Blocking action of furosemide on chloride conductance induced by acetylcholine and gaba in molluscan neuron membrane

Experiments on isolated neurons of the molluskPlanorbarius corneus under membrane voltage clamp conditions showed that furosemide (2×10^?4 to 1×10^?3 g/mg) inhibits the increase in chloride conductance evoked by iontophoretic application of acetylcholine, suberyldicholine, and gamma-aminobutyric acid (GABA). If microelectrodes filled with potassium sulfate were used in the experiments furosemide did not shift the reversal potential, but when microelectrodes filled with potassium chloride were used the reversal potential of the chloride-dependent responses became less negative. In the last case, the action of furosemide evidently was exhibited not only on passive chloride conductance of the chemoreceptive membrane, but also on active chloride transport. Furosemide had no effect on sodium- and potassium-dependent responses evoked by activation of choline receptors. Unlike D-tubocurarine, which selectively blocks acetylcholine effects, furosemide also depressed conductance evoked by GABA. In the presence of furosemide chloride-dependent responses not only were reduced in amplitude, but also developed more slowly. It is postulated that the action of furosemide is aimed not at receptors, but at chloride channels of the chemoreceptive membrane common to both acetylcholine and GABA.     

Modulation of transmitter release from the terminals of the locust wing stretch receptor neuron by muscarinic antagonists

The forewing stretch receptor (SR) neuron makes monosynaptic connections with wing depressor motoneruons; in this article the pharmacology of its output onto the first baslar motoneuron (BA1) has been investigated. The SR, like other insect afferents that have been studied so far, appears to be cholinergic; transmission was suppressed reversibly by the nicotinic antagonist gallamine (10^?4M) and irreversibly by α-bungarotoxin (10^?6 M). The choline reuptake blocker hemicholinium-3 (10^?4 M) also caused a reversible reduction in the amplitude of SR excitatory postsynaptic potentials (EPSPs) recorded in BA1. The receptor subtype nonselective muscarinic antagonists atropine (10^?4 M), scopolamine (10^?4 M), and quinuclidinyl benzilate (10^?5 M), unlike nicotinic antagonists, caused an augmentation in EPSP amplitude. This effect does not appear to be caused by an increase in sensitivity of the motoneuron to acetylcholine (ACh), since atropine produced a marked reduction rather than an increase in the amplitude of responses to ACh pressure applied to the soma of BA1. Scopolamine only caused a modest reduction in the amplitude of ACh somatic responses. The simplest explanation for these observations is that muscarinic antagonists bring about an increase in EPSP amplitude by blockade of presynaptic autoreceptors that normally down-regulate the release of ACh from SR terminals. The effects of muscarinic receptor subtype-selective antagonists indicate that presynaptic receptors in this preparation may have a pharmacological profile more similar to that of vertebrate M₂ receptors than to that of M₁ or M₂ subtypes. The functional significance of autoreceptors in this preparation are discussed. © 1995 John Wiley & Sons, Inc.     

Modulation of transmitter release from the locust forewing stretch receptor neuron by GABAergic interneurons activated via muscarinic receptors

The role of muscarinic receptors in the down‐regulation of acetylcholine (ACh) release from the locust forewing stretch receptor neuron (fSR) terminals has been investigated. Electrical stimulation of the fSR evokes monosynaptic excitatory postsynaptic potentials (EPSPs) in the first basalar motoneuron (BA1), produced mainly by the activation of postsynaptic nicotinic cholinergic receptors. The general muscarinic antagonists scopolamine (10⁻⁶ M) and atropine (10⁻⁸ to 10⁻⁶ M) caused a reversible increase in the amplitude of electrically evoked EPSPs. However, scopolamine (10⁻⁶ M) caused a slight depression in the amplitude of responses to ACh pressure‐applied to the soma of BA1. These observations indicate that the EPSP amplitude enhancement is due to the blockade of muscarinic receptors on neurons presynaptic to BA1. The muscarinic receptors may be located on the fSR itself and act as autoreceptors, and/or they may be located on GABAergic interneurons which inhibit ACh release from the fSR. Electron microscopical immunocytochemistry has revealed that GABA‐immunoreactive neurons make presynaptic inputs to the fSR. The GABA antagonist picrotoxin (10⁻⁶ M) caused a reversible increase in the EPSP amplitude, which does not appear to be due to an increase in sensitivity of BA1 to ACh, as picrotoxin (10⁻⁶ M) slightly decreased ACh responses recorded from BA1. Application of scopolamine (10⁻⁶ M) to a preparation preincubated with picrotoxin did not cause the EPSP amplitude enhancement normally seen in control experiments; in fact, it caused a slight depression. This indicates that at least some of the presynaptic muscarinic receptors are located on GABAergic interneurons that modulate transmission at the fSR/BA1 synapse. © 1999 John Wiley & Sons, Inc. J Neurobiol 40: 420–431, 1999     

