Permeability of the endplate membrane activated by acetylcholine to some organic cations

The ability of various organic cations to depolarize the ACh-activated endplate membrane in the absence of Na ions was examined on frog sartorius muscle by measuring the endplate potential on the muscle surface with the moving electrode technique. The ACh-activated endplate membrane was very permeable to ammonium and its methyl and hydroxy derivatives, and moderately permeable to guanidine derivatives and Tris (hydroxymethyl) aminomethane. The permeability of alkylol derivatives of ammonium diminished progressively with increase in molecular size. The present results suggested that the endplate ionic channels can be represented by a pore of about 6.4 Å in diameter.     

Effects of ammonium ions on endplate channels

Miniature endplate currents, recorded from voltage-clamped toad sartorius muscle fibers in solutions containing ammonium ions substituted for sodium ions, were increased in amplitude and decayed exponentially with a slower time constant than in control (Na) solution. The peak conductance of miniature endplate currents was also greater in ammonium solutions. The acetylcholine null potential was - 2.8 +/- 0.8 mV in control solution, and shifted to 0.9 +/- 1.6 mV in solutions in which NH4Cl replaced half the NaCl. In solutions containing NH4Cl substituted for all the NaCl, the null potential was 6.5 +/- 1.3 mV. Single channel conductance and average channel lifetime were both increased in solutions containing ammonium ions. The exponential relationship between the time constant of decay of miniature endplate currents or channel lifetime and membrane potential was unchanged in ammonium solutions. A slight but consistent increase in peak conductance during miniature endplate currents and single channel conductance was seen as membrane potential became more positive (depolarized) in both control and ammonium solutions. Net charge transfer was greater in ammonium solutions than in control solution, whether measured during a miniature endplate current or through a single channel. The results presented here are consistent with an endplate channel model containing high field strength, neutral sites.     

Current-dependent block of endplate channels by guanidine derivatives

Methyl- and ethylguanidine block the endplate current in frog muscle. Both derivatives blocked inward-going endplate currents without affecting outward endplate currents. Repetitive stimulation that evoked several inward endplate currents enhanced the block, which suggests that these agents interact with open endplate channels. The relative conductance vs. potential curve exhibited a transition from a low to a high value near the reversal potential for the endplate current, both in normal and in 50% Na solution. In the latter solution, the reversal potential for endplate current was shifted by a mean value of 16 mV in the direction of hyperpolarization. The results suggest that methyl- and ethylguanidine block open endplate channels in a manner dependent on the direction of current flow rather than on the membrane potential.     

CHOLINESTERASE ACTIVITY OF THE MOTOR ENDPLATE IN ISOLATED MUSCLE MEMBRANE

Abstract— The cholinesterase activity of motor endplates in tibialis anterior muscle of rats accounted for about 20 per cent of the total cholinesterase activity of the muscle. In the isolated muscle membrane preparation of rat intercostal muscle, the cholinesterase activity was localized solely in the motor endplate, as shown by cholinesterase staining. The cholinesterase activity of the membrane per unit of nitrogen was 26·9 times that of the muscle homogenate. The membrane (endplate) cholinesterase had an optimal pH of 8, K_m value of 3·1 m m , and was stable at 4° for at least 13 days. Cholinesterase of a motor endplate hydrolysed 2·69 × 10⁸ acetylcholine molecules in 1 msec. Since it is estimated that 10⁸ cholinesterase active sites are present in a motor endplate, the turnover time (time necessary for one enzyme site to hydrolyse one acetylcholine molecule) is calculated to be 372 μ sec, and the turnover number (molecules of acetylcholine hydrolysed by one enzyme site/min) to be 1·61 × 10⁵. From studies with cholinesterase inhibitors, cholinesterase activity was estimated to be due mostly to acetylcholinesterase, and only a minor part to pseudocholinesterase. The muscle membrane preparation seems to be useful for the study of other properties of the motor endplate.     

Selectivity of cations and nonelectrolytes for acetylcholine-activated channels in cultured muscle cells

The selectivity of acetylcholine (A-Ch)-activated channels for alkali cations, organic cations, and nonelectrolytes in cultured muscle cells has been studied. To test the effect of size, charge, and hydrogen- binding capacity of permeant molecules on their permeability, we have obtained the selectivity sequences of alkali cations, compared the permeability of pairs of permeant molecules with similar size and shape but differing in charge, and studied the permeability of amines of different hydrogen bonding capacity. ACh-activated channels transport alkali cations of small hydration radii and high mobility. The molecules with positive charge and (or) a hydrogen-bond donating moiety are more permeable than the ones without. On the other hand, several nonelectrolytes, i.e., ethylene glycol, formamide, and urea, do have a small, but measurable, permeability through the channels. These results are consistent with a model that ACh-activated channel is a water- filled pore containing dipoles or hydrogen bond accepting groups and a negative charged site with a pK of 4.8.     

