Iontophoretic application of acetylcholine: advantages of high resistance micropipettes in connection with an electronic current pump

Electrical activity and postsynapse formation in adult muscle: gamma-AChRs are not required

Skeletal muscle fibers will not accept hyperinnervation by foreign motor axons unless they are paralyzed, suggesting that paralysis makes them receptive to innervation, e.g., by upregulating extrasynaptic expression of gamma-AChRs and/or of the agrin receptor MuSK. To examine the involvement of these parameters in paralysis-mediated synapse induction, ectopic expression of agrin, a factor from motor neurons controlling neuromuscular synapse formation, was made dependent on the administration of doxycycline in innervated adult muscle fibers. In response to doxycycline-induced agrin secretion, adult fibers did form ectopic postsynaptic specializations, even when they were electrically active, lacked fetal AChRs, and expressed normal low levels of MuSK. These data demonstrate that paralysis and changes associated with it are not required for agrin-induced postsynapse formation. They suggest that paralyzed muscle induces synapse formation via the release of factors that make motor neurites contact muscle fibers and secrete agrin.

The channel-blocking action of methonium compounds on rat submandibular ganglion cells. 1983

The effects of drugs of the polymethylene bis-trimethylammonium (methonium) series on the characteristics of the synaptic currents (e.s.cs) recorded from voltage-clamped rat submandibular ganglion cells have been studied. The drugs studied were from C4 to C10 (decamethonium).

All of the drugs except C4 shortened the initial decay phase of the e.s.c.; C9 and C10 produced an additional slowly decaying component. These effects were interpreted in terms of an open channel block mechanism, the calculated rate constants for association with the open channel at − 80 mV being fairly similar (5.9 × 10⁶ to 18.1 × 10⁶M⁻¹ s⁻¹) for all of the compounds except C4, which had no effect on the e.s.c. decay.

All of the compounds produced use-dependent block when tested with short trains of stimuli at 10 Hz, or with trains of ionophoretic pulses of acetylcholine, consistent with their channel blocking property. Tubocurarine had a similar effect, but not trimetaphan or mecamylamine.

Recovery from use-dependent block with short chain methonium compounds, up to C8, was very slow in the absence of agonist, being incomplete even after several minutes. With C9 or C10 or tubocurarine, recovery from use-dependent block was complete within a few seconds. With C6 recovery in the absence of agonist was unaffected by membrane potential, but could be accelerated by applying acetylcholine with the cell depolarized to − 40 mV. This persistent block was ascribed to the ability of the blocking molecule to become trapped by closure of the channel. With C9 and C10 it is assumed that their presence inhibits channel closure, so they can escape without the help of agonist.

When use-dependent block is avoided by leaving the ganglion unstimulated during equilibration with the blocking drug, the first e.s.c. elicited shows no appreciable reduction of amplitude, though with C6, C7 or C8 subsequent responses elicited at 0.1 Hz become progressively more blocked.

Even at 1 Mm, C6 does not prevent acetylcholine from opening ionic channels.

It is concluded that all of the effects on e.s.c. amplitude can be interpreted in terms of channel block, there being no evidence of any receptor blocking action.

A constant current source for extracellular microiontophoresis

A sophisticated constant-current source suitable for extracellular microiontophoresis of tract-tracing substances, such as Phaseolus vulgaris leucoagglutinin, Biocytin or Fluoro-Gold, is described. This design uses a flyback switched-mode power supply to generate controllable high-voltage and operational amplifier circuitry to regulate current and provide instrumentation. Design features include a fast rise time, +/- 2000 V supply (stable output in < 250 ms), simultaneous load current and voltage monitoring, and separate pumping and holding current settings. Three features of this constant-current source make it especially useful for extracellular microiontophoresis. First, the output voltage monitor permits one to follow changes in the microelectrode resistance during current injection. Second, the voltage-limit (or out-of-compliance) indicator circuitry will sound an alarm when the iontophoretic pump is unable to generate the desired current, such as when the micropipette is blocked. Third, the high-compliance voltage power supply insures up to +/- 20 microA of current through 100 M omega resistance. This device has proven itself to be a reliable constant-current source for extracellular microiontophoresis in the laboratory.

Ionophoretically applied acetylcholine and vagal stimulation in the arrested sinus venosus of the toad, Bufo marinus

1. The effects of acetylcholine (ACh), applied by ionophoresis, on the isolated arrested sinus venosus of the toad, Bufo marinus, were examined. 2. At each position where ACh was applied across the surface of sinus venosus preparations, a hyperpolarization was produced. These responses were abolished by hyoscine, indicating that muscarinic cholinoceptors are widely distributed over the surface of these muscle cells. 3. Vagal stimulation produced hyperpolarizations which were mimicked, to some extent, by ionophoretically applied ACh. 4. The responses to ionophoretically applied ACh were abolished by adding barium ions to the perfusion fluid, whereas responses to vagal stimulation persisted. 5. The responses to ionophoretically applied ACh were consistently slower than those to vagal stimulation. It is argued that the pathways activated by neural and applied ACh have different kinetics of activation.

Potassium currents in chick sensory neurons change with development

We used the whole-cell configuration of the giga-seal voltage-clamp to study voltage-gated potassium currents in sensory neurons dissociated from dorsal root ganglia from embryonic and hatched chicks. Neurons from 8-, 10-, 14-, and 18-day-old embryos (E8, E10, E14, E18) and 1- to 5-day-old chicks were studied under conditions which inhibited inward currents and calcium-activated currents (tetrodotoxin, no added calcium, intracellular EGTA). At all ages, potassium currents were activated by depolarizations to potentials positive to -40 mV. At a given age the amount of inactivation of outward current during 50- to 100-ms steps varied from cell to cell; some cells showed no inactivation while in others the outward current declined to about half of the peak current. On average, the amount of inactivation was fairly stable at E8, E10, E18, and in hatched chicks but showed a transient increase at E14. In contrast, currents elicited by 50-ms test steps following 2-s conditioning steps showed an age dependent change. In E8 neurons, shifting the conditioning voltage from -100 to -90 mV had little or no effect on the current at the end of the test step while earlier outward current was reduced. In cells from older embryos or hatched chicks, similar conditioning voltages caused reductions of both early and late currents during the test step. The relative amount of late current inactivated by this protocol increased as the age of the chicks increased. In addition, the amount of variation in the inactivation properties was larger in cells from older embryos and hatched birds. The changes in outward current occur during a period in which new neurons are formed and existing neurons mature and establish function.

Whole-cell calcium current in guinea-pig ventricular myocytes dialysed with guanine nucleotides