Acetylcholine responses of identified neurons in Helix pomatia--I. Interactions between acetylcholine-induced and potential-dependent membrane conductances

The influence of potential-dependent membrane conductances on amplitude and time course of acetylcholine (ACh) responses was studied. The investigations were performed on the identified neurons B1 and B3 of the buccal ganglion of Helix pomatia. The neurons B1 and B3 were depolarized by ACh. The depolarization was accompanied by a decrease of membrane resistance. An inward rectification occurring negative to the resting membrane potential (RMP) reduced the amplitude of the ACh depolarizations. An outward rectification occurring positive to the RMP consisted of two parts and ceiled the ACh responses. The early outward current reduced the amplitude and modified the time course of ACh responses. Local responses or axonal action potentials increased the amplitude of the ACh depolarizations.     

Effect of curare on responses to different putative neurotransmitters in Aplysia neurons

We have studied the effects of curare on responses resulting from iontophoretic application of several putative neurotransmitters onto Aplysia neurons. These neurons have specific receptors for acetylcholine (ACh), dopamine, octopamine, phenylethanolamine, histamine, γ-aminobutyric acid (GABA), aspartic acid, and glutamic acid. Each of these substances may on different specific neurons elicit at least three types of response, caused by a fast depolarizing Na⁺, a fast hyperpolarizing Cl^?, or a slow hyperpolarizing K⁺ conductance increase. All responses resulting from either Na⁺ or Cl^? conductance increases, irrespective of which putative transmitter activated the response, were sensitive to curare. Most were totally blocked by ≤ 10^?4 M curare. GABA responses were less sensitive and were often only depressed by 10^?3 M curare. K⁺ conductance responses, irrespective of the transmitter, were not curare sensitive. These results are consistent with a model of receptor organization in which one neurotransmitter receptor may be associated with any of at least three ionophores, mediating conductance increase responses to Na⁺, Cl^?, and K⁺, respectively. In Aplysia nervous tissue, curare appears not to be a specific antagonist for the nicotinic ACh receptor, but rather to be a specific blocking agent for a class of receptor-activated Na⁺ and Cl^? responses.     

Calcium dependence of acetylcholine induced conductance changes.

The influence of external calcium variation (0.7–28 mM) on acetylcholine (ACh) induced conductance changes was examined under voltage clamp conditions in snail neurons in which ACh elicitis hyperpolarizing responses and in which the main current-carrying ion species is Cl^?. Raising external calcium to 28 mM as well as lowering external calcium to 1.75 mM decreased the ACh-induced condutance change without altering the reversal potential for ACh-induced currents. Lowering external calcium to 0.7 mM increased the ACh-induced conductance change and shifted the reversal potential to less negative values. The results at 28 mM calcium can be best explained on the assumption that excess calcium interferes with the interaction between ACh and the receptor. The results at 1.75 mM calcium can be satisfactorily explained in terms of the concept that fixed membrane charges play a role in regulating Cl^? permeation through transmitter sensitive membranes. Evidence was also obtained that in snail neurons receptor inactivation increases when external calcium is reduced.     

Modulation of sprouting in organ culture after axotomy of an identified molluscan neuron

