Effects of extracellular calcium and calcium channel blocker on silver-induced contractures in frog skeletal muscle fibers

The mechanism by which Ag+ induces muscle contracture was elucidated by investigating the effect of external Ca2+ concentration and Ca2+ channel blocker on the maximum tension amplitude in single fibers from frog toe skeletal muscle. Five microM Ag+ induced two different types of contracture in the presence of external Ca2+ more than 0.1 mM, i.e., a phasic and a subsequent tonic contracture. The phasic contracture appeared only in fibers with intact T-tubules immersed in a solution with or without Ca2+ after a lag time of 5.7 +/- 0.9 s (N = 5). The maximum amplitude was 58% of the tetanus tension observed in the same fiber immediately before Ag+ exposure. Diltiazem at high-concentration (100 microM) inhibited the Ag+-induced phasic contracture only to a small extent (17%). The contracture was not affected by 1 microM TTX or 1 mM DAP at all. These results indicate that Na+, K+, and Ca2+ channels on the T-tubular membrane would not be attributed to the phasic tension development induced by Ag+. On the contrary, a tonic contracture did not require intact T-tubules. The amplitude and the rate of rise of the contracture depended on external Ca2+ concentrations and were inhibited by a high concentration of diltiazem. Neither 1 microM TTX nor 1 mM DAP affected them. Therefore, the tonic contracture seems to be triggered by Ca2+ which entered the muscle fiber through the surface but not T-tubular membranes.     

Effects of external calcium reduction on biphasic potassium contractures and action of divalent cations on the calcium reduction in frog single twitch muscle fibers

The effects of external Ca2+ reduction on the biphasic potassium (K) contractures and the action of divalent cations under conditions of the Ca2+ reduction were examined in detail, using frog single twitch muscle fibers. The peak tension of the initial component of 80 mM K+ contractures was greatly potentiated by exposing the fiber to low Ca2+ solution for 30 sec, and the degree of this potentiation was decreased with increasing the exposing time. In contrast, the peak tension of the secondary component was rapidly inhibited by Ca2+ reduction. The potentiation of the initial component was removed by 3 mM Mg2+ or 0.5 mM Ni2+. The inhibition of the secondary component, especially the shortening of its time course, was reversed partially by 3 mM Mg2+ and almost completely by 0.5 mM Ni2+. The difference between the inhibitory effect of 10 mM Mg2+ or 1-3 mM Ni2+ on the initial component and that on the secondary component was also demonstrated. The tension development of the secondary component was completely inhibited by external Ca2+ reduction for 20 min, but it was observed in the presence of 3 mM Mg2+, although its time course was shorter. These results indicate that the actions of Mg2+ and Ni2+ on the initial component differ from those on the secondary component and suggest the possible mechanisms of the actions of these divalent cations on the biphasic K contractures.     

Effects of divalent cations on biphasic potassium contractures and on contractile inactivation in low calcium solutions in frog single twitch muscle fibers

When the concentration of external Ca2+ was reduced for 30 sec in a single twitch muscle fiber of a frog, the peak tension of the initial component of biphasic 80 mM K+ contractures was potentiated, whereas that of the secondary component was markedly inhibited, despite the fact that in the early stage it was potentiated usually in case of contractures in 60 and 40 nM K+ but rarely in 80 mM K+. These changes were not observed, however, in the presence of 0.5-1 nM Mn2+, i.e., Mn2+ having been substituted for Ca2+. The foregoing result and the authors' previously reported data indicated the following. First, the concentrations of divalent cations having an equal effect in bringing about the peak tensions of both components are 3 mM Mg2+, 0.7 mM Mn2+, 0.5 mM Ni2+, and 1.8 mM Ca2+. Secondly, this sequence constitutes their increasing order of effectiveness on the time course of the secondary component. Meanwhile, a similar order was found to exist in another experiment concerning the effectiveness in inhibiting the inactivation of K contractures facilitated by lowering the concentration of external Ca2+. All these findings indicated that the divalent cations act on the activation processes of both components in a stabilizing manner, differing from the way in which they act on the inactivation process of the secondary component. The mechanisms in which the peak tensions of the initial and secondary components are inhibited in a low Ca2+ solution and the divalent cations act on both components are discussed. Finally, another experiment made in the absence and presence of Ca2+ revealed that the effect of high concentrations of Mn2+ in the initial component is different from that on the secondary component.     