1. Whole-cell calcium current (ICa) was recorded in guinea-pig ventricular myocytes superfused with Na+,K(+)-free solution and dialysed with a substrate-free solution (minimum intracellular solution, MICS). A dual tight-seal pipette method was often used to permit pressure-enhanced dialysis of a test solution after a given pre-dialysis. 2. In dual-pipette experiments, test dialysates contained 100 mM-GTP-gamma-S (guanosine 5'-O-(3-thiotriphosphate] or 100 microM-GMP-PNP (guanyl-5'-imidodiphosphate). These non-hydrolysable analogues of guanosine triphosphate (GTP) enhanced ICa amplitude (+ 10 mV) by 20-40%. Dialysates containing 100 microM-GTP or GDP-beta-S (guanosine 5'-O-(2-thiodiphosphate] were ineffective, and pre-dialysis with GDP-beta-S blocked stimulation by GTP-gamma-S. 3. Non-hydrolysable GTP analogues slowed the inactivation of ICa and shifted the voltage eliciting maximum ICa by 5-10 mV in the negative direction. 4. ICa enhancement by GTP analogues was attributed to the activation of three GTP-binding regulatory (G) proteins (Gi, Gp and Gs). In single-pipette experiments, the inactivation of Gi by pre-treatment with pertussis toxin did not block enhancement, and a Gp-activating regimen (external acetylcholine-internal GTP) was without effect. Thus, it is probable that the effects of GTP analogues on ICa were primarily mediated by Gs activation. 5. PI-MICS dialysates contained phosphorylation-pathway inhibitors and were used to inhibit Ca2+ channel phosphorylation via the adenyl cyclase pathway. These were deemed effective since forskolin (1-5 microM) doubled ICa during control dialysis but was without effect after 8 min PI-MICS dialysis. However, 0.1 microM-isoprenaline increased ICa by 35% in myocytes totally unresponsive to forskolin, suggesting that beta-adrenergic receptor occupation can stimulate ICa even when the phosphorylation pathway is blocked. 6. After prolonged dialysis of myocytes with PI-MICS, ICa was still enhanced by pressure-assisted dialysis of 100 microM-GTP-gamma-S or GMP-PNP. We conclude that activated Gs has a direct effect on cardiac Ca2+ channels.

A dual-pipette technique that permits rapid internal dialysis and membrane potential measurement in voltage-clamped cardiomyocytes

Guinea pig ventricular myocytes were voltage-clamped and dialysed using two glass patch pipettes (P1, P2) with tip openings of around 2 microns. A substantial improvement in the efficacy of dialysis from P2 was achieved by the application of positive pressure (15-30 cm H2O) to P2, and similar negative pressure to P1. Evidence of enhanced dialysis was obtained by measuring the effect on Ca channel current of P2 dialysates containing Ca, cAMP, GTP [gamma-S], trypsin, or the catalytic subunit of protein kinase A. Times to maximum response were 3-5 times shorter than those calculated or observed by others using a single-pipette method. The speeding-up was verified in comparative experiments with 100 microM GTP [gamma-S] dialysates; maximum stimulation of ICa occurred after 1.3-1.8 min with the dual-pipette method, versus 8.2 min with a single pipette. Other advantages of the dual-pipette method include the option of following a control dialysis from P1 with a test dialysis from P2, and the measurement of actual membrane potential. The disadvantages are that the rate of success is lower than with single-pipette experiments, and that smaller cardiomyocytes are difficult subjects.

An electrophysiological investigation of the characteristics and function of GABAA receptors on bovine adrenomedullary chromaffin cells

The characteristics and function of gamma-aminobutyric acidA (GABAA) receptors expressed on bovine chromaffin cells in culture have been investigated using patch-clamp techniques. In voltage-clamped whole-cells, locally applied GABA (100 microM) evoked a transmembrane chloride current which demonstrated outward rectification. The amplitude of such currents was reversibly suppressed by the GABAA receptor antagonists bicuculline, picrotoxin and RU5135, and enhanced by the general anaesthetic propanidid. Glycine (100 microM) and baclofen (100 microM) were ineffective as agonists. In support of a physiological role for GABA in the adrenal medulla, the co-existence of GABAA and nicotinic acetylcholine (ACh) receptors was demonstrated on whole cells and outside-out membrane patches. Ionophoretically applied GABA reduced the amplitude of depolarization and action potential discharge occurring in response to locally applied ACh (100 microM), but had no effect upon the underlying ACh-induced current. In addition, an excitatory action of GABA was demonstrated by recording action potential waveforms in cell-attached patches. The results are discussed in the context of a GABA-ergic regulation of catecholamine secretion.

Constant current source for iontophoresis

A simple, battery-powered current source is described that is suitable for the iontophoresis of axonal tracing substances, such as Phaseolus vulgaris leucoagglutinin. Unlike the previous designs that form the basis of most commonly used iontophoretic devices, this circuit does not use operational amplifiers to provide controlled current. Instead, a pair of bipolar transistors that can be selected to provide a compliance of many hundreds of volts form the regulating circuitry.

The properties of 5-HT3 receptors in clonal cell lines studied by patch-clamp techniques

1 The characteristics of transmembrane currents evoked by 5-hydroxytryptamine (5-HT) in the neuroblastoma x Chinese hamster brain cell line NCB-20 and neuroblastoma clonal cell line N1E-115 have been studied under voltage-clamp conditions by the whole-cell recording and outside-out membrane patch modes of the patch-clamp technique. 2 In 73% of NCB-20 cells examined (n = 221), and all N1E-115 cells studied (n = 80), 5-HT (10 microM) elicited a transient inward current at negative holding potentials, this being associated with an increase in membrane conductance. In both cell lines responses to 5-HT reversed in sign at a potential of approximately -2 mV and demonstrated inward rectification. 3 The reversal potential of 5-HT-induced currents (E5-HT) recorded from either NCB-20 or N1E-115 cells was unaffected by total replacement of internal K+ by Cs+. In N1E-115 cells, reducing internal K+ concentration from 140 to 20 mM produced a positive shift in E5-HT of approximately 28 mV, whereas reducing external Na+ from 143 to 20 mM was associated with a negative shift in E5-HT of about 37 mV. A large reduction in internal Cl- concentration (from 144 to 6 mM) had little effect on E5-HT. 4 5-HT-induced currents of NCB-20 cells were unaffected by methysergide (1 microM) or ketanserin (1 microM), but were reversibly antagonized by GR38032F (0.1-1.0 nM) with an IC50 of 0.25 nM. GR 38032F (0.3 nM) reduced 5-HT-induced currents in N1E-115 cells to approximately 26% of their control value. 5 On outside-out membrane patches excised from both NCB-20 and N1E-115 cells, 5-HT induced small inward currents which could not be clearly resolved into discrete single channel events. Such responses were: (i) reversibly antagonized by GR 38032F (1 nM) (ii) reversed in sign at 0 mV, and (iii) subject to desensitization. 6 Fluctuation analysis of inward currents evoked by 5-HT (1 microM) in N1E-115 cells suggests that 5-HT gates a channel with a conductance of approximately 310fS. Such a relatively small conductance could readily explain why the response of outside-out membrane patches to 5-HT cannot at present be resolved into clear single channel events.

The mechanism of action and pharmacological specificity of the anticonvulsant NMDA antagonist MK-801: a voltage clamp study on neuronal cells in culture

1. Some possible molecular mechanisms of action of the anxiolytic, anticonvulsant and neuroprotective agent MK-801 have been examined in 'whole-cell' voltage clamp recordings performed on rat hippocampal and cortical neurones, bovine adrenomedullary chromaffin cells and N1E-115 neuroblastoma cells maintained in cell culture. 2. Transmembrane currents recorded from rat hippocampal and cortical neurones in response to locally applied N-methyl-D-aspartate (NMDA) were antagonized by MK-801 (0.1-3.0 microM). Blockade was use-dependent, and little influenced by transmembrane potential. MK-801 (3 microM) had no effect on currents evoked by kainate (100 microM). 3. The antagonism of NMDA-induced currents by MK-801 was only slowly and incompletely reversed when the cell membrane potential was clamped at -60 mV during washout. Prolonged applications of NMDA at +40, but not -60 mV during washout, markedly accelerated recovery from block. 4. In contrast to MK-801, ketamine (10 microM) blocked NMDA-induced currents in a voltage-dependent manner. Blockade increased with membrane hyperpolarization and was completely reversible upon washout. 5. MK-801 (1-10 microM) produced a voltage- and concentration-dependent block of membrane currents elicited by ionophoretically applied acetylcholine (ACh) recorded from bovine chromaffin cells. The block was readily reversible upon washout. 6. gamma-Aminobutyric acidA (GABAA) receptor-mediated chloride currents of chromaffin cells were unaffected by MK-801 (1-100 microM). In contrast, such currents were potentiated by diazepam (1 microM). MK-801 (100 microM) had no effect on currents evoked by GABA on hippocampal neurones. 7. MK-801 (10 microM) had little effect on membrane currents recorded from N1E-115 neuroblastoma cells in response to ionophoretically applied 5-hydroxytryptamine (5-HT). Such currents were antagonized by the 5-HT3 receptor antagonist GR 38032F (1 nM) and also by MK-801 at high concentration (100 microM). 8. Voltage-activated, tetrodotoxin-sensitive, sodium currents of chromaffin cells were unaffected by 10 microM MK-801. However, at a relatively high concentration (100 microM), MK-801 reduced the amplitude of such currents to approximately 77% of control. 9. The relevance of the present results to the central actions of MK-801 is discussed.

