Neurophysiology and pharmacology of long-term potentiation in the rat sympathetic ganglion.

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Neurophysiology and pharmacology of long-term potentiation in the rat sympathetic ganglion.

C A Briggs, T H Brown and D A McAfee

Brief tetanic stimulation of the preganglionic nerve induceda persistent potentiation of nicotinic synaptic transmissionin the rat superior cervical sympathetic ganglion. Quantitativemeasurements of the post-tetanic increase in synaptic efficacyrevealed two distinct time courses. The early, rapidly decayingcomponent, termed post-tetanic potentiation (p.t.p.), had adecay time constant of 2-3 min, as reported elsewhere. The durationof the more persistent component, called long-term potentiation(l.t.p.), was extremely temperature dependent, lasting muchlonger at 32 degrees C than at 22 degrees C. In half of theexperiments performed at 32 degrees C, l.t.p. showed no detectabledecay over the course of 1 h or more after a brief tetanic stimulation.Other experiments were conducted at 22 degrees C. The inductionof l.t.p. was dependent on the extracellular [Ca2+]. Transientelevation of the extracellular [K+] also produced a long-termenhancement of synaptic efficacy, and this effect was also Ca2+dependent. The tetani that were effective in inducing l.t.p.(5-20 Hz for 5-20 s) were well within the physiological rangeof preganglionic activity. The magnitude and time course wererelated to frequency and duration of stimulation. The occurrenceof l.t.p. was restricted to those preganglionic fibres thatwere tetanically stimulated. This lack of heterosynaptic orgeneralized effects was demonstrated by splitting the preganglionicnerve into two branches that could be independently tested andconditioned. Physiological activation of muscarinic or nicotinicreceptors apparently does not play an essential role in causingganglionic l.t.p., which is expressed as an enhancement of nicotinictransmission. A muscarinic antagonist (2 microM-atropine) didnot block l.t.p. Preganglionic stimulation induced l.t.p. evenwhen a high concentration of a nicotinic antagonist (3 mM-hexamethonium)was present during the tetanic stimulation. Furthermore, bathapplication of a cholinergic agonist (100-1000 microM-carbachol)could not substitute for tetanic stimulation in provoking l.t.p.Activation of adrenergic receptors also appeared not to playan essential role. Neither a beta-adrenergic antagonist (10microM-sotolol or 1 microM-propranolol) nor an alpha-adrenergicantagonist (1 microM-phentolamine) had any significant effecton the magnitude or duration of l.t.p. The results indicatethat ganglionic l.t.p. is a Ca2+- and temperature-dependentprocess that can be created independently of the activationof nicotinic, muscarinic or adrenergic receptors.

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