Role of calcium ions in processes of serotonin-induced modulation of neuronal response to acetylcholone application in Helix pomatia

The role of calcium ions in modulating serotonin action on acetylcholine (ACh) response in nonidentified and identified (LPa3 and RPa3) neurons ofHelix pomatia was investigated using voltage-clamping at the neuronal membrane. Exposure for 1 min to serotonin prior to ACh application reduced response to ACh in neuron LPa3 and raised it in RPa3. The same two patterns of modulating ACh-induced response were produced by extracellular application of theophylline and dibutyryl c-AMP. Injecting calcium ions into neuron LPa3 led to reinforcement of ACh-induced current in the presence of serotonin, thus changing the pattern of serotonin-induced modulation of ACh response in this unit. In neuron RPa3, the same process enhanced the serotonin-induced modulating effect on ACh response but without changing the pattern of modulation, while injected EDTA produced the reverse effects. Increased intracellular concentration of calcium ions brought about a reduction in the degree of serotonin-induced modulation of ACh response in neuron RPa3. Possible reasons are discussed for changes in serotonin-induced bimodal modulation of ACh response in test neurons produced by altering the extracellular concentration of calcium ions.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 20, No. 5, pp. 666–671, September–October, 1988.     

Effects of α-bungarotoxin on acetylcholine-induced response at the Helix neuronal membrane

The effects of -bungarotoxin (-BT) on two patterns of acetylcholine (ACh)-induced response differing in desensitization rate were investigated in isolated mollusk neurons using intracellular dialysis and concentration clamping techniques. It was found that -BT depressed both types of ACh-induced response — a reversible action in the majority of experiments performed. It also exerted a blocking effect on ACh-induced currents dependent on the presence of albumin, although albumin itself produced no noticeable change in ACh-induced response. Concentration dependence of -BT-induced blockade on both types of currents evoked by 1 and 10 µM ACh was investigated. The -BT concentrations producing a 50% suppression of the current evoked by 1 µM ACh were calculated by approximating concentration plots as (13.85±1.25)×10^–9 and (5.56±1.0)×10^–8 g/ml for type A and B cells respectively.Institute of Experimental Biology. Academy of Sciences of the Armenian SSR, Erevan. Translated from Neirofiziologiya, Vol. 21, No. 6, pp. 729–735, November–December, 1989.     

Mechanisms of tubocurarine action on nicotinic cholinoreceptors of rat sympathetic ganglia neurons

The effects of tubocurarine (TC) on current induced by acetylcholine (ACh) in neurons of rat upper cervical ganglia were investigated using techniques for voltage-clamping at the membrane. Reinforcement of TC-induced blockade was achieved by paired application of ACh following prior activation of nicotinic cholinoreceptors, indicating that TC blocked the channels opened by ACh. On average, the TC-open channel complex persisted for 9.8±0.5 sec (n=7) at –50 mV and 20–24°C. It was found that increases exponentially with hyperpolarization at the membrane (a shift in membrane potential of 61 mV corresponds to an e-fold change). Suppression of ACh-induced current (ACh current) was eliminated completely under the effects of 3–30 M with depolarization of up to 80–100 mV at the membrane. Suppression of ACh current produced by membrane potential at negative levels is intensified with increasing doses of ACh. Findings would indicate that blockade of ionic channels opened by ACh is the only mechanism of TC action on nicotinic cholinoreceptors in rat sympathetic ganglia.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 20, No. 5, pp. 672–680, September–October, 1988.     

The Na,K pump regulates a decrease in the cholinosensitivity of the neurons in the snail Helix lucorum taurica Kryn in a cellular analog of habituation: its dependence on intracellular calcium

In Helix lucorum snail we studied the effects of ouabain, inhibitor of Na,K-pump, on the depression of cholinosensitivity in command neurons of withdrawal behavior and the role of the intracellular free Ca2+. The cellular analog of the negative learning (habituation) was used Transmembrane integral inward currents were recorded from the identified LPa2, LPa3, RPa3, and RPa2 neurons in ganglia preparation using two-electrode voltage clamp technique. Acetylcholine (ACh) was locally applied iontophoretically. Reduction of neuronal cholinosensitivity was estimated as a depth of depression of the ACh-induced inward current during rhythmic local application of ACh (interstimulus interval of 1-3 min) onto the somatic membrane. Bath application of ouabain (0.1 mM) produced an increase in depression in one group of neurons and its decrease in another group. After 60-150 min of spontaneous diffusion of a calcium ion chelator BAPTA (1 mM) from the intracellular microelectrode, ouabain produced only the increase in depression. If CaCl2 (100 mM) was added to the solution of the voltage-recording intracellular microelectrode, 60 min later ouabain produced only the reduction of the depression of the ACh current. The conclusion is drawn that the inhibition of the Na,K-pump by ouabain modifies the depression of neuronal cholinosensitivity in the cellular analog of habituation. The direction of the modulatory effect depends on the basal concentration of the intracellular free Ca2+.     