We examined a variety of factors that might modulate the initiation of neurite outgrowth in an attempt to identify means by which its initiation might be accelerated. We examined this initiatio from an identified molluscan neuron, Helisoma trivolvis buccal neuron B5 after axotomy, and determined whether the site of injury, temperature, ion channel blockers, pH, the second messenger cAMP, and protein synthesis affect the initiation of neurite outgrowth. Neurite outgrowth was assayed from axotomized neurons by filling the neurons intracellularly with Lucifer Yellow and examining the percentage of axons that extended (sprouted) new process after 9 or 24 h in organ culture. About one-third (31%) of axotomized neurons sprouted from the site of injury after 9 h (n = 22), and 88% (n = 20) sprouted after 24 h in saline at 22°–24°C when the injury was located 800 μm from the soma. Elevating the temperature to 32°C or moving the lesion site to 400 or 1500 μm from the soma did not significantly alter the incidence of sprouting. Blocking sodium channels with tetrodotoxin [TTX (2 × 10^?5 M)] did not significantly reduce the incidence of sprouting, whereas the sodium channel agonist, veratridine (10^?5 M) did. The calcium channel blocker lanthanum (10^?6–10^?4 M), stimulated neurite outgrowth; however, the organic calcium channel blocker verapamil (10^?3–10^?5 M), and the calcium ionophore A23187 (10^?5 M), had no effect on sprouting. Exposure of neurons to the potassium channel blocker tetraethylammonium [TEA (20 mM)], elevation of intracellular pH with NH₄Cl (5 mM), or treatment with the adenylate cyclase activator forskolin (10^?5 M) reduced the incidence of sprouting, whereas dideoxy-forskolin (10^?5 M) had no effect. Inhibition of protein synthesis with anisomycin (2 × 10^?4 to 2 × 10^?6 M) did not significantly suppress sprouting 24 h after axotomy. Both d and l isomers of glutamate (300 μM) stimulated sprouting. The present results suggest that the initiation of sprouting is regulated locally at or near the site of injury, and that blocking specific ion channels may either inhibit or enhance the initiation of neurite outgrowth.     

Excitatory action of γ-aminobutyric acid (GABA) on crustacean neurosecretory cells

Summary 1. Intracellular and voltage-clamp recordings were obtained from a selected population of neuroscretory (ns) cells in the X organ of the crayfish isolated eyestalk. Pulses of -aminobutyric acid (GABA) elicited depolarizing responses and bursts of action potentials in a dose-dependent manner. These effects were blocked by picrotoxin (50 µM) but not by bicuculline. Picrotoxin also suppressed spontaneous synaptic activity.2. The responses to GABA were abolished by severing the neurite of X organ cells, at about 150 µm from the cell body. Responses were larger when the application was made at the neuropil level.3. Topical application of Cd²⁺ (2 mM), while suppressing synaptic activity, was incapable of affecting the responses to GABA.4. Under whole-cell voltage-clamp, GABA elicited an inward current with a reversal potential dependent on the chloride equilibrium potential. The GABA effect was accompanied by an input resistance reduction up to 33% at a –50 mV holding potential. No effect of GABA was detected on potassium, calcium, and sodium currents present in X organ cells.5. The effect of GABA on steady-state currents was dependent on the intracellular calcium concentration. At 10^–6 M [Ca²⁺]_i, GABA (50 µM) increased the membrane conductance more than threefold and shifted the zero-current potential from–25 to–10 mV. At 10^–9 M [Ca²⁺]_i, GABA induced only a 1.3-fold increase in membrane conductance, without shifting the zero-current potential.6. These results support the notion that in the population of X organ cells sampled in this study, GABA acts as an excitatory neurotransmitter, opening chloride channels.     

Effects of apelin-13 in mice model of experimental pain and peripheral nociceptive signaling in rat sensory neurons

Objective: Apelin-13 is an endogenous peptide with potential analgesic action, although the sites of its analgesic effects remain uncertain and the results are even controversial with regard to its pain modulating action. This study evaluated the possible pain-modulating action of peripherally administered apelin-13 using heat-induced, withdrawal latency to the thermal stimuli, acute pain model in mice. Involvement of peripheral mechanisms was tested, by using the intracellular calcium concentrations as a key signal for nociceptive transmission, in cultured rat dorsal root ganglion (DRG) neurons. Methods: DRG neurons were cultured on glass coverslips following enzymatic digestion and mechanical agitation, and loaded with the calcium-sensitive dye Fura-2 acetoxymethyl ester (1?µM). Intracellular calcium responses in individual DRG neurons were quantified by ratiometric calcium imaging technique. Results: Peripheral injection of a single dose of apelin-13 (100?mg/kg and 300?mg/kg) significantly decreases the latency to painful stimuli in a dose and time-dependent manner (p?<?0.01, p?<?0.05, respectively, n?=?8 each). Apelin-13 (0.1?µM and 1?µM) did not produce a significant effect on cytoplasmic Ca²⁺ ([Ca²⁺]_i) responses, evoked by membrane depolarization, in cultured rat DRG neurons. Conclusion: Together these results indicate that apelin-13 can cause increased pain sensitivity after peripheral administration, but this effect does not involve calcium mediated signaling in primary sensory neurons.     

