Competition between sodium and calcium ions in transmitter release at mammalian neuromuscular junctions

1. Frequencies of miniature end-plate potentials (m.e.p.p.s) were recorded at neuromuscular junctions in rat diaphragm-phrenic nerve preparations in vitro.2. In the presence of raised [K] (15-20 mM) lowering [Na] caused a rapid increase in m.e.p.p. frequency whether [Ca] was low or normal. Raising [Na] towards the normal concentration (162 mM) caused a slow fall in frequency and raising [Ca] in the range 0.32-2 mM caused a slow increase in frequency. These effects were less in the normal [K] (5 mM).3. Mean m.e.p.p. frequencies were determined for solutions containing 15 mM-K and combinations of [Ca] and [Na]. M.e.p.p. frequency varied inversely with [Na] when [Ca] was constant. In each of the three Na concentrations used (162, 113 and 65 mM) raising [Ca] in the range 0.32-2 mM increased m.e.p.p. frequency but when raised above 2-3 mM, Ca depressed frequency.4. A model was proposed in which Ca affected transmitter release by changing the concentration in the presynaptic membrane of a complex CaX to which the rate of transmitter release was directly proportional. Higher concentrations of Ca depressed transmitter release by inactivating CaX. Sodium ions competitively depressed release either by competing with calcium ions for association with X or by reducing the affinity of X for Ca.5. When [Na] was lowered in solutions containing raised [Mg] and [Ca], the increase of mean m.e.p.p. frequency was greater than that observed in raised [Ca] and normal [Mg] and was of the same order as the increases seen in low [Ca]. The result was interpreted to indicate either that Na and Mg do not compete with Ca at the same site or that Mg affects the affinity of X for Ca and Na.6. The effect of lowering [Na] on m.e.p.p. frequency was a specific effect of Na ions. When LiCl was substituted for NaCl, the increase of m.e.p.p. frequency persisted. Changes in [Cl] had no effect on m.e.p.p. frequency.7. There was a linear relation between the mean logarithm of m.e.p.p. frequencies and [K], the slope of the relation increasing as [Na] was lowered. Conversely, lowering [Na] caused a greater increase in m.e.p.p. frequency as [K] was raised.8. The variation of m.e.p.p. frequencies in a diaphragm was roughly proportional to a second or higher power of [Na] and inversely proportion to [Ca]. It was thought that this could be due to differences in chelation of Ca which were more apparent at low Ca concentrations.9. The similarities between the effects of Na, Ca and K on m.e.p.p. frequency and the effects of these ions on Ca-influx in heart muscle led to the suggestion that transmitter release is proportional to the concentration of a negatively charged complex of a carrier X with one calcium ion (CaX) at the internal surface of the membrane and that changes in membrane potential affect transmitter release by changing the distribution or location of CaX in the membrane.     

On the mechanism by which calcium and magnesium affect the spontaneous release of transmitter from mammalian motor nerve terminals

1. The frequency of miniature end-plate potentials (m.e.p.p.s) was recorded from neuromuscular junctions in rat diaphragm phrenic nerve preparations in vitro after preparations had soaked in solutions containing Ca in concentrations between 10(-10) and 10(-2)M and a similar range of [Mg].2. Ethylenediamine tetra-acetate (EDTA) and ethyleneglycol bis (beta-aminoethyl ether) tetra-acetate (EGTA) buffers were added to prepare solutions with [Ca] and [Mg] below 10(-4)M. A computer program was used to estimate the free [Ca(2+)] in these solutions, and it was shown that the effects of Ca could be attributed to the free [Ca(2+)] in the bathing solution.3. M.e.p.p.s could still be detected without difficulty after soaking preparations for 6-8 hr in solutions containing EDTA or EGTA buffers and no added Ca. The basal frequency was unchanged upon exhibition of Ca in concentrations up to 10(-5)M and/or Mg in concentrations up to 10(-3)M.4. Ca in concentrations of and above 10(-4)M accelerated m.e.p.p. frequency from the basal level. This effect reached a maximum in [Ca] of 10 mM and raising the [Ca] above this level did not further change frequency. These effects were explained by the combination of Ca molecules with a nerve terminal receptor site. It was postulated that this combination allosterically activated the spontaneous release mechanism.5. Mg could accelerate m.e.p.p. frequency in the absence of added Ca. The interactions of Ca and Mg upon m.e.p.p. frequency indicated that Ca and Mg competed for the same sites.6. Raising the [H(+)] of the bathing medium accelerated m.e.p.p. frequency. This effect was thought to be exerted partly by combination with the same receptor sites as Ca and Mg and partly by variation of the ionization of the CaCl(2) of the bathing solution.     

