Experimental studies upon a bundle of tonic fibres in the locust extensor tibialis muscle

The bundle of tonic fibres situated at the proximal end of the locust metathoracic extensor tibialis muscle is innervated by the dorsal unpaired median neurone (DUMETi) as well as by the slow excitatory (SETi)) and common inhibitor (CI) neurones. It is not innervated by the fast excitatory neurone (FETi).These fibres contract spontaneously and rhythmically. The myogenic rhythm can be modified by neural stimulation.Spontaneous slow depolarizing potentials resembling the pacemaker potentials of insect cardiac muscle were demonstrated in these fibres.The actions of glutamate on the tonic muscle fibres are not compatible with its being a specific excitatory transmitter. Glutamate can stimulate weak contractions of the muscle, but this action is inhibited when chloride ions are removed from the saline.10^?6 M Octapamine hyperpolarizes the tonic fibre membrane. Octopamine, GABA and glutamate all inhibit the myogenic contractions and reduce the force of the neurally evoked contractions.The tonic muscle is very responsive to proctolin. At 5 × 10^?11 M proctolin enhances the force and increases the frequency of myogenic contractions. At 10^?9 M it depolarizes the muscle membrane potential, and at that and higher concentrations it causes the muscle to contract. At 2 × 10^?7 M proctolin induces contractures which resemble those evoked by sustained high-frequency neural stimulation. Iontophoretic experiments show that proctolin receptors occur at localized sites on the tonic fibre membrane.     

Activation and inhibition of the action potential Na+ ionophore of cultured rat muscle cells by neurotoxins.

Both myoblasts and myotubes in cultures of clonal rat muscle cells have action potential Na⁺ ionophore activity. The ionophore is activated by batrachotoxin (K_0.5 = 3 to 5 × 10^?7 M) and veratridine (K_0.5 = 4 to 6 × 10^?5 M) which compete for the same activation site. As in denervated rat muscle, the ionophore of cultured muscle is 100 fold more resistant to inhibition by tetrodotoxin (K_0.5 = 1.5 to 3 × 10^?6 M) and 20 fold more resistant to inhibition by saxitoxin (K_0.5 = 1.5 to 3 × 10^?7 M) than in nerve, innervated muscle, or cultured neuroblastoma cells.     

Actions of amantadine at synaptic and extrasynaptic cholinergic receptors in the central nervous system of the cockroach Periplaneta americana

The effects of amantadine were investigated on cercal afferent, giant interneurone synapses and on the cell body membrane of the fast coxal depressor motoneurone (D_f), in the cockroach Periplaneta americana. Bath-applied amantadine at concentrations above 2.0 × 10^?5 M significantly reduced the amplitude of unitary and compound epsps recorded by sucrose-gap methods from cercal afferent, giant interneurone synapses in the desheathed sixth abdominal ganglion. Complete block of synaptic transmission was achieved at 1.0 × 10^?3 M amantadine. Synaptic blockade, which was not accompanied by changes in resting potential, was almost fully reversed by washing the ganglion in normal saline. From the dose-dependence of the synaptic blocking action, a Hill coefficient of 0.94 was estimated, indicating that there is no co-operativity in the binding of amantadine to its site of action.Bath-application of amantadine (5.0 × 10^?5 M) resulted in a parallel shift to the right of the dose-response curve for the depolarizing postsynaptic actions of acetylcholine. Nevertheless, even at a concentration of 2.0 × 10^?3 M, amantadine failed to protect the synaptic acetylcholine receptor/ion channel complex from the blocking action of α-bungarotoxin (5.0 × 10^?7 M). In addition, the block by amantadine of the acetylcholine-induced current recorded from the cell body membrane of the fast coxal depressor motoneurone (D_f), was strongly dependent on membrane potential in the range ? 120mV to ? 70mV. An action of amantadine at the open acetylcholine receptor/ion channel complex is proposed.     