Amyloid β-Peptide Inhibits High-Affinity Choline Uptake and Acetylcholine Release in Rat Hippocampal Slices

Abstract: The characteristic pathological features of the postmortem brain of Alzheimer's disease (AD) patients include, among other features, the presence of neuritic plaques composed of amyloid β-peptide (Aβ) and the loss of basal forebrain cholinergic neurons, which innervate the hippocampus and the cortex. Studies of the pathological changes that characterize AD and several other lines of evidence indicate that Aβ accumulation in vivo may initiate and/or contribute to the process of neurodegeneration and thereby the development of AD. However, the mechanisms by which Aβ peptide influences/causes degeneration of the basal forebrain cholinergic neurons and/or the cognitive impairment characteristic of AD remain obscure. Using in vitro slice preparations, we have recently reported that Aβ-related peptides, under acute conditions, potently inhibit K⁺-evoked endogenous acetylcholine (ACh) release from hippocampus and cortex but not from striatum. In the present study, we have further characterized Aβ-mediated inhibition of ACh release and also measured the effects of these peptides on choline acetyltransferase (ChAT) activity and high-affinity choline uptake (HACU) in hippocampal, cortical, and striatal regions of the rat brain. Aβ_1–40 (10^?8M) potently inhibited veratridine-evoked endogenous ACh release from rat hippocampal slices and also decreased the K⁺-evoked release potentiated by the nitric oxide-generating agent, sodium nitroprusside (SNP). It is interesting that the endogenous cyclic GMP level induced by SNP was found to be unaltered in the presence of Aβ_1–40. The activity of the enzyme ChAT was not altered by Aβ peptides in hippocampus, cortex, or striatum. HACU was reduced significantly by various Aβ peptides (10^?14 to 10^?6M) in hippocampal and cortical synaptosomes. However, the uptake of choline by striatal synaptosomes was altered only at high concentration of Aβ (10^?6M). Taken together, these results indicate that Aβ peptides, under acute conditions, can decrease endogenous ACh release and the uptake of choline but exhibit no effect on ChAT activity. In addition, the evidence that Aβ peptides target primarily the hippocampus and cortex provides a potential mechanistic framework suggesting that the preferential vulnerability of basal forebrain cholinergic neurons and their projections in AD could relate, at least in part, to their sensitivity to Aβ peptides.     

Extracellular calcium dependence of contracture and modulation by serotonin in buccal muscle E1 of Aplysia

Serotonin [5-hydroxytryptamine (5-HT)] enhances acetyl choline (ACh)-elicited contractures of Aplysia buccal muscles E1 and I5. The possible role of external calcium in regulating the magnitude of ACh contracture in the presence and absence of 5-HT was investigated. Superfusion of E1 with zero calcium medium caused ACh contractures to fail within one to two minutes. Recovery of ACh contracture upon restoring normal medium occurred within two to four minutes. In the absence of 5-HT, ACh contracture decreased proportionally to external [Ca⁺⁺] in the concentration range of 0–10 mM; however, the amount of enhancement of of ACh contracture following 5-HT treatment did not decrease with external [Ca⁺⁺] as long as [Ca⁺⁺] was above a threshold concentration that varied from preparation to preparation. For most preparations, the enhancement of ACh contracture by 5-HT was dependent on the presence of external calcium during 5-HT treatment. Calcium influx into muscles E1 and I5 increased approximately two and a half fold in the presence of 10^?6 M 5-HT. A model in which 5-HT brings about calcium “loading” of an ACh releasable intracellular storage site is discussed.     

