A new class of calcium channels activated by glucose in human pancreatic beta-cells

Single calcium-channel currents were recorded from membrane patches of cultured beta-cells dissociated from human islets of Langerhans. In the absence of exogenous glucose, low frequency spontaneous calcium-channel openings of small amplitude (-0.34 +/- 0.02 pA at 0 mV pipet potential) were observed in all membrane patches examined (25 mM Ca2+ in the patch pipet). The frequency of channel openings was rather insensitive to the membrane potential across the patch (range from ca 0 to 60 mV pipet potential; chord conductance 4.9 +/- 0.2 pS). Addition of glucose induced a dose-dependent increase in the frequency of openings of the Ca2(+)-channel (from now on referred to as the CaG-channel). A few minutes after the addition of glucose (greater than or equal to 11 mM), bursts of action potentials were often observed which were elicited only if Ca2+ was present in the solution bathing the beta-cells. Application of glucose in the presence of mannoheptulose (11 mM), a blocker of the hexokinase controlling the first stage of glycolysis, had no effect and the activity of the CaG-channel remained at its resting level. The readily permeant mitochondrial substrate 2-keto-isocaproate (KIC, 10 mM) was as effective as glucose in eliciting action potentials from cells forming part of cell aggregates. The activity of the CaG-channel was significantly increased by KIC (11 mM). Although spike and Ca2(+)-channel activity were markedly stimulated by glucose or KIC in all cells examined, regular bursts of action potentials were seen only if the patch was formed on beta-cells which were part of a cell aggregate. Mannoheptulose (11 mM) prevented the activation of the CaG-channel by glucose (11 mM) but not by KIC (11 mM). Once activated, the CaG-channel remained active even after excision of the patch. We propose that the physiological control of this Ca2(+)-channel is mediated by one or more products of glucose metabolism.

Quinine blocks the high conductance, calcium-activated potassium channel in rat pancreatic beta-cells

The [Ca2+]i-activated K+-channel, one of the 3 K+ -channels described in pancreatic beta-cells, is a high conductance, voltage-dependent K+-channel. Quinine, known to block [Ca2+]i-activated K(+)-channels in other cells, has been described to block the silent phase between the bursts of glucose-evoked electrical activity in mouse pancreatic beta-cells, and to inhibit K+ efflux from rat pancreatic islets. We report here that quinine blocks the [Ca2+]i-activated K(+)-channel in rat pancreatic beta-cells from the external side of the membrane. We also show that the blockade is characterized by fast flickering of the K(+)-channel between the open and closed state. Mean open and closed times within bursts were found to be exponentially distributed, suggesting that the blockade by quinine involves obstruction on the K(+) flow through the open to be exponentially distributed, suggesting that the blockade by quinine involves obstruction on the K+ flow through the open channel.

Effects of calcium and Bay K-8644 on calcium currents in adrenal medullary chromaffin cells

The kinetic and steady-state characteristics of calcium currents in cultured bovine adrenal chromaffin cells were analyzed by the patch-clamp technique. Whole cell inward Ca2+ currents, recorded in the presence of either 5.2 or 2.6 mM Ca2+ exhibited a single, noninactivating component. To analyze the effects of Ca2+ and Bay K-8644 on the kinetics of the Ca2+ currents, we used a modified version of the Hodgkin-Huxley empirical model. At physiological [Ca2+] (2.5 mM) the midpoint of the steady-state Ca2(+)-channel activation curve lay at -6.9 mV. Increasing the [Ca2+] to 5.2 mM shifted the midpoint by -4.3 mV along the voltage axis. At the midpoint, changes in potential of 7.8 mV (for 5.2 mM Ca2+) and 9.2 mV (for 2.5 mM Ca2+) induced an e-fold change in the activation of the current. Increasing [Ca2+]o from 2.5 to 5.2 mM induced a marked increase in the rate constant for turning on the Ca2+ permeability. Conductances were estimated from the slope of the linear part of the current-voltage relationships as 8.7 and 4.2 nS in the presence of 5.2 and 2.5 mM Ca2+, respectively. Incubation of the cells in the presence of Bay K-8644 at increasing concentrations from 0.001 to 0.1 microM increased the slope conductance from 4.2 to 9.6 nS. Further increases in the concentration of Bay K-8644 from 1 to 100 microM induced a marked reduction in the conductance to 1.1 nS. In the presence of Bay K-8644 (0.1 microM) the midpoint of the activation curve was shifted by 6.1 mV towards more negative potentials, i.e., from -6.9 to -13 mV. At the midpoint potential of -13 mV, a change in potential of 6.9 mV caused an e-fold change in Ca2+ permeability. The kinetic analysis showed that Bay K-8644 significantly reduced the size of the rate constant for turning off the Ca2+ permeability.

Characteristics of two types of calcium channels in rat pituitary gonadotrophs

The properties of Ca2+ channels in cultured rat pituitary gonadotrophs were analyzed by the patch-clamp technique. The inward Ca2+ currents, recorded in the presence of 5.2 mM Ca2+ or Ba2+, included a fast, transient component with activation-inactivation kinetics and a delayed component with slower activation. The midpoint of the activation curve lay at -30 mV for the transient component and at -12 mV for the delayed component. At the midpoint, changes in potential of 9.5 and 13 mV induced an e-fold change in the activation of the transient and delayed components, respectively. The rate of inactivation of the first component was strongly voltage dependent. At -43 mV, a 7.4-mV change in potential induced an e-fold change in the fraction of Ca2+ channels available to conduct Ca2+ current. During long-lasting (100-200 ms) low-frequency depolarizing voltage-clamp pulses, the size of the delayed component of the Ca2+ current remained constant. The differential effects of membrane potential on inactivation and the different time constants for activation of the two components of the Ca2+ conductance indicate the presence of two types of Ca2+ channels in the membrane of the gonadotroph: the rapidly inactivating current appears to be attributable to a T-type channel, and the noninactivating current corresponds to the L-type channel described in many other cell types.

[Evaluation of social functioning in patients at a health center]

The Social Functioning Scale (SFS) is described, together with its rationale and development. The instrument consists of 35 items, and was administered to a sample of 320 adult patients of a health center. Social functioning is assessed in a semistructured, 30 minute interview. The patient reports the level of satisfaction related to his/her role performance in five major areas: occupational, social relationships, economic, marital and familiar. Reliability and validity have been established for the SFS. The reliability coefficients for all areas were over 0.80 (p = 0.01). A varimax factor analysis was applied and five factors emerged for the construct validity. This accounted for 52 percent of the total variance. The use of the SFS is recommended since its validity and reliability have been demonstrated. The instrument could be useful for Mexico, and also for other Spanish speaking countries.

