Spontaneous and Evoked Quantal Transmitter Release at a Vertebrate Central Synapse

THIS report deals with some of the statistical properties of quantal transmitter release at the Mauthner fibre-giant fibre synapse in the hatchetfish Gasteropelecus and the way in which these properties are modified by presynaptic intracellular depolarization. The experiments reported indicate that Poisson statistics describe transmitter release in the hatchetfish at low, but not at high, release levels.     

Temperature Effect on Carbachol-Induced Depression of Spontaneous Quantal Transmitter Release in Frog Neuromuscular Junction

The effects of carbachol (CCh) on the frequency (f) of the miniature endplate potentials were tested at temperatures between 5 and 30°C. Higher CCh concentrations, 1 × 10^–5 and 5 × 10^–6 M, reduced the f to 60% and the temperature dependence was negligible. However, an inverse temperature dependence was found when low concentrations 3 × 10^–7 and 6 × 10^–7 M were applied. The depression of f was 40–50% in 5–10°C but only 10–20% of the control in the 25 and 30°C. During application of CCh, the new steady of f was reached at temperatures between 5 and 30°C within 17–20 min (Q₁₀ = 1.07). Much greater temperature dependence of recovery was observed during washing out CCh (Q₁₀ = 1.6). The temperature-independence of the steady state effects of CCh, good agreement with Langmuir adsorption-desorption theory and non-steady kinetics indicate that physical rather than receptor-mediated events are responsible for the depression of f.     

Functional Organization of the Cardiac Ganglion of the Lobster, Homarus americanus

External recording and stimulation, techniques were used to determine which neurons and interactions are essential for production of the periodic burst discharge in the lobster cardiac ganglion. Burst activity can be modulated by brief single shocks applied to the four small cells, but not by similar stimulation of the five large cells, suggesting that normally one or more small cells primarily determine burst rate and duration. Repetitive electrical stimulation of large cells initiates spike activity in small cells, probably via excitatory synaptic and/or electrotonic connections which may normally act to prolong bursts and decrease burst rate. Transection of the ganglion can result in burst activity in small cells in the partial or complete absence of large cell spike activity, but large cells isolated from small cell excitatory synaptic input by transection or by application of dinitrophenol do not burst. Generally, transections which decrease excitatory feedback to small cells are accompanied by an increase in burst rate, but mean spike frequency over an entire burst cycle stabilizes at the original level within 10–30 min for various groups of cells whose spike-initiating sites are still intact. These and previous results suggest that the system is two layered: one or more small cells generate the burst pattern and impose it on the large cells which are the system's motorneurons.     

Neuromuscular synapses on the dactyl opener muscle of the lobster Homarus americanus

The crustacean dactyl opener neuromuscular system has been studied extensively as a model system that exhibits several forms of synaptic plasticity. We report the ultrastructural features of the synapses on dactyl opener of the lobster (Homarus americanus) as determined by examination of serial thin sections. Several innervation sites supplied by an inhibitory motoneuron have been observed without nearby excitatory innervation, indicating that excitatory and inhibitory inputs to the muscle are not always closely matched. The ultrastructural features of the lobster synapses are generally similar to those described previously for the homologous crayfish muscle, with one major distinction: few dense bars are seen at the presynaptic membranes of these lobster synapses. The majority of the lobster neuromuscular synapses lack dense bars altogether, and the mean number of dense bars per synapse is relatively low. In view of the finding that the physiology of the lobster dactyl opener synapses is similar to that reported for crayfish, these ultrastructural observations suggest that the structural complexity of the synapses may not be a critical factor determining synaptic plasticity.This work was supported by funds from the University of Virginia Research and Development Committee.     

