Differential effect of hypertonicity on FMLP-, anti-IgE- and Ca2+ ionophore A23187-induced histamine release from human basophil leukocytes.

Effects of different extracellular Na+ and K+ concentrations (respectively, 135, 155, 220, 260 mM NaCl, and 2.7, 20, 50, 100 mM KCl) on IgE-dependent and IgE-independent histamine release from human basophils were examined. High extracellular Na+ and K+ concentrations were shown to reduce N-formyl-methionyl-leucyl-phenyl-alanine- (FMLP), but not anti-IgE- or Ca2+ ionophore A23187-induced histamine release. A high extracellular Ca2+ (7.2 mM CaCl2) concentration increased basophil response to anti-IgE and FMLP. The enhancement of FMLP- but not of anti-IgE-induced histamine release was antagonized by high extracellular Na+ and K+ concentrations. When leukocytes were suspended in isotonic choline chloride solutions (choline is a nonpermeant monovalent cation), an enhancement of anti-IgE- and FMLP-induced histamine release was observed. This suggests that monovalent cations, namely Na+ ions, at physiological concentrations, downregulate histamine release from human basophils. At high choline chloride concentrations, FMLP-, but not anti-IgE-induced histamine release was inhibited. Thus, the reduction of FMLP-evoked histamine secretion from human basophils seems to be due to hypertonicity and not to the type of monovalent cation, either permeant or nonpermeant, contained in extracellular milieu. The different effects of a hypertonic solution on anti-IgE and FMLP-induced histamine release are probably related to the different cell activation pathways triggered by the two stimuli.     

Pancreatic acinar cells: the role of calcium in stimulus-secretion coupling.

1. Segments of mouse or rat pancreas were placed in a flow cell through which physiological salt solutions of varying composition were pumped at a constant rate. Intracellular recordings of membrane potential, resistance and electrical time constant were made from the acini using fine glass micro-electrodes. In some experiments two micro-electrodes were inserted into two acinar cells within the same acinus to assess directly cell to cell coupling. The concentration of amylase in the effluent was measured continuously. 2. Electrical coupling between two acinar cells was observed when the tips of the two micro-electrodes were less than 50 mum from each other. The coupling ratio was close to 1. Acetylcholine (ACh) always evoked depolarization of exactly the same amplitude in two coupled cells and reduced the amplitude of current-pulse induced membrane potential changes in both cell simultaneously. 3. Stimulation with ACh caused an immediate increase in amylase output. Replacement of superfusion fluid Na by Tris or Cl by sulphate abolished ACh-evoked increase in amylase release, but the subsequent reintroduction of Na or Cl caused an increase in amylase release of a magnitude similar to what was normally observed following stimulation. 4. Omitting Ca from the superfusion fluid and adding EGTA rapidly depolarized the acinar cell membrane, reduced the input resistance and caused a marked reduction in amylase secretion. During exposure to a Ca-free, EGTA containing solution a marked increase in amylase release occurred following maximal ACh stimulation. 5. Addition of small amounts of Mg, Ca or Mn to a Ca-, Mg-free solution caused an increase in membrane potential, input resistance and electrical time constant and markedly increased amylase release. The effect on the electrical parameters was reversed in the absence of extracellular Na while extracellular Na was of no importance for the effect on amylase release. 6. The effect of ACh on amylase was enhanced during superfusion with a fluid containing 20 mM-Ca. The presence of Mn (5 mM) in an otherwise normal control had no effect on ACh-evoked release. 7. These results show that ACh acts on the acinus by reducing the surface cell membrane resistance. It is suggested that the ACh-receptor interaction causes a release of Ca from the surface cell membrane and that the concentration of Ca in the surface cell membrane determines the specific membrane resistance particularly for Na. The release of Ca to the cytosol activates exocytosis while the Na influx is of importance for acinar fluid secretion. The effect of ACh on amylase secretion can be mimicked by agents displacing membrane-bound Ca (Mg, Ca, Mn).     