Desensitization of pituitary gonadotropin secretion by agonist-induced inactivation of voltage-sensitive calcium channels

Gonadotropin-releasing hormone (GnRH) stimulates calcium mobilization and influx in pituitary gonadotrophs, and agonist-induced calcium entry through voltage-sensitive channels (VSCC) is required for the maintenance of gonadotropin secretion. However, prolonged or frequent exposure to GnRH attenuates the extracellular Ca2+-dependent cytosolic Ca2+ signal and diminishes hormone secretion. Measurements of membrane Ca2+ currents revealed significant impairment of VSCC activity in gonadotrophs during desensitization by GnRH. VSSC were also inactivated in a calcium-dependent manner during exposure to high K+. Prolonged inactivation of such Ca2+ channels by high K+ reduced the calcium and secretory responses to GnRH and vice versa. The calcium-dependent inactivation of VSCC during GnRH action appears to be a primary factor in the onset of desensitization in pituitary gonadotrophs. This mechanism could also account for the development of agonist-induced refractoriness in other calcium-regulated target cells.

Muscarinic receptor modulation of glucose-induced electrical activity in mouse pancreatic B-cells

Acetylcholine (1-10 microM) depolarized the membrane and stimulated glucose-induced bursts of electrical activity in mouse pancreatic B-cells. The acetylcholine effects were mimicked by muscarine while nicotine had no effect on membrane potential. Pirenzepine, an antagonist of the classical M1-type muscarinic receptors, but not gallamine (1-100 microM), an antagonist of the classical M2-type receptors, antagonized the acetylcholine action on glucose-induced electrical activity (IC50 = 0.25 microM). Bethanechol, an agonist of the classical M2-type muscarinic receptors, was approximately 100 times less effective than acetylcholine in stimulating the electrical activity. In addition, acetylcholine (1 microM) induced a marked increase (25%) in input resistance to the B-cell membrane. The results indicate that acetylcholine exerted its effects on the B-cell membrane by inhibiting K+ conductance via activation of a muscarinic receptor subtype distinct from the classical M2-type receptor.

Calcium channel activity of purified human synexin and structure of the human synexin gene

Synexin is a calcium-dependent membrane binding protein that not only fuses membranes but also acts as a voltage-dependent calcium channel. We have isolated and sequenced a set of overlapping cDNA clones for human synexin. The derived amino acid sequence of synexin reveals strong homology in the C-terminal domain with a previously identified class of calcium-dependent membrane binding proteins. These include endonexin II, lipocortin I, calpactin I heavy chain (p36), protein II, and calelectrin 67K. The Mr 51,000 synexin molecule can be divided into a unique, highly hydrophobic N-terminal domain of 167 amino acids and a conserved C-terminal region of 299 amino acids. The latter domain is composed of alternating hydrophobic and hydrophilic segments. Analysis of the entire structure reveals possible insights into such diverse properties as voltage-sensitive calcium channel activity, ion selectivity, affinity for phospholipids, and membrane fusion.

[Xenodiagnosis using Lutzomyia youngi in Venezuelan cases of cutaneous leishmaniasis due to Leishmania braziliensis]

Eight patients infected with Leishmania braziliensis were used for xenodiagnosis with Lutzomyia youngi, before and after specific antileishmanial treatment with "glucantime" and "gabbromycin". All of them infected sandflies fed on the borders of the skin lesions before the treatment, suggesting that infected persons might act as reservoirs of infection for an indoor-biting sandfly species. The negative results obtained by xenodiagnosis carried out after specific treatment of the same individuals indicated cure of the patients, and a reduction of risk for further intradomiciliary transmission.

Production of monovalent anti-Bothrops asper antivenom: development of immune response in horses and neutralizing ability

A monovalent antivenom was produced by immunizing two horses with venom of the pit viper Bothrops asper (Ophidia: Viperidae). Although development of the immune response against four toxic and enzymatic activities of the venom was similar in both horses during the first two thirds of the immunization schedule, antibody response in one of the horses reached much higher levels in the last part of the immunization. Immunoelectrophoretic analysis indicates that there were precipitating antibodies in the sera of these horses during all the stages of immunization. However, immunoprecipitation did not correlate with the ability of sera to neutralize toxic activities of B. asper venom. Monovalent antivenom was more effective than the commercially available polyvalent antivenom in the neutralization of Bothrops asper venom. On the other hand, despite the fact that it neutralizes lethal and hemorrhagic activities of the venoms of Lachesia muta and Crotalus durissus durissus, it was less effective than polyvalent antivenom in these neutralizations. Moreover, it does not neutralize defibrinating activity induced by these two venoms, whereas it neutralizes this effect in the case of B. asper venom. It is proposed that monovalent antivenom may be highly effective in the case of envenomations induced by Bothrops asper venom; its use in treating accidents by L. muta and C. durissus would be indicated only if polyvalent antivenom is not available. Results also demonstrate that it is important to monitor antibody response individually in horses being immunized for antivenom production, due to the conspicuous variability in the response of different animals.

A molecular basis for synexin-driven, calcium-dependent membrane fusion

Membranes of secretory vesicles fuse with each other and with plasma membranes during exocytosis in many different cell types. The probable role of calcium in the process is now widely accepted, and it is possible that at least one cytosolic mediator of calcium action is synexin. Synexin is a 47,000 Mr calcium-binding protein, initially discovered in the bovine adrenal medulla, which binds to granule membranes and to inner aspects of chromaffin cell plasma membranes. Synexin causes chromaffin granules to aggregate, and such aggregates can be caused to fuse in the additional presence of arachidonic acid. Synexin also mediates the direct fusion of liposomes and chromaffin granule ghosts. To understand better the mechanisms of membrane fusion promoted by synexin we have attempted to define the primary sequence of the protein. Our initial efforts were directed towards purification of bovine synexin in sufficient amounts to allow us to sequence tryptic peptides. However, as the project progressed we also directed our attention to human synexin, preparing peptides from this protein as well. From analysis of bovine peptides we learned that the synexin molecule might be closely related to a class of proteins including lipocortin I, calpactin (p36), endonexin II, protein II and calelectrin 67K. Complete analysis of a human synexin cDNA clone revealed strong homology with bovine synexin. The analysis also showed that synexin contained a unique, long, highly hydrophobic N-terminal leader sequence followed by a characteristic four-fold repeat homologous with those found in other members of the synexin gene family. The highly hydrophobic character of synexin seems consistent with information previously obtained that synexin is able to insert directly into the interior of bilayers prepared not only from purified phosphatidylserine but also from biological membranes. The evidence for such insertions is a dramatic increase in the capacitance of the membrane, formed at the tip of a patch pipette, when calcium-activated synexin is applied to the bilayer. Additional evidence is the fact that synexin also forms calcium-selective channels when the protein is applied to the cytosolic aspect of the plasmalemma when that side is also exposed to calcium at sub-millimolar concentrations. Thus, the synexin molecule not only enters the membrane, but also spans it. From these and other data we have developed the concept that the fusion process may involve synexin forming a ‘hydrophobic bridge’ between two fusing membranes. Lipid movement across this bridge may then be the material basis for final fusion.(ABSTRACT TRUNCATED AT 400 WORDS)