Na channel distribution in vertebrate skeletal muscle

The loose patch voltage clamp has been used to map Na current density along the length of snake and rat skeletal muscle fibers. Na currents have been recorded from (a) endplate membrane exposed by removal of the nerve terminal, (b) membrane near the endplate, (c) extrajunctional membrane far from both the endplate and the tendon, and (d) membrane near the tendon. Na current densities recorded directly on the endplate were extremely high, exceeding 400 mA/cm2 in some patches. The membrane adjacent to the endplate has a current density about fivefold lower than that of the endplate, but about fivefold higher than the membrane 100-200 micron from the endplate. Small local variations in Na current density are recorded in extrajunctional membrane. A sharp decrease in Na current density occurs over the last few hundred micrometers from the tendon. We tested the ability of tetrodotoxin to block Na current in regions close to and far from the endplate and found no evidence for toxin-resistant channels in either region. There was also no obvious difference in the kinetics of Na current in the two regions. On the basis of the Na current densities measured with the loose patch clamp, we conclude that Na channels are abundant in the endplate and near-endplate membrane and are sparse close to the tendon. The current density at the endplate is two to three orders of magnitude higher than at the tendon.     

An endplate potential due to potassium released by the motor nerve impulse

A small endplate potential can be recorded in frog muscle fibres, after all acetylcholine-mediated transmission has been eliminated by pre- or postsynaptic blocking agents (botulinum toxin, calcium lack, manganese, curare, alpha-bungarotoxin). It is usually necessary to hyperpolarize the muscle membrane to detect this 'non-cholinergic' endplate potential. Below--100 mV little or no response is seen; a maximum is reached at about--140 mV, when the amplitude can be as large as 100 microV (endplate current up to about 1 nA). Other characteristic features are: the response shows no quantal fluctuations; its amplitude is not facilitated by repetitive impulses; its size and time course are not noticeably affected by prostigmine, curare or alpha-bungarotoxin; the half-time of decline of the endplate current is approximately 1.7 ms at 20 degrees C, and is lengthened by lowering the temperature with a Q10 of about 1.3; the response is abolished by barium. When iontophoretic pulses of potassium are applied to the endplate, local depolarization is recorded whose amplitude varies with membrane potential similarly to that of the nerve-evoked response. These observations strongly indicate that this 'non-cholinergic', 'non-quantal' endplate potential arises from a rapid synaptic transfer of potassium ions, released by the active nerve terminal into the synaptic cleft and entering the muscle fibre through 'anomalous rectifier' channels in the endplate membrane.     

Habitual exercise enhances neuromuscular transmission efficacy of rat soleus muscle in situ.

Rat motor nerve terminals and the endplates they interact with exhibit changes to varying patterns of use, as when exposed to increased activation in the form of endurance exercise training. The extent to which these changes affect neuromuscular transmission efficacy is uncertain. In this study, the effects of habitual exercise on the electrophysiological properties of neuromuscular transmission in rat soleus muscle were investigated using a novel in situ approach. Consistent with previous reports, miniature endplate potential frequency was enhanced by habitual exercise. Other passive properties, such as resting membrane potential, miniature endplate potential amplitude, and "giant" miniature endplate potential characteristics were unaltered by the training program. Full-size endplate potentials were obtained by blocking soleus muscle action potentials with mu-conotoxin GIIIb. Quantal content values were 91.5 and 119.9 for control and active groups, respectively (P < 0.01). We also measured the rate and extent of endplate potential amplitude rundown during 3-s trains of continuous stimulation at 25, 50, and 75 Hz; at 50 and 75 Hz, we found both the rate and extent of rundown to be significantly attenuated (10--20%) in a specific population of cells from active rats (P < 0.05). The results establish the degree of activity-dependent plasticity as it pertains to neuromuscular transmission in a mammalian slow-twitch muscle.     

