The function of the proximal synapses of the squid stellate ganglion

In the oxygenated excised squid (Loligo pealii) stellate ganglion preparation one can produce excitation of the stellar giant axons by stimulating the second largest (accessory fiber, Young, 1939) or other smaller preganglionic giant axons. Impulse transmission is believed to occur at the proximal synapses of the stellar giant axons rather than the distal (giant) synapses which are excited by the largest giant preaxon. Proximal synaptic transmission is more readily depressed by hypoxia and can be fatigued independently of, and with fewer impulses than, the giant synapses. Intracellular recording from the last stellar axon at its inflection in the ganglion reveals both proximal and distal excitatory postsynaptic potentials EPSP's). The synaptic delay, temporal form of the EPSP, and depolarization for spike initiation were similar for both synapses. If the proximal EPSP occurs shortly after excitation by the giant synapse it reduces the undershoot and adds to the falling phase of the spike. If it occurs later it can produce a second spike. Parallel results were obtained when the proximal EPSP's arrived earlier than the EPSP of the giant synapse. In fatigued preparations it was possible to sum distal and proximal or two proximal EPSP's and achieve spike excitation.     

Axonal neurofilaments differ in composition and morphology from those in the soma of the squid stellate ganglion

Triton X-100 insoluble neurofilament (NF) fractions were obtained from two parts of the stellate ganglion and the main giant axon. These were analyzed by one- and two-dimensional gradient polyacrylamide gel electrophoresis, cyclic assembly and disassembly, and electron microscopy. The NF fractions from the ganglion cell bodies (GCB) and from the part of the ganglion mainly consisting of axon initial segments (GIS) were of similar composition; neither contained detectable amounts of the 220 kda and high molecular weight (greater than 400 kda) NF subunits that were prominent in the axonal NF fraction. However, the GCB and GIS did contain large quantities of a set of 65 kda polypeptides that were minor constituents of the axonal NF fraction. The 65 kda-containing NF fraction from the ganglion could be cyclically disassembled and reassembled, but only under low salt conditions, in contrast to the high salt conditions used to cycle axonal NFs. A comparison of the peptide map of the 65 kda polypeptides with that of the 60 kda axonal NF subunit showed them to be different. These biochemical differences between the ganglionic and axonal NF fractions correlated with morphologic distinctions: ganglionic NFs were relatively smooth surfaced, whereas axonal NFs had long sidearms. Such observations support the hypothesis that the NF cytoskeleton of the neuron soma is different from that of the axon. Furthermore, the change from the somal form to the axonal form of NFs appears to occur in the region where the axon initial segment increases in diameter to become the axon proper.     

Slow cardioacceleration mediated by noncholinergic transmission in the stellate ganglion of the cat

In C1-spinal, pentobarbital-anaesthetized or anemically decerebrated cats, the preganglionic input to the acutely decentralized right stellate ganglion was stimulated with 10- to 30-s strains at 20-40 Hz. Electrical stimulation consistently produced an increase in heart rate in the presence of blocking doses of hexamethonium and atropine or after depletion of acetylcholine from the preganglionic axons by prolonged low frequency stimulation in the presence of hemicholinium. The increase in heart rate had a delayed slow onset, lasted several minutes, and was abolished by propranolol or by section of the inferior cardiac nerve. The magnitude and duration of the heart rate increase were related to intensity, frequency, and duration of preganglionic stimulation. The response to stimulation of a given white ramus was progressively attenuated, and eventually irreversibly lost, during prolonged continuous stimulation of that ramus, while the response to stimulation of a different unstimulated ramus was unchanged. We conclude that the slow cardioacceleration results from a slow and prolonged excitation of postganglionic neurons by a noncholinergic transmitter released by the preganglionic axons.     

The effects of morphine on sympathetic transmission in the stellate ganglion of the cat

The aim of this study was to investigate which of the processes involved in synaptic transmission are affected by morphine in concentrations comparable to those used during surgical procedures. The effects of morphine sulfate on ganglionic transmission were studied in the stellate ganglion of the cat using intracellular and extracellular recordings in vitro. The neurons of the stellate ganglion were depolarized using preganglionic nerve stimulation, postganglionic nerve stimulation, and intracellular stimulation before and after introduction of morphine sulfate (up to 20 micrograms/mL). Tissue concentrations of morphine were estimated using radiolabeled morphine. Axonal transmission and the excitability of the postganglionic neurons to direct intracellular stimulation was not affected at the concentrations of morphine studied. In addition, morphine had a dose-dependent depolarizing effect on the resting membrane potential of most of the neurons in the stellate ganglion. Such neuronal depolarizations alone could initially produce excitation in some cell populations, followed by inhibition, secondary to the membrane depolarization, leading to depression of sympathetic nerve activity. The overall ganglionic transmission as recorded using an evoked potential was biphasic. At low doses morphine facilitated transmission, while at larger doses morphine attenuated evoked potentials. These effects do not appear to be mediated through classical opiate receptors since they are not blocked by naloxone.     