On the effect of the ionophore X-537A on neuromuscular transmission in the rat

In the rat phrenic nerve-diaphragm muscle preparation, X-537A at 6×10^?6 to 3×10^?5 M (1) depolarized muscle fibre membranes, (2) caused an occasional transient increase in and ultimate block of spontaneous transmitter release, (3) did not increase the amplitude of the end-plate potential (epp) but abruptly blocked stimulus-evoked transmitter release, and (4) produced an increase in the occurrence of “giant” miniature epp's (mepp's). The possibility is discussed that the sporadically raised mepp frequency was due to an ionophore-induced depolarization of nerve terminals. The increased occurrence of “giant” mepp's apparently reflected a X-537A-induced spontaneous multiquantal release of acetylcholine. This was not dependent on extracellular calcium but appeared to be of presynaptic origin.     

Inhibiton and gamma-aminobutyric acid-induced conductance on locust (Schistocerca gregaria) extensor tibiae muscle fibres

• 1.1. Increases in membrane conductance (g_m) were induced by GABA in distal bundles 32, 33 and 34 of extensor tibiae muscles of the locust (Schistocerca gregaria).
• 2.2. Bath application of GABA (10⁻⁵−5 × 10⁻³ M) induced reductions in muscle fibre space constant (λ).
• 3.3. GABA (5 × 10⁻³ M) induced additional membrane conductance of 2.21 ± 0.03 × 10⁻⁶ S/mm, 0.38 ± 0.03 × 10⁻⁶ S/mm and 0.29 ± 0.06 × 10⁻⁶ S/mm on muscle bundles 34, 33 and 32 respectively. The greater sensitivity of muscle fibres in bundle 34 to GABA is due at least in part to a larger number of GABA receptors on bundle 34 muscle fibres.
• 4.4. The decrement of electrotonic potentials in the presence of GABA were measured over distances of both half fibre length and whole fibre length. Good agreement was obtained between changes in space constant produced by GABA using half fibre length and whole fibre length data.
• 5.5. By taking into account changes in space constant induced by GABA it was possible to demonstrate that presynaptic GABA receptors were involved in the inhibition of slow excitatory postsynaptic potentials by GABA.
• 6.6. “Slow” excitatory postsynaptic potentials recorded under current clamp were inhibited in a dose-dependent manner by GABA. This inhibition was not dependent on muscle-fibre GABA sensitivity and could not be completely accounted for by GABA-induced changes in the cable properties of the muscle fibres.

     

L-glutamate as an excitatory transmitter at the neuromuscular junction of a beetle larva

The effects of L-glutamate and acetylcholine on the ventral muscle fibres of the larval mealworm Tenebrio molitor were studied by means of microelectrodes. Bath application of L-glutamate at concentrations higher than 1 × 10 ⁴M suppressed excitatory postsynaptic potentials (EPSPs) and evoked both a depolarisation and a reduction in the input resistance of the muscle fibre. In contrast, acetylcholine chloride (up to 1 mM) had no effect at all. Circumscribed spots could be detected on the fibre surface where iontophoretic applications of L-glutamate caused transient depolarizations (glutamate potentials). Focal extracellular recordings revealed that the glutamate sensitive spots were identical with synaptic sites. The reversal potentials of the EPSP and the L-glutamate potential were identical. These results are compatible with the hypothesis that L-glutamate is an excitatory transmitter at the neuromuscular junction.     

Studies on action mechanisms of a possible false cholinergic transmitter, (2-hydroxyethyl) methyldiethylammonium

(2-Hydroxyethyl) methyldiethylammonium (DEC; Diethylcholine) was found to inhibit cholinergic fibers slowly, both in skeletal muscle (ED₅₀: 2.25 × 10^?5 M in chick biventer cervicis and 42 mg/kg in rat sciatic-gastrocnemius) and in smooth muscle preparations (ED₅₀: 7.7 × 10^?4 M in transmurally stimulated guinea-pig ileum) without having any effect on dose-response curves of acetylcholine to contract chick biventer cervicis, frog rectus abdominis and guinea-pig ileum. These results indicate that DEC acts at the prejunctional nerve fibers, but not at the postjunctional cholinergic receptor sites. DEC was acetylated efficiently both by choline acetyltransferase and by minced rat brain, suggesting that it can be acetylated to acetyl-DEC in the nerve ending. Acetyl-DEC was found to block acetylcholine actions competitively both in smooth and in skeletal muscle preparations (1 × 10^?3 ? 1 × 10^?2M) indicating that the acetylated product of DEC can serve as an antagonist at the cholinergic receptor site. It is therefore concluded that DEC is a false cholinergic transmitter.     