Potency of depolarization-induced transmitter release is determined by divalent cation influx in PC 12 cells.

Evoked release of [3H]dopamine ([3H]DA) from pheochromocytoma cells (PC 12) is dependent on extracellular calcium ([Ca2+]ex), but it can take place if calcium ions (Ca2+) are substituted by other divalent ions such as strontium (Sr2+) and barium (Ba2+). The potency of the divalent cations at supporting release varies with the cell type; in PC 12 cells the order of potency is Ba2+ > Sr2+ > Ca2+. The close correlation between depolarization-evoked Ca2+ entry and depolarization-evoked transmitter release prompted us to examine whether the higher evoked transmitter release in the presence of Sr2+ correlates with an increased evoked Sr2+ influx. Influx studies were conducted on PC12 cells using a radioactive tracer (45Ca2+ or 85Sr2+, < 1 microM) in the presence of either Sr2+ (0.5 mM) or Ca2+ (0.5 mM). Depolarization with K Cl (60 mM) increased evoked 45Ca2+ influx 2-fold when Ca2+ was substituted with Sr2+. Similarly, evoked 85Sr2+ influx increased 1.87-fold by substituting Ca2+ for Sr2+. Thus the amount of evoked cation influx is determined by the type of divalent ion which is accessible in the extracellular medium, independently of the radioactive tracer used. Increased evoked transmitter release in the presence of Sr2+ was associated with increased evoked Sr2+ influx. This suggests that the potency of evoked transmitter release is determined predominantly by the influx of divalent cations. Furthermore, the steps subsequent to cation influx in the release process are equally efficient for both cations.     

Aconitine-induced delayed afterdepolarization in frog atrium and guinea pig papillary muscles in the presence of low concentrations of Ca2+

Aconitine will induce arrhythmias after the fiber has been completely repolarized. This arrhythmia is generally facilitated in the presence of high Ca2+ solution, yet the aconitine-induced arrhythmia occurs even in the presence of low Ca2+ solutions. We studied aconitine-induced arrhythmia (particularly the amplitude of delayed afterdepolarization) in the frog atrium or guinea-pig papillary muscles in Ca2+-free solution, in the presence or absence of Ca2+ channel blocking agents. In Ca2+-free solution, aconitine (10(-5) g/ml) decreased the resting potential, overshoot, Vmax, and shortened the duration of the 90% action potential, before the onset of delayed afterdepolarization in frog atrial preparations. Tetrodotoxin (TTX) (2 X 10(-7) g/ml) blocked these aconitine-induced electrical changes. Verapamil (10(-6) g/ml) in nominally Ca2+-free solution blocked neither the generation of delayed afterdepolarization nor the triggered activity, while LaCl3 (0.5 mM) or TTX halted it. Delayed afterdepolarization appeared following the aconitine-induced transient increase in twitch tension. This transient increase in twitch tension was blocked by LaCl3 and TTX but not by verapamil. Delayed afterdepolarization in Ca2+-free solution demonstrated the voltage dependence of a U shape between -40 and -80 mV and was inhibited by low Na+ and high K+. Under the influence of aconitine in the guinea pig papillary muscle exposed to the Ca2+-free solution, depolarizing clamp pulses produced a transient inward current, and here the sigmoid time- and voltage-dependent characteristics were similar to those seen in the case of digitalis intoxication. These results suggest that intracellular Na+ loading plays an important role in the aconitine-induced delayed afterdepolarization and transient inward currents in low Ca2+ solution.     