On the mechanism by which calcium and magnesium affect the release of transmitter by nerve impulses

1. The relationship between the quantal content of end-plate potentials (e.p.p.s) and the bathing [Ca] and [Mg] was determined at neuromuscular junctions in the rat diaphragm in vitro.2. E.p.p.s were recorded intracellularly from preparations exposed to solutions with [Ca] between 0.05 and 10 mM and [Mg] between 0.1 and 12.5 mM. The quantal content of e.p.p.s was increased by raising the [Ca] over this range and decreased by raising the [Mg]. There appeared to be competition of Mg with Ca at three sites in the nerve terminal membrane.3. A kinetic scheme based on competition of Ca and Mg at three sites could quantitatively explain the effects of Ca and Mg upon the quantal content of e.p.p.s and also the effects of these ions upon miniature end-plate potential frequency.     

The role of calcium in depolarization—secretion coupling at the motor nerve terminal

1. The relation between m.e.p.p. frequency (F) and [Ca] was studied at the mouse neuromuscular junction, at varied concentrations of K(+) and at nerve terminals depolarized by focal depolarization.2. Under all conditions the relation between log F and log [Ca] was sigmoid, with a maximum slope that increased with depolarization or raised [K(+)]. In addition, depolarization or raised K(+) caused a progressive shift of the sigmoid curve upward and to the left (to reduced log [Ca]) and increased the range over which log F could be altered by [Ca].3. Reduction of osmotic pressure changed the relation between log F and log [Ca] in the same way as increase of depolarization, while increase of osmotic pressure did the opposite.4. Raised [Mg] acted in two ways: (a) to shift the curve of log F vs. log [Ca] to the right and (b) to reduce maximum Delta log F/Delta log [Ca] without altering the range of log F sensitive to [Ca].5. The relation between log quantal content of e.p.p.s and log [Ca] was similar to that between log m.e.p.p. frequency and log [Ca].6. Individual nerve terminals varied in both Ca-dependent and Ca-independent fractions of log F; a large Ca-independent portion appears to be associated with a low Ca-dependent portion and vice versa. With large prolonged depolarization the Ca-independent portion was increased, apparently at the expense of the Ca-dependent portion.7. The results of all experiments were summarized in terms of parameters found by fitting the observed log release -log [Ca] curves to two theoretical equations, each derived on the basis of a model: (a) all-or-nothing activation of release probability by Ca-complex(es) and (b) graded activation of release probability by Ca complex(es).8. On the basis of the all-or-nothing model, from which follows alinear relation between F and amounts of Ca complex(es), the number of Ca(2+) atoms that ;cooperate' to mediate release appeared to increase progressively with presynaptic depolarization, to a value of 4 or more with a presynaptic action potential.9. On the basis of the graded activation model, which predicts an exponential relation between F and amount of Ca complex, the number of Ca(2+) atoms that combine with Ca receptor appears to be independent of presynaptic depolarization.10. Various models which could account for the data are discussed. It was concluded that all the data are consistent with a model in which:(i) quantal release probability is continuously graded with the amount of a simple Ca complex (CaX) inside the nerve terminal.(ii) Ca entry is governed by presynaptic membrane potential (increasing exponentially with depolarization) and by the amount of a Ca complex (Ca(2)Y) on or in the membrane.(iii) Mg(2+) competes with Ca(2+) at both receptors, X and Y.(iv) The internal Ca receptor X is also increased by presynaptic depolarization.     