Electrophysiology of neuromuscular transmission in guinea-pig mesenteric veins

1. Neuromuscular transmission in the smooth muscle of mesenteric veins has been investigated by recording intracellular potential changes resulting from stimulation of the sympathetic nerves and comparing these potential changes with responses obtained by ionophoresis of noradrenaline. 2. Neural stimulation or exogenous noradrenaline acted similarly to cause two excitatory depolarizations, a slow response reported previously (Suzuki, 1981) and a separate fast depolarization. 3. The fast depolarization was distinct from the slow depolarizing response in that it had a different dependence on the level of stimulation, was readily desensitized and was more suppressed in low-chloride solution. 4. The fast but not the slow depolarization shared certain characteristics with constriction. The fast depolarization and constriction both increased with the intensity of stimulation; inactivation in both was dependent on the recovery interval between trains of stimuli and both were suppressed to a similar degree by antagonists to alpha-adrenoceptors. The fast depolarization was, however, not a prerequisite for constriction to occur. 5. The fast and slow depolarizations were activated after a long latency which had a high temperature coefficient consistent with the postulate that these responses are rate limited by intracellular biochemical reactions. 6. The fast depolarization was preferentially suppressed by prazosin, an antagonist to the alpha 1-adrenoceptor subtype. Suppression of the slow depolarization required relatively higher concentrations of antagonist, indicating that these responses were mediated by receptor interactions involving a different alpha-adrenoceptor subtype. 7. It is concluded that neuromuscular transmission in mesenteric veins occurs through activation of alpha-adrenoceptors. A number of responses result, including voltage-independent constriction and two distinct excitatory depolarizations which can lead to voltage-dependent constriction.

Action potentials in epithelial taste receptor cells induced by mucosal calcium

Chemosensory cells in the taste bud of the tongue of Necturus generate action potentials in response to electrical stimulation through a microelectrode, as recently described by Roper (Science, 220: 1311-1312, 1983). We report that the epithelial receptor cells also respond to 10 mM CaCl2, applied to the mucosal surface, with a depolarization which elicits action potentials when a threshold of -50 mV is reached. Since CaCl2 is one of the taste stimuli in amphibia, the firing of action potentials by chemoreceptor cells may be part of the signal chain in gustatory reception of Ca ions.

A comparison between mechanisms of action of different nicotinic blocking agents on rat submandibular ganglia

The blocking properties of tubocurarine, decamethonium, hexamethonium and trimetaphan on nicotinic agonists applied by repetitive ionophoretic pulses were examined in rat submandibular ganglion cells using a two-microelectrode voltage-clamp technique at 30 degrees C. Hexamethonium, a proposed slowly dissociating, open-channel blocker at concentrations of 2-20 microM did not produce a 'use-dependent' run-down of responses, but its antagonism was clearly dependent on membrane potential. The voltage-dependent reduction of agonist response by hexamethonium was not dependent on the nature of agonist used. Similar results were obtained with acetylcholine (ACh) and carbamylcholine (CCh) ionophoresis. (+)-Tubocurarine (5 microM) and decamethonium (10 microM) produced 'use-dependent' run-down of agonist responses which became more pronounced at higher frequency and as the cell was hyperpolarized, consistent with open-channel blockade. In contrast, trimetaphan (2.5 microM), a receptor antagonist did not cause 'use-dependent' run-down of responses. Hence, the antagonism produced by hexamethonium, unlike tubocurarine and decamethonium, could not be accounted for in terms of open-channel blockade but requires an alternative mechanism, the nature of which is discussed.

Cholinergic suppression: a postsynaptic mechanism of long-term associative learning

Food avoidance learning in the mollusc Pleurobranchaea entails reduction in the responsiveness of key brain interneurons in the feeding neural circuitry, the paracerebral feeding command interneurons (PCNs), to the neurotransmitter acetylcholine (AcCho). Food stimuli applied to the oral veil of an untrained animal depolarize the PCNs and induce the feeding motor program (FMP). Atropine (a muscarinic cholinergic antagonist) reversibly blocks the food-induced depolarization of the PCNs, implicating AcCho as the neurotransmitter mediating food detection. AcCho applied directly to PCN somata depolarizes them, indicating that the PCN soma membrane contains AcCho receptors and induces the FMP in the isolated central nervous system preparation. The AcCho response of the PCNs is mediated by muscarinic-like receptors, since comparable depolarization is induced by muscarinic agonists (acetyl-beta-methylcholine, oxotremorine, pilocarpine), but not nicotine, and blocked by muscarinic antagonists (atropine, trifluoperazine). The nicotinic antagonist hexamethonium, however, blocked the AcCho response in four of six cases. When specimens are trained to suppress feeding behavior using a conventional food-avoidance learning paradigm (conditionally paired food and shock), AcCho applied to PCNs in the same concentration as in untrained animals causes little or no depolarization and does not initiate the FMP. Increasing the concentration of AcCho 10-100 times, however, induces weak PCN depolarization in trained specimens, indicating that learning diminishes but does not fully abolish AcCho responsiveness of the PCNs. This study proposes a cellular mechanism of long-term associative learning--namely, postsynaptic modulation of neurotransmitter responsiveness in central neurons that could apply also to mammalian species.

Preparation of a toxic derivative of sea anemone toxin II from Anemonia sulcata which has peroxidase activity

Sea anemone toxin II (ATX II) is a useful tool for investigation of sodium channels in excitable membranes. Coupling of ATX II with microperoxidase, a heme-octapeptide, is described. The isolated cross-linked product possesses both toxic and peroxidase activity. The lowest concentration of the modified toxin that affects the action potential and the membrane currents in single cardiac myocytes is 16 nM. The enzymatically active ATX II derivative may be useful for biochemical applications and as a non-radioactive tracer for electron microscopy studies of excitable tissue.