Voltage dependence of acetylcholine-activated membrane conductance in sympathetic ganglion neurons

Acetylcholine-induced membrane conductance was investigated in superior cervical ganglion neurons using a patch-clamp technique. It was found that hyperpolarization and depolarization produce an increase and a reduction in acetylcholine (ACh) conductance. This reduction was unconnected with either reversal of the current induced by iontophoretic ACh application or the presence of Ca ions in the external solution. The time constant of relaxation (_r) of this current, produced by a jump in membrane potential, was found to increase e-fold when the membrane was hyperpolarized by 70 mV, matching the voltage dependence of ACh conductance. This led to the hypothesis that voltage-dependent ACh-induced conductance is entirely determined by the voltage dependence of nicotinic receptor channel gating kinetics.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 20, No. 2, pp. 167–171, March–April, 1988.     

Further study of the correlation between na-pump activity and membrane chemosensitivity

Using internally dialyzed neurons of Helix, we have examined the effects of sodium-pump activity and intracellular ATP concentration on transmembrane currents induced by acetylcholine (ACh) and gamma-aminobutyric acid (GABA). We also report on the effects of pump activity and levels of intracellular ATP on binding by Helix ganglia of 3H-alpha-bungarotoxin (3H-alpha-BT) and 3H-GABA. Both ouabain-containing and potassium-free solutions depressed the neurotransmitter-induced transmembrane current of one type of dialyzed neurons. An increase in the intracellular ATP concentration led to a depression of ACh-induced currents and to the disappearance of the blocking effect of ouabain on these currents. Intracellular ADP had a similar but smaller effect on transmitter-induced currents, and intracellular AMP was ineffective. The depressing effect of internal ATP on ACh-induced currents was absent in the presence of an inhibitor of membrane phosphorylation (dinitrophenol). The binding of tritium-labeled alpha-BT and GABA to the membranes was depressed by both ouabain-containing and K-free solutions and also by compounds (theophylline and NaF) which increase the levels of intracellular ATP. The results suggest that the Na pump modulates the affinity of ACh and GABA membrane receptors by the regulation of the phosphorylated state of membrane receptors.     

Modulatory effects of oxytocin on functional properties of three types of cholinoreceptors in molluskan neurons

It was found that applying 10^–8 M oxytocin (OT) affects the functional properties of three types of cholinoreceptors under conditions of voltage clamping at the membrane of identified ganglia neurons inHelix pomatia. This neuropeptide depressed acetycholine-(ACh-)induced sodium-potassium-calcium current in neuron RB3 without altering reversal potential of ACh-induced current. Two (sub-) types of cholinoreceptors were distinguished on the basis of findings on OT effects on ACh-induced chloride currents; ACh-induced chloride current was reduced by the action of OT on the cholinoreceptors of one of these (neuron F4) and increased in the case of neurons D5 and F86. The effects of applying OT and serotonin were reversible but not cumulative. Injection of OT exerted an action on ACh-induced chloride current independent of that of OT application. Involvement of cyclic adenosine monophosphate in OT-induced bimodal modulation of functional properties of three types of cholinoreceptors was demonstrated.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziology, Vol. 22, No. 1, pp. 87–93, January–February, 1990.     