Ruthenium red and magnesium ion partially inhibit silver ion-induced release of calcium from sarcoplasmic reticulum of frog skeletal muscles

Effects of Ca2+-induced Ca2+ release blockers, ruthenium red (RR) and Mg2+, on Ag+-induced Ca2+ release were studied using skinned muscle fibers or fragmented heavy SR (HSR) prepared from frog muscle, and compared with those on caffeine-induced one. Exposure of the skinned fibers to 5 microM Ag+ produced a rapid and large contraction in the presence of 0.043 mM free Mg2+. When Mg2+ concentration was increased to 0.86 mM, Ag+ led to a large transient contraction, combined with a small tonic one. The transient component was completely blocked by high Mg2+ (3.64 mM), but the tonic one was not. Ca2+-ATPase activity was not stimulated by increase of Mg2+ from 0.86 to 3.64 mM. Ag+ and caffeine induced a rapid Ca2+ efflux from HSR in a dose-dependent manner. RR over a range from 1 to 10 microM dose-dependently inhibited the Ca2+ efflux induced by 10 microM Ag+. Despite increase of RR to 30 microM, however, further inhibition of the Ca2+ efflux was not produced any more (77.8 +/- 12.2% inhibition). A 10 mM caffeine-induced efflux of Ca2+ was blocked slightly by only 0.5 microM RR and almost completely by 3 microM. A slight inhibition (about 28%) of the Ca2+-ATPase activity was observed in the presence of 10 microM Ag+ in 0.5 mg SR protein/ml of medium. RR and caffeine did not affect the enzyme activity. These results indicate that frog SR could induce a rapid release of Ca2+ upon Ag+ and caffeine, suggesting that Ag+ may have two different binding sites to release Ca2+; one is on Ca2+-induced Ca2+ release channel and the other on RR-insensitive site.     

Differential effects of divalent cations on spontaneous and evoked glycine release from spinal interneurons

The effects of Ca2+, Sr2+, and Ba2+ on spontaneous and evoked glycinergic inhibitory postsynaptic currents (mIPSCs and eIPSCs) were studied using the "synaptic bouton" preparation of rat spinal neurons and conventional whole cell recording under voltage-clamp conditions. In response to application of Ca2+-free solution, the frequency of mIPSC initially rapidly decreased to 40 approximately 50% of control followed by a gradual further decline in mIPSC frequency to approximately 30% of control. Once mIPSC frequency had significantly decreased in Ca2+-free solution, application of Ca2+, Sr2+, or Ba2+ increased mIPSC frequency. The rank order of effect in restoring mIPSCs was Ba2+>Ca2+>Sr2+. Moreover, the application of excess external [K+]o solution (30 mM) containing Sr2+ or Ba2+ after 2 h in Ca2+-free solution also increased mIPSC frequency in the order Sr2+>or==Ba2+>Ca2+. The mean mIPSC amplitude was not affected at all. In contrast, eIPSCs produced by focal stimulation of single boutons were completely abolished in Ca2+-free solution or when Ca2+ was replaced by Sr2+ or Ba2+ (2 mM each). However, eIPSCs were restored in increased concentrations of Sr2+ or Ba2+ (5 mM each). The results show that these divalent cations affect mIPSC and eIPSCs differently and indicate that the mechanisms underlying transmitter release that generates eIPSCs and mIPSC in presynaptic nerve terminals are different. The different mechanisms might be explained by the different sensitivity of synaptotagmin isoforms to Ca2+, Sr2+, and Ba2+.     