Bioaccumulation and Metabolic Effects of the Endocrine Disruptor Methoprene in the Lobster, Homarus americanus

Methoprene is a pesticide that acts as a juvenile hormone agonist.Although developed initially against insects, it has since beenshown to have toxic effects on larval and adult crustaceans.Methoprene was one of several pesticides applied to the WesternLong Island Sound (WLIS) watershed area during the summer of1999; the other pesticides were malathion, resmethrin, and sumethrin.These pesticides were applied as part of a county-by-countyeffort to control the mosquito vector of West Nile Virus. Subsequently,the seasonal lobster catches from the WLIS have decreased dramatically.The lethality of the pesticides to lobsters had been unknown.We studied the effects of methoprene while other investigatorsstudied effects of the other pesticides. We questioned whethermethoprene, through its effects on larvae, adults or both, couldhave contributed to this decline. We found that low levels ofmethoprene had adverse effects on lobster larvae. It was toxicto stage II larvae at 1 ppb. Stage IV larvae were more resistant,but did exhibit significant increases in molt frequency beginningat exposures of 5 ppb. Juvenile lobsters exhibited variationsin tissue susceptibility to methoprene: hepatopancreas appearedto be the most vulnerable, reflected by environmental concentrationsof methoprene inhibiting almost all protein synthesis in thisorgan. Our results indicated that methoprene concentrates in the hepatopancreas,nervous tissue and epidermal cells of the adult lobster. Methoprenealtered the synthesis and incorporation of chitoproteins (cuticleproteins) into adult postmolt lobster explant shells. SDS PAGEanalyses of adult post–molt shell extracts revealed changesin the synthesis of chitoproteins in the methoprene-treatedspecimens, suggesting that methoprene affects the normal pathwayof lobster cuticle synthesis and the quality of the post-moltshell. Although it is likely that a combination of factors ledto the reduced lobster population in WLIS, methoprene may havecontributed both by direct toxic effects and by disrupting homeostaticevents under endocrine control.     

A Description of a New "Amoebozoan" Isolated from the American Lobster, Homarus americanus

ABSTRACT. Our knowledge of the diversity of amoeboid protists is rapidly expanding as new and old habitats are more fully explored. In 2003, while investigating the cause of an amoeboid disease afflicting lobsters on the East Coast, samples were examined for the presence of amoebae from the carapace washings of the American lobster, Homarus americanus . During this survey a unique community of gymnamoebae was discovered. Among the new taxa discovered was a small Thecamoeba -like organism with a single posteriorly directed pseudopodium. Although resembling Parvamoeba rugata , this amoeba displayed distinctive morphology from that isolate or any other amoebozoan. Phylogenetic analysis shows this amoeba is distantly related to the Thecamoebidae. In this paper we describe the unique morphology of a second species of Parvamoeba and discuss its phylogenetic position with respect to the "Amoebozoa."     

Influence of the Latency Fluctuations and the Quantal Process of Transmitter Release on the End-Plate Potentials' Amplitude Distribution

Spontaneous synaptic potentials and their relation to the end-plate potential (e.p.p.) are studied. It has been suggested earlier that the e.p.p. at a single nerve-muscle junction is built up statistically of small all-or-none units which are identical in size with the spontaneous miniature end-plate potentials (m.e.p.p.'s). In this paper, a more general theory is developed which takes into account latency fluctuations of the unit components. A general equation for e.p.p. amplitude probability distribution is derived. This probability distribution is a function of the latency distribution, m.e.p.p.'s pulse shape, m.e.p.p.'s amplitude distribution, and the mean quantal content. The time course of transmitter release, or latency distribution, is derived from a histogram of synaptic delays in a frog muscle, but obtained equations can be used for other distribution functions as well.     

Phenobarbital Increases Spontaneous Transmitter Release at the Frog Neuromuscular Junction

Phenobarbital (1-2 × 10^-4M) markedly increases the frequency of miniature end-plate potentials at the neuromuscular synapse of the frog. This effect was seen in calcium free media containing EGTA. The drug probably acts presynaptically at an intracellular locus to increase the presynaptic free calcium concentration.     