Effects of transmitters on pyramidal and nonpyramidal neurons in hippocampal slices

Investigations were performed on the effects of acetylcholine (ACh), norepinephrine (NE), 5-hydroxytryptamine (5-HT), and -aminobutyric acid (GABA) on the background firing of the three following groups of field CA₃ neurons in guinea pig hippocampal slices: nonpyramidal neurons of the stratum radiatum moleculare (NSR), stratum pyramidale cells with single spike discharges (SD units), and those with complex discharge patterns (CD units) within the same layer. The action of ACh and NE on presumed interneurons of the pyramidal layer (IPL) was also investigated; CD units were found to differ from the remaining groups, which reacted similarly to the transmitters tested. It was shown that NE, 5-HT, and GABA inhibited the activity of CD cells, while ACh produced inhibitory-activating response in 50% of these units. Both NE and ACh exerted a monophasic activating effect on NSR, ISP, and SD, however, while 5-HT and GABA induced activation in a proportion of NSR and SD cells, as well as inhibitory response. The excitatory effects produced by ACh, NE, and 5-HT on NSR persisted during blockade of synaptic transmission, indicating that associated afferent fibers may be acting directly on these cells.Institute of Biological Physics, Academy of Sciences of the USSR, Pushchino-on-Oka. Translated from Neirofiziologiya, Vol. 20, No. 1, pp. 64–74, January–February, 1988.     

Characteristics of chloride-dependent effects of acetylcholine and neutral aminoacids on neurons of the snail (Achatina)

The response was investigated of neurons composing the cerebral ganglia inAchatina fulica (the Giant African snail) to application of acetylcholine (ACh), gamma-aminobutyric acid (GABA), and glycine (Gly). Chloride-dependent currents induced by these transmitters in 1 1/2-month old siblings were inhibited by dibutyryl-cAMP and strychnine. Inhibition of ACh response produced 10^–8 M GABA was mimicked by application of dibutyryl-cAMP and isobutylmethylxanthine. Complete cross-desensitization was characteristic of both GABA- and Bly-induced response, but this effect did not occur when ACh and GABA (or Gly) were applied. A conclusion was reached on the basis of the pharmacological relationship between GABA- and Gly-induced response that these amino acids act on a single receptor — channel complex in the neurons of infant snails, whereas ACh-, GABA-, and Gly-induced chloride currents were not so related in cells of 4 year-oldAchatina.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 23, No. 1, pp. 35–43, January–February, 1991.     

Physiological and pharmacological properties of responses to GABA and ACh by abdominal motor neurons in Manduca sexta

1. GABA, ACh, and other agents were applied by pressure ejection to the neuropil of the third abdominal ganglion in the isolated nerve cord of Manduca sexta. Intersegmental muscle motor neurons with dendritic arborizations in the same hemiganglion were inhibited by GABA (Fig. 2) and excited by ACh (Fig. 5).
2. Picrotoxin was a potent antagonist of GABA (Fig. 4A). Bicuculline reduced GABA responses in some motor neurons (Fig. 4C), but had no effect on many other motor neurons. Curare reduced ACh responses (Fig. 6A). Bicuculline was an effective ACh antagonist in most motor neurons tested (Fig. 6B).
3. Motor neurons with dendrites across the ganglion from the ejection pipette exhibited different responses to GABA and ACh. Contralateral motor neurons often showed smaller, delayed hyperpolarizing GABA responses (Fig. 7). On two occasions, contralateral motor neurons had excitatory responses (Fig. 8). Contralateral motor neurons were hyperpolarized by ACh (Fig. 9). The inhibitory responses had only slightly longer latencies than ipsilateral excitatory ACh responses (Fig. 10A). The contralateral inhibitory ACh responses, but not the ipsilateral excitatory ACh responses, were eliminated by TTX (Fig. 10B).
4. A model, which includes inhibitory interneurons that cross the ganglionic midline to inhibit their contralateral homologs and motor neurons (Fig. 11), is proposed to account for contralateral responses to GABA and ACh and antagonistic patterns of activity of motor neurons during mechanosensory reflex responses.

     

ATP-induced currents in submucous plexus neurons of the guinea pig small intestine