Influences of ionic environments on ACh-induced secretory responses in isolated perfused pancreas of rats

The influence of extracellular Ca2+ concentration, [Ca2+]o, on the secretory response to acetylcholine (ACh) was analyzed in isolated perfused rat pancreas. The decrease of [Ca2+]o strongly diminished the amylase output and pancreatic juice flow in response to continuous stimulation with 5 X 10(-8) M ACh. A quantitative relation was found between the amount of amylase release by 5 X 10(-8) M ACh and the [Ca2+]o over a range of 0.1--2.5 mM. The partial replacement of NaCl with LiCl produced a diminution in both amylase output and pancreatic juice flow. A quantitative relation existed between the amount of ACh-induced amylase release and the [Na+]o over a range of 86--157 mM. The partial replacement of KCl with NaCl produced falls in both amylase output and pancreatic juice flow. Again, a quantitative relation existed between ACh-induced amylase release and [K+]o over a range of 1.0--5.6 mM. These results are compatible with the view that both the amylase output and the juice flow induced by 5 X 10(-8) M ACh are proportional to the amount of carrier-Ca complex and that the inward movement of the complex may be linked closely to the activation of Na pumps on the pancreatic acinar cell. A dose-response relation was found between the concentration of ACh and the amylase output. The relation was shifted to the left when 1 mU/ml cholecystokinin-pancreozymin (CCK-PZ) was added. A similar shift was observed when 1 mU/ml secretin was added. These results support the view that ACh, CCK-PZ, and secretin may activate the common cellular process in stimulus-secretion coupling, although these secretagogues may severally act on the different receptor sites.     

Activation of Ca2+-dependent Cl- and K+ conductances in rat and mouse parotid acinar cells

Isolated acinar cells from rat and mouse parotid glands were studied with patch-clamp whole-cell current recordings. Acetylcholine (ACh) stimulation caused a transient inward current at a membrane potential of -70 mV, and a sustained outward current at a membrane potential of 0 mV, in quasi physiological Na+, K+ ion gradients, except the zero-Cl- ion gradient condition across the membrane. The reversal potential obtained from the ACh-evoked steady current was about -75 mV, in this ionic condition. When major Cl- ions of both the pipette and the bath solution were replaced, either by glutamate or by sulphate, only a large outward current was observed, at a membrane potential of -60 mV, in the presence of ACh. The addition of Ca2+-ionophore A23187 caused responses similar to those evoked by ACh. The reversal potential of A23187-induced current was close to the K+ equilibrium potential of -90 mV, in a Cl- -free condition. When K+-free NaCl solution was used in the pipette and the bath, A23187 caused only a large inward current, at a membrane potential of -60 mV. The reversal potential of A23187-evoked current was about -15 mV, in a symmetrical K+-free, NaCl condition. These results suggest that the ACh and A23187 activate Cl- as well as K+ conducting pathways via an increase in [Ca2+]i in the parotid acinar cells. The A23187-evoked large K+ current could not be explained solely by a rise in open probability of the channels.     

The effect o f calcium on contraction and conductance thresholds in frog skeletal muscle

1. The effect of extracellular calcium and magnesium on the contraction threshold and on the thresholds for an increase in sodium and potassium conductance with depolarization was studied in voltage-clamped frog muscle fibres.2. A larger depolarization was required to reach each of the three thresholds when the concentration of divalent cation was increased.3. The contraction and potassium conductance thresholds appeared to shift in parallel with alterations in calcium over the concentration range 0.2-10.0 mM and in magnesium over the concentration range 5.4-90.0 mM. The shift amounted to about 4 mV for a threefold change in concentration of divalent cation.4. The sodium conductance threshold was much more sensitive to alterations in divalent cation concentration than was either the contraction or the potassium conductance threshold.     

