potassium conductance (but see ref. 11), and is not mediated by catecholamines. The situation is less clear in mammalian sympathetic ganglia and monosynaptic s.-i.p.s.ps observed in other ganglia could be exceptions to the hypothesis. We showed earlier that the s.-i.p.s.p. in rabbit superior cervical ganglia is not affected by catecholamine antagonists. We now show that the s.-i.p.s.p. in a mammalian sympathetic ganglion is due to the monosynaptic activation of muscarinic receptors, probably by an increase in potassium conductance.
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ISSN:0028-0836
1476-4687
DOI:10.1038/307270a0