Action potentials and net membrane currents of isolated smooth muscle cells (urinary bladder of the guinea-pig)

Cells were isolated by incubating chunks of tissue from the urinary bladder of the guinea-pig in a high potassium, low chloride medium containing 0.2 mM calcium plus the enzymes collagenase and pronase. After isolation, the cells were superfused with a physiological salt solution (PSS) containing 150 mM NaCl, 3.6 mM CaCl2 and 5.4 mM KCl (35 degrees C). Patch electrodes filled with an isotonic KCl-solution were used for whole cell recordings. With a single electrode voltage clamp we measured a capacitance of 50 +/- 5 pF per cell, an input resistance of 200 +/- 25 kOhm X cm2 and a series resistance of 44 +/- 4 Ohm X cm2. The cells had resting potentials of -52 +/- 2 mV. They did not beat spontaneously but responded to stimuli with single action potentials (APs) which rose from the threshold (-38 mV) with a maximal rate of 6.5 +/- 1.8 V/s to an overshoot of 22 +/- 3 mV. The AP lasted for 36 +/- 4 ms (measured between threshold and -40 mV). Continuous cathodal current produced repetitive activity, a pacemaker depolarization followed the AP and preceded the next upstroke. Net membrane currents evoked by clamp steps to positive potentials were composed of an inward and an outward component. The inward component generating the upstroke of the AP was carried by Ca ions (iCa, Klöckner and Isenberg 1985). The repolarization resulted from a potassium outward current iK. Ca-channel blockers (5 mM NiCl2) reduced iK suggesting that (part of) iK was Ca-activated. iK rose within about 100 ms to a peak of 40-200 muA/cm2 from which it inactivated slowly and incompletely. The inactivating iK followed a bell-shaped voltage-dependence, the noninactivating iK an outwardly rectifying one. Both parts had similar steady state inactivation curves with a half maximal inactivation potential at -36 mV and a slope of 9 mV. Repolarization to -50 mV induced outward tail currents which reversed polarity at -85 mV (the calculated potassium equilibrium potential). The amplitude and the time course of the envelope of the tail currents varied in proportion to iK during the prestep. Thus, the tail current is suggested to reflect the turning off of a potassium conductance which had been activated during the prepulse. iK was largely reduced but not blocked by 20 or 150 mM tetraethylammonium (TEA). TEA did not significantly change the resting potential, but it prolonged the AP and facilitated upstroke and overshoot.(ABSTRACT TRUNCATED AT 400 WORDS)

On the neurotrophic control of acetylcholine receptors at frog end-plates reinnervated by the vagus nerve

To test whether the properties of subsynaptic acetylcholine (ACh) receptors in skeletal muscle fibre are influenced by the type of the innervating neurone some pharmacological properties of ACh receptor in normal end-plates and in denervated end-plates reinnervated by the vagus nerve in the frog were compared. Blockade of nerve-evoked synaptic currents by 200 microM-hexamethonium was stronger at vagus-reinnervated than at normal end-plates. Blockade at both types of junctions was voltage dependent. The effect of hexamethonium on equilibrium currents induced by bath-applied ACh and carbamylcholine was similar at the two types of junctions. At both normal and vagus-reinnervated junctions, decamethonium had similar partial agonist properties. Following a step in membrane potential, the relaxations of ACh-induced conductance changes at the two types of junctions were affected in a similar fashion by hexamethonium: hyperpolarization first produced a fast decrease and then a slow exponential increase in conductance. Upon depolarization, a fast increase was followed by an exponential decline to its original level. The time constant of the slow relaxation was slightly prolonged compared to control. These findings are consistent with a fast blocking action of open channels by hexamethonium. The effectiveness of hexamethonium in blocking end-plate currents was reduced in the presence of (+)-tubocurarine, indicating that hexamethonium has a competitive blocking action on the receptors. These results do not indicate that the pharmacological properties of the ACh receptors are changed after an end-plate is reinnervated by a preganglionic neurone. The differential effect of hexamethonium on transmission at normal and vagus-reinnervated end-plates is discussed as a consequence of different transmitter release characteristics at the two types of junctions.

Chemotactic signaling in filamentous cells of Escherichia coli

Video techniques were used to record chemotactic responses of filamentous cells of Escherichia coli stimulated iontophoretically with aspartate. Long, nonseptate cells were produced from polyhook strains either by introducing a cell division mutation or by growth in the presence of cephalexin. Markers indicating rotation of flagellar motors were attached with anti-hook antibodies. Aspartate was applied by iontophoretic ejection from a micropipette, and the effects on the direction of rotation of the markers were measured. Motors near the pipette responded, whereas those sufficiently far away did not, even when the pipette was near the cell surface. The response of a given motor decreased as the pipette was moved away, but it did so less steeply when the pipette remained near the cell surface than when it was moved out into the external medium. This shows that there is an internal signal, but its range is short, only a few micrometers. These experiments rule out signaling by changes in membrane potential, by simple release or binding of a small molecule, or by diffusion of the receptor-attractant complex. A likely candidate for the signal is a protein or ligand that is activated by the receptor and inactivated as it diffuses through the cytoplasm. The range of the signal was found to be substantially longer in a cheZ mutant, suggesting that the product of the cheZ gene contributes to this inactivation.

The effects of the Anemonia sulcata toxin (ATX II) on membrane currents of isolated mammalian myocytes

The effects of Anemonia sulcata toxin (ATX II) on action potentials and membrane currents were studied in single myocytes isolated from guinea-pig or bovine ventricles. Addition of ATX II (2-20 nM) prolonged the action potential duration without a significant change in resting membrane potential. Concentrations of 40 nM-ATX II or more induced after-depolarizations and triggered automaticity. The effects were reversible after washing or upon addition of 60 microM-tetrodotoxin (TTX). 5 mM-Ni did not modify the effects. The single patch-electrode voltage-clamp technique of Hamill, Marty, Neher, Sakmann & Sigworth (1981) was applied to record membrane currents in response to 8.4 S long depolarizations starting from a holding potential of -90 mV. Currents flowing later than 5 ms after the depolarizing step were analysed. The fast events could not be considered because of insufficient voltage homogeneity. After 2 min of exposure to ATX II (20 nM) the changes in net membrane currents were measured. The difference between the currents in the presence of ATX II and during control was defined as the 'ATX-II-induced current' (iATX). After 4 min of wash iATX disappeared. Within 10 S of exposure to 60 microM-TTX, iATX was blocked completely. At potentials positive to -60 mV, iATX was inwardly directed and decayed slowly but incompletely during the 8.4 S long depolarizing pulse. The rate of decay was faster during clamp pulses to more positive potentials. A high amplitude noise was superimposed on the current trace; its amplitude decreased with more positive potentials. We analysed the voltage dependence of iATX with 'isochronous' current-voltage relations. The 0.1 S isochrone of iATX was characterized by a 'threshold' for negative currents at -60 mV, a branch with a negative slope (k = -7 mV, potential of half-maximal activation (V0.5) = -38 mV, bovine cells) leading to a maximum inward current at -20 mV, and an ascending branch which led to an apparent reversal potential (Erev) around +40 mV. The values measured in guinea-pig myocytes were similar though not identical (k = -5.5 mV, V0.5 = -30 mV, maximum of inward current at -5 mV, Erev = +50 mV). Erev shifted to less positive potentials in later isochrones. Holding the membrane at -45 mV prevented the induction of extra current by ATX II. When the holding potential was then changed to -85 mV, iATX developed within some 2 min. Returning the holding potential to -45 mV blocked iATX with a similar slow time course.(ABSTRACT TRUNCATED AT 400 WORDS)

The effect of calcium ions on the glutamate response and its desensitization in crayfish muscle fibres

The responses of crayfish muscle fibres to bath application or long ionophoresis of L-glutamate were studied in normal and low Ca2+ solutions. The smaller responses recorded in low Ca2+ solutions have characteristics suggesting a faster desensitization. Desensitization and recovery have complex kinetics. Desensitization is faster and recovery slower when external Ca2+ concentration is reduced. Both components of the recovery phase, which can be fitted by the sum of two exponentials, are affected by the external Ca2+ concentration. Recovery can be accelerated by external Ca2+ ionophoresis onto desensitized glutamate receptors. Responses to brief glutamate pulses of low intensity are not affected by Ca2+ reduction. For higher intensities, signs of desensitization are detectable early in the rising phase of the response. Concanavalin A (Con A) blocks both desensitization and Ca2+ dependence with similar time courses. Whether or not the preparation has been treated with Con A, the slowly rising responses recorded in isotonic Ca2+ do not show signs of desensitization. Con A causes a partial blockade of the glutamate response. The Ca2+ dependence of the glutamate response can be explained by the Ca2+ dependence of the desensitization process, the cation acting at ectocellular sites of the muscle membrane.