Intracellular calcium and extra-retinal photoreception in Aplysia giant neurons

The early or “instantaneous” current-voltage relationship for the light-activated potassium current in Aplysia giant neurons was linear during the first second of illumination. However, the light current was greatly reduced or abolished by prolonged hyperpolarization. It was also greatly reduced by the injection of calcium EGTA buffers having calcium activities of 5.6 × 10^?8 M and simulated by injecting buffers with calcium activities of 2.8–5.6 × 10^?7 M. Removal of calcium from the extracellular fluid had no effect. Both the light-and calcium-activated outward potassium currents were reduced by tetra-ethylammonium (TEA) ions. The light current was not affected by substituting rubidium for potassium nor by substituting either lithium or Tris for sodium. The calcium-activated potassium current persisted when the neuron was cooled to 5°C. However, the light response could no longer be elicited. Light hyperpolarizes Aplysia neurons probably by increasing intracellular calcium activity two-to six-fold which activates a membrane potassium conductance. Calcium levels appear to be restored within the cell and are energy dependent. The light-activated release of calcium is inhibited by cooling. The body wall of Aplysia transmits enough visible or 500-nm light to hyperpolarize some Aplysia giant neurons under ambient conditions. These neurons may be involved in the extraretinal light entrainment that occurs in Aplysia.     

Effects of different ions on resting polarization and on the mass receptor potential of carotid body chemosensors

The carotid body and its own nerve were removed from cats anesthetized with sodium pentobarbital and placed in an air gap system; the carotid body was bathed in modified Locke's solution equilibrated with 50% O₂ in N₂, pH 7.43 at 35°C. The sensory discharges, changes in “resting” receptor polarization and the mass receptor potential evoked by ACh or NaCN were recorded with nonpolarizable electrodes placed across the gap. Receptor potentials and sensory discharges evoked by ACh showed an appreciable increase in amplitude and frequency when the preparation was bathed in eserinized Locke. Eserine did not change appreciably the responses evoked by NaCN. Excessive depolarization elicited by either ACh or NaCN was accompanied by sensory discharge block. Removal of K⁺ ions from the bathing solution induced receptor hyperpolarization and an increase in the amplitude of the evoked receptor potentials. An increase of K⁺ concentration had the opposite effect. Reduction of Na⁺ or NaCl to one half, or total removal of this salt, induced an initial reduction and later disappearance of the sensory discharges, some receptor hyperpolarization and a reduction in the amplitude of the evoked receptor potentials. Reduction or removal of Ca⁺⁺ produced receptor depolarization, a marked depression of the evoked receptor potentials, an increase in the frequency of the sensory discharges and a reduction in the amplitude of the nerve action potentials. High Ca⁺⁺ or Mg⁺⁺ had little or no effect on action potential amplitude or resting polarization, but decreased sensory discharge frequency and the evoked receptor potentials. Total or partial replacement of Ca⁺⁺ with Mg⁺⁺ induced complex effects: (1) receptor depolarization which occurred in low Ca⁺⁺, was prevented by addition of Mg⁺⁺ ions; (2) the amplitude of the evoked receptor potentials was depressed; (3) the nerve discharge frequency was reduced as it was in high Mg⁺⁺ solutions; and (4) the amplitude of the nerve action potentials was reduced as it was in low Ca⁺⁺ solutions. Temperature had a marked effect on the chemoreceptors since a t high temperatures the receptors were depolarized and the discharge frequency increased. The baseline discharge and responses evoked by ACh or NaCN were depressed at low temperatures. The results are discussed in terms of possible receptor mechanisms influenced by the different ions.     

Electrophysiology of phagocytic membranes: Induction of slow membrane hyperpolarizations in macrophages and macrophage polykaryons by intracellular calcium injection

Summary Some electrophysiological characteristics of macrophages and macrophage polykaryons of foreign body granuloma have been investigated. Cells were obtained from implants of small coverslips in the subcutaneous tissue or in the peritoneal cavity of rats and mice. Transmembrane potentials ranged from –5 to –40 mV. Input resistances ranged from 5 to 120 M, being significantly higher in mice polykaryons. Approximately 10% of the cells exhibited spontaneous slow membrane hyperpolarizations (SH) indistinguishable from those observed in macrophages. SH responses were invariably evoked by iontophoretic injection of calcium ions into the cytoplasm of mice macrophages or macrophage polykaryons. The amplitude of these responses increased with the amount of current carried by calcium ions into the cells. The maximum amplitude of the calcium-induced SH responses is a linear function of the logarithm of [K⁺] ₀ (from 3 to 40mm). The slope of the regression line is 43 mV for a 10-fold increase in [K⁺] ₀ . Substituting sodium chloride by sodium isethionate or by choline chloride does not interfere with the occurrence of SH. The assumption that the SH is solely a consequence of an increase in the membrane conductance to K⁺ was used to calculate the potassium equilibrium potential (E _K). TheE _K value is also a linear function of the logarithm of [K⁺] ₀ (from 3 to 40mm). The slope of the regression line is 46 mV for a 10-fold increase in [K⁺] ₀ . These results constitute evidence of the calcium dependence of K⁺ permeability during SH both in macrophages and macrophage polykaryons. Macrophage polykaryons are a more convenient model than macrophages for the study of the mechanisms underlying the SH responses and their possible physiological implications.     