Rat hippocampal neurons in culture: Ca2+ and Ca2+-dependent K+ conductances

Rat hippocampal neurons grown in dissociated cell culture were studied in a medium containing 1 microM tetrodotoxin (TTX) and 25 mM tetraethylammonium (TEA), which eliminated the Na+ and K+ conductances normally activated by depolarizing current injections. In this medium depolarizing current pulses evoked depolarizing regenerative potentials and afterhyperpolarizations in most cells. Both of these events were blocked by close application of Co2+ or Cd2+. These events resemble Ca2+ spikes reported previously in hippocampal pyramidal cells. The membrane potential at which these Ca2+ spikes could be triggered and the rheobase current necessary were dependent on the potential at which the cell was conditioned: the more depolarized the holding potential, the more negative the absolute potential at which a spike could be triggered and the less rheobase current required. The duration of these Ca2+ spikes was also sensitive to the holding potential: the more depolarized the holding level, the longer the duration of the triggered spikes. The amplitude and duration of the Ca2+ spikes were enhanced in a reversible manner by 0.5-1.0 mM 4-aminopyridine (4-AP) delivered in the vicinity of the cell. Two-electrode voltage-clamp analysis of cells studied in TTX, TEA-containing medium revealed an inward current response that peaked in 25-50 ms during depolarizing commands. This response first became detectable during commands to -30 mV. It peaked in amplitude during commands to -10 mV and was enhanced in medium containing elevated [Ca2+]0. It was blocked by either 20 mM Mg2+, 0.2 mM Cd2+, 5 mM Co2+, or 5 mM Mn2+. These results have led us to identify this inward current response as ICa2+. 4-AP enhanced the magnitude and duration of ICa2+ independent of the drug's depressant effects on a transient K+ current also observed under these same experimental conditions. In many but not all cells the Ca2+ spike was followed by a long-lasting hyperpolarization associated with an increase in membrane conductance. This was blocked by Co2+. Under voltage clamp ICa2+ was followed by a slowly developing outward current response that was attenuated by Co2+ or Cd2+. These properties observed under current- and voltage-clamp recording conditions are superficially similar to those previously reported for Ca2+-dependent K+ conductance mechanisms (IC) recorded in these and other membranes. Long-lasting tail currents following activation of IC inverted in the membrane potential range for the K+ equilibrium potential found in these cells.     

The effects of Ni2+ on ionic currents and tension generation in frog ventricular muscle

The effect of Ni2+ on E-C coupling events of the frog ventricular muscle were studied using a single sucrose gap voltage clamp technique. The results showed that Ni2+ increased the overshoot potential and depressed and prolonged the plateau of the action potential. Ni2+ also increased the dependence of the overshoot potential on [Na]0 from 18 to 58 mV per decade. In the presence of Ni2+, TTX blocked both the upstroke and the plateau of the action potential. The combination of TTX and Ni2+ suppressed the tension-voltage relation, the time-dependent outward currents and K+ efflux. While suppression of the tension-voltage relation by Ni2+ alone was reversed by increasing [Ca]0, the effects of Ni2+ plus TTX are not reversed by addition of Ca2+. The results suggest that Ni2+ may alter the action potential by slowing the inactivation of the Na+ current and blocking the inward Ca2+ current. Although the tension-suppressant effects of Ni2+ could be attributed to the inhibition of a slowly inactivating Ca2+ current, the effects of Ni2+ in the presence of TTX were less readily explained. Several possible mechanisms are considered which are all consistent with the hypothesis that development of tension in ventricular strips is mediated by both a Ca2+ current and a Ca2+ counter-transport system.     

Intracellular calcium mobilization by muscarinic receptors is regulated by micromolar concentrations of external Ca2+

Carbachol-induced contractions of rat stomach fundus strips, obtained in a nutrient solution containing 1.8 mM Ca2+, were resistant to Ca2+ withdrawal, even after 1 h of bathing the tissues in a nominal 0 Ca2+ solution. This was not observed when K+ was used to evoke contractions, which were rapidly inhibited after Ca2+ removal (t1/2=2 min). The effect of carbachol in 0 Ca2+ solution was reduced by using drugs that reduce intracellular pools of Ca2+, such as caffeine (1-3 mM), ryanodine (30 microM) or thapsigargin (1 microM), corroborating the involvement of intracellular Ca2+ stores. On the other hand, when the 0 Ca2+ solution contained EGTA, a complete decline of carbachol effects was observed within about 8 min, indicating the involvement of extracellular Ca2+. Atomic absorption spectrometry showed that our 0 Ca2+ solution still contained 45 microM Ca2+, which was drastically reduced to 5.9 nM in the presence of EGTA. Taken together, our results indicate that the effects of carbachol are due to the mobilization of caffeine-, ryanodine- and thapsigargin-sensitive intracellular Ca2+ stores, and that these stores are not inactivated or depleted if micromolar concentrations (45 microM), but not nanomolar concentrations (5.9 nM) of Ca2+ are maintained in the extracellular milieu.     