ATP-induced membrane durrents in the submucous neurons of the guinea pig small intestine were studied using the whole-cell patch-clamp recording technique. Being applied at –50 mV. ATP activated an inward non-selective cationic current in 68.3% of the investigated neurons. An increase in ATP concentration within the 1–1,000 µM range resulted in the s-like increase in the amplitude of ATP-induced current. The EC₅₀ was 150.0±18.5 µM, while the Hill number was 1.6. The current was selectively activated by ATP and was not blocked by P2 purinoreceptor antagonist suramin (50–300 µM).,-Methylene-ATP (100–200 µM) and,-methylene-ATP (100–200µM), which are P2-purinoreceptor agonists, as well as adenosine (100–300 µM), exerted no effects. Reactive blue 2, if applied up to 4 min, enhanced ATP-induced current, while its longer application partially suppressed this current. In most submucous neurons, acetylcholine (ACh) likewise activated an inward cationic current. The amplitude of ACh-induced current was lower if ACh was applied during a long-lasting application of ATP than if ACh only was applied. Hexamethonium (50 µM), d-tubocurarine (20–40 µM), and trimethaphan (30 µM) completely and reversibly blocked ACh-induced currents, regardless of the presence of ATP, and did not affect ATP-induced currents. The results suggest that ATP-induced currents in submucous neurons are due to activation of a unique type of P2 purinoreceptors, which function in connection with nicotinic ACh receptors.Neirofiziologiya/Neurophysiology, Vol. 28, No. 2/3, pp. 100–110, March–June, 1996.     

Subunit Composition of Nicotinic Acetylcholine Receptors in Neurons of the Rat Intracardiac Ganglia

The effect of the antibodies against 3, 4, 5, and 7 subunits of neuronal nicotinic acetylcholine receptors (nAChR) on ACh-induced shifts of the membrane potential (ACh potentials) in neurons of the intracardiac ganglia of the rat left atrium was studied using intracellular electrodes. It was found that (i) antibodies against each of the above subunits caused only a partial block of ACh potential; (ii) the blocking effect of each particular antibody could be observed only in some of the examined neurons; (iii) in all neurons under study the block caused by a single antibody was only partial; (iv) the blocking effects of two or more antibodies on the ACh potential recorded from the same neuron were additive. It was concluded that (1) each of the above nAChR subunits is present only in a part of the intracardiac neurons, and (2) each intracardiac neuron has nAChR composed of more than one subunit.     

Dopamine modulation of the In vivo acetylcholine response in the Drosophila mushroom body

Olfactory sensory information in Drosophila is transmitted through antennal lobe projections to Mushroom Body neurons (Kenyon cells) by means of cholinergic synapses. Application of acetylcholine (ACh) and odors produce significant increases in intracellular calcium ([Ca²⁺]_i) in these neurons. Behavioral studies show that Kenyon cell activity is modulated by dopaminergic inputs and this modulation is thought to be the basis for an olfactory conditioned response. However, quantitative assessment of the synaptic inputs to Kenyon cells is currently lacking. To assess neuronal activity under in vivo conditions, we have used the endogenously‐expressed camgaroo reporter to measure [Ca²⁺]_i in these neurons. We report here the dose‐response relationship of Kenyon cells for ACh and dopamine (DA). Importantly, we also show that simultaneous application of ACh and DA results in a significant decrease in the response to ACh alone. In addition, we show inhibition of the ACh response by cyclic adenosine monophosphate. This is the first quantitative assessment of the effects of these two important transmitters in this system, and it provides an important basis for future analysis of the cellular mechanisms of this well established model for associative olfactory learning. © 2009 Wiley Periodicals, Inc. Develop Neurobiol, 2009     

Reversible alterations in the Golgi complex of cultured neurons treated with an inhibitor of active Na and K transport

Highly differentiated cultures of rat and mouse sensory ganglia were treated for varying periods (up to 6 hr) with selected doses (1 x 10^-3 M to 5 x 10^-5 M) of the cardiac glycoside, ouabain (Strophanthin G). This inhibitor of active Na and K transport produced a selective and progressive swelling of elements of the Golgi complex in many, but not all, neurons. After 6 hr of treatment, virtually all Golgi complexes in affected neurons were either altered or absent; large cytoplasmic vacuoles limited by agranular membrane were prominent in these neurons. This response was not observed in satellite cells and Schwann cells. Within a few hours of ouabain withdrawal, the neuronal vacuoles disappeared and normal Golgi areas were again observed. These observations suggest that there is a site for active transport of Na and K on the Golgi membrane of these neurons. In discussing the possible significance of this observation, it is suggested that if this site were directed so that cation was actively pumped from Golgi cisternae into cytoplasm (and if there were differential water and ion permeabilities in various parts of the endoplasmic reticulum-Golgi system), then such a pumping mechanism could provide an explanation for the concentrating function of the Golgi apparatus.     

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.     