Nitric oxide modulates intensity of non-quantal acetylcholine release in myocardium of the right atrium of rat

The main parasympathetic neurotransmitter acetylcholine (ACh) is released in the myocardium from the intramural postganglionic parasympathetic nerve endings. The mechanism of non-quantal ACh release has been recently demonstrated in these neurons. Non-quantal ACh release does not depend on exocytosis of ACh-containing vesicles in response to nerve impulse activity but is assumed to be mediated by the high-affinity choline uptake system. The intensity of non-quantal ACh release in the myocardium correlates with the degree of manifestation of the effects of acetylcholinesterase inhibitors inducing the accumulation of non-quantal ACh in the myocardium. The present study deals with the influence of putative modulators of non-quantal ACh release: nitric oxide (NO) and ATP, on the intensity of cholinergic effects induced by organophosphorous acetylcholinesterase inhibitor paraoxon. Intracellular registration of bioelectrical activity in isolated right atrium preparations from rats was used. Under normal conditions, paraoxon (10^?7–10^?5 M) induced a marked decrease in the action potential (AP) duration at a level of 50 and 90% repolarization in the working right atrial myocardium and slowed down the sinus rhythm. ATP, which is known to suppress nonquantal ACh release in the neuromuscular junction, did not induce significant reduction or augmentation of the effects of paraoxon (5 × 10^?6 M). The NO donors, sodium nitroprusside (10^?5 M) and SNAP (10^?4 M), significantly reduced the paraoxon-induced AP shortening. Moreover, sodium nitroprusside decreased the negative chronotropic effect of paraoxon by 43.7%. On the contrary, NO synthase inhibitor L-NAME (10^?4 M), which is known to suppress endogenous NO production, augmented the AP shortening caused by paraoxon. It may be deduced that NO is a universal regulator of non-quantal ACh release intensity both in the myocardium and in the neuromuscular junction.     

Excitatory neuromuscular transmission in crayfish: Calcium dependence is unaffected by picrotoxin

Picrotoxin, 1 × 10^?5M to 1.6 × 10^?3M, had little or no effect on the amplitude of intracellularly recorded excitatory junctional potentials (EJPs) at extracellular calcium concentrations [Ca²⁺]₀ ranging from 0.5 to 15 mM. The slope of the log EJP vs. log[Ca²⁺]₀ relationship was approximately 1 with or without picrotoxin. The reduction of EJP amplitude resulting from the addition of 5 × 10^?5M GABA was largely reversed by 10^?5M picrotoxin.     

Vitamin e regulates acetylcholine receptor function of molluscan neurons

1. Intracellular recorclings were made from identified LP11, RBc4, D1 and E4 neurons in perioesophageal ganglionic ring with buccal ganglia of the mollusc Helix pomatia.2. The modulations of acetylcholine (ACh)-induced current by vitamin E in these neurons were investigated using two-microelectrode intracellular recorcling and voltage-clamp techniques.3. ACh receptors function on LP11 and RBc4 neurons was strongly regulated by intracellular calcium ions. For these ACh receptors application of 10⁻⁶ to 10⁻⁴ M vitamin E and calcium influx both induced an enhancement of the ACh-induced chloride current. Application of 10⁻⁵ to 5.10⁻⁵M arachidonic acid on the same identified LP11 and RBc4 neurons was shown to evoke a decrease of the ACh-induced chloride current.4. The elevation of calcium levels into D1 and E4 neurons induced a faint decrease of ACh-induced chloride current, but vitamin E and arachidonic acid were ineffective.5. The calmodulin inhibitor, chloropromazine (6.10^−-5M), strongly inhibited the enhancing effect of calcium influx on ACh-induced chloride current in LP11 and RBc4 neurons, but it had a weak influence on the effect of vitamin E.6. The effect of vitamin E on surface distribution of functional ACh receptors in LP11 and RBc4 neurons was found.7. Application of 10⁻⁴ to 10⁻⁶ M vitamin E (DL-α-tocopherol) triggered mechanisms, which after a 5 to 45-min period lead to appearance of functional ACh receptors on the parts of neuronal soma, which were further from the axon.8. Arachidonic acid (vitamin F) evoked a disappearance of functional ACh receptors, which were activated by vitamin E.     