Cyclic AMP-mediated inhibition of noradrenaline-induced contraction and Ca2+ influx in guinea-pig vas deferens

The relaxation effects of forskolin and methylxanthines on noradrenaline (NA)-induced contractions were investigated by measuring isotonic contraction and intracellular calcium concentration ([Ca2+]i) in the epididymal side of guinea-pig vas deferens. NA (100 microM) and high K+ (55 mM) induced a biphasic contraction; fast, transient (phasic) and slow, sustained (tonic) phases. Both phases in either NA or high K+ stimulation were abolished in Ca2+-free solution. Pretreatment with 10 microM nifedipine, an L-type Ca2+ channel blocker, reduced both phasic and tonic contractions induced by high K+. In the case of NA-induced contraction, however, nifedipine reduced the phasic contraction but not the tonic contraction. The nifedipine-insensitive tonic contraction was relaxed by the application of polyvalent cations (Mn2+, Co2+, Cd2+ and La3+). These findings indicate that NA-induced biphasic contraction is mainly due to nifedipine-insensitive Ca2+ influx, especially in the tonic phase. Cyclic AMP-increasing agents such as forskolin (0.5-10 microM), IBMX (5-500 microM) and caffeine (1-20 mM) relaxed the NA-induced contraction extensively in a concentration-dependent manner. However, these agents only partially relaxed the high K+-induced contraction. Forskolin (10 microM) and IBMX (100 microM) reduced the [Ca2+]i response to NA, but had no effect on the [Ca2+]i response to high K+. These results suggest that an increase in intracellular cAMP may relax the NA-induced contraction by attenuating a nifedipine-insensitive Ca2+ influx and by a mechanism independent of a reduction in [Ca2+]i.     

Influences of pressure-injected cyclic AMP on the membrane current and characteristics of an identified neuron of Aplysia kurodai

The ionic mechanism of the effect of intracellularly injected adenosine 3',5'-cyclic monophosphate (cAMP) on the membrane of identified neuron L5 of Aplysia kurodai was investigated with conventional voltage-clamp and ion-substitution techniques. The intracellular elevation of cAMP caused an inward current (IcAMP), which was not accompanied by a significant change in membrane conductance at potentials more hyperpolarized than -60 mV. The current increased over the voltage range (-50 to -30 mV) associated with a conductance decrease and decreased at potentials more hyperpolarized than -60 mV. Elevated intracellular cAMP was found to enhance a region of negative slope resistance in steady-state I-V relations. Duration of the IcAMP was greatly prolonged by bath-applied isobutylmethylxanthine (50 microM), but imidazole (10 mM) had an opposite effect on the IcAMP. Tolbutamide (5 mM), a protein kinase inhibitor, reduced the IcAMP. The current was not affected by the presence of bath-applied TTX (50 microM), ouabain (50 microM), or triaminopyrimidine (5 mM). Reduction of [Na+]0 reversibly decreased the IcAMP. Li+ could largely substitute for Na+. Alterations of [K+]0, and bath application of 4-AP (5 mM) and TEA (30 mM) did not affect the IcAMP. In the presence of Na+, Cl-, and divalent cations such as Ca2+ and Ba2+ inhibited the IcAMP. These results suggest that fast elevation of intracellular cAMP induces a TTX-resistant slow Na+ inward current, and the current might be due to activation of cAMP-dependent protein kinase.     

Selective inhibition of transient K+ current by La3+ in crab peptide-secretory neurons