Ionic basis for the antagonism between adenosine and isoproterenol on isolated mammalian ventricular myocytes

We studied the effects of adenosine and isoproterenol on membrane currents of isolated bovine and guinea pig ventricular myocytes with a two-microelectrode voltage clamp technique. Adenosine (50 microM to 0.2 mM) alone had no effect on any of the membrane currents measured, but it antagonized the effects induced by 10 nM isoproterenol. Peak calcium membrane current was augmented by isoproterenol from a control of 4.8 +/- 0.6 to 8.6 +/- 0.8 nA and adenosine reduced it to 5.7 +/- 0.7 nA (mean +/- SEM of six cells). The inactivation time constant was not altered by isoproterenol alone or isoproterenol plus adenosine, and neither was the voltage dependence of peak calcium membrane current. Thus, the changes caused by isoproterenol could be described as an increase in maximal calcium conductance from 0.86 +/- 0.7 to 1.55 +/- 0.04 mS/cm2 and partially antagonized by adenosine to 0.97 +/- 0.04 mS/cm2. Isoproterenol also increased the non-inactivating component of calcium membrane current from 17 +/- 1 to 24 +/- 4%, and adenosine reduced it to 18 +/- 2% (n = 4). The steady state activation and inactivation variables remained unchanged. Consistent with these effects on calcium membrane current, adenosine completely antagonized the isoproterenol-induced increase of the slow action potentials obtained in sodium-free medium. Isoproterenol increased the steady state outward currents at potentials between -90 and -30 mV (i.e., probable iK1). Adenosine alone had no effect on potassium membrane current, but it antagonized the effects of isoproterenol. Slow action potentials in 25 mM potassium were enhanced by isoproterenol, but were only moderately attenuated by adenosine. Accordingly, in 25 mM potassium the isoproterenol-induced changes in membrane currents were not antagonized by adenosine. This lack of inhibition by adenosine of the isoproterenol effects in 25 mM potassium could not be mimicked by 1-minute-long conditioning prepulses to -45 mV. The results indicate that adenosine by itself (absence of isoproterenol) has no effect on maximal calcium conductance, that the isoproterenol-induced increase in cyclic adenosine 3',5'-monophosphate, which leads to an increase in maximal calcium conductance, is antagonized by adenosine, and that such action can account for the ability of adenosine to attenuate the stimulatory effects of isoproterenol.

The channel-blocking action of methonium compounds on rat submandibular ganglion cells

The effects of drugs of the polymethylene bis-trimethylammonium (methonium) series on the characteristics of the synaptic currents (e.s.cs) recorded from voltage-clamped rat submandibular ganglion cells have been studied. The drugs studied were from C4 to C10 (decamethonium). All of the drugs except C4 shortened the initial decay phase of the e.s.c.; C9 and C10 produced an additional slowly decaying component. These effects were interpreted in terms of an open channel block mechanism, the calculated rate constants for association with the open channel at -80 mV being fairly similar (5.9 X 10(6) to 18.1 X 10(6)M-1S-1) for all of the compounds except C4, which had no effect on the e.s.c. decay. All of the compounds produced use-dependent block when tested with short trains of stimuli at 10 Hz, or with trains of ionophoretic pulses of acetylcholine, consistent with their channel blocking property. Tubocurarine had a similar effect, but not trimetaphan or mecamylamine. Recovery from use-dependent block with short chain methonium compounds, up to C8, was very slow in the absence of agonist, being incomplete even after several minutes. With C9 or C10 or tubocurarine, recovery from use-dependent block was complete within a few seconds. With C6 recovery in the absence of agonist was unaffected by membrane potential, but could be accelerated by applying acetylcholine with the cell depolarized to -40 mV. This persistent block was ascribed to the ability of the blocking molecule to become trapped by closure of the channel. With C9 and C10 it is assumed that their presence inhibits channel closure, so they can escape without the help of agonist. When use-dependent block is avoided by leaving the ganglion unstimulated during equilibration with the blocking drug, the first e.s.c. elicited shows no appreciable reduction of amplitude, though with C6, C7 or C8 subsequent responses elicited at 0.1 Hz become progressively more blocked. Even at 1 mM, C6 does not prevent acetylcholine from opening ionic channels. It is concluded that all of the effects on e.s.c. amplitude can be interpreted in terms of channel block, there being no evidence of any receptor blocking action.

Freeze-fracture and electrophysiological studies of newly developed acetylcholine receptors in Xenopus embryonic muscle cells

The development of acetylcholine receptors on Xenopus embryonic muscle cells both in culture and in situ was studied using electrophysiology and freeze-fracture electron microscopy. Acetylcholine sensitivity first appeared at developmental stage 20 and gradually increased up to about stage 31. Freeze-fracture of muscle cells that were nonsensitive to acetylcholine revealed diffusely distributed small P-face intramembraneous particles. When cells acquired sensitivity to acetylcholine, a different group of diffusely distributed large P-face particles began to appear. This group of particles was analyzed by subtracting the size distribution found on nonsensitive cells from that found on sensitive cells. We call this group of particles difference particles. The sizes of difference particles were large (peak diameter 11 nm). The density of difference particles gradually increased with development. The density of small particles (less than 9 nm) did not change with development. At later stages (32-36) aggregates of large particles appeared, which probably represent acetylcholine receptor clusters. The size distribution of difference particles was close to that of the aggregated particles, suggesting that at least part of difference particles represent diffusely distributed acetylcholine receptors. Difference particles exist mostly in solitary form (occasionally double), indicating that an acetylcholine receptor can be functional in solitary form. This result also shows that diffuse acetylcholine receptors that have previously been observed with 125I-alpha-bungarotoxin autoradiography do indeed exist in solitary forms not as microaggregates.

The effects of alcohols and diols at the nicotinic acetylcholine receptor of the neuromuscular junction

A series of straight chain aliphatic alcohols from ethanol to octanol were tested at voltage-clamped frog endplates. In the presence of high concentrations of ethanol (greater than 1 M) the individual current responses to ionophoretic pulses of ethanol were reduced in amplitude and the dose-response curve for acetylcholine was shifted to the right. All the alcohols tested had this effect and their potency increased with the length of the carbon chain. The results were interpreted to indicate that as the molecular weight of the alcohol increased, its potency as a channel blocker also increased. The diol derivative of ethanol, which is ethylene glycol (ethanediol), was totally inactive up to 400 mM. However, 1,3-propanediol was a more potent blocker than propanol. After dose-response curves were carried out in high doses of ethanol and propanediol, the number of receptors was found to be permanently reduced. This effect could be due to irreversible denaturation of the receptor and therefore reversible denaturation could account for some of the reversible blocking effects caused by such drugs. An additional effect on the receptor was observed in that low concentrations of ethanol and propanol reduced the apparent dissociation constant for acetylcholine, thus increasing the amplitude of individual responses and shifting the dose-response curve to the left.