A molecular basis for synexin-driven, calcium-dependent membrane fusion

Membranes of secretory vesicles fuse with each other and with plasma membranes during exocytosis in many different cell types. The probable role of calcium in the process is now widely accepted, and it is possible that at least one cytosolic mediator of calcium action is synexin. Synexin is a 47,000 Mr calcium-binding protein, initially discovered in the bovine adrenal medulla, which binds to granule membranes and to inner aspects of chromaffin cell plasma membranes. Synexin causes chromaffin granules to aggregate, and such aggregates can be caused to fuse in the additional presence of arachidonic acid. Synexin also mediates the direct fusion of liposomes and chromaffin granule ghosts. To understand better the mechanisms of membrane fusion promoted by synexin we have attempted to define the primary sequence of the protein. Our initial efforts were directed towards purification of bovine synexin in sufficient amounts to allow us to sequence tryptic peptides. However, as the project progressed we also directed our attention to human synexin, preparing peptides from this protein as well. From analysis of bovine peptides we learned that the synexin molecule might be closely related to a class of proteins including lipocortin I, calpactin (p36), endonexin II, protein II and calelectrin 67K. Complete analysis of a human synexin cDNA clone revealed strong homology with bovine synexin. The analysis also showed that synexin contained a unique, long, highly hydrophobic N-terminal leader sequence followed by a characteristic four-fold repeat homologous with those found in other members of the synexin gene family. The highly hydrophobic character of synexin seems consistent with information previously obtained that synexin is able to insert directly into the interior of bilayers prepared not only from purified phosphatidylserine but also from biological membranes. The evidence for such insertions is a dramatic increase in the capacitance of the membrane, formed at the tip of a patch pipette, when calcium-activated synexin is applied to the bilayer. Additional evidence is the fact that synexin also forms calcium-selective channels when the protein is applied to the cytosolic aspect of the plasmalemma when that side is also exposed to calcium at sub-millimolar concentrations. Thus, the synexin molecule not only enters the membrane, but also spans it. From these and other data we have developed the concept that the fusion process may involve synexin forming a 'hydrophobic bridge' between two fusing membranes. Lipid movement across this bridge may then be the material basis for final fusion.(ABSTRACT TRUNCATED AT 400 WORDS)

The ATP-sensitive potassium channel in pancreatic B-cells is inhibited in physiological bicarbonate buffer

The effects of bicarbonate buffer (HCO3-/CO2) on the activity of the two K+ channels proposed by some to control the pancreatic B-cell membrane response to glucose were studied. Single K+-channel records from membrane patches of cultured B-cells dissociated from adult rat islets exposed to a glucose- and bicarbonate-free medium (Na-Hepes in place of bicarbonate) exhibit the activity of both the ATP-sensitive as well as the [Ca2+]i-activated K+ channels. However, in the presence of bicarbonate-buffered Krebs solution, the activity of the ATP-sensitive K+ channel is inhibited leaving the activity of the K+ channel activated by intracellular [Ca2+]i unaffected. In the absence of bicarbonate (Hepes/NaOH in place of bicarbonate), lowering the external pH from 7.4 to 7.0 also has differential effects on the two K+ channels. While the K+ channel sensitive to ATP is inhibited, the K+ channel activated by a rise in [Ca2+]i is not affected. To determine whether the response of the B-cell in culture to bicarbonate is also present when the B-cell is functioning within the islet syncytium, the effects of bicarbonate removal on membrane potential of B-cells from intact mouse islets were compared. These studies showed that glucose-evoked electrical activity is also blocked in bicarbonate-free Krebs solution. Furthermore, in the absence of bicarbonate and presence of glucose (11 mM), electrical activity was recovered by lowering the pHo from 7.4 to 7.0. The ATP-sensitive K+-channel activity is greatly reduced by physiologically buffered solutions in pancreatic B-cells in culture. The most likely explanation for the bicarbonate effects is that they are mediated by cytosolic pH changes. Removal of bicarbonate (keeping the external pH at 7.4 with Hepes/NaOH as buffer) would increase the pHi. Since the activity of the [Ca2+]i-dependent K+ channels is not affected by the removal of the bicarbonate buffer, our patch-clamp data in cultured B-cells indicate an involvement of [Ca2+]i-activated K+ channels in the control of the membrane potential. For the B-cell in the islet, we propose that the burst pattern of electrical activity (Ca2+ entry) is controlled, at least in part, by the [Ca2+]i-activated K+ channel.

Differential effects of maitotoxin on ATP secretion and on phosphoinositide breakdown in rat pheochromocytoma cells

Maitotoxin (MTX) induced exocytotic secretion of ATP from PC12 rat pheochromocytoma cells. The threshold for stimulation of secretion was at concentrations of about 2 ng/ml of MTX. Maximal release occurred at 40 ng/ml. MTX-induced ATP release required the presence of calcium in the extracellular medium and could be inhibited by nifedipine, a specific blocker of voltage-dependent calcium channels. In addition to the effects on ATP secretion from PC12 cells, MTX stimulated the breakdown of phosphoinositides, as measured by the accumulation of [3H]inositol phosphates. Maximal stimulation of phosphoinositide breakdown was reached at only 0.5-1.0 ng/ml MTX. MTX at concentrations required to evoke ATP release (greater than 2 ng/ml) had lesser or no effect on phosphoinositide breakdown. Although stimulation of phosphoinositide breakdown by MTX was dependent on extracellular calcium, it was insensitive to the calcium channel blockers nifedipine, D-600 and cobalt ions. The different concentration range required to elicit these responses and the varying sensitivity to calcium channel blockers indicate that MTX-evoked secretion and MTX-stimulated phosphoinositide breakdown are independent phenomena in PC12 cells.