Properties of synaptic transmission at the neuromuscular junction of the squid, Loligo opalescens

1. Spontaneous and evoked synaptic activity were recorded from the muscles of squid fin and mantle. These spontaneous synaptic potentials were large (up to 30 mV) and pleomorphic. Their amplitudes were not normally distributed, nor did they appear to be clustered in integral multiples of some "unit" event size. 2. Electrical stimulation of the nerve resulted in muscle twitches when the bath calcium concentration was a third normal or higher. The frequency of spontaneous synaptic events was unaffected by low calcium. 3. The large size of spontaneous events may mean that the synchronized release of only a few such "quanta" are sufficient to cause muscle action potentials and contraction. 4. The shapes of spontaneous events correlated poorly with their amplitudes, which is consistent with release from multiple synaptic sites with distinct properties.     

Long-lasting synaptic potentials and the modulation of synaptic transmission.

Long-lasting postsynaptic potentials (PSPs) generated by decreases in membrane conductance (permeability) have been reported in many types of neurons. We investigated the possible role of such long-lasting decreases in membrane conductance in the modulation of synaptic transmission in the sympathetic ganglion of the bullfrog. The molecular basis by which such conductance-decrease PSPs are generated was also investigated. Synaptic activation of muscarinic cholinergic receptors on these sympathetic neurons results in the generation of a slow EPSP (excitatory postsynaptic potential), which is accompanied by a decrease in membrane conductance. We found that the conventional "fast" EPSPs were increased in amplitude and duration during the iontophoretic application of methacholine, which activates the muscarinic postsynaptic receptors. A similar result was obtained when a noncholinergic conductance-decrease PSP--the late-slow EPSP--was elicited by stimulation of a separate synaptic pathway. The enhancement of fast EPSP amplitude increased the probability of postsynaptic action potential generation, thus increasing the efficacy of impulse transmission across the synapse. Stimulation of one synaptic pathway is therefore capable of increasing the efficacy of synaptic transmission in a second synaptic pathway by a postsynaptic mechanism. Furthermore, this enhancement of synaptic efficacy is long-lasting by virtue of the long duration of the slow PSP. Biochemical and electrophysiological techniques were used to investigate whether cyclic nucleotides are intracellular second messengers mediating the membrane permeability changes underlying slow-PSP generation. Stimulation of the synaptic inputs, which lead to the generation of the slow-PSPs, increased the ganglionic content of both cyclic AMP and cyclic GMP. However, electrophysiological analysis of the actions of these cyclic nucleotides and the actions of agents that affect their metabolism does not provide support for such a second messenger role for either cyclic nucleotide.     

Action of colchicine on membrane currents and synaptic transmission in Aplysia ganglion cells

The action of colchicine, a drug known to disrupt microtubules, on synaptic transmission and voltage-dependent phenomena was studied. Colchicine depressed transmission in both cholinergic and noncholinergic Aplysia ganglionic synapses. In some synapses, this effect was partly due to the curare like properties of the alkaloid. Ca²⁺ currents, analyzed by voltage clamp techniques, were rapidly depressed by intracellular injection of colchicine and more slowly depressed by external application. Injected colchicine acted at much lower concentrations than required extracellularly. The implication of the reduced calcium influx in synaptic transmission is discussed. Colchicine caused a shift in the reversal potential of acetylcholine-activated chloride channels in a direction consistent with an increased intracellular chloride activity. It was concluded that the wide range of actions of colchicine on membrane properties should be taken into account when this drug is used in biological research.     

Kainic acid: neurophysiological and neurotoxic actions.

Kainic acid, an anthelmintic drug structurally related to glutamate, has excitatory electrophysiological actions on neurons in the vertebrate CNS and at the invertebrate neuromuscular junction. Recently, it has been shown to destroy neuronal cell bodies and dendrites in several regions of the vertebrate CNS, while sparing afferent fibers and fibers of passage. Kainic acid can be used to make lesions in experimental animals that closely resemble the pathology associated with certain neurological conditions in man. Its actions on vertebrate and invertebrate nervous systems are reviewed and possible neuroexcitatory and neurotoxic mechanisms are considered.     

Distribution of neuropeptides in the porcine stellate ganglion

The localization and distribution of neuropeptides including neuropeptide Y (NPY), [Met⁵]enkephalin-Arg⁶-Gly⁷-Leu⁸ (MEAGL), vasoactive intestinal polypeptide (VIP), calcitonin gene-related peptide (CGRP), substance P and somatostatin (SOM) were analyzed in the stellate ganglion of the pig by use of the indirect immunofluorescence technique. NPY, MEAGL, SOM, VIP and CGRP immunoreactivities were found to exist in subpopulations of neuronal cell bodies of the stellate ganglion. A population of the small intensely fluorescent (SIF) cells showed MEAGL immunoreactivity. In addition, the presence of NPY-, MEAGL-, CGRP-, SP-, SOM- and VIP-immunoreactive nerve fibers and axonal varicosities were observed in the stellate ganglion. The localization and pattern of distribution of these peptides in the porcine stellate ganglion were compared with studies carried out on stellate ganglia of other mammalian species.