The mechanism of block of glutamate synapses by dipicolinic acid

The effect of dipicolinic acid (2,6-pyridine dicarboxylic acid) on the mealworm neuromuscular junction was studied using conventional microelectrode recording techniques. Dipicolinic acid (10^?5-10^?3 M) added to the bathing solution reversibly blocked neuromuscular transmission. The depolarization in response to iontophoretically applied L-glutamate (glutamate potential) was not affected by dipicolinic acid even when the neurally evoked excitatory postsynaptic potential (EPSP) was totally abolished. Focal extracellular recordings from single synaptic sites revealed that in the presence of 1 x 10^?4 M dipicolinic acid the presynaptic spike was unchanged, but the quantal content for evoked transmitter release was reduced. The calcium-dependent action potential elicited by direct stimulation of the muscle fiber was not impaired by dipicolinic acid. These results suggest that dipicolinic acid interferes with the transmitter-releasing mechanism from the presynaptic terminal.     

Octopamine and chlordimeform enhance sensory responsiveness and production of the flight motor pattern in developing and adult moths

Octopamine and an agonist, chlordimeform, increase the responsiveness of adult and pharate adult Manduca sexta to gentle mechanical stimulation of the wing. Higher doses of chlordimeform elicit almost continuous production of the flight motor pattern in both adults and pharate adults, and the effect persists for more than 24 h. The dose of chlordimeform necessary for this effect increases with age. Mechanical stimulation of the wing of pharate adults elicits several cycles of flight motor pattern, but with repeated stimulation the animal habituates. Habituation is slower in chlordimeform-treated animals than in controls. Injection of octopamine (1–8 × 10^?8 mol) or chlordimeform (3 × 10^?9 mol) into the mesothoracic ganglion elicits the flight motor pattern. The excitatory actions of both compounds can be blocked by cyproheptidine. Chlordimeform (5 × 10^?8 mol) in acetone applied to the wing does not cause a noticeably greater increase in the electrical activity of sensory neurons than does acetone applied alone; this result suggests that chlordimeform does not act on these peripheral sites or on axonal membranes in general. We suggest that chlordimeform and octapamine act on the thoracic ganglia to alter the level of excitation on reffectiveness of synaptic transmission among central neurons, including those involved in producing the flight motor pattern.     

Presynaptic Control of the Synthesis and Release of Dopamine from Striatal Synaptosomes: A Comparison Between the Effects of 5-Hydroxytryptamine, Acetylcholine, and Glutamate