Electrical activity in chromaffin cells of intact mouse adrenal gland

Membrane potentials of medullary chromaffin cells of the adrenal gland of the mouse were measured in situ. Resting potential (-54.3 +/- 8.8 mV) depended on extracellular [K+] as predicted by the constant-field equation with a permeability ratio, PNa/PK, of 0.09. Current-voltage (I-V) relationships showed that the current is rectified across the chromaffin cell membrane. A rectification ratio of 0.4 was calculated from the slopes of the I-V curves for positive (41 +/- 26 M omega) and negative (103 +/- M omega) currents. Because input resistance for a resting chromaffin cell in isolation is approximately 5 G omega, the chromaffin cells in situ behave as if they were electrically coupled. Most cells responded to depolarizing current pulses with repetitive action potentials, but only 50% of them showed spontaneous electrical activity. Spontaneous activity was often seen in the presence of tetrodotoxin (3 microM). Although the application of the K+-channel blockers tetraethylammonium and Ba2+ greatly increased the amplitude of the action potentials, only Ba2+ induced continuous electrical activity. Application of acetylcholine (ACh) always depolarized the cell membrane. This effect was blocked by atropine but not by D-tubocurarine, suggesting that ACh stimulation of chromaffin cells in the mouse involves activation of muscarinic receptors.

Ca2+-activated synexin forms highly selective, voltage-gated Ca2+ channels in phosphatidylserine bilayer membranes

Synexin, a cytosolic protein that mediates Ca2+-dependent membrane fusion, was incorporated into acidic phospholipid bilayers, formed at the tip of a patch pipet. The pipet was filled with a high-Ca2+ solution (50 mM) and immersed in a chamber containing a low-Ca2+ solution (1 mM). Brief exposures of the bilayer to synexin increased the capacitance of the bilayer by a factor of 10 and decreased the membrane resistance by a factor of 20. Reduction of Ca2+ in the chamber to 1 microM caused an abrupt increase in the current required to hold the pipet potential at 0 mV. Under certain conditions channel events could be detected, often occurring in bursts. Consistently, open-time histograms were found to be voltage-dependent and to exhibit one time constant in the time range examined here. The slope conductance for the synexin channel was estimated as 10.2 +/- 2.1 pS for the large Ca2+ gradient with low chamber Ca2+. However, for symmetrical, low-Cl- solutions containing 25 mM Ca2+ the conductance was 26.5 +/- 5.2 pS. Ion-replacement studies showed the synexin channel to much prefer Ca2+ over Ba2+ or Mg2+. Cd2+, a potent blocker of other voltage-gated Ca2+ channels at 100 microM, blocked synexin channels only at very high concentrations (greater than or equal to 10 mM). Similarly, nifedipine, an inhibitor of the nonactivating Ca2+ channel, was effective only at extremely high concentrations (greater than 300 microM). The high selectivity for Ca2+ and the lack of response of the channel to various drugs known to block Ca2+ channels thus distinguish the synexin channel from other types of Ca2+ channels hitherto reported.

An alternative in vitro method for testing the potency of the polyvalent antivenom produced in Costa Rica

The ability of several batches of polyvalent antivenom to neutralize indirect hemolytic activity of Bothrops asper venom was studied using a sensitive plate test. All samples of antivenom tested effectively neutralized this activity. A highly significant correlation was observed between neutralization of indirect hemolysis and neutralization of lethal activity. This simple and sensitive in vitro test could be used to monitor antibody levels in horses immunized to produce polyvalent antivenom.

Use of selective toxins to separate surface and tubular sodium currents in frog skeletal muscle fibers

The interaction between toxin gamma from the venom of the scorpion Tityus serrulatus and sodium channels in skeletal muscle membranes from the frog Caudiverbera caudiverbera was studied. Sodium current from cut sartorius muscle fibers is a complex signal in which early and late components are difficult to separate. External application of Tityus gamma toxin initially blocked the early component in a voltage-dependent manner. Longer exposure to the toxin induced a complete blockade of the two components of the inward current. Application of tetrodotoxin to fibers pretreated with Tityus toxin at submaximal concentrations allowed the observation of the two distinct components of the inward current. Binding of 125I-labelled toxin to highly purified membrane fractions from the same muscle was used to establish the presence of high affinity receptors both in the transverse-tubular and in the surface membrane.

Evidence for modulation of cell-to-cell electrical coupling by cAMP in mouse islets of Langerhans

The effects of forskolin on electrical coupling among pancreatic beta-cells were studied. Two microelectrodes were used to measure membrane potentials simultaneously in pairs of islet beta-cells. Intracellular injection of a current pulse (delta I) elicited a membrane response delta V1 in the injected cell and also a response delta V2 in a nearby beta-cell confirming the existence of cell-to-cell electrical coupling among islet beta-cells. In the presence of glucose (7 mM), application of forskolin evoked a transient depolarization of the membrane and electrical activity suggesting that the drug induced a partial inhibition of the beta-cell membrane K+ conductance. Concomitant with this depolarization of the membrane there was a marked decrease in beta-cell input resistance (delta V2/delta I) suggesting that exposure to forskolin enhanced intercellular coupling. Direct measurements of the coupling ratio delta V2/delta V1 provided further support to the idea that forskolin enhances electrical coupling among islet cells. Indeed, application of forskolin reversibly increased the coupling ratio. These results suggest that cAMP might be involved in the modulation of electrical coupling among islet beta-cells.

Membrane capacity measurements suggest a calcium-dependent insertion of synexin into phosphatidylserine bilayers

The mechanism by which synexin mediates calcium-dependent aggregation of medullary cell chromaffin granules and fusion of granule ghosts involves specific interactions with the lipid component of the membrane. To study the details of these interactions we measured synexin-induced changes in capacitance of phosphatidylserine bilayers formed at the tip of a patch pipet using the double-dip method. Provided calcium was present in the solution filling the pipet (10-50 mM) stable phosphatidylserine bilayers were easily formed. Addition of synexin (0.1 microgram/ml) to an external medium lacking added calcium induced no measurable changes in either bilayer resistance (10-30 G omega) or displacement current across the membrane. However, addition of calcium (0.1-2.5 mM) in the presence of synexin in the external solution caused a marked increase in the size and time constant of decay of the displacement current. From the steady-state value of the current we calculated a 5-fold decrease in resistance and from the charge displaced during the voltage-clamp pulses we calculated a 10-fold increase in membrane capacitance (from 20 to 200 fF). The size of the synexin-specific charge displacement in one direction during a pulse was always equal to the charge returning to the original configuration after the pulse. The synexin-specific transfer of charge reached saturation when the pipet potential was taken to a sufficient positive or negative value. These properties of the extra charge movement support our view that in the presence of calcium the cytosolic protein synexin penetrates into the bilayer. It is possible that these properties may be related to the mechanism by which synexin promotes membrane fusion in natural membranes.