Pancreatic acinar cells: acetylcholine-induced membrane depolarization, calcium efflux and amylase release

1. The effects of acetylcholine upon the output of amylase, Ca(2+) efflux and membrane potential of pancreatic acinar cells have been measured in segments of mouse pancreas superfused in vitro.2. Amylase output was measured continuously using an on-line automated fluorimetric method; Ca(2+) efflux was monitored by measuring the release of (45)Ca(2+) from pre-labelled tissue; and intracellular recordings of acinar transmembrane potentials were obtained with glass micro-electrodes. In some experiments membrane potentials, and in others (45)Ca(2+) efflux, were measured concomitantly with amylase release.3. Acetylcholine depolarized the acinar cells, increased tissue (45)Ca(2+) efflux and raised amylase output, each with a similar dose-dependence, i.e. a maximal response at 10(-5)M, threshold =/< 10(-8)M, and ED(50) values of 0.7 x 10(-7)M, 0.5 x 10(-7)M, and 2 x 10(-7)M for depolarization, amylase release, and (45)Ca(2+) efflux, respectively.4. In response to acetylcholine both depolarization and (45)Ca(2+) efflux preceded or coincided with the increase in amylase output.5. Acetylcholine 10(-5)M and [K](0) 47 mM were without effect on (45)Ca(2+) efflux in the presence of atropine (3 x 10(-6)M) but pancreozymin (0.3 u./ml.) still elicited a marked increase in (45)Ca(2+) release.6. These results suggest that the stimulatory action of acetylcholine on the pancreatic acinar cell involves, sequentially, a specific receptor-activated increase in membrane permeability, depolarization, Ca(2+) mobilization and amylase release. These events are discussed in relation to the integrated mechanism of stimulus-secretion coupling.     

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.     

Effect of extracellular K+ concentration on resting potential,caerulein-induced depolarization and amylase release from mouse pancreatic acinar cells

Summary Acinar cell membrane potentials and amylase release were measured from in vitro preparations of mouse pancreas. The effect of a 10-fold increase of the extracellular K⁺ concentration (to 47 mM) was studied on the resting membrane potential and amylase release as well as on the membrane depolarization and amylase release induced by the cholecystokinin-pancreozymin analogue, caerulein. In the presence of atropine (to exclude the effect of a possible release of endogenous acetylcholine), the increased K⁺ concentration depolarized the cells from –45 to –20 mV without influencing the rate of the unstimulated release of amylase. Under these conditions, the depolarizing effect of caerulein was almost abolished, while the caerulein-induced amylase was not. It is concluded that caerulein-induced enzyme secretion from pancreatic acinar cells is independent of the level of the membrane potential as well as extracellular K⁺ concentration in the range from 4.7–47 mM.     

Calcium fluxes in isolated pancreatic acini: effects of secretagogues

45Ca2+ exchange and total calcium content were measured in isolated mouse pancreatic acini. 45Ca2+ uptake could be described as the sum of a constant and a single exponential kinetic component; about 60% of total acinar calcium was exchangeable. Stimulation by bethanechol increased 45Ca2+ uptake, but the time course of uptake could be fit only by the addition of a more rapid kinetic component without any change in the total exchangeable Ca2+. 45Ca2+ washout after 1-h loading could be fit as the sum of two exponential components. Stimulation increased the rate of 45Ca2+ washout with the appearance of a third and more rapid kinetic component. There was not, however, a good correspondence between the exponential constants measured in uptake and washout protocols in unstimulated acini. Exponential constants were also affected by the concentration of calcium in the medium, further indicating the presence of nonlinearities in 45Ca2+ exchange. The dose-response relationships were similar for bethanechol stimulation of 45Ca2+ uptake and amylase release, whereas stimulation of 45Ca2+ washout reached a maximum at a higher concentration of bethanechol. Both 45Ca2+ uptake and analytical measurement of total Ca2+ showed a rapid drop in acinar Ca2+ content followed by a gradual reuptake on stimulation by bethanechol. It is concluded that the initial primary effect of secretagogues is to increase Ca2+ efflux, which is interpreted to be the result of release of sequestered calcium into the cytosol.     