Effects of ionic concentration on sodium permeability properties of myelinated nerve fibres of Xenopus laevis.

1. The nodal currents of single myelinated nerve fibres were recorded under potential clamp conditions, and the effect of [Ca], [Na] and [K] in the external solution on some of the Na permeability properties were analysed. 2. [Ca], [Na] and [K] all affected the position of the steady-state Na inactivation (h) curve on the potential axis. The curve was displaced in positive direction by high ionic concentration. 3. The shift associated to different [Ca] was largest in low [Na] and [K]. Similarly the shift associated to different [Na] and [K] was largest in low [Ca]. 4. The maximum peak sodium permeability (max. peak - PNa) was affected by the [Ca], [Na] and [K]. It was greater in (i) low [Ca], (ii) high ([Na] + [K]) and (iii) high [Na]:[K] ratio. 5. The effect of [Ca] on peak - Na was mainly a consequence of a change in PNa (which is the value of PNa if activation were complete, m = 1, and inactivation fully removed, h = 1).     

Intracellular Mg(2+) hyperpolarizes rabbit coronary artery smooth muscle cells by differential modulation of Ca(2+)(i)-dependent ion channels

We investigated the role of intracellular Mg(2+) ([Mg(2+)](i)) in the regulation of membrane potential ( V(m)) in rabbit coronary artery smooth muscle cells. V(m), membrane currents and intracellular Ca(2+) ([Ca(2+)](i)) were measured using standard patch-clamp and microfluorometry techniques. When [Ca(2+)](i) was increased by caffeine, V(m) depolarized at low [Mg(2+)](i) (0.1 mM), but hyperpolarized at high [Mg(2+)](i) (> or =1.2 mM). Effects of [Mg(2+)](i) on caffeine-induced currents were investigated. [Mg(2+)](i) selectively facilitated the activation of Ca(2+)-activated K(+) currents ( I(K,Ca)), while Ca(2+)-activated Cl(-) currents ( I(Cl,Ca)) were unaffected. Simultaneous recording of [Ca(2+)](i) and I(K,Ca) at different [Mg(2+)](i) showed that [Mg(2+)](i) increased the Ca(2+) sensitivity of I(K,Ca). [Ca(2+)](i) also inhibited voltage-dependent K(+) (K(V)) currents, although this effect was significant only at low [Mg(2+)](i). These results imply that the relative contributions of I(K,Ca), I(Cl,Ca) and K(V) currents to V(m) during an increase in [Ca(2+)](i) are affected by [Mg(2+)](i): at low [Mg(2+)](i), activation of I(Cl,Ca) and inhibition of K(V) currents depolarized V(m); at high [Mg(2+)](i) the activation of I(K,Ca) predominated, resulting in hyperpolarization of V(m). In conclusion, [Mg(2+)](i) hyperpolarizes V(m) by selective facilitation of I(K,Ca) and may thus possibly contributes to the relaxation of the coronary artery.     

A note of the mechanism by which inhibitors of the sodium pump accelerate spontaneous release of transmitter from motor nerve terminals.