Although divalent cations and lanthides are well-known inhibitors of voltage-dependent Ca2+ currents (ICa), their ability to selectively inhibit a voltage-gated K+ current is less widely documented. We report that La3+ inhibits the transient K+ current (IA) of crab (Cardisoma carnifex) neurosecretory cells at ED50 approximately 5 microM, similar to that blocking ICa, without effecting the delayed rectifier K+ current (IK). Neurons were dissociated from the major crustacean neuroendocrine system, the X-organ-sinus gland, plated in defined medium, and recorded by whole cell patch clamp after 1-2 days in culture. The bath saline included 0.5 microM TTX and 0.5 mM CdCl2 to eliminate inward currents. Responses to depolarizing steps from a holding potential of -40 mV represented primarily IK. They were unchanged by La3+ up to 500 microM. Currents from -80 mV in the presence of 20 mM TEA were shown to represent primarily IA. La3+ (with TEA) reduced IA and maximum conductance (GA) by approximately 10% for 1 microM and another 10% each in 10 and 100 microM La3+. Normalized GA-V curves were well fit with a single Boltzmann function, with V1/2 +4 mV and slope 15 mV in control; V1/2 was successively approximately 15 mV depolarized and slope increased approximately 2 mV for each of these La3+ concentrations. Cd2+ (1 mM), Zn2+ (200 microM), and Pb2+ (100 microM) or removal of saline Mg2+ (26 mM) had little or no effect on IA. Steady-state inactivation showed similar right shifts (from V1/2 -39 mV) and slope increases (from 2.5 mV) in 10 and 100 microM La3+. Time to peak IA was slowed in 10 and 100 microM La3+, whereas curves of normalized time constants of initial decay from peak IA versus Vc were right-shifted successively approximately 15 mV for the three La3+ concentrations. The observations were fitted by a Woodhull-type model postulating a La3+-selective site that lies 0.26-0.34 of the distance across the membrane electric field, and both block of K+ movement and interaction with voltage-gating mechanisms; block can be relieved by depolarization and/or outward current. The observation of selective inhibition of IA by micromolar La3+ raises concerns about its use in studies of ICa to evaluate contamination by outward current.     

The effect of alpha-latrotoxin on the neurosecretory PC12 cell line: studies on toxin binding and stimulation of transmitter release

alpha-Latrotoxin of black widow spider venom was found to bind with high affinity (KA = 1.8 X 10(9)M-1) to specific sites present in discrete number (approximately 6300/cell, approximately 12/micron2) at the surface membrane of PC12 cells. This binding correlated with (and therefore, probably caused) the secretory response produced by the toxin. Binding was enhanced (approximately 2-fold) in the presence of mM concentrations of various divalent cations (Ca2+, Mn2+ and Co2+) while Ba2+ and Sr2+ had a smaller effect and Mg2+ was inactive. Hypertonicity, concanavalin A and trypsin pretreatment of the cells blocked the binding interaction. The alpha-latrotoxin-induced stimulation of 3H-dopamine release was massive and occurred very rapidly when cells were exposed to the toxin in a Ca2+-containing Krebs-Ringer medium, whereas it occurred at a much slower rate in a Ca2+-free, Mg2+-containing Ringer. Introduction of Ca2+ into the latter medium resulted in a shift of the release rate from slow to fast. In contrast, in divalent cation-free medium the response was abolished. The toxin-induced secretory response was unaffected by Na+ and Ca2+ channel blockers (tetrodotoxin and D600) as well as by calmodulin inhibitors (calmidazolium and trifluoperazine). The effects of Ca2+ and Mg2+ were found to be concentration-dependent, with half maximal responses occurring at approximately 0.3 and 1.5 mM for the two divalent cations, respectively. Other divalent cations could substitute for Ca2+ and Mg2+, the relative efficacy being Sr2+ greater than Ca2+ greater than Ba2+ much greater than Mn2+ greater than Mg2+ greater than Co2+. Moreover, the response occurring at suboptimal concentration of Ca2+ (0.4 mM) was potentiated by the concomitant addition of either Mg2+, Mn2+ or Co2+. The effect(s) of divalent cations in supporting the alpha-latrotoxin-induced release response seem(s) to occur primarily at step(s) beyond toxin binding because (a) the stimulatory effects of the various cations on release were not matched by parallel effects on binding, and (b) Ca2+ maintained its ability to stimulate fast release even when toxin binding had occurred in a Ca2+-free medium. Delays in the release responses were observed when cells were exposed to alpha LTx in Na+-free, glucosamine or methylamine-based media, or depolarized with high K+ (in the presence of D600) before toxin treatment. Moreover, in these two conditions the ability of Mg2+ to support the alpha LTx response was considerably decreased.(ABSTRACT TRUNCATED AT 400 WORDS)     

Spontaneous and secretagogue-induced changes in cytosolic free Ca concentration measured by microfluorimetry with fura-2 on single bovine adrenal chromaffin cells