Induction of action potentials in fish red muscle by denervation

The effects of denervation on the electrical membrane properties of fish red muscle were investigated. Forty to fifty hours after denervation, miniature endplate potentials disappeared abruptly and field stimulation of the nerve within the muscle failed to evoke endplate potentials, indicating that transmission failure occurred at this time. The membrane resistance of the red muscle fibre increased after denervation. Normally innervated fish red muscles do not generate action potentials in response to either nerve or direct muscle stimulation. However, approximately 3 weeks after nerve sectioning, action potentials could be induced in the muscles. The action potential was sodium-dependent, and was sensitive to tetrodotoxin. Actinomycin D injected in the early phase after operation suppressed the induction of the action potential. These results indicate that RNA synthesis is preliminary to the induction of the action potential mechanism, and that this mechanism is under neural control.     

Development of rat soleus endplate membrane following denervation at birth

Rat soleus endplates develop some of their characteristic features before birth and others after birth. Specializations appearing before birth include a localized cluster of acetylcholine receptors (AChRs), an accumulation of acetylcholinesterase (AChE) in the synaptic basal lamina, and a cluster of nuclei near the endplate membrane. In contrast, postsynaptic membrane folds are elaborated during the first three weeks after birth. We denervated soleus muscles on postnatal day 1, before folds had appeared, and followed the subsequent development of endplate regions with light and electron microscopy. We found that the denervated endplates initiated fold formation on schedule and maintained their accumulations of AChRs, AChE, and endplate nuclei. However, the endplates stopped fold formation prematurely and eventually lost their rudimentary folds. At about the same time, the junctional AChR clusters were joined by ectopic patches of AChRs. The former endplate regions also became unusually elongated, possibly as a consequence of the lack of membrane folds. Apparently, endplate membranes have only a limited capacity for further development in the absence of both the nerve and muscle activity.     

Endplate channel block by guanidine derivatives

The effects of the n-alkyl derivatives of guanidine on the frog neuromuscular junction were studied using the two-microelectrode voltage clamp and other electrophysiological techniques. Methyl-, ethyl- , and propylguanidine stimulated the nerve-evoked release of transmitter. However, amyl-and octylguanidine had no apparent presynaptic action. All of the derivatives blocked the postsynaptic response to acetylcholine, the potency sequence being octyl-greater than amyl-greater than propyl-, methyl-greater than ethylguanidine. Methyl- and octylguanidine did not protect the receptor from alpha- bungarotoxin block, suggesting that these compounds do not bind to the receptor but probably block the ionic channel. Methyl-, ethyl-, and propylguanidine shortened inward endplate currents but prolonged outward currents. Amylguanidine prolonged both inward and outward endplate currents, and the currents became biphasic at negative membrane potentials. Octylguanidine increased the rate of decay of endplate currents at all potentials. All of the derivatives blocked inward endplate currents more markedly than outward currents, resulting in a highly nonlinear current-voltage relation. Methyl-, ethyl-, and propylguanidine reversed the voltage dependence of endplate current decay, while amyl-and octylguanidine reduced the voltage dependence of endplate current decay. Octylguanidine appears to block the ionic channel in both the open and the closed state. The block of the open channel follows pseudo-first-order kinetics with a forward rate constant of 4-6 X 10(7) M-1 s-1.     

Electrical Inexcitability of the Frog Neuromuscular Synapse

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

alpha-Tocopherol modifies lead induced functional changes at murine neuromuscular junction

Lead impacts neuromuscular junction and might induce skeletal muscle weakness. Antioxidants may prevent toxic actions of lead on muscle. In this study, resting membrane potentials, endplate potentials, miniature endplate potentials (MEPPs) and isometric twitch tensions were recorded to investigate effects of alpha-tocopherol (Vitamin E) on lead induced changes at murine dorsiflexor muscle. Moreover, levels of endplate nicotinic receptors were measured by receptor autoradiography. Forty rats were divided into four groups (lead alone, alpha-tocopherol, lead plus alpha-tocopherol and saline). Lead (1 mg/kg, i.p.), was administered daily for 2 weeks and alpha-tocopherol (100 mg/kg, i.p.) was given daily for 3 weeks. Lead treatment significantly reduced twitch tension (from 4.4+/-0.4 to 2.2+/-0.3 g) and delayed half time of decay. MEPP frequencies and quantal content were also significantly reduced after lead treatment. Pretreatment with alpha-tocopherol reversed twitch tension reduction (4.1+/-0.3 g) and modified lead induced delay in half time of decay. Similarly, alpha-tocopherol modified the negative actions of lead exposure on MEPP frequencies and quantal content. Receptor autoradiographic studies revealed significant increase of nicotinic receptor levels at the endplate region of flexor muscle in lead treated mice. However, animals treated with lead plus alpha-tocopherol showed significantly decreased levels of nicotinic receptors. alpha-Tocopherol appears to protect against lead induced neuromuscular dysfunction. These effects of alpha-tocopherol are possibly mediated via a free radical mechanism or modification of calcium homeostasis.     