The ionic mechanism of the excitatory action of glutamate upon the membranes of motoneurones of the frog

Simultaneous intra- and extracellular recordings with K+, Na+, Ca2+, and Cl- sensitive microelectrodes were performed in motoneurones of the spinal cord of the frog during depolarizations mediated by glutamate (GLUT) and by experimentally increased extracellular K+. Depolarization resulting from increased K+ activity (alpha K+) in the bathing solution evoked a decrease of intracellular Na+ activity (alpha Na+i); a transient increase of alpha Na+i accompanied by a decrease of alpha Na+e was observed during the depolarization induced by GLUT. Both modes of depolarization led to an increase of alpha Cl-i and a concomitant decrease of alpha Cl-e. An experimental increase of alpha K+e led to a threshold dependent increase of alpha Ca2+i by at least one order of magnitude and to an equally threshold dependent strong decrease of alpha Ca2+e. The threshold of these changes of alpha Ca2+ was at a membrane potential of -25 mV. During a depolarization of half the amplitude induced by GLUT a comparable increase of alpha Ca2+i and a smaller decrease of alpha Ca2+e were observed. The GLUT mediated changes of alpha Ca2+ were not threshold dependent and occurred synchronously with the onset of depolarization. A transient decrease of alpha K+i and a parallel strong increase of alpha K+e occurred during the GLUT induced depolarization. Depolarization evoked by an experimental increase of alpha K+e led to an increase of alpha K+i. The observed changes in the ionic composition of the intra- and extracellular fluids indicate that GLUT evokes an increase in membrane permeability to Na+ and Ca2+ and a subsequent influx of these ions into motoneurones, while the inward shift of Cl- and the outward shift of K+ are presumably passive. A voltage dependent Ca2+ influx is triggered at -25 mV membrane potential.     

Roles of Ca2+ influx through ATP-activated channels in catecholamine release from pheochromocytoma PC12 cells.

1. Extracellular ATP evokes catecholamine release concomitant with depolarization in pheochromocytoma PC12 cells. Roles of Ca2+ influx through ATP-activated channels during the catecholamine release were investigated. 2. Norepinephrine or dopamine release induced by > or = 100-microM concentrations of ATP was insensitive to 300 microM Cd2+, whereas the release induced by increasing extracellular KCl (50-150 mM) was completely blocked by this concentration of Cd2+. 3. ATP (100 microM) increased the intracellular free Ca2+ concentration measured with fura-2. The increase was not affected by 300 microM Cd2+ or 100 microM nicardipine, suggesting that Ca2+ influx through ATP-activated channels but not through voltage-gated Ca2+ channels contributes to the ATP-evoked catecholamine release. 4. Inward currents permeating through voltage-gated Ca2+ channels were measured using the whole-cell voltage clamp. In the presence of 10 microM ATP, a concentration that induces an ATP-activated channel-mediated current equivalent to that induced by 100 microM ATP during the depolarization in "non-voltage clamped" cells, the Ca2+ current activated by a voltage step to +10 mV was reduced. The reduction in the Ca2+ channel-mediated current was not observed when the extracellular Ca2+ was replaced with Ba2+. 5. The ATP (100 microM)-evoked dopamine release was inhibited by 300 microM Cd2+ when measured with extracellular Ba2+ instead of Ca2+. This effect of Ba2+ may not be related to K+ channel-blocking activity, because the ATP-evoked dopamine release obtained with 5 mM tetraethylammonium (TEA) was not inhibited by Cd2+.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of guanidine on transmitter release and neuronal excitability.