Mode of action of furosemide on the chloride-dependent short-circuit current across the ciliary body epithelium of toad eyes

Summary The effects of furosemide on the chloride-dependent short-circuit current across the toad ciliary epithelium were examined. Under control conditions, the short-circuit current obeyed Michaelis-Menten kinetics against medium chloride concentration, the Michaelis constant (K _m ) for chloride being 90mm and the maximal short-circuit current (V _max) 128 A/cm². Furosemide added to the aqueous side of the epithelium rapidly reduced the short-circuit current; the effect was reversible. The effect of furosemide addition to the stromal side was much smaller and slower than that from the aqueous side. The dose-dependent range of furosemide action was from 0.1 m to 1mm with 50% inhibition occurring at about 3 m. Line-weaver-Burk plot of the short-circuit current against the chloride concentration showed that furosemide decreased the value ofV _max and increased theK _m ; the inhibition being of mixed type. A Hill plot of the dose-response curve yielding a slope of unity suggested one furosemide molecule combines with one chloride transport site. Probenecid, a competitive inhibitor of organic acid transport, reduced the effects of furosemide significantly when added simultaneously. The involvement of organic acid transport system in the mechanism of furosemide action on chloride transport was suggested.Department of Ophthalmology.     

Electromechanical uncoupling in a molluscan muscle examined by the sucrose gap technique

Summary Membrane potential and tension ofBusycon radular protractor muscles were studied by sucrose gap methods.Excitation-contraction (EC) coupling was examined in response to acetylcholine (ACh) and high K which depolarized the fibres and induced tension, but without action potential firing. Potassium depolarization did not follow predictions expected from the Nernst equation at low and very high K levels, and maximum tension was found at about 100 mM K. EC coupling was very sensitive to [Ca]_o. Ca-free media eliminated K- and ACh-induced tension but with normal depolarization, showing full electromechanical uncoupling.Ionophore A23187 enhanced K- and ACh-induced responses and X-537A enhanced ACh responses, demonstrating acute dependence of activation on [Ca]_o in this muscle. The calcium antagonists nifedipine and nisoldipine reduced tension in the muscle only at very high concentrations, and both agents slightly reduced K- and ACh-induced depolarization.Verapamil reduced K- and ACh-induced tension but paradoxically it enhanced the depolarizing actions of these agents leading to electromechanical uncoupling. Abscisic acid (ABA) enhanced ACh- and K-induced tension and simultaneously enhanced their depolarizing actions. Ionophores and ABA appear to enhance calcium influx which may secondarily influence sodium influx.Calcium antagonists have no consistent actions on this muscle, suggesting that calcium channel activity of the radular protractor may be different from that seen in mammalian visceral muscles.Abbreviations ABRM Anterior byssus retractor muscle - ACh acetylcholine - ABA abscisic acid - EC excitation-contraction - SR sarcoplasmic reticulum - EGTA ethylene-diamine-tetraacetic acid     

Subcellular distribution of potassium, sodium, magnesium, calcium and chloride in cerebral cortex

The subcellular distributions of potassium, sodium, magnesium, calcium and chloride have been determined for rabbit cerebral cortex. After homogenization and differential centrifugation, the following percentages of ions were associated with the particulate fraction (nuclear, mitochondrial, synaptic vesicles, and microsomal): (a) 19% of the total potassium; (b) 22% of the total sodium; (c) 77% of the total calcium; (d) 69% of the total magnesium; and (e) less than 2% of the total chloride. However, the sum of the potassium and sodium content in each of the particulate fractions was greater than the sum of the calcium and magnesium content. After hypo-osmotic shock of the crude mitochondrial fraction (M_T), more sodium than potassium (μmol/g wet wt.) was associated with the mitochondrial (M₁) and synaptic vesicle (M₂) fractions. The molar ratio of sodium to potassium was 1·4 for M₁ and 4·5 for M₂. The association of ²²Na⁺ with the particulate fractions was further studied by the method of equilibrium dialysis. The data from both types of experiments indicate that a large fraction of the sodium in cortical tissue appears to be in a bound state.