Inositol 1,4,5-trisphosphate-induced Ca2+ release from the sarcoplasmic reticulum and contraction in crustacean muscle

Intracellular applications of a fixed amount (0.2 to 8 nmol) of inositol 1,4,5-trisphosphate (InsP3) over a brief period (2 s) into barnacle muscle fibers induced vigorous contractures. Peak tension attained during the first application depended on [InsP3]: the maximum tension evoked by the injection of 8 nmol was 1.6 kg/cm2. Peak tension during a second application of a high dose of InsP3 (greater than 10 microM) was always smaller than that during the first application. Extracellular Ca2+ could be omitted with no measurable effects on either the amplitude or time course of the contractures evoked by InsP3. Aequorin was used to measure InsP3-evoked Ca2+ release from intracellular stores in minced muscle fibers from lobster and in skinned muscle fibers from barnacle. Provided the sarcoplasmic reticulum was preloaded with Ca2+, application of InsP3 induced a transient Ca2+ release that was [InsP3] dependent. During each transient, [Ca2+] rose rapidly to a peak value (t1/2 less than 5 s) and then slowly returned (t1/2 less than 100 s) to a basal level. Maximum Ca2+ release was obtained at [InsP3] less than 100 microM and amounted to 4 nmol Ca2+/g of muscle, enough to increase [Ca2+]i from 0.1 to 8 microM had the Ca2+ release occurred in the intact fiber. Successive applications of a fixed amount of InsP3 elicited successive transient increases in Ca2+. The effects of [Ca2+] on the incorporation of [3H]inositol into the pools of phosphatidylinositol, phosphatidylinositol 4-phosphate, and phosphatidylinositol 4,5-bisphosphate pools were measured.(ABSTRACT TRUNCATED AT 250 WORDS)

TEA-insensitive K-channels in the crab giant axon

TTX and TEA-insensitive permeabilities were studied in the crab giant axon under voltage-clamp. Membrane currents in the presence of internal TEA (40 mmol/l) and external TTX (300 nmol/l) may be analyzed as the sum of two components: a linear component, identified as the so-called leakage current, and a non-linear component, identified as a TEA-insensitive potassium channel. Ion permeability ratio of the TTX and TEA insensitive cation channel calculated from reversal potential shows the following sequence pK+:pNa+:pCs+:pRb+:pNH+4 = 1.00:0.16:0.16:0.09:0.06. TEA-insensitive outward currents, carried mainly by Cs+, may be recorded in the presence of different external solutions. Voltage-dependence and equilibrium potential of this channel in physiological conditions allows to postulate its contribution to maintain the cell depolarized during repetitive firing.

Muscarinic receptor enhancement of nicotine-induced catecholamine secretion may be mediated by phosphoinositide metabolism in bovine adrenal chromaffin cells

Bovine adrenal chromaffin cells possess both nicotinic and muscarinic cholinergic receptors, but only nicotinic receptors have heretofore appeared to mediate Ca2+-dependent exocytosis. We have now found that muscarinic receptor stimulation in bovine adrenal chromaffin cells leads to enhanced inositol phospholipid metabolism as evidenced by the rapid (less than 1 min) formation of inositol trisphosphate (IP3) and inositol bisphosphate (IP2). Muscarinic receptor-mediated accumulation of IP3 and IP2 continues beyond 1 min in the presence of LiCl and is accompanied by large increases in inositol monophosphate. Muscarinic receptor stimulation was also found to enhance nicotine-induced catecholamine secretion by 1.7-fold if muscarine was added 30 s before nicotine addition. Moreover, since the muscarinic antagonist atropine reduces acetylcholine-induced secretion, we conclude that muscarinic receptor stimulation somehow primes these cells for nicotinic receptor-mediated secretion, perhaps by causing small nonstimulatory increases in cytosolic free Ca2+ mediated by IP3. Furthermore, we show that small depolarizations of these cells with 10 mM K+, which themselves do not affect basal secretion, also enhance nicotine-induced secretion. Thus, small increases in cytosolic free Ca2+ produced either by physiologic muscarinic receptor stimulation or by small experimental depolarizations with K+ may prime the chromaffin cells for nicotinic receptor-mediated secretion.

Potassium channel selectivity in mouse pancreatic B cells

High-resistance microelectrodes were used to measure membrane potential changes in response to increased extracellular K+ concentration ([K+]o; or a test cation X+ such as Li+, Rb+, Cs+, NH+4) in B cells from mouse islets of Langerhans. In the absence of glucose, a sudden increase in [K+]o (or [X+]o), keeping the sum [Na+]o + [K+]o constant (or [Na+]o + [K+]o + [X+]o), induced a rapid depolarization of the membrane. The membrane potential changes were essentially unchanged in the presence of 20 mM tetraethylammonium (TEA). The Goldman-Hodgkin-Katz equation was fitted to the experimental relationship between membrane potential and [K+]o (or [X+]o), and permeability (P) ratios were estimated. In the absence of TEA, P Na/PK was estimated to be approximately 0.046. In the presence of TEA the following ratios were estimated: P Rb/PK = 0.74, P Cs/PK = 0.62, and P NH4/PK = 0.36. From these ratios the following sequence of permeabilities was obtained, PK greater than P Rb greater than P Cs greater than P NH4 greater than P Na. It is proposed that this sequence reflects the selectivity of the intracellular [Ca2+]-activated K+ channel of the pancreatic B cell.