The effects of 5-HT and glutamate on dopamine synthesis and release by striatal synaptosomes were investigated and compared with the action of acetylcholine, which acts presynaptically on this system. 5-HT inhibited (28%) synthesis of [¹⁴C]dopamine from L-[U-¹⁴C]tyrosine, at 10-⁵M and above. This contrasts with the action of acetylcholine, which stimulated [¹⁴C]-dopamine synthesis by 24% at 10-⁴ M. Tissue levels of GABA were unaffected by either 5-HT or acetylcholine up to concentrations of 10-⁴ M. The inhibitory action of 5-HT (5 × 10^?5 M and 2 × 10^?4 M) on [¹⁹C]dopamine synthesis was completely abolished by methysergide (2 × 10^?6 M). Higher concentrations of methysergide (10^?4 M) or cyproheptadine (10^?5 M) inhibited [¹⁴C]dopamine synthesis by 28% and 25%, respectively, when added alone to synaptosomes. However, only methysergide prevented the further inhibition of synthesis caused by 5-HT. At concentrations of 2 × 10^?5 M and above, 5-HT stimulated [¹⁴C]dopamine release. This releasing action differed from that of acetylcholine, which occurred at lower concentrations (e.g., 10^?6 M). Methysergide (up to 10^?4 M) or cyproheptadine (2 × 10^?4 M) did not reduce the 5-HT (5 × 10^?5 M)-induced release of [¹⁴C]dopamine, but methysergide (10^?4 M) showed a potentiation (49%) of this increased release. The stimulatory effects of 5-HT (2 × 10^?5 M) and K⁺ (56 mM) on [¹⁴C]dopamine release were additive, indicating that two separate mechanisms were involved. However, when both agents were present the stimulatory effect of K⁺ (56 mM) on [¹⁴C]dopamine synthesis was not seen above the inhibitory effect of 5-HT. Glutamate (0.1-5 mM) did not affect [⁴C]dopamine release or its synthesis from L-[U-¹⁴C]tyrosine. It is concluded that 5-HT modulates the synthesis of dopamine in striatal nerve terminals through a presynaptic receptor mechanism, an action antagonised by methysergide. The releasing action of 5-HT apparently occurs through a separate mechanism which is also distinct from that involved in the response to K⁺ depolarisation.     

IgE-mediated 14C-serotonin release from rat mast cells modulated by morphine and endorphins

The formaldehyde method was used to examine the interaction of PGE₁ with morphine, β-endorphin and Met-enkephalin on rat mast cells by their effects on IgE-mediated ¹⁴C-serotonin release. PGE₁ (2×10^?8?2×10^?5 M) caused a dose-related inhibition of the mediator release 1 min after an antigen challenge, and morphine (3×10^?7?3×10^?5 M) reversed this PGE₁ effect dose-dependently and stereospecifically; naloxone (2×10^?4 M) antagonized this action of morphine. β-Endorphin (3×10^?7?10^?5 M) and Met-enkephalin (3×10^?6?10^?4 M) mimicked this morphine action dose-dependently and were antagonized by naloxone (2×10^?4 M). These results suggest that morphine and endorphins modulate immunological mediator release from rat mast cells through opioid receptors.     

Acetylcholine potentiation of field stimulated rat vas deferens: A pre-synaptic muscarinic mechanism?

Acetylcholine (ACh) was found to markedly enhance the nerve stimulation induced twitch response of isolated, field-stimulated rat vas deferens (RVD). The ED₂₀₀ (concentration which enhances the twitch response to 200% of control) for this potentiation was 6 × 10^?6M with the maximum twitch response being increased by more than 3 fold (325 ± 30%). Carbachol (ED₂₀₀ = 8.5 × 10^?7M) showed identical results. With each drug the potentiation was competitively antagonized by atropine (10^?7?10^?5M). Physostigmine 10^?8?10^?6M) both enhanced the basal twitch response (215 ± 8% of control at 10^?5M) and the sensitivity of the RVD to ACh (ED₂₀₀ = 3.3 × 10^?7M) but not to carbachol. Atropine, on the other hand reduced the basal twitch response by 18 ± 3% at 10^?5M. Hemicholinium (10^?4M) also reduced the basal twitch responses by 23 ± 5%. ACh (10^?7M?10^?5M) did not modify the responses of unstimulated RVD to norepinephrine or KCl suggesting a pre-synaptic site of action. Taken together these results are compatible with the presence of a pre-junctional, excitatory muscarinic mechanism in the field stimulated RVD. That this cholinergic system may be of physiological significance is supported by the observations that atropine and hemicholinium depress while physostigmine enhances the twitch response in the absence of exogenous ACh.     

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

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

Selective depression of dopamine-induced depolarization by morphine and enkephalins in snail neurons

Morphine, met-enkephalin, and leu-enkephalin in a concentration of 1×10^?5 M depress rapidly and reversibly the amplitude of depolarization induced by dopamine application toHelix pomatia neurons; the effect is naloxone-dependent. The amplitudes of dopamine-induced hyperpolarization and also of the depolarization and hyperpolarization responses to acetylcholine application are unchanged under these circumstances. The hypothesis of blocking of chemosensitive sodium channels by enkephalins is discussed. It is suggested that this hypothesis is true for high concentrations of morphine and enkephalins (1×10^?4 to 1×10^?3 M). In lower concentrations (1×10^?5 M) morphine and enkephalins lead to modulation of the reponses to the action of neurotransmitters, evidently through their influence on the cyclic nucleotide system.     