The effects of short-chain fatty acids on the neuronal membrane functions ofHelix pomatia. II. cholinoreceptive properties

We have examined the effects of short-chain fatty acids on acetylcholine (ACh)-induced transmembrane currents using internally dialyzed neurons of Helix. Decenoic acid, which increased the fluidity of excitable membranes, caused dramatic changes in the voltage sensitivity of ACh currents consisting of an ACh-induced increase in membrane permeability for K+ and Na+ ions and a shift of the Erev of these ACh responses to more positive potentials. Valeric acid, which did not change the membrane fluidity, had no effect on this type of ACh response. Changes of the ENa and ECl had no effect on the size of the decenoic acid-induced shift of the Erev. But the influence of decenoic acid on the voltage sensitivity of ACh-induced currents almost disappeared after the change of the EK by the reduction of the internal K concentration. Decenoic acid had no effect on ACh responses in which K+ ions were not involved in the generation of ACh-induced currents. The results suggest that decenoic acid-induced changes in membrane fluidity modulate cholinoreceptive properties of the neuronal membrane by the inhibition of the K+ carrier involved in the generation of ACh responses.     

“Intracellular” GABA affects the equilibrium distribution of Cl− across the plasma membrane of a GABA acceptive neuron

The permeability of Cl^– ions through single microdissected plasma membranes from Deiters' neurons was studied by a microtechnique. In particular, the time course of the passage of³⁶Cl^– ions from a microchamber, M₁, to another one, M₂, across the membrane was followed. This study was performed with or without -amino-butyric acid (GABA) in the two microchambers. The results suggest that in basal conditions the high intracellular concentration normally present in these neurons, 3.3 mM (1), causes a higher permeability of Cl^– in the direction inside outside in the respect of the plasma membrane. Extracellular GABA, 0.1 mM, is able to abolish this imbalance in Cl^– permeability in the two opposite directions. This event appears to be the basis for GABA induced hyperpolarization of these neurons.     

The pharmacological characteristics of two types of cholinoreceptors in the membrane of dialyzed neurons

1. The ramped voltage clamp technique was developed as a rapid means of studying the effects of certain nicotinic and muscarinic agents on ionic involvement and conductance changes during acetylcholine (ACh) responses of Helix pomatia neurons. 2. Atropine was found to be a potent cholinolytic on A-type neurons, ACh responses of which are blocked by ouabain and mediated by Na+ and Cl- permeabilities, while d-tubocurarine blocked B-type ACh responses which are insensitive to ouabain and mediated by Na+ and K+ permeabilities. 3. Nicotinic agent butyrylcholine was found to be a potent cholinomimetric on B-type cells. 4. The results suggest that ACh receptors on A-type cells are more "muscarinic" while those on B-type cells are more "nicotinic". 5. It was also suggested that both muscarinic and nicotinic ACh receptors may coexist in the Helix neuronal membrane and the possibility of ACh interacting with one of them is determined by the level of phosphorylation of the membrane proteins.     

Effects of "non-quantal" acetylcholine on postsynaptic membrane senstitivity: Effects of ouabain,and mimicry by exogenous acetylcholine

The development of postsynaptic potentiation (PSP) and desensitization due to "non-quantal" acetylcholine that occurs when acetylcholinesterase (AChE) is inhibited was studied using the Na,K-ATPase inhibitor, ouabain, to alter (initially increasing, then decreasing) the level of non-quantal acetylcholine secretion, and exogenous acetylcholine. When ouabain increased non-quantal secretion the time constant () of the miniature end-plate current (MEPC) decay increased, i.e., PSP developed. The later the application of ouabain relative to inhibition of AChE, the greater the degree of PSP. During the next phase when non-quantal secretion was inhibited the MEPC time course shortened more rapidly than in the controls, i.e., desensitization occurred. If ouabain abolished non-quantal secretion before AChE had been inhibited did not change, and neither PSP nor desensitization developed. When AChE was not inhibited ouabain had no effect on . When ACh was continuously applied at 20 nmol·liter^–1, similar to the nonquantal concentration, the shortening of slowed down, and the signal amplitude declined more rapidly than in controls. Addition of exogenous ACh (50 nmol·liter^–1) after acceleration of MEPC decay had developed caused to increase to its initial value. The combined appearance of PSP and desensitization during the action of non-quantal ACh, and the sustained desensitization after removal of released ACh from the synaptic cleft are discussed.S. V. Kurashova Institute of Medicine, Russian Federation Ministry of Public Health, Kzan. Translated from Neirofiziologiya, Vol. 24, No. 4, pp. 396–404, July–August, 1992.     

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.