Some effects of proctolin on the cardiac ganglion of the Maine Lobster, Homarus americanus (Milne Edwards)

The neuropeptide proctolin has excitatory effects on the isolated lobster cardiac ganglion. Selective application to the anterior cell body region produces a dose-dependent (10(-8)--10(-5) M) prolonged depolarization of large anterior cells as well as marked increases in burst frequency and/or duration. In ganglia which have been silenced with tetrodotoxin, proctolin application to anterior cells elicits long-lasting depolarizing responses which are accompanied by a 10-30% increase of the apparent membrane input resistance. Higher proctolin concentrations produce high-frequency trains of driver potentials. It is proposed that a proctolin like peptide may serve a neurohumoral role in the lobster cardiac ganglion and that the anterior motor neurons exhibit endogenous rhythmicity in its presence.     

Quantal Mechanism of Transmitter Release during Progressive Depletion of the Presynaptic Stores at a Ganglionic Synapse : The action of hemicholinium-3 and thiamine deprivation

In the present experiments we interfered with the mechanism of acetylcholine (ACh) synthesis in the rat superior cervical ganglion by impairing the supply of either the choline group (hemicholinium no. 3 [HC-3]treatment) or the acetyl group (thiamine deprivation). Under both conditions stimulation causes in the ganglion a progressive decline in ACh output associated with a depletion of transmitter tissue content. ACh release from the terminals of a single preganglionic fiber was estimated from the quantum content value of the evoked excitatory postsynaptic potentials (EPSP's) recorded intracellularly in the ganglion neuron under test. The present observations indicate that Poisson statistics describe transmitter release at either low or high release levels. Furthermore, the progressive decline in the rate of ACh output occurring during repetitive stimulation is shown to correspond to a progressive decrease in the number of transmitter quanta released per impulse and not to any modification in the size of individual quanta. Some 8,000 transmitter quanta proved to represent the presynaptic transmitter store initially present in those terminals on a neuron that are activated by stimulation of a single preganglionic fiber. Speculations are considered about synaptic efficacy and nerve connections in rat autonomic ganglia. It is suggested that six preganglionic fibers represent the mean input to a ganglion neuron.     

Modulatory Mechanisms at a Primitive Neuromuscular Synapse: Membrane Currents, Transmitter Release and Modulation by Transmitters in a Cnidarian Motor Neuron

The phylum Cnidaria arose early in metazoan evolution and, assumingmonophyly, is regarded as being close to the ancestral metazoan.The simplicity of structure in the cnidariannervous system isnot reflected in the physiology of neurons. The motor neuronsthat control swimming in the jellyfish Polyorchis penicillatusepitomise this operational complexity. Synchrony in the contractionof the swimming muscle sheets is achieved by compensatingforthe conduction time of motor APs propagating to distant partsof the motor network. This depends on motor APs continuouslydecreasing in duration as they propagate through the networkwhich in turn leads to a decrease in the delay of muscle actionpotential initiation. Two membrane currents are critical forthis mechanism, a fast, transient K⁺ current (I_K-fast). anda transient Ca⁺⁺ current. A PCR-based screen of genomicDNA producedclones having considerable sequence identity with the Shaker,Shal, Shab and Shaw subfamilies. One full-length clone, jShaklwhen expressed in Xenopus oocytes reveals an A-like Shaker currentwhich activates at very positive voltages. Motor neuron activitycan be modulated by two endogenous transmitters, dopamine andFMRFamide-related peptides which are found endogenously. Dopaminecauses a long lasting hyperpolarization by activating a potassiumcurrent that is regulated by D₂ receptors. In addition dopaminereduces action potential duration. Pol-RFamides, on the otherhand have an excitatory effect by blocking the slowly inactivatingcurrent, I_K-slow     

Interaction between the Cholinergic and Purinergic Control of Transmitter Release in the Neuromuscular Junction

The interaction between the cholinergic and purinergic receptors in the frog neuromuscular junction was studied using a standard microelectrode technique. The inhibitory action of an acetylcholine analog, carbachol, on transmitter release virtually disappeared when the releasing machinery was initially blocked by adenosine, indicating the existence of a functional cross-talk between the purinergic and cholinergic receptors.     