The concentration of cytosolic Ca2+ ([Ca]in) was examined in single bovine adrenal chromaffin cells by monitoring fura-2 fluorescence with microspectrofluorimetry. To see the correlation between [Ca]in and secretion, we also measured the rates of catecholamine (CA) secretion and 45Ca efflux from populations of cells. [Ca]in was constant in the majority of single cells, but the small oscillatory changes in [Ca]in were observed in a population of cells. These spontaneous Ca oscillations, when observed, disappeared either after removal of extracellular Ca2+ or by addition of D-600 or Mn2+, but still persisted in the presence of tetrodotoxin (TTX) or after removal of extracellular Na+. In the silent cells the Ca fluctuations were often induced by Bay-K-8644. The characteristics of Bay-K-8644-induced Ca fluctuations were very similar to those of spontaneous ones. Low concentrations of nicotine (1 microM), acetylcholine (ACh; 1-2 microM), or KCl (12.5 mM) often induced oscillations riding on a steady rise in [Ca]in. These changes were rapidly suppressed by removal of either extracellular Ca2+ or Na+, or by addition of either D-600 (methoxyverapamil) or TTX. A low concentration of ACh (1 microM) or KCl (12.5 mM) also increased the rate of 45Ca efflux, but substantial secretion was not detected. On the other hand, the sustained rise in [Ca]in was evoked by 0.1 mM ACh, 20 microM nicotine, or 30 mM KCl, which was suppressed by removal of extracellular Ca2+, but was little affected by TTX. A sustained increase in 45Ca efflux upon exposure to ACh was observed, possibly reflecting the sustained rise in [Ca]in. ACh also stimulated CA secretion, which was faded out during the prolonged application. Veratridine, a Na channel activator, caused repetitive sequence of Ca transients followed by a sustained rise in [Ca]in. These results, together with the previous electrophysiological findings, suggest that: (1) the spontaneous Ca fluctuations are closely associated with occurrence of spontaneous Ca2+ and Na+ action potentials; (2) the rise in [Ca]in induced by a low concentration of nicotinic agonists of KCl is mediated by Na+ action potentials as well as gradual membrane depolarizations; (3) the oscillatory changes subsequent to a rise in [Ca]in reflect fluctuations in Ca2+ influx through the Ca2+ channels; (4) the critical [Ca]in needs to be attained before the CA secretion takes place.     

The receptive mechanism of various metallic ions in the lateral-line organ of the tadpoles of Rana catesbeiana.

The stimulating effect on the receptor organ of various mono-and divalent metallic ions on the lateral-line nerve of tadpoles was studied. The orders of the effectiveness were Ag + greater than T1+ greater than K+==Na+ greater than Li for monovalent ions and Sr2+ greater than Mg2+ greater than or equal too Ba2+ greater than Cd2+ greater than or equal too Co2+ greater than Mn2+ greater than Zn2+ for divalent ions. Both agree well with the order of Pearson's softness parameter for monovalent ions and Edwards' modified parameter for divalent ones. All sorts of divalent cations exhibited suppressive effects on the stimulating effect of the monovalent cations when they were applied together with the monovalent cations. A simple selection rule was found for the suppressive effect. The stimulating effect of Na+ or K+ was suppressed by all sorts of divalent cations. But the effect of Ag+ was suppressed by Cd2+, but not by Mg2+ nor by Ca2+. In order to remove the Ag+ effect, a dilute solution of DTT was used, although the effect of K+ or Na+ was removed easily by rinsing with distilled water. From these results the receptive mechanism of the endorgan was thought to be chemical adsorption of ions in the receptor cell membrane. Based on the principle of "hard and soft acid and base", it is suggested that there are two types of binding sites for the ions on the membrane, a soft site and a hard one.     

Effects of cations on Helicobacter pylori urease activity, release, and stability.