Anti-curare action of stannous ion in the frog neuromuscular junction

For the purpose of elucidating the mechanism of action of stannous ion (Sn2+), we investigated effects of stannous chloride (SnCl2) on the twitch and on the electrical phenomena in the muscle fiber. Sciatic nerve-sartorius muscle preparations from the bullfrog were used as the material. Effect of SnCl2 was examined on the twitch partially inhibited by pretreatment with d-tubocurarine. SnCl2 (1-100 microM) antagonized d-tubocurarine and enhanced the twitch dose-dependently. Tartaric acid, which is the solvent used for SnCl2 solution, had no augmentative effect on the twitch, even at a concentration as high as 250 microM. SnCl2 (1-50 microM) increased the amplitude of the endplate potential; that is, it exerted an anti-curare action. The resting potential and the membrane resistance of the muscle fiber were not altered by 30 microM SnCl2. These findings lead to the conclusion that Sn2+ enhances the twitch by increasing the endplate potential of the muscle fibers.     

Changes in synaptic potential properties during acetylcholine receptor accumulation and neurospecific interactions in Xenopus nerve-muscle cell culture

Acetylcholine receptors in the muscle cell membrane accumulate at the nerve contact area in Xenopus cell cultures. The correlation between spontaneous synaptic potential properties and extent of acetylcholine receptor accumulation was studied. Small and infrequent miniature endplate potentials were measured before acetylcholine receptor accumulation which was observed with fluorescence microscopy using tetramethylrhodamine-conjugated α-bungarotoxin. As acetylcholine receptors accumulate at the nerve contact area, these synaptic potentials become larger and their frequency increases dramatically. In nerve-contacted muscle cells where spontaneous synaptic activity could not be detected, extensive acetylcholine receptor accumulation was not found at sites of nerve contact. Furthermore, muscle cells which exhibited extensive acetylcholine receptor accumulation along the nerve always produced miniature endplate potentials. Thus acetylcholine receptor accumulation and the presence of miniature endplate potentials were strongly correlated. Noncholinergic neurons from dorsal root ganglia did not form functional synaptic contacts with muscle cells nor acetylcholine receptor accumulation along the path of contact. Furthermore, explants from tadpole spinal cord formed functional synaptic contacts with muscle cells but rarely caused AChR localization. These data are discussed in terms of developmental processes during neuromuscular junction formation.     

α-Tocopherol Modifies Lead Induced Functional Changes at Murine Neuromuscular Junction

Lead impacts neuromuscular junction and might induce skeletal muscle weakness. Antioxidants may prevent toxic actions of lead on muscle. In this study, resting membrane potentials, endplate potentials, miniature endplate potentials (MEPPs) and isometric twitch tensions were recorded to investigate effects of α-tocopherol (Vitamin E) on lead induced changes at murine dorsiflexor muscle. Moreover, levels of endplate nicotinic receptors were measured by receptor autoradiography. Forty rats were divided into four groups (lead alone, α-tocopherol, lead plus α-tocopherol and saline). Lead (1?mg/kg, i.p.), was administered daily for 2 weeks and α-tocopherol (100?mg/kg, i.p.) was given daily for 3 weeks. Lead treatment significantly reduced twitch tension (from 4.4±0.4 to 2.2±0.3?g) and delayed half time of decay. MEPP frequencies and quantal content were also significantly reduced after lead treatment. Pretreatment with α-tocopherol reversed twitch tension reduction (4.1±0.3?g) and modified lead induced delay in half time of decay. Similarly, α-tocopherol modified the negative actions of lead exposure on MEPP frequencies and quantal content. Receptor autoradiographic studies revealed significant increase of nicotinic receptor levels at the endplate region of flexor muscle in lead treated mice. However, animals treated with lead plus α-tocopherol showed significantly decreased levels of nicotinic receptors. α-Tocopherol appears to protect against lead induced neuromuscular dysfunction. These effects of α-tocopherol are possibly mediated via a free radical mechanism or modification of calcium homeostasis.     