1. The actions of 0-1 mM ouabain and of K-free Ringer have been examined at the frog neuromuscular junction. 2. After a delay of more than 30 min, ouabain produces an increase in the miniature end-plate potential (m.e.p.p.) frequency. This increase occurs unchanged in Ca-free Ringer containing 1 mM-EGTA and is therefore unlikely to be due to an entry of Ca into the motor nerve terminals. 3. If the nerve to the preparation is stimulated repetitively in Ca-free Ringer containing 0-1 mM ouabain and 1 mM-EGTA the response of the m.e.p.p. frequency depends on the timing of the tetanus relative to the beginning of the ouabain treatment. 4. During the first 30 min of exposure to ouabain, the tetanus produces a small, transient increase in the m.e.p.p. frequency similar to that which occurs before ouabain is present. After about 30 min the same tetanus produces large, irreversible increases in the m.e.p.p. frequency. 5. Superfusion of an end-plate with K-free Ringer causes an immediate exponential rise in the m.e.p.p. frequency that is unaffected by the presence of external Ca ions. On replacing the normal K of the Ringer (2 mM) the m.e.p.p. frequency recovers quickly to its original value. 6. Late in an exposure to 0-1 mM ouabain the m.e.p.p. frequency becomes extremely sensitive to changes in the external Na concentration, [Na]o. Reducing [Na]o increases the m.e.p.p. frequency. The sensitivity to [Na]o is independent of external Ca ions or whether the isotonic substitute for NaCl is LiCl or sucrose. 7. It is suggested that the spontaneous release of transmitter is facilitated, in some way, by the changes in the monovalent cation content of the nerve terminals that result from blocking the Na-K exchange pump. The Na sensitivity of the m.e.p.p. frequency that develops simultaneously can be explained if a Na-dependent Ca efflux system is present in the membrane of the presynaptic terminals.     

Cumulative and persistent effects of nerve terminal depolarization on transmitter release

1. Following focal depolarization of rat motor nerve terminals there could often be observed an ;after-discharge' of m.e.p.p.s with transient frequencies of up to 1000/sec. This after-discharge was graded with intensity and duration of the previous depolarization.2. Following pulses which were relatively short (about 1 sec) and not too large (< -100 mV local extracellular potential field) the logarithm of m.e.p.p. frequency fell exponentially. With larger or longer pulses there was a tail to the after-discharge which could persist for several minutes.3. M.e.p.p. frequency during an after-discharge was not inhibited appreciably by nerve terminal hyperpolarization, raised [Ca] (8 mM) or lowered pH.4. Measured as a multiplication of spontaneous m.e.p.p. frequency after-discharge was depressed in solution containing no Ca(2+) and added 1 mM-MgEDTA but equal in 0.125 mM-Ca(2+) or 2 mM-Sr(2+) to that in 2 mM-Ca(2+) or 8 mM-Ca(2+).5. During an after-discharge the multiplication of m.e.p.p. frequency by focal nerve terminal depolarization or raised K(+) was reduced. This phenomenon was termed ;uncoupling'.6. It was concluded that the after-discharge is not caused by a persistent rise of K(+) concentration in the synaptic cleft, nor by a maintained nerve terminal depolarization.7. In preparations depolarized by raised K(+) m.e.p.p. frequency during a relatively small focal depolarizing pulse rose continuously, after an initial rapid rise, and after the pulse there was a tail of increased m.e.p.p. frequency. The magnitude of the rise during the pulse and the tail after it were similar on, a logarithmic basis; during both processes the logarithm of m.e.p.p. frequency usually followed (approximately) an exponential time course.8. The relative magnitude of the slow effect of depolarization, as compared with the fast effect, was increased by lowering [Ca] or increasing [Mg], and the slow effect of depolarization in contrast to the fast effect was found to exist in the presence of Ca reduced to about 10(-7)M, but only during pulses. At this [Ca] there was no rapid response to depolarization. At [Ca] about 10(-10)M, there was no response at all of m.e.p.p. frequency to nerve terminal depolarization.9. The results are discussed, and compared with similar data referring to ;facilitation' and ;post-tetanic potentiation'. It is concluded that these and the slow effect of depolarization represent the same phenomenon, a response of the transmitter release system which can be distinguished from the fast response in terms of ionic requirement as well as time course.     