The urease of Helicobacter pylori is an important antigen and appears critical for colonization and virulence. Several studies have indicated a superficial localization for the H. pylori urease, and the purpose of this study was to determine the effects of cations on the release and stability of urease activity from H. pylori cells. Incubation of partially purified H. pylori urease in water containing 1, 5, or 10 mM Ca2+, Mg2+, K+, Na+, EDTA, or EGTA [ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid] had little effect on activity. In contrast, 1 mM Fe3+, Cu2+, Co2+, or Zn2+ substantially (> 80%) inhibited activity, and 10 mM Fe2+, Mn2+, and Ni2+ inhibited about 30% of the activity. Addition of Ca2+ or Mg2+ markedly decreased extraction of urease from intact H. pylori cells by water, but 1 mM Na+, K+, EGTA, or EDTA each had minimal effects on release, suggesting that divalent cations have a role in attachment of urease to H. pylori cells. The stability of enzymatic activity at 4 degrees C was enhanced by addition of glycerol or 2-mercaptoethanol; however, even after loss of activity, full antigenicity for human serum was retained.     

Influence of divalent cations on potassium contracture duration in frog muscle fibres

Single fibres or small fibre bundles were dissected from twitch muscles of frogs and washed in low Cl-solutions. Contractures were provoked by 122.5 mM K⁺. At room temperature (17–20° C) the contracture duration was about 1.5 s in the absence of divalent cations and about 3 s in the presence of 2 mM Ca²⁺. Contractures were prolonged when Ca²⁺ was replaced by Ni²⁺ showing that inward Ca current was not the factor responsible for the contracture prolongation. K contracture duration was prolonged in the cold (3° C) by a factor of about 4 in the presence of non-permeating divalent cations (Ni, Co), when 0.1 mM La³⁺ was applied together with 2 mM Ca²⁺, and in the virtual absence of divalent cations. The contractures were prolonged in the cold by a factor of 6 or more in the presence of permeant divalent cations (Ca, Sr, Ba, Mg, and Mn at 8 mM). Diffusion of divalent cations in the transverse tubules of the muscle fibres was shown to have a Q₁₀ similar to that in free solution. It was concluded that inward current of divalent cations may shorten contracture duration by causing ionic depletion of the transverse tubules.     

Increase in passive tension of spontaneously beating atria in hyperosmolar media.

Spontaneously beating rabbit atria were used for study of increases in passive tension induced by hyperosmolar Tyrode bathing media. The time course and degree of passive tension change was dependent on the level of osmolality and the osmotic agent used. The effectiveness of various agents added to Tyrode solution in increasing resting tension was in the order sucrose greater than mannitol greater than or equal to NaCl greater than glucose greater than = no change. The hyperosmotically induced "contracture" was similar to contracture induced by high Ca2+ medium, but the maximum hyperosmotic effect was greater than that of high Ca2+. In contrast to active atria, inactive atria showed no increase in passive tension in hyperosmotic solutions or in Tyrode solution containing high Ca2+. After depolarization with Tyrode medium containing high K+ or zero K+, increased Ca2+ caused contracture in inactive left atria greater than that caused by hyperosmotic media (+200 mM sucrose) in active right atria or atrial pairs. Results of the study indicate that although other factors may be involved, increased Ca2+ flux inward could largely account for the passive tension response.     

Inhibitory effects of cations on the Ca2+ response of water fibers in the frog tongue.

The effects of various cations on water fibers in the frog (Rana catesbeiana) tongue were investigated. The following results were obtained. 1. Water fibers responded well to Ca2+ and Sr2+. 2. SO2-(4) did not inhibit the Ca2+ response. Cl- at high concentrations had an inhibitory effect on the response to high Ca2+ stimulation. However, when the Ca2+ concentration was low, Cl- did not induce any inhibition. Therefore, low Ca2+ stimulation (0.1 mM CaCl2) was used to examine the inhibitory effect of cation. 3. MgCl2 and MgSO4 strongly inhibited the response to low Ca2+ stimulation. The inhibition by Mg salts was not caused by anion but by Mg2+. 4. The Ca2+ response was inhibited by various cations. The order of the inhibitory effects of cations was as follows: La3+ greater than Mn2+ = Mg2+ greater than or equal to Ni2+ greater than Co2+ greater than monovalent cations (Na+, K+, NH4+ and choline+). 5. The Sr2+ response, as well as the Ca2+ response, was inhibited by Na+ and Mg2+.