The interaction between hexamethonium and tubocurarine on the rat neuromuscular junction

The ability of hexamethonium (C6) to reverse the neuromuscular blocking action of tubocurarine (Tc) has been reinvestigated at the voltage clamped endplate of the omohyoid muscle of rat. The possibility that a weak anticholinesterase action of C6 could contribute to the paradoxical potentiation of the peak amplitude of the endplate response has been examined. C6 (50-200 microM) caused an increase in the amplitude of nerve-evoked endplate currents (e.p.cs) recorded in the presence of 0.6 microM Tc. The effect decreased with hyperpolarization of the muscle fibre. Irreversible inhibition of acetylcholinesterase resulted in a loss of the anti-curare effect of C6. C6 did not cause an increase in e.p.c. amplitude when acetylcholine (ACh) receptors were blocked irreversibly by alpha-bungaratoxin. When transmission was blocked by increased Mg2+ concentration, C6 (50-400 microM) reduced the amplitude of e.p.cs without appreciably affecting their time course. C6 caused a decrease in the amplitude of miniature endplate currents (m.e.p.cs) the effect being slightly increased when the fibre was hyperpolarized. An e-fold increase in the effectiveness of C6 occurred with approximately 58 mV hyperpolarization. High concentrations (greater than 400 microM) affected the time course of m.e.p.cs in a manner suggestive of open channel block, but this was not evident at 200 microM, the concentration that was most effective in reversing Tc block. When tested against responses to short ionophoretic pulses of agonists, C6 was less effective against ACh (EC50ca. 300 microM) than against carbachol (CCh) (EC50 100 microM). When cholinesterase was irreversibly inhibited, C6 blocked responses to both agonists equally (EC50ca. 100 microM). The effectiveness of C6 in blocking the action of CCh was reduced 10 fold in the presence of 0.6 microM Tc, implying that the two antagonists compete for the same binding site. C6 (50-200 microM) in the presence of Tc (0.6 microM) increased the response to ionophoretically applied ACh but not that to CCh. C6 was equipotent in blocking m.e.p.cs and responses to ionophoretically applied ACh whereas Tc was more potent against the exogenously applied agonist. C6 was a weak inhibitor of acetylcholinesterase activity in rat muscle homogenates (EC50 1.5 mM). The results are discussed in terms of the kinetic hypothesis advanced by Ginsborg & Stephenson (1974) to account for the Tc reversal phenomenon. It is concluded that this theory can explain most of the effect on e.p.cs, but that the weak anticholinesterase action of C6 is also a factor, particularly in the reversal of Tc block of ionophoretic responses.

Linear electrical properties of isolated cardiac cells

A frequency domain equivalent circuit analysis of isolated ventricular cells indicated the presence of an internal membrane structure which has a total capacitance four- to sixfold larger than the surface membrane. The internal membrane was mainly attributed to the sarcoplasmic reticulum since other morphological studies have shown that its area is many-fold larger than that of the surface membrane. Corresponding estimates from the transverse tubular system indicate an area less than that of the surface; thus this structure is not a likely candidate for the observed internal capacitance. Measurements in hypertonic solutions showed that the access resistance to the internal membrane reversibly increased as the tonicity was elevated. Freeze-fractured electron microscopic studies confirmed that hypertonic solutions increased the volume of transverse tubular system, which thus appears to have little relation to the access resistance. The most probable source of the access resistance is the diadic junction to the sarcoplasmic reticulum, which therefore would electrically couple it to the surface membrane.

The effect of cyanide on the K-current in guinea-pig ventricular myocytes

The mechanism of the shortening of the cardiac action potential by cyanide was studied in guinea-pig ventricular myocytes using a two micro-electrode voltage clamp technique. It is shown that the shortening can be counteracted by glucose and is due to a marked increase in K conductance.

Effects of the sea anemone Anemonia sulcata toxin II on skeletal muscle and on neuromuscular transmission

Effects of anemone toxin II (ATX II) have been analysed on the neuromuscular junction of the frog and different twitch muscles. Amplitudes of evoked endplate potentials and endplate currents are increased by ATX II, without effects on the amplitudes of miniature endplate potentials and endplate currents resulting from ionophoretically applied transmitter. The increase in evoked transmitter release is due to an increase in quantal content caused by an effect of the toxin on the presynaptic action potentials. ATX II is also effective on muscle fibers. The action potentials of frog twitch muscles are reversibly prolonged by ATX II. Their rate of rise and amplitudes are increased, while there is no effect on resting membrane potential. Similarly, action potentials of fast twitch muscle (extensor digitorum longus, EDL) of the mouse are reversibly prolonged by ATX II. In slow twitch muscle (soleus, SOL) of the mouse the toxin induces repetitive action potentials following the generation of a single action potential. Tetrodotoxin resistant action potentials of both denervated EDL and SOL are greatly and irreversibly prolonged by ATX II. The effects on muscle are due to a Na+ channel specific action of ATX II. Na+ current inactivation is slowed with the time constant tau h increasing towards positive membrane potentials. The steady state inactivation curve hoo was shifted to more positive potentials and its slope reduced.

Effects of fast and slowly acting antagonists on the time course of the muscarinic response in guinea-pig atrial muscle

In sino-atrial and atrial preparations of the guinea-pig heart the effects of slowly and rapidly reversible antagonists on the time course of the acetylcholine or carbachol-evoked hyperpolarization (muscarinic response) were studied using double-barreled micropipettes for ionophoretic drug application. The muscarinic response can be inhibited not only if an antagonist is applied before or simultaneously with the agonist but also during its late decay phase. Local ionophoretic application of a slowly reversible (atropine-like) antagonist results in a prolongation of time-to-peak of a subsequently evoked muscarinic response, whereas bath application of this type of antagonists only results in an inhibition without affecting the time course. It is concluded that the remaining response after ionophoretic ejection of a small amount of this type of antagonists is due to activation of more distant receptor populations, which give a slower contribution to the integral response than receptors close to the source of release. Both, local and bath application of rapidly reversible antagonists (TEA, Pentyl-TEA) causes a faster time course of the muscarinic response. This can be explained by the apparent equilibrium constant of the agonist receptor complex to be increased in the presence of a true competitive antagonist. Under this condition proximal receptors, which should respond faster are less inhibited than distant ones. The results strongly suggest that the duration of the muscarinic response in the heart is governed by diffusion of agonist molecules on the surface or inside the cardiac muscle.

Interaction with membrane remnants of target myotubes maintains transmitter sensitivity of cultured neurons

Parasympathetic neurons, when cultured alone, lose sensitivity to acetylcholine, but if striated muscle is included in the culture, neuronal chemosensitivity is maintained. The membrane remnants of myotubes ruptured by osmotic shock also supported the responsiveness of the cultured neurons to transmitter, whereas muscle-conditioned medium or membrane remnants of nonmuscle embryonic skin cells did not support this responsiveness. The regulation of chemosensitivity by contact of neurons with the target cell membrane may be important in the formation and maintenance of neuronal circuitry.

Membrane potential responses to ionophoretically applied alpha-adrenoceptor agonists in the mouse anococcygeus muscle

1 Noradrenaline phenylephrine, naphazoline and oxymetazoline were applied by ionophoresis to the mouse anococcygeus muscle and the membrane potential was recorded with an intracellular microelectrode. 2 The ionophoretic application of noradrenaline and phenylephrine produced dose-related depolarizations in 96% of the cells tested; in contrast, naphazoline and oxymetazoline depolarized only 62% of the cells although contraction was always seen. 3 The depolarizations produced by all four drugs had similar characteristics in shape and time course except that the latency of responses induced by the imidazoline-related drugs was significantly longer than the value obtained with the phenylethanolamines. This discrepancy was not due to the difference in susceptibility to neuronal uptake of the two groups of drugs. 4 The time to peak depolarization for naphazoline and oxymetazoline was longer than that for noradrenaline and phenylephrine but was not sufficient to account for the considerably slower contraction produced by the former drugs. 5 At room temperature the sensitivity of the mouse anococcygeus to ionophoretically applied naphazoline and oxymetazoline was significantly lower than that to noradrenaline and phenylephrine but at 35 degrees C the sensitivity was similar for all drugs. 6 These results suggest that there might be two subclasses of alpha 1-adrenoceptor in the mouse anococcygeus; stimulation of one type leads to depolarization and contraction and activation of the other class produces contraction with no change in membrane potential.