Comparison of the cholinoreceptor and cholinesterase properties of the frog Rana temporaria and the squid Todarodes pacificus

Studies have been made on the interaction of several groups of quartenary ammonium salts with cholinoreceptors of m. rectus abdominis of the frog Rana temporaria, and isolated m. retractor infundibuli of the octopus Todarodes pacificus, as well as with cholinesterases of the frog brain and visual ganglia of the octopus. The derivatives of polymethylene bis(trimethylammonium) compounds, being cholinomimetic drugs for frog muscle, do not exert cholinomimetic influence on octopus muscle. The same difference with respect to their effect on frog and octopus receptors was found in anabazin derivatives. Among amide derivatives of acetylcholine, the strongest mimetic effect on cholinoreceptors of both animals was exhibited by a piperazine isolog with gauche-conformation, whereas N-methyl isolog with trans-conformation was found to be the strongest inhibitor of cholinesterases. Cholinoreceptors and cholinesterase of the octopus were less sensitive to the effect of the investigated quartenary ammonium salts than those of the frog.     

A Linear Dose-Response Curve at the Motor Endplate

The motor endplate of frog sartorius muscle was voltage clamped and the peak current to different concentrations of acetylcholine and carbachol applied in the perfusing fluid was measured. Perfusing fluid was hypertonic in order to suppress contractions. Current responses were smooth and reached a peak value within 2–5 s. The dose-response curve was usually linear even with concentrations of 10^-2 M acetylcholine, indicating that the conductance change was probably proportional to the concentration of acetylcholine or carbachol. With high concentrations nonlinearity sometimes appeared but in these cases the fast onset of desensitization appeared to be preventing the current response from reaching its expected peak amplitude. When the depolarization produced by acetylcholine in a non-voltage-clamped endplate was measured the dose-response curve was hyperbolic. This relationship was imposed by the electrical properties of the endplate membrane and its surrounding sarcolemma, and could be predicted if the input resistance of the fiber was known. Experiments were also done on slow muscle fibers. Depolarizing analogues of acetylcholine had similar effects to acetylcholine. d-Tubocurarine reduced the proportionality constant between concentration of acetylcholine and conductance change, and this resulted in a parallel shift of the log-concentration depolarization curve. A linear dose-response curve was unexpected within the context of current theories of drug action.     

Design and synthesis of cell-permeable fluorescent nitrilotriacetic acid derivatives

Fluorescence labeling of the target molecules using a small molecule-based probe is superior than a method using genetically expressed green fluorescence protein (GFP) in terms of convenience in its preparation and functionalization. Fluorophore-nitrilotriacetic acid (NTA) conjugates with several ester protecting groups were synthesized and evaluated for their cell membrane permeability by fluorescence microscopy analysis. One of the derivatives, acetoxymethyl (AM)-protected NTA conjugate is hydrolyzed, resulting in intracellular accumulation, thus providing localized fluorescence intensity in cells. This modification is expected as an effective method for converting a non-cell membrane permeable NTA-BODIPY conjugates to a cell membrane permeable derivatives.     

An aromatic heptaene antibiotic levorin and its derivatives in muscle activity]

The review is concerned with the outlooks for the use of levorin, a membrane active and channel forming polyene antibiotic, and its alkyl derivatives in muscle activity. In complex with cholesterol and ergosterol, the aromatic heptaene antibiotic levorin forms structural ionic channels of the molecular size in the lipid and cell membranes. Levorin increases the membrane permeability for monosucrose and other neutral molecules as follows: H2O > urea > acetamide > glycerine > ribose > arabinose > glucose > saccharose. As a channel forming compound, levorin is able to induce in the cell membranes of the muscle fibres formation of additional channels permeable for the cations and to increase the flow of the energy dependent substrates to the cells and the outburst of the metabolites from them during intensive muscle activity. Levorin several times decreases the surface tension of aqueous solutions. In some models of experimental animals levorin promoted an increase of the blood fluidity and accelerated the blood stream in the blood vessels both in rest and in muscle activity. Physical load in a high power zone increases the intensity of lipid peroxidation that results in fatigue and lower physical efficiency. Possible prevention of an increase of the rate of free radical reactions by levorin and its alkyl derivatives providing higher antioxidant protection is discussed.