1. Guanidine hydrochloride (CH5N3-HCl) was applied to frog neuromuscular junctions blocked by reduced external Ca2+, or increased external Mg2+ concentration, or by both. Guanidine produced a dose-dependent increase in the average number of quanta released by presynaptic action potentials, the threshold dose being 0-1-0-2 mM. No post-synaptic effects were observed. 2. Guanidine also increased the excitability of the motor nerve fibres, as evidenced by multiple firing to single electrical stimuli and finally by spontaneous action potentials. These effects were studied in greater detail in giant axons (Müller axons) in the spinal cord of lamprey. Exposure to guanidine produced in these axons a progressive increase in excitability, manifested by repetitive firing to a single electrical stimulus, spontaneous membrane potential oscillations and spontaneous bursts of action potentials. Guanidine had no effect on the resting potential. 3. The effect of guanidine on the excitability of Müller axons was mimicked in every detail simply by reducing the divalent cation concentration of the bathing solution. 4. Guanidine also produced dose-dependent increases in the duration of action potentials in Müller axons. This effect always preceded in time the appearance of the excitability effects and was not mimicked by reducing the divalent cation concentration. It is suggested that the broadening of the action potential is separate from the excitability effects and may reflect a decrease of delayed rectification. 5. Guanidine (0-3 mM) increased the frequency of miniature end-plate potentials (min. e.p.p.) in solutions containing 2-11 mM-K+ in such a way as to shift the relationship between min. e.p.p. frequency and extracellular K+ toward lower values of K+. This effect was interpreted to mean that guanidine produced a depolarization of the nerve terminal which summed with the depolarization produced by a given concentration of K+. The calculated depolarization produced by 0-3 mM guanidine was 5-7 mV. 6. The effects of guanidine on evoked transmitter release, excitability, and min. e.p.p. frequency are consistent with a hypothesis which states that guanidine binds at or near fixed negative changes on the outside of nerve membrane and reduces the screening effect of divalent cations.     

Effects of membrane potential on Na+ -dependent Mg2+ extrusion from rat ventricular myocytes

To study Mg2+ transport across the cell membrane, the cytoplasmic concentration of Mg2+ ([Mg2+](i)) in rat ventricular myocytes was measured with the fluorescent indicator furaptra (mag-fura-2) under Ca2+ -free conditions (0.1 mM EGTA) at 25 degrees C. The fluorescence ratio signal of furaptra was converted to [Mg2+](i) using calibration parameters previously estimated in myocytes (Watanabe and Konishi, Pflügers Arch 442: 35-40, 2001). After [Mg2+](i) was raised by loading the cells with Mg2+ in a solution containing 93 mM Mg(2+), the cells were voltage-clamped at a holding potential of -80 mV using the perforated patch-clamp technique with amphotericin B. At the holding potential of -80 mV, the reduction of extracellular Mg2+ to 1.0 mM caused a rapid decrease in [Mg2+](i) only in the presence of extracellular Na(+). The rate of the net Mg2+ efflux appeared to be dependent on the initial level of [Mg2+](i); the decrease in [Mg2+](i) was significantly faster in the myocytes markedly loaded with Mg2+. The rate of decrease in [Mg2+](i) was influenced little by membrane depolarization from -80 to -40 mV, but the [Mg2+](i) decrease accelerated significantly at 0 mV by, on average, approximately 40%. Hyperpolarization from -80 to -120 mV slightly but significantly slowed the decrease in [Mg2+](i) by approximately 20%. The results clearly demonstrate an extracellular Na(+)- and intracellular Mg2+ -dependent Mg2+ efflux activity, which is consistent with the Na(+)-Mg2+ exchange, in rat ventricular myocytes. We found that the apparent rate of Mg2+ transport depends slightly on the membrane potential: facilitation by depolarization and inhibition by hyperpolarization with no sign of reversal between -120 and 0 mV.     

Caffeine-induced depolarization in amphibian skeletal muscle fibres: role of Na+/Ca2+ exchange and K+ release.