Impulse responses in bacterial chemotaxis

The chemotactic behavior of Escherichia coli has been studied by exposing cells tethered by a single flagellum to pulses of chemicals delivered iontophoretically. Normally, wild-type cells spin alternately clockwise and counterclockwise, changing their direction on the average approximately once per second. When cells were exposed to a very brief diffusive wave of attractant, the probability of spinning counterclockwise quickly peaked, then fell below the prestimulus value, returning to baseline within a few seconds; repellent responses were similar but inverted. The width of the response indicates that cells integrate sensory inputs over a period of seconds, while the biphasic character implies that they also take time derivatives of these inputs. The sensory system is maximally tuned to concentration changes that occur over a span of approximately 2 sec, an interval over which changes normally occur when cells swim in spatial gradients; it is optimized to extract information from signals subject to statistical fluctuation. Impulse responses of cells defective in methylation were similar to those of wild-type cells, but did not fall as far below the baseline, indicating a partial defect in adaptation. Impulse responses of cheZ mutants were aberrant, indicating a serious defect in excitation.

Enhanced chemosensitivity of chick parasympathetic neurones in co-culture with myotubes

1. The influence of target interaction upon the electrophysiological properties of dissociated ciliary ganglion cells was investigated by testing the sensitivity of the neuronal somal membrane to ionophoretically applied acetylcholine (ACh). Variations in the percentage of cells responsive to the transmitter were measured with time in culture. 2. Twenty-four hours after plating, all cells respond to an ionophoretic pulse of ACh with a depolarization. However, 1 week after plating (between 7 and 14 days) most of the neurones are unresponsive, and highly responsive cells (greater than 100 mV peak depolarization/nC) are extremely rare. At even later times in culture, neurones sensitive to the transmitter are again more frequent. 3. When neurones are plated onto pre-formed pectoral myotubes, however, ACh sensitivity is maintained throughout a 3 week culture period. Neuromuscular junctions are formed by the neurones, and when sufficient neurones are present, all the muscle fibres tested show evidence of functional synaptic transmission. Chemosensitivity to ACh is not maintained by neurones in muscle-free microcultures are present on the same cover-slip. 4. Interneuronal synaptic contacts, defined by ultrastructural criteria, are formed in cultures of neurones alone, but evidence of widespread functional synaptic interaction between cells was not found at 7-14 days in culture. 5. It is concluded that the maintenance of ACh sensitivity of cultured ciliary ganglion cells is enhanced by the presence of muscle in co-culture. The interneuronal synaptic contacts observed are apparently not as potent a stimulus as co-culture with muscle for the full expression of the cholinergic phenotype under these culture conditions.

The passive electrical properties of guinea-pig ventricular muscle as examined with a voltage-clamp technique

1. A voltage-clamp technique was developed for stable recording of small currents in guinea-pig ventricular muscle. Small cylindrical preparations were impaled with three micro-electrodes, one for measuring the feed-back potential and two for injecting current. 2. The longitudinal potential profile resulting from current injection at one point was measured. It agreed well with the theoretical predictions for a linear cable which is sealed at both ends ('healing over'), with a length constant (lambda) of 580 +/- 145 micron. 3. When the clamp current was injected symmetrically into each half of the preparation via two electronic current pumps a spatially homogeneous clamp could be achieved in preparations with a diameter of less than or equal to 250 micron and a length of less than or equal to 2 lambda. 4. The membrane capacity and the membrane resistance of the preparations at the resting potential were measured with small voltage-clamp pulses. Assuming a specific membrane capacity (Cm) of 1 microF/cm2 a specific membrane resistance (Rm) of 6.7 +/- 1.8 k omega cm2 was obtained in Tyrode solution containing 3 mM-K. 5. The total surface area was calculated from the measured capacity of the preparation assuming a Cm of 1 microF/cm2. The total cellular volume was estimated from optical measurement of the external dimensions of the preparation assuming an extracellular space of 25%. From these data the average surface/volume ratio of individual cells was calculated to be 7200 cm2/cm3. 6. From the measured electrical constants the specific resistance of the intracellular space (Ri) was calculated to be 200-250 omega cm. With small constant current pulses a membrane time constant of 6.6 +/- 1.3 ms was measured. 7. The influence of the extracellular potassium concentration ([K]o) on Rm was studied in the range 1.5-6 mM-[K]o. Rm was found to depend on [K]o less than predicted by the constant field theory.

Concanavalin A blocks the Ca2+ -dependence of crayfish muscle fiber responses to glutamate

(1) The response of crayfish muscle fibers to bath-applied glutamate is strongly inhibited when the Ca concentration of the physiological solution is reduced. Other divalent cations cannot substitute for Ca. The trivalent impermeant cation La can at low concentration replace Ca. Moreover, decreasing the Ca concentration in the presence of La potentiates the glutamate response. (2) The time course of responses to ionophoretically applied glutamate suggests a faster desensitization in low Ca solutions. The lectin concanavalin A, which blocks desensitization, also eliminates the decrease of the glutamate response in low Ca solutions. (3) The above results are compared to available data concerning Ca-dependence, desensitization and effects of concanavalin A.

Effects of ethidium bromide on the nicotinic acetylcholine receptor

Ethidium bromide was tested for electrophysiological effects at the postsynaptic membrane of the frog muscle endplate. At low concentrations ethidium bromide blocked the open ion channel of the nicotinic acetylcholine receptor and reduced its open time. The rates for channel blocking and unblocking were calculated giving a dissociation constant of 139 nM at -80 mV membrane potential.

Membrane potential responses of the mouse anococcygeus muscle to ionophoretically applied noradrenaline

1. Membrane potential responses to ionophoretically applied noradrenaline and to field stimulation were studied in the mouse anococcygeus muscle using intracellular recording techniques.2. The ionophoretic application of noradrenaline produced charge-dependent depolarizations whose total duration was 1-2 s at room temperature and which were characterized by a delay between the start of the ionophoretic pulse and the onset of depolarization (termed the latency of the responses). On occasion ionophoresis of noradrenaline did not depolarize the muscle even though it seemed that successful ejection of noradrenaline had occurred as small localized contractions could be seen.3. The characteristics of these depolarizations were unaffected by tetrodotoxin (10(-7) M) and could not be reproduced when the ionophoretic pipette contained 2 M-NaCl rather than noradrenaline. Moreover noradrenaline still produced depolarizations in denervated muscle and thus it is concluded that the responses were caused by noradrenaline released from the ionophoretic micropipette and not from the intrinsic noradrenergic nerves.4. Field stimulation of innervated muscle usually evoked excitatory junction potentials (e.j.p.s), but sometimes inhibitory junction potentials (i.j.p.s) or a mixture of e.j.p.s and i.j.p.s were observed. The time course of the e.j.p.s was slightly longer than that of the ionophoretic depolarizations which was accounted for by a smaller latency of the ionophoretically induced responses.5. The pharmacology of the nerve-evoked e.j.p.s and the ionophoretically induced depolarizations was similar as both types of responses were antagonized by alpha(1)-adrenoceptor blocking agents (phentolamine and prazosin) but were unaffected by the beta-adrenoceptor antagonist, propranolol. It is probable that noradrenaline released from the intrinsic nerves and that from the ionophoretic micropipette were acting on the same adrenoceptors.6. The latency and to a lesser extent the rise-time of the depolarizations produced by the ionophoretic application of noradrenaline was highly sensitive to changes in temperature of the bathing fluid (Q(10)s > 2) whereas the half-decay time was relatively insensitive to temperature changes (Q(10) approximately 1.5). In addition the latency of the depolarizations was not altered by inhibiting the noradrenaline-uptake mechanism with cocaine (2 x 10(-6) M) or by alpha-adrenoceptor blocking agents. Thus it seems likely that the latency of the responses is a property of the noradrenaline-receptor interaction rather than being caused by other phenomena such as diffusion of noradrenaline.