Cyclic AMP,Transmitter Release and the Effect of Adenosine on Neuromuscular Transmission

THE high activities of the enzymes in nervous tissue regulating the metabolism of 3',5' adenosine monophosphate (cyclic AMP) and its apparent involvement in secretion from glands have prompted considerable speculation about its possible role in the release of transmitters from nerve endings^1–4. There is some evidence that cyclic AMP is concerned in the release of acetylcholine from motor nerve endings^1,3. It has been found, for example, that neuromuscular transmission is facilitated by catecholamines^5,6 and methylxanthines^1,3; noradrenaline is known to increase both the quantal content of the endplate potential⁶ and the level of cyclic AMP in nervous tissue^7,8 and the increase in the quantal content is more marked in the presence of theophylline³. It was also found that increases in cyclic AMP concentration of up to thirty-fold occur in brain slices in the presence of 0.1-1 mM adenosine. We have therefore examined the effect of this substance on transmitter release.     

Correlation of Transmitter Release with Membrane Properties of the Presynaptic Fiber of the Squid Giant Synapse

Depolarization of the presynaptic terminal by current produced a postsynaptic potential (PSP) which increased with increasing presynaptic polarization and then reached a plateau. Iontophoretic injection of tetraethylammonium ions (TEA) into the presynaptic axon near the terminal produced a prolonged presynaptic spike. The resulting PSP is increased in size and its time course closely followed that of the presynaptic spike. The presynaptic fiber no longer exhibited rectification and strong depolarizations revealed that the PSP reached a maximum with about 110 mv depolarization. Further depolarization produced a decrease in PSP amplitude and finally transmission was blocked. However, a PSP then always appeared on withdrawal of the depolarizing current. Under the conditions of these experiments, the PSP could be considered a direct measure of transmitter release. Bathing the TEA-injected synapse with concentrations of tetrodotoxin (TTX) sufficient to block spike activity in both pre- and postsynaptic axons did not greatly modify postsynaptic electrogenesis. However, doubling TTX concentration reversibly blocked PSP. Thus the permeability changes to Na and K accompanying the spike do not appear necessary for transmitter release. Some other processes related to the level of presynaptic polarization must be involved to explain the data. The inhibition of transmitter release by strong depolarizations appears to be related to Ca action. A membrane Ca current may also be necessary for normal transmitter release.     

Electrical Inexcitability of the Frog Neuromuscular Synapse

Frog muscle endplates were explored with an extracellular microelectrode. An intracellular microelectrode nearby simultaneously monitored invasion of the endplate by a spike directly evoked by a third microelectrode placed away from the endplate in the same fiber. External positivities were seen only at sites generating miniature endplate potentials. The external positivity reached a maximum prior to the internally recorded potential and was followed by a small late negativity. Small movements away from active synaptic sites resulted in positive-negative-positive potential sequences characteristic of activity and propagation. Since the external potential is a function of membrane current, the absence of negativity associated with the rising phase of the spike indicates the absence of inward current at synaptic sites. Thus, the synaptic membrane appears not to be excited by a depolarization of the magnitude of an action potential. In an Appendix it is shown that the late negativity and earlier maximum of the external potential can be accounted for by capacitative current through passive membrane.     

Changes in the Asynchronicity of Transmitter Release at the Neuromuscular Junction during Prolonged High-Frequency Stimulation

In experiments on neuromuscular junctions in the frog m. cutaneous-pectoris, changes in the intensity and asynchronicity of transmitter release during high-frequency (10 and 50 sec^-1) rhythmic stimulation of the motor nerve were investigated using extracellular recording. At low extracellular Ca²⁺ concentrations, rhythmic stimulation resulted in a gradual enlargement of the quantum content of end-plate currents (EPC), the so-called facilitation. The latter phenomenon was accompanied by an increase in the average value and variance of synaptic delays of single-quantum EPC, a shift of the main mode of their distribution towards greater values, and an increase in the latency of the nerve ending responses. The above-described changes reduce the magnitude of facilitation in the neuromuscular synapse.