Glucose-induced oscillatory changes in extracellular ionized potassium concentration in mouse islets of Langerhans

Liquid membrane [K+]-sensitive microelectrodes (1-2 micron tip diameter) were used to measure the extracellular ionized potassium concentration in mouse pancreatic islets of Langerhans. With the tip of the microelectrode at the surface of the islet, the time course of the [K+]-sensitive electrode potential changes in response to the application of rapid changes in [K+]o (from 1.25 to 5 mM), could be reproduced by the equation for K+-diffusion through a 100-micron-thick unstirred layer around the islet (diffusion coefficient for K+ at 27 degrees C, DK,o, taken as 1.83 X 10(-5) cm2/s). The time to reach 63% of the steady-state electrode response with the tip in the chamber at the surface of the islet was from 5 to 6 s. When the tip of the [K+]-sensitive electrode was placed in the islet tissue, the time for the response to reach 63% of the steady-state level increased. The time course of the [K+]-sensitive electrode response could be reproduced using the same diffusion model assuming that K+ diffusion into the islet tissue takes place in a tortuous intercellular path with an apparent diffusion coefficient, DK,I, about half of DK,o, in series with the unstirred layer around the islet. In the absence of glucose the potassium concentration in the extracellular space, [K+]I, was found to be higher than the concentration in the external modified Krebs solution, [K+]o. The difference in concentration [K+]I - [K+]o was greater when [K+]o was smaller than 2 mM. In the presence of glucose (between 11 and 16 mM), under steady-state conditions, small oscillatory changes in the [K+], (1.48 +/- 0.94 mM) were detected. Simultaneous recording of membrane potential from one B-cell and [K+], in the same islet indicated that the potassium concentration increased during the active phase of the bursts of electrical activity. Maximum concentration in the intercellular was reached near the end of the active phase of the bursts. We propose that the space between islet cells constitutes a restricted diffusion system where potassium accumulates during the transient activation of potassium channels.

Real-time measurements of acetylcholine-induced release of ATP from bovine medullary chromaffin cells

The luminescent oxidation of luciferin has been used to monitor acetylcholine-induced ATP release from cultured bovine chromaffin cells. Acetylcholine (1-100 microM) evoked ATP release of up to 30% of the total cellular ATP. This secretion required external free calcium and could also be elicited by K+-induced membrane depolarization. The size of the cytosolic ATP compartment was estimated as 5% of the ATP in the cell by solubilising the cell membrane using digitonin (20 microM) or by application to the cells of brief pulses (2 microseconds) of high electric field (2000 V/cm). Blockers of the voltage-gated Ca2+ channel effectively blocked K+-induced ATP release, while the acetylcholine antagonists d-tubocurarine and beta-bungarotoxin inhibited the acetylcholine-induced release of ATP. These data support the concept that ATP is released together with the catecholamines by exocytosis of chromaffin granule contents.

Monovalent cation permeabilities of the potassium systems in the crab giant axon

Permeability ratios for pairs of monovalent cations permeating the two potassium systems proposed for the giant axon of the crab Carcinus maenas (M.E. Quinta-Ferreira, E. Rojas & N. Arispe, J. Membrane Biol. 66:171-181, 1982b) were estimated from measurements of the reversal potential of the currents under voltage-clamp conditions. With K+ inside the axon, permeability ratios from the reversal potential of the currents through the late channel are: PRb/PK = 0.9, PNH4/PK less than 0.2 and PCS/PK = 0.18. With CS+ inside the ratios are: PK/PCS = 8.7, PRb/PCS = 7.1 and PNH4/PCS = 2.4. The analysis of the inward currents carried by Rb+ or NH+4 showed similar reversal potentials for the early transient component and the late sustained component. Whence, the sequence of permeabilities for the two types of potassium channels is: PK greater than PRb greater than PNH4 greater than PNa = PCS. The time constants for the activation of the two components recorded either in K-, Rb-, or NH4-artificial seawater are twice as large as the corresponding time constants measured in Na-artificial seawater.

Differential blockage of two types of potassium channels in the crab giant axon

Measurements were made of the kinetic and steady-state characteristics of the potassium conductance in the giant axon of the crabs Carcinus maenas and Cancer pagirus. The conductance increase during depolarizing voltage-clamp pulses was analyzed assuming that two separate types of potassium channels exist in these axons (M.E. Quinta-Ferreira, E. Rojas and N. Arispe, J. Membrane Biol. 66:171-181, 1982). It is shown here that, with small concentrations of conventional K+-channel blockers, it is possible to differentially inhibit these channels. The potassium channels with activation and fast inactivation gating (m3h, Hodgkin-Huxley kinetics) were blocked by external application of 4 amino-pyridine (4-AP). The potassium channels with standard gating (n4, Hodgkin-Huxley kinetics) were preferentially inhibited by externally applied tetraethylammonium (TEA). The differential blockage of the two types of potassium conductance changes suggests that they represent two different populations of potassium channels. It is further shown here that blocking the early transient conductance increase leads to the inhibition of the repetitive electrical activity induced by constant depolarizing current injection in fibers from Cardisoma guanhumi.

A comparative analysis of two methods for the study of alcohol intake in Mexico

Two different methodologies were studied in a semi-rural community in Mexico city to investigate alcohol-intake patterns and attitudes towards drinking and drunkenness. One of the methods consisted of a household survey. The other used the anthropological informant's technique. These methods were compared only at those points where were found similarities in the data collected. We conclude that both methods give comparable estimates of what goes on in the community. Nevertheless the informant method is cheaper, results are obtained in less time and the community members are engaged in this problem, thus permitting future action to be taken.

Membrane potential measurements in islets of Langerhans from ob/ob obese mice suggest an alteration in [Ca2+]i-activated K+ permeability

High-resistance micro-electrodes were used to measure membrane potentials in beta-cells from islets of Langerhans of ob/ob obese mice (Norwich colony). In the presence of glucose the burst pattern of electrical activity recorded in ob/ob beta-cells, although similar to the burst pattern recorded from normal beta-cells, presents important differences. The membrane potential of the ob/ob beta-cells in the presence of 11 mM glucose in the modified Krebs solution oscillates between a silent-phase level at -48 mV and an active-phase level at -36 mV, similarly to normal mouse islet beta-cells. However, the average active-phase duration is 20 s in ob/ob beta-cells compared with 5 s in normal beta-cells. The average burst frequency is 1.8 bursts/min in ob/ob beta-cells compared with 3 bursts/min in normal beta-cells. While normal beta-cells show continuous spike activity above 16 mM glucose, ob/ob beta-cells often exhibit a burst pattern of electrical activity at glucose concentrations as high as 33 mM. Compared with normal beta-cells, the relationship between spike frequency and glucose concentration is shifted towards lower concentrations in ob/ob beta-cells. Thus, the concentration for half-maximal spike frequency is 6.9 mM for the ob/ob beta-cells and 10.2 mM for the normal beta-cells. In ob/ob beta-cells, the mitochondrial inhibitor carbonyl-cyanide m-chlorophenylhydrazone induces hyperpolarization of the membrane, consistent with its effect of stimulating K+ permeability in normal islets. However, quinine and the sulphonylurea glibenclamide did not block the silent phase between the bursts of electrical activity. Both drugs block the [Ca2+]i-activated K+ permeability thought to control the membrane potential at the silent phase in normal beta-cells. The modified pattern of response to glucose and decreased sensitivity to quinine and glibenclamide suggest that the beta-cell membrane of the ob/ob islet of Langerhans has a modified [Ca2+]i-activated K+ permeability.