Interaction between sodium and calcium ions in the process of transmitter release at the neuromuscular junction

1. The interaction between Na and Ca ions on quantal transmitter release at the frog neuromuscular junction has been studied, using intracellular recording and averaging of responses.2. At low calcium concentrations, partial withdrawal of Na ions increases end-plate potential (e.p.p.) amplitudes and quantal content (m) and decreases the amplitude of the miniature e.p.p.s (m.e.p.p.s). Under these conditions the relation between [Ca] and m is highly non-linear. When plotted on double logarithmic co-ordinates withdrawal of [Na] causes a nearly parallel shift of this relation.3. Mutual interaction occurs between Ca, Na and Mg in transmitter release. With a constant low [Ca] in the medium, withdrawal of [Na] produces a smaller increase in m when [Mg] is high, than when [Mg] is low.4. In the presence of normal [Ca] (1.8 mM), [Na] withdrawal decreases the amplitude of the e.p.p. and produces a small decrease in m.5. The results can be explained by assuming that [Na] reduction has two mutually opposing effects on transmitter release: it makes more sites available for the action of Ca, and it lowers the amplitude of the action potential in the nerve terminals. The former effect dominates at low, the latter at high, calcium concentrations.     

The effect of calcium ions on the binomial statistic parameters that control acetylcholine release at preganglionic nerve terminals.

1. A study has been made of the effects of changing [Ca]O and [Mg]O on the binomial statistic parameters p and n that control the average quantal content (m) of the excitatory post-synaptic potential (e.p.s.p.) due to acetylcholine release at preganglionic nerve terminals. 2. When [Ca]O was increased in the range from 0-2 to 0-5 mM, p increased as the first power of [Ca]O whereas n increased as the 0-5 power of [Ca]O; when [Mg]O was increased in the range from 5 to 200 mM, p decreased as the first power of [Mg]O whereas n decreased as the 0-5 power of [Mg]O. 3. The increase in quantal release of a test impulse following a conditioning impulse was primarily due to an increase in n; the increase in quantal content of successive e.p.s.p.s in a short train was due to an increase in n and p, and the increase in n was quantitatively described in terms of the accumulation of a Ca-receptor complex in the nerve terminal. 4. The decrease in quantal content of successive e.p.s.p.s during long trains of impulses over several minutes was primarily due to a decrease in n. These results are discussed in terms of an hypothesis concerning the physical basis of n and p in the release process.     

The specific effect of potassium on transmitter release by motor nerve terminals and its inhibition by calcium

1. There exist two distinct effects of potassium on the transmitter release system, one which develops rapidly and another which becomes maximal much more slowly. The fast effect is inhibited by raised Ca(2+), which does not inhibit transmitter release evoked by depolarizing pulses. Thus the fast effect is not secondary to nerve terminal depolarization.2. The fast effect of K(+) was found to consist in an increase in the slope of the linear relation between log m.e.p.p. frequency and nerve terminal depolarization. This effect is complete within a few seconds, is inhibited by raised Ca(2+), and is not produced by prolonged focal or electrotonic depolarization, which instead tends to reduce the slope of log m.e.p.p. frequency vs. depolarization.3. A slope change effect like that of K(+) was not found with ouabain or ethanol, nor did these agents depress the slope change effect of K(+). The specific action of K(+) was not exerted on release evoked in the absence of Ca(2+) by ethanol, chloral hydrate, or raised osmotic pressure.4. It is suggested that the specific action of K(+) is to increase the lability of nerve terminal Ca permeability with respect to depolarization of the nerve terminal membrane, while the slow effect of K(+) simply reflects nerve terminal depolarization, slow to become maximal because of diffusion barriers limiting access of raised K(+) to the Ranvier nodes of motor axons.     

The effect of calcium ions on the binomial statistic parameters which control acetylcholine release at synapses in striated muscle.

A study has been made of the effects of changing [Ca]O and [Mg]O on the binomial statistic parameters p and n which control the average quantal content (m) of the synaptic potential due to acetylcholine release. 2. When [Ca]O was varied in the range 0-1 to 1-0 mM, p increased as the first power of [Ca]O whereas n increased as the third power of [Ca]O. 3. Increasing [Mg]O depressed both p and n, however variations of [Ca]O in the presence of high [Mg]O did not significantly change the power relationship between either p and [Ca]O or between n and [Ca]O. 4. The facilitated increase in m during a short train was due to an increase in n, whereas the post-tetanic increase in m during a tetanus was due to an increase in p. These results are considered in terms of the role of Ca ions in facilitation and post-tetanic potentiation.     