An analysis of the direct effect of chloridazepoxide on mammalian cardiac tissues and crayfish and squid giant axons: possible basis of antiarrhythmic activity.

Chlordiazepoxide has been found to be antiarrhythmic $\text{in vivo}$. The purpose of the present investigation is to identify the mechanism(s) of such antiarrhythmic activity. In canine heart, chlordiazepoxide effectively depressed the enhanced repetitive discharges in subendocardial Purkinje fibers surviving acute myocardial infarction. Chlordiazepoxide altered the action potential characteristics of Purkinje fiber by shortening the APD₅₀, APD₁₀₀ and effective refractory period with little effect on the resting membrane potential. The maximal rate of upstroke (dv/dt) was significantly reduced only at 1 × 10^?4M and above in Purkinje fibers and the membrane response curve was consistently shifted to the right by chlordiazepoxide. The ventricular muscle was little affected by chlordiazepoxide except for the shortened APD₅₀ and reduced dv/dt. Chlordiazepoxide exerted nerve blocking potency comparable to lidocaine in the crayfish giant axon. Voltage-clamp experiments in squid axon showed that chlordiazepoxide suppressed both components of membrane current, the transient inward sodium current being diminished far greater than the steady-state potassium current. These results demonstrate a direct action on cardiac and axonal membranes which may be partially responsible for the antiarrhythmic activity of this agent.     

Effects of prostacyclin on the canine isolated basilar artery

Prostacyclin (PGI₂) produced a biphasic response in canine isolated basilar arteries. In low doses (1 × 10^?8M?1 × 10^?7M) PGI₂ caused a slight but consistent relaxation of resting muscle tone. In low concentrations (1 × 10^?8M?1 × 10^?6M) PGI₂ antagonized muscle contractions caused by serotonin or prostaglandin (PG) F_2α. This relaxant effect with low doses of PGI₂ on the isolated cerebral artery contrasts with findings obtained with other PGs and supports the hypothesis that PGI₂ is a mediator of vasodilatation. However, in 1 × 10^?5M concentrations PGI₂ contracted the arterial muscle and did not antagonize contractions induced by serotonin or PGF_2α.     

Properties of synaptic currents during nonadrenergic inhibition of smooth-muscle cells of the guinea pig large intestine

Using a double sucrose gap method, inhibitory junction potentials (IJP) appeared in muscles of the circular layer of the large intestine in response to intramural stimulation in the presence of atropine. Under voltage clamp conditions, an inhibitory junction current (IJC) in the outward direction appeared in response to the same stimulus, declining exponentially 100–150 msec after the peak. The amplitude of IJC was a linear function of membrane potential; the reversal potential of the peak IJC was in the region of the potassium equilibrium potential. The time constant of decay (τ) depended exponentially on membrane potential, falling by a factor ofe on hyperpolarization by 120 mV. A decrease or increase in quantum composition of IJC caused a corresponding change in τ of IJC decay. Meanwhile apamine (5×10^?7 g/ml) reduced the amplitude of IJC without affecting its kinetics. The action of ATP (10^?3 M) led to a decrease in amplitude and τ of decay of IJC, evidently on account of occupation of some postsynaptic receptors by ATP. It is suggested that ATP facilitates the delayed diffusion of releasing mediator, by occupying synaptic receptors. Since an increase in the quantity of secreted mediator caused only a very small increase in the amplitude of IJC, it was postulated that under normal conditions the postsynaptic effect of the released mediator is close to maximal.     