The response of pancreatic beta-cell membrane potential to potassium-induced calcium influx in the presence of glucose

Membrane potential measurements were made in pancreatic beta-cells from microdissected islets from normal mice. In the presence of 11 mM glucose, depolarization of the membrane for 1 min with 50 mM potassium is followed by an inhibition of electrical activity before the normal burst pattern resumes. This inhibitory period, called the recovery time, is steady for each beta-cell after three consecutive pulses of 50 mM potassium. The mean recovery time is 109 s. During the recovery time, the membrane is hyperpolarized and the input resistance is decreased, indicating that potassium permeability is high over this period. The recovery time is dependent on the size of the depolarization: 1 min exposure to potassium concentrations below 50 mM reduces the recovery time with a half-maximal effect at 38.5 mM potassium, corresponding to -27 mV. Also, increasing the extracellular calcium concentration lengthens the recovery time. Increasing the glucose concentration, however, shortens the recovery time. It is postulated that the recovery time represents activation of the calcium-gated potassium permeability and is a reflexion of the time taken for the beta-cell to buffer the increased intracellular calcium resulting from the potassium depolarization.

Electrophysiological evidence for the inhibition of potassium permeability in pancreatic beta-cells by glibenclamide

The effects of glibenclamide on the electrical activity of the beta-cells of the islets of Langerhans of normal mice have been investigated in the absence and presence of glucose (11.1 mM). Glibenclamide depolarized the cell membrane and this has been interpreted in terms of an increase in the ratio of the Na+ and K+ permeabilities, PNa/PK. This ratio increased from 0.05 to 0.24 in the presence of 4 microM glibenclamide and zero glucose. The input resistance of the beta-cells also increased. These observations indicate a decrease in K+ permeability. The effect is only slowly reversed after removal of glibenclamide. Uncouplers of oxidative phosphorylation do not reverse the depolarization induced by glibenclamide. It is suggested that glibenclamide is acting directly to inhibit the [Ca2+]i-gated K+ permeability in the beta-cell membrane.

The topography of electrical synchrony among beta-cells in the mouse islet of Langerhans

beta-Cells in microdissected islets of Langerhans produce rhythmical bursts of electrical activity. This was monitored with two micro-electrodes simultaneously and the frequency and phase (collectively referred to as synchrony) of the two signals was investigated. At any instant two impaled cells produced bursts of the same frequency even when separated by up to 400 micron. When the electrode tips were separated by less than about 20 micron and current injection showed the cells to be ionically coupled the two signals were in phase and had almost identical shape. The phase relations between cells further apart were variable, the leading cell usually being located deeper within the islet than the other impaled cell. Increasing the glucose concentration increased electrical activity, reduced any phase lags and made the shape of the bursts more similar. There was less lag between the responses from two cells when the glucose concentration was suddenly reduced, than when it was suddenly increased. Qualitatively similar observations were made in glibenclamide-treated mice, a treatment previously shown to increase dye coupling between islet cells. However, the response to increasing glucose concentrations showed less phase lag; likewise the phase lag between bursts was reduced. Furthermore the response to current injected into one cell could be detected at much larger distances (up to 80 micron) than in control islets. This suggests that electrical coupling of beta-cells was improved in sulphonylurea-treated mice. Electron microscopy of both control and glibenclamide-treated mouse islets fixed at the end of each electrophysiological experiment showed the region impaled by the electrodes to be well preserved and, whenever the electrodes penetrated at least 20 micron into the islet, to contain a large proportion of beta-cells. The data support the view that, within an islet, most but not necessarily all cells are electrically synchronized, and that the coupling can be modulated by natural and pharmacological secretagogues.

Effects of Zn2+ on glucose-induced electrical activity and insulin release from mouse pancreatic islets

The effects of Zn2+ and CO2+ on glucose-induced beta-cell electrical activity and on insulin release from microdissected mouse pancreatic islets were studied. In 11 mM glucose the electrical activity is characterized by a burst pattern with a bimodal distribution of spike amplitudes along the plateau phase. Zn2+ at 0.05 mM induced a reduction in the number of spikes during the bursts and preferentially blocked the large action potentials. Zn2+ at 0.1 mM and CO2+ at 1.0 mM completely inhibited the electrical activity in response to glucose. Zn2+ inhibition of electrical activity was poorly reversible, whereas CO2+ inhibition was rapidly and completely reversible. Zn2+ and CO2+ inhibited the glucose-stimulated insulin release from microdissected perifused islets. Half-maximal inhibition occurred at about 0.3 mM for both metals. Zn2+ also inhibited K+-induced insulin release in the absence of glucose, indicating that Zn2+ inhibition does not involve glucose metabolism. It is proposed that Zn2+ blocks the voltage-gated Ca2+ channels in pancreatic beta-cells.

Cooling dissociates glucose-induced insulin release from electrical activity and cation fluxes in rodent pancreatic islets

Insulin release and beta-cell membrane potentials in response to glucose at 37 and 27 degrees C have been measured simultaneously in single, micro-dissected, perifused islets of Langerhans from normal mice. Insulin release and 45Ca outflow in response to glucose at 37 and 27 degrees C have been measured simultaneously from perfused islets isolated by collagenase digestion from normal rats. The effect of cooling on beta-cell membrane potassium permeability was assessed by changes in measured membrane potential and input resistance (in the mouse) and by changes in 86Rb outflow (in the rat). Resting and active beta-cell membrane parameters (i.e. membrane potential, spike frequency, input resistance, 45Ca outflow and 86Rb outflow), in both mouse and rat islets, were affected only slightly by cooling to 27 degrees C, with temperature coefficients of 2 or lower. At 27 degrees C glucose-stimulated insulin release was inhibited completely in mouse islets and almost completely in rat islets. The temperature coefficients in both preparations were greater than 5. It is concluded that beta-cell electrical activity and changes in membrane permeability induced by glucose are not consequences of insulin release.