Reciprocal interactions between calcium and chloride in rod photoreceptors

This study used imaging and electrophysiological techniques in salamander retinal slices to correlate Ca2+ and Cl- levels in rods and thus test the hypothesis of a feedback interaction between Ca2+- and Ca2+-activated Cl- channels whereby Cl- efflux through Cl- channels can inhibit Ca2+ channels. Increasing [K+]o levels produced a concentration-dependent depolarization of rods accompanied by increases in [Ca2+]i measured with Fura-2. The voltage dependence of increases in [Ca2+]i was compared with the voltage dependence of the calcium current (ICa). [Cl-]i was measured with the dye, MEQ. Depolarization with high K+ to membrane potentials below -20 mV reduced [Cl-]i; larger depolarizations increased [Cl-]i. The Na/K/Cl cotransport inhibitor, bumetanide, shifted the apparent Cl- equilibrium potential (ECl) to more negative potentials, suggesting that this cotransporter helps establish a relatively depolarized ECl. MEQ fluorescence changes evoked by high K+ were inhibited by niflumic acid (0.1 mM), NPPB (2 microM), or replacement of Ca2+ with Ba2+, suggesting that depolarization-evoked Cl- changes result partly from stimulation of Ca2+-activated Cl- channels. Replacing >/=12 mM [Cl-]o with CH3SO4- produced a significant reduction in [Cl-]i. [Ca2+]i increases evoked by 20 or 50 mM K+ were also significantly inhibited by replacing >/=12 mM [Cl-]o with CH3SO4-. Thus modest depolarization can evoke increases in [Ca2+]i that lead to reductions in [Cl-]i, and conversely, reductions in [Cl-]i inhibit depolarization-evoked [Ca2+]i increases. These findings support the hypothesis that feedback interactions between Ca2+- and Ca2+-activated Cl- channels may contribute to the regulation of presynaptic Ca2+ currents involved in synaptic transmission from rod photoreceptors.     

Effects of calcium and magnesium on the frequency of miniature end-plate potentials during prolonged tetanization

1. End-plate potentials (e.p.p.s) and miniature end-plate potentials (min.e.p.p.s) were recorded intracellularly from the cutaneous pectoris nerve-muscle preparation of the frog during prolonged stimulation at low frequencies (5/sec-50/sec).2. When Ca was present in the bathing solution, the quantum content of the e.p.p. and the frequency of occurrence of the min.e.p.p.s gradually increased during the period of stimulation. During the first few minutes of stimulation, the min.e.p.p. frequency increased linearly with time, and the rate of increase was dependent on the Ca concentration of the bathing solution. However, Mg had no effect on this Ca-dependent increase in min.e.p.p. frequency.3. A large maintained increase in min.e.p.p. frequency also occurred during prolonged stimulation in solutions that contained no added Ca and 1-2 mM-EGTA. Under these conditions the increase in min.e.p.p. frequency was dependent on the Mg concentration of the bathing solution and was exponential in time.4. It is suggested that the rise in min.e.p.p. frequency is caused by an accumulation of Ca or Mg ions in the nerve terminal, and it is suggested that these ions enter the terminal at relatively non-specific sites distinct from the Ca-specific sites that trigger the ;phasic' release of transmitter.     

Co-operative action a calcium ions in transmitter release at the neuromuscular junction

1. The quantitative dependence of transmitter release on external calcium concentration has been studied at the frog neuromuscular junction, using intracellular recording and taking the amplitude of the end-plate potential (e.p.p.) as an index of the number of packets released.2. The relation between [Ca] and the e.p.p. is highly non-linear. The initial part of this relation on double logarithmic co-ordinates gives a straight line with a slope of nearly four (mean 3.78 +/- 0.2 S.D. in 28 experiments). Addition of a constant amount of Mg reduces the e.p.p. without altering the slope of the log e.p.p./log Ca relation.3. The slope of this logarithmic relation diminishes as [Ca] is raised towards the normal level.4. The results are explained quantitatively on the hypothesis that Ca ions combine with a specific site X on the nerve terminal forming CaX, and that the number of packets of acetylcholine released is proportional to the fourth power of [CaX].5. The analysis suggests that a co-operative action of about four calcium ions is necessary for the release of each quantal packet of transmitter by the nerve impulse.     