Calcium and cyclic AMP as possible mediators of neurohormone action in the hindgut of the cockroach, Leucophaea maderae

Adenosine 3′,5′-monophosphate (cyclic AMP) (10⁻⁵ g/ml) often caused a gradual increase in spotaneous contractile activity of the hindgut of the cockroach, Leucophaea maderae, and on rare occasions it would evoke a hormone-like response. However, aminophylline (2·5 × 10⁻⁴ g/ml) was capable of mimicking the neurohormone, and a concentration of 2·5 × 10⁻⁵ g/ml potentiated the contractile response evoked by the neurohormone: these responses were blocked by either the presence of 1 mM manganous ion or in a high potassium solution (162 mM). Propranolol (10⁻⁶ g/ml) and dopamine (10⁻⁴ g/ml) suppressed both spontaneous contractile events and neurohormone action. Dopamine (5 × 10⁻⁶ g/ml) also blocked action potential generation as did propranolol at 10⁻⁴ g/ml.These results lead us to suppose that cyclic AMP might serve as a mediator of neurohormone action by increasing calcium transport across the surface membrane of muscle fibres. Caffeine (2·5 × 10⁻⁴ g/ml), like aminophylline, caused a hormone-like response in normal hindguts. Even when the visceral muscles of the hindgut were depolarized in 162 mM potassium solution (without calcium), caffeine was still capable of inducing a phasic response. However, the addition of 2 mM calcium to such potassium-depolarized preparations caused a gradual increase in muscle tonus and substantially potentiated the response to caffeine.Such findings clearly implicate calcium as the mediator of excitation-contraction coupling in visceral muscle. While the interactions between the neurohormone, cyclic AMP, and calcium seem to be largely associated with the surface membrane and action potential generation.     

Inhibition of growth and cellular aggregation of Dictyostelium discoideum by steroid compounds.

A study of the effects of steroid hormones on the development of Dictyostelium discoideum has shown that 4 × 10^?5M progesterone, and to a lesser extent dehydro-epiandrosterone, oestradiol and testosterone, inhibit both the growth and aggregation of these amoebae. Pregnenolone is active at lower concentrations (3 × 10^?6M), but at the level of growth only. Progesterone exerts its inhibitory action throughout the aggregation phase. The steroid prevents starved cells from becoming aggregation competent, and inhibits the aggregation of amoebae previously allowed to achieve the competent stage. However, unlike other agents such as dinitrophenol or EDTA, the steroid does not considerably affect cell morphology. Upon addition of progesterone cells become rounded, but after a brief lag they regain their ability to adhere to solid supports and form pseudopods. The fact that the steroids active on Dictyostelium are among the most liposoluble might indicate that their inhibitory action is dependent upon their incorporation into membrane lipids.     

The mode of action of phenylhydrazine hydrochloride on the locust neuromuscular system

The action of the carbonyl reagent phenylhydrazine hydrochloride (Phen. HCl) on locust excitatory neuromuscular systems was studied by examining the effects of this compound on the mechanical and electrical properties of the retractor unguis and extensor tibiae muscles of the locust Schistocerca gregaria.Low concentrations of Phen. HCl (10^?9 w/v to 2·5 × 10^?5 w/v) potentiated the muscle contractions and the excitatory post-synaptic potential (EPSP), the optimum concentration being about 10^?5 w/v. 10^?8 w/v Phen. HCl increased miniature EPSP frequency, but this increase became less pronounced as the concentration was raised, and no increase at all was observed at 10^?5 w/v. There was no change in miniature EPSP amplitude at any concentration. Higher concentrations of Phen. HCl (> 2·5 × 10^?6 w/v) depressed the neurally evoked contraction, the EPSP, and the response of the muscle to iontophoretically applied l-glutamate. A gradual increase in muscle input conductance was observed on perfusion with these high concentrations of Phen. HCl. The presence of magnesium in the bathing fluid (15 m-moles/l.) reduced the effectiveness of Phen. HCl in potentiating the EPSP and delayed or reduced the increase in input conductance observed on perfusion with high concentrations of Phen. HCl.The results indicate that low concentrations of Phen. HCl act presynaptically, possibly by depolarizing the excitatory nerve terminals. Higher concentrations may act directly on the post-synaptic glutamate receptors.