Electrical coupling between cells in islets of Langerhans from mouse

Two microelectrodes have been used to measure membrane potentials simultaneously in pairs of mouse pancreatic islet cells. In the presence of glucose at concentrations between 5.6 and 22.2 mM, injection of current i into cell 1 caused a membrane potential change in this cell, V1, and, provided the second microelectrode was less than 35 micron away, in a second impaled cell 2, V2. This result establishes that there is electrical coupling between islet cells and suggests that the space constant of the coupling ratio within the islet tissue is of the order of a few beta-cell diameters. The current-membrane potential curves i-V1 and i-V2 are very similar. By exchange of the roles of the microelectrodes, no evidence of rectification of the current through the intercellular pathways was found. Removal of glucose caused a rapid decrease in the coupling ratio V2/V1. In steady-state conditions, the coupling ratio increases with the concentration of glucose in the range from 0 up to 22 mM. Values of the equivalent resistance of the junctional and nonjunctional membranes have been estimated and found to change with the concentration of glucose. Externally applied mitochondrial blockers induced a moderate increase in the junctional resistance possibly mediated by an increase in intracellular Ca2+.

Properties of the Ca-activated K+ channel in pancreatic beta-cells

The existence of [Ca2+]i-activated K+-channels in the pancreatic beta-cell membrane is based in two observations: quinine inhibits K+-permeability and, increasing intracellular Ca2+ stimulates it. The changes in K+-permeability of the beta-cell have been monitored electrically by combining measurements of the dependence of the membrane potential on external K+ concentration and input resistance. The changes in the passive 42K and 86Rb efflux from the whole islet have been measured directly. Intracellular Ca2+ has been increased by various means, including increasing extracellular Ca2+, addition of the Ca2+-ionophore A23187 or noradrenaline and application of mitochondrial uncouplers and blockers. In addition to quinine, many other substances have been found to inhibit or modulate the [Ca2+]i-activated K+-channel. The most important of these is the natural stimulus for insulin secretion, glucose. Glucose may inhibit K+-permeability by lowering intracellular Ca2+. Glibenclamide, a hypoglycaemic sulphonylurea, is about 25 times more active than quinine in blocking the K+-channel in beta-cells. The methylxanthines, c-AMP, various calmodulin inhibitors and Ba2+ also inhibit K+-permeability. Genetically diabetic mice have been studied and show an alteration in the [Ca2+]i-activated K+-channel. It is concluded that the [Ca2+]i-activated K+-channel plays a major role in the normal function of the pancreatic beta-cell. The study of its properties should prove valuable for the understanding and treatment of diabetes.

Valinomycin inhibition of the electrical activity of mouse pancreatic beta-cells

The effect of the K-ionophore valinomycin (VAL) on the electrical activity of single mouse pancreatic beta-cells was measured using the glass micro-electrode technique. In the presence of 11.1 mM glucose, after 4 min of exposure to 10 nM VAL the spike activity was abolished, bursts became irregular and after 10 min the membrane hyperpolarized 4 mV. The electrical activity was completely blocked by 100 nM VAL within 3 min and the membrane hyperpolarization averaged 10 mV. The effect of VAL was irreversible. VAL (100 nM) also inhibited the electrical activity induced by 11.1 mM glucose plus 10 mM tetraethylammonium chloride (TEA), a specific blocker of the voltage sensitive PK. Total inhibition was observed 6-7 min after VAL addition and the cell hyperpolarized 14 mV. With the simultaneous application of 10 mM TEA and 100 microM quinine, a specific blocker of the [Ca2+]i-dependent PK, in the presence of 16.7 mM glucose, the membrane showed continuous activity and progressive depolarization from -45 to -5 mV within 23 min. The subsequent addition of 100 nM VAL also hyperpolarized the cell, with the membrane potential reaching -17 mV after 7 min. On the basis of these data, we suggest that VAL affects the glucose-dependent depolarization of the beta-cell membrane by increasing K+ permeability.

[Patterns of urinary aminoacid excretion in exceptional children and patients with mental disorders in Costa Rica]

The amino acid profile was studied in individual random samples of urine from 1147 normal schoolchildren and 1074 exceptional children: 628 with mental retardation, 332 with hearing and speech defects and 114 with visual defects as well as in 673 patients with mental disorders. Laboratory procedures included chemical tests and one-dimension paper- electro- and column-chromatography. Phenylketonuria was found in a mentally retarded girl and in one of her brothers; iminoglycinuria in a mentally retarded boy and heterozygote cystinuria in a man with manic-depressive psychosis. The percentage of high excretors of beta-aminoisobutyric acid (B-AIB) in the controls (4.88%) was similar to previous findings in the Caucasian race. The children with hearing and speech defects showed a number of high excretors of B-AIB significantly lower (X2 = 5.32; p less than 0.025) and the children with visual defects a number of hyperglycinurias significantly higher (X2 = 9.19; p less than 0.05). Previous non-consistent findings on the excess of high excretors of B-AIB in Down's syndrome were not confirmed in this study. These results suggest a relationship between transport defects in the plasma membrane and pathological disorders in some of the cases screened.

Effects of adrenaline and noradrenaline on glucose-induced electrical activity of mouse pancreatic beta cell

The effects of adrenaline and noradrenaline on membrane potential and glucose-induced electrical activity were studied in micro-dissected mouse Islets of Langerhans. Both catecholamines induced hyperpolarization and blocked electrical activity in the presence of 11.1 mM glucose. Phentolamine, but not propranalol, blocked these effects, indicating predominantly alpha receptor action. Quinine, but not tetraethylammonium ions, antagonized the inhibitory effects of the catecholamines. The data are consistent with the hypothesis that alpha receptor activation induces a transient increase in intracellular Ca2+ concentration which in turn leads to an increase in K+ permeability.

Beta cell membrane potential and insulin release; role of calcium and calcium:magnesium ratio

Glucose-induced insulin release from perfused rat pancreas was compared with glucose-induced changes in membrane potential of beta cells from mouse islets. Extracellular concentrations of Ca and Mg were varied as steps, simultaneously or separately, from 10% to 200% of normal in the presence of 11.1 mM glucose. A change in Ca induced a transient change in electrical activity paralleled by a transient change in insulin release. If the Ca/Mg ratio was maintained, steady-state insulin release remained constant between 10% and 200% Ca, while electrical activity showed alterations. Analysis of burst parameters indicated that increased or decreased Ca entry was balanced by decreased or increased excitability. It is postulated that the beta cell contains a compensator mechanism for the regulation of Ca influx.