Transmitter release by mammalian motor nerve terminals in response to focal polarization

1. A method is described by which mammalian motor nerve terminals may be uniformly polarized by focally applied current, and the extra-cellular potential in the synaptic cleft, corresponding to any current, estimated.2. The relationship between log m.e.p.p. frequency and local extra-cellular field is flat for hyperpolarization and ascends linearly with depolarization. With depolarization, m.e.p.p. frequency is multiplied about tenfold for every - 18 mV. This characteristic becomes steeper the closer the polarizing electrode to the nerve terminal with a limiting value of ten-fold per - 15 mV.3. There exists a population of small m.e.p.p.s which are generated at the same end-plate as normal m.e.p.p.s.4. Following a prolonged depolarizing pulse there is an increase of m.e.p.p. frequency which continues for periods of up to several minutes.5. With hyperpolarizing pulses m.e.p.p. frequency may increase in a characteristic ;bursty' manner. Similar bursts of m.e.p.p.s also occur spontaneously, but far less frequently, without polarization.6. During a depolarizing pulse, m.e.p.p. frequency becomes maximal or near maximal within 2 sec. There is little subsequent alteration of m.e.p.p. frequency. Numbers of m.e.p.p.s occurring during depolarizing pulses follow the Poisson distribution.7. Following a depolarizing pulse, numbers of m.e.p.p.s released by a subsequent pulse may be either increased or diminished.8. Comparison of the response of m.e.p.p. frequency to raised [K] and to extrinsic presynaptic polarization leads to the conclusion that the presynaptic transmembrane potential change corresponding to any focal current pulse is about two thirds of the local extracellular potential field. Hence the slope of the linear portion of the presynaptic transfer function is about tenfold per 10 mV presynaptic depolarization.     

Regulation of potassium and magnesium effluxes by external magnesium in barnacle muscle fibres

Fluxes and flux rate constants for potassium and magnesium were measured as a function of ambient magnesium concentration in giant muscle fibres from the acorn barnacle. Experiments were carried out in the absence of both external Na and Ca (to prevent possible effects of these ions), and fibres were depleted of internal Na and Ca by soaking in Na- and Ca-free solution before each experiment. K efflux was biphasic with respect to increases in external Mg concentration [( Mg+2]0). K efflux approximately doubled (from about 63 to 130 pmol/cm2.s) when [Mg+2]0 was increased from 2 to 5 mM; K efflux remained elevated in Mg up to 60 mM. However, at [Mg+2]0 = 120 mM, the stimulatory effect of external Mg vanished, and at 357 mM it was replaced by an inhibitory effect. Mg efflux was also biphasic with respect to [Mg+2]0, and this efflux was matched at low to moderate [Mg+2]0 by Mg influx of comparable magnitude. This study suggests the possible existence of a Mg transport system that can serve variously as a Na/Mg or a Mg/Mg exchanger that may require the participation of K ions for its operation.     

Interacting effects of temperature and extracellular calcium on the spontaneous release of transmitter at the frog neuromuscular junction