Advantages of the triangularis sterni muscle of the mouse for investigations of synaptic phenomena

The triangularis sterni muscle (TS) of the mouse is a thin trapezoidal sheet of fibres in which individual neuromuscular junctions are easily observed with Nomarski optics. Thus, microelectrodes are readily positioned to accurately record various synaptic phenomena. For example, miniature end-plate currents were easily recorded with a focally positioned extracellular electrode and the end-plate sensitivity to acetylcholine averaged 2062 mV/nC. In addition, the intercostal nerves segmentally innervate the TS. Electrophysiologic and histologic analysis showed that each nerve innervates a sharply defined territory of the muscle surface. These preliminary observations suggest that the TS may be ideal for studies of synaptic function and the processes underlying synapse stabilization in the mammal.

A high voltage electrometer for recording and iontophoresis with fine-tipped, high resistance microelectrodes

A high voltage electrometer is described which incorporates a controlled current source, direct current monitoring, balance bridge, electrode resistance, and capacitance compensation test circuits. This device is suitable for making biophysical measurements and iontophoresing dyes or enzymes through extremely fine micropipettes with impedances an order of magnitude higher than conventional micropipettes. Such electrodes are useful for recording from the small neurons of the central nervous system in vivo.

The characteristics of synaptic currents and responses to acetylcholine of rat submandibular ganglion cells

1. Synaptic currents and responses to acetylcholine (ACh) have been recorded at 20 degrees C from rat submandibular ganglion cells by a two micro-electrode volatage-clamp technique.2. The peak amplitude (a(p)) of excitatory synaptic currents (e.s.c.s) was linearly related to membrane potential (E(m)), with a reversal potential close to - 10 mV. E.s.c.s decayed with a bi-exponential time course, the fast phase comprising just over half the total amplitude. The time constant (tau(f)) of the fast phase was 5-9 msec, while that of the slow phase (tau(s)) was 27-45 msec. The relative amplitudes of the two components remained constant at different membrane potentials, showing that the reversal potential was the same for both.3. Both tau(f) and tau(s) increased as the cell was hyperpolarized, the ratio tau(-80)/tau(-40) being about 1.6 for both fast and slow components.4. Increasing the calcium concentration from 2.5 to 7.5 mm increased the amplitude of both components by about 40% and also prolonged the synaptic currents 30-50%, its effect being slightly greater on tau(s) than on tau(f).5. In contrast to e.s.c.s, spontaneous or potassium-evoked miniature synaptic currents (m.s.c.s) showed a simple exponential decay with a time constant (tau(m.s.c.)) very similar to tau(f). tau(m.s.c.) showed the same sensitivity to membrane potential and calcium concentration as tau(f).6. In the presence of neostigmine (10 mum) e.s.c.s were prolonged, tau(f) about 3.5-fold and tau(s) about 2.5-fold. The decay remained bi-exponential, with little change in the relative amplitude or voltage-dependence of the two components. M.s.c.s were prolonged to a lesser extent (1.5-2-fold) and the voltage dependence of tau(m.s.c.) was unaffected by neostigmine.7. Reduction of the quantal content of the e.s.c. by low calcium-high magnesium solution did not affect the time course. The relative amplitudes, and the time constants of the two components were unchanged even with a 90% reduction of a(p).8. Voltage-jump studies, in which the cell was abruptly hyperpolarized by 20-40 mV during a response to ionophoretically applied ACh, showed a relaxation pattern consisting of two distinct exponential components, whose relative amplitudes varied considerably in different cells. The two rate constants tau(f.rel) and tau(s.rel) were somewhat shorter than tau(f) and tau(s) for e.s.c.s, the difference being generally less than two-fold.9. Measurements of ACh noise also revealed two kinetic components, the time constants of which corresponded closely to tau(f) and tau(s) for e.s.c.s. On the assumption that the two components represent channels of equal conductance, the single channel conductance, gamma, was calculated to be 31+/-3 pS, similar to that of endplate channels.10. It is concluded that the two kinetic components of e.s.c.s and ACh responses probably represent two distinct classes of ACh-operated ionic channels, whose mean lifetime differs about fivefold. The two types of channel show the same ionic selectivity and their mean lifetime varies in the same way with the membrane potential. The absence of a slow component in m.s.c.s suggests that the two types of channel are spatially separate in the membrane.

Determination with high resistance micropipettes of acetylcholine sensitivity in frog slow muscle fibres

1. Acetylcholine (ACh) sensitivity was determined in slow muscle fibres of Rana temporaria by ionophoretic application of ACh from high resistance micropipettes. 2. The amplitude of ACh responses decreased with the third power of the distance between fibre surface and tip of the pipette; latency and time-to-peak of ACh responses increased with the second power of the distance. 3. ACh sensitivity values obtained by application of ACh at short distance (approx. 10 micrometers) were generally of the order of 150 mV/nC, but larger values (greater than 1000 mV/nC) pipette the ACh response was often completely lost or markedly reduced in amplitude. The latency of ACh responses was generally longer, but occasionally as short as observed in twitch fibres; time-to-peak and rate of decay were always longer than in twitch fibres. 4. It is concluded that ACh sensitive membrane areas in slow muscle fibres are generally of small diameter. There sensitivity is, however, similar to that of junctional areas in twitch muscle fibres.

Monocular activation of visual cortex in normal and monocularly deprived cats: an analysis of evoked potentials

The unilaterally induced patterns of prominent excitatory post-synaptic activity within Areas 17 and 18 were investigated in normal and monocularly deprived cats. They were elicited by electrical stimulation of the optic nerves and evaluated with the one-dimensional current source-density method. 1. In Area 18 of normal cats the unilaterally and bilaterally induced current source-density patterns closely resemble each other. None of the mono-, di- or tri-synaptic activities is potentiated by binocular convergence. 2. In Area 18 of monocularly deprived cats the synaptic currents elicited by stimulating the nerve on the deprived side lead to approximately the same spatial and temporal distribution of sinks and sources as those induced from the normal eye; but the amplitudes are considerably smaller. This reduction is similar for mono-, di- and trisynaptic responses which indicates (a) that the imbalance between activity from the deprived and non-deprived eye is mainly due to reduced input to the cortical target cells from the deprived eye and (b) that the activity from the deprived eye still relayed to these cells is passed on to supra- and infragranular layers without diminution and in the same way as activity from the normal eye. 3. The imbalance of afferent activity from the deprived and non-deprived eye is apparent in the evoked potentials recorded from the white matter. This indicates that activity from the deprived eye is already strongly reduced in the thalamo-cortical fibres. 4. In monocularly deprived, but not in normal cats the monosynaptic activities from the two eyes are often segregated in depth within layer IV. 5. In Area 17 of both normal and deprived cats only a small fraction of the potential monosynaptic activity can be elicited by electrical stimulation of the optic nerves because of transmission failure in the lateral geniculate nucleus. Comparison of the current source-density patterns elicited from the normal and deprived nerve in monocularly deprived cats indicates that activity produced by fast conducting afferents is more affected (reduced) by deprivation that that conveyed by slower afferents.