1. Temperature has a characteristic effect on the frequency of m.e.p.p.s at the frog neuromuscular junction; the spontaneous release of transmitter is not affected by temperature changes below 10 degrees C whereas the system is highly temperature-sensitive above 20 degrees C.2. A very similar result is obtained when the experiment is repeated in saline containing Ca(2+) buffered at 5 x 10(-7)M, suggesting that it is unlikely that the major action of temperature is to cause an increase in Ca(2+) influx.3. It is suggested that the main effect of temperature at the presynaptic terminals is a modification of [Ca(2+)](i) by an action on intracellular Ca(2+) stores.4. The interacting effects of theophylline and the divalent cation ionophore A23187 on m.e.p.p. frequency suggest that intracellular Ca(2+) stores, in addition to the mitochondria, may well be of importance in controlling [Ca(2+)](i).5. Changes in [Ca(2+)](o) produce a modification of m.e.p.p. frequency, but the details of the response are dependent on temperature. The spontaneous release of transmitter is most sensitive to an increase in [Ca(2+)](o) at 23 degrees C, whereas the greater effect is found at 13 degrees C when [Ca(2+)](o) is lowered.6. It is suggested (i) that m.e.p.p. frequency is primarily determined by [Ca(2+)](i) at the presynaptic terminals, (ii) that the presynaptic terminals are normally able to maintain [Ca(2+)](i) almost constant in spite of increases in Ca influx associated with ionophore treatment or with a rise in [Ca(2+)](o). However, if the steady-state position of [Ca(2+)](i) is previously raised by an increased efflux from intracellular stores (produced by elevated temperature or theophylline pre-treatment), increased influx causes a rise in both [Ca(2+)](i) and in m.e.p.p. frequency.     

Dual effect of external calcium on the frequency of miniature synaptic potentials in frog sympathetic ganglion cells

The effect of calcium on spontaneous transmitter release and on the release induced by tetanic stimulation and by raising the external potassium concentration ([K]0) was studied in sympathetic ganglion cells of Rana esculenta. 1. In standard Ringer's solution the frequency of miniature excitatory postsynaptic potentials (mepsp) ranged from 0.05--2.0 s-1 (0.05 +/- 0.09 s-1, n = 37) at room temperature. 2. At a [K]0 of 2.5 mM mepsp frequency was approximately linearly related to the logarithm of the external calcium concentration (log [Ca]0) (0.1 mM less than or equal to [Ca]0 less than or equal to 20 mM). 3. Duration and amplitude of the potentiation of transmitter release after tetanic preganglionic stimulation increased depending on [Ca]0. 4. Mepsp frequency was strongly dependent on [K]0 between 10 and 20 mM; the frequency being increased to about 40 times control level at a [K]0 of 20 mM. 5. Raising [Ca]0 up to 1.8 mM in high K solutions resulted in an increase in mepsp frequency followed by a decrease at higher [Ca]0. 6. These results are consistent with the idea that the effect of calcium on mepsp frequency depends on: (a) the driving force for calcium entry, (b) the effect of Ca ions on the potential gradient within the nerve membrane.     

On the effect of calcium on the frequency of miniature end-plate potentials at the frog neuromuscular junction.

1. The effect of the extracellular Ca concentration on the frequency of miniature end-plate potentials (min. e.p.p.s) at the frog neuromuscular junction was studied. 2. In saline containing elevated K (5 or 11 mM), the frequency of min. e.p.p.s increased as Ca concentration was increased from 0-1 to 1-3 mM. However, with further increases of Ca concentration up to 10 mM, min. E.P.P. frequency declined. 3. In saline containing the normal concentration of K (2 mM), increasing Ca concentration from 0-1 to 10 mM produced a slight, monotonic increase in min. e.p.p. frequency. 4. The non-monotonic effect of Ca on min. e.p.p. frequency in preparations depolarized by elevated K is consistent with the existence of two opposing effects of Ca on transmitter release. Firstly, raising the external concentration of Ca increases the electrochemical potential for Ca entry, which tends to increase Ca influx and transmitter release. Secondly, increasing external Ca concentration increases electrostatic screening of fixed negative charges on the outer surface of the nerve terminal membrane. Such an increase in screening of charges near voltage-sensitive Ca gates would produce a hyperpolarization across the gates and they would tend to close, an effect which would tend to decrease Ca influx. The monotonic increase in min. e.p.p. frequency with increasing Ca concentration in 2 mM-K is consistent with the voltage insensitivity of the Ca gates at potentials close to the normal resting potential.