Caffeine (4 mM) produces a depolarization of about 10 mV in frog muscle fibres (Leptodactylus ocellatus). The aim of this work was to study the mechanisms of this effect. An approximately threefold rise in membrane resistance [Cl--free (SO(4)2-) medium] substantially increased, and both Na+-free medium and Ni2+ (5 mM) reduced, the caffeine-induced depolarization. In voltage-clamped (-60 mV) short fibres from lumbricalis muscle of the toad (Buffo arenarum), caffeine generated an inward current of 4.13 +/- 0.48 microA cm(-2). This caffeine-induced current was reduced by 60% in Na+-free medium, 44% in the presence of 5 mM amiloride and 48% by 5 mM Ni2+, suggesting that the activation of the Na+-Ca2+ exchanger in its forward mode may play a role in the observed electrical effects of the drug. Caffeine also produced a marked release of K+. Net K+ efflux increased from 3.5 +/- 0.2 (control) to 22.1 +/- 2.3 pmol s(-1) cm(-2) (caffeine). It is shown that in the presence of the drug, [K+] in the lumen of the T tubules may well increase to levels which could produce, in part, both the observed depolarization and the caffeine-induced current under voltage clamp conditions. The caffeine-induced K+ efflux was not reduced by 5 mM Ni2+. At a holding potential of 30 mV the caffeine-induced current was reversed (outward) and roughly halved by 5 mM Ni2+. The Ni2+-sensitive fraction of the caffeine-induced current, assumed to represent the Na+-Ca2+ exchanger current, had an estimated reversal potential close to 12 mV ([Na+]o = 115 mM; [Ca2+]o = 1 mM). In conclusion, the depolarizing effect of caffeine described here would be produced by two mechanisms: (a) an inward current generated by the activation of the Na+-Ca2+ exchanger in its forward mode, and (b) the rise of the external [K+] in restricted spaces like the T tubules.     

Membrane potential measurement in parotid acinar cells

1. Intracellular recording of membrane potential was made from acinar cells of the isolated mouse parotid gland superfused with physiological salt solutions.2. The mean acinar resting membrane potential was - 68.5 mV during superfusion with Krebs-Henseleit solution. Shift of the superfusion solution to one containing ACh or adrenaline (10(-5)M) always caused a transient hyperpolarization (about 10-15 mV).3. The membrane potential was mainly dependent on the extracellular K concentration ([K](o)). Increasing [K](o) tenfold decreased the membrane potential by 50 mV. This depolarization was not mediated by ACh release from depolarized nerve endings, since it was seen in the presence of atropine (1.4 x 10(-6)M) and not caused by the accompanying reduction in [Na](o) to 40 mM caused only a small depolarization (less than 10 mV).4. When the superfusion solution was shifted, during intracellular recording, from a normal Krebs-Henseleit solution ([K] = 4.7 mM) to a K-free solution, a hyperpolarization of about 8 mV was measured. Reintroduction of the normal K-containing solution after a longer period of K deprivation (30-70 min) resulted in a short-lasting pronounced hyperpolarization (about 20 mV) which could be blocked by Strophanthin-G (10(-3)M).5. In contrast to previous reports, the present findings indicate that the membrane potential of salivary acinar cells is similar, with respect to magnitude and K-dependence, to that of cells of more thoroughly investigated tissues, such as muscle and nerve, and that the membrane Na-K pump is electrogenic, at least when the cells have been loaded with Na.     

Divalent cations and the action potential of leech Retzius cells

Summary The effects of Sr, Ba, Mn, La and Co on the action potential of the leech Retzius cell were examined using intracellular recording techniques. A previous paper showed that these cells could fire Ca-dependent action potentials in Na-free solution provided TEA was present (Kleinhaus and Prichard, 1975). Under the same conditions Sr 1.5-20 mM was capable of substituting as a current carrier. Ba 2–25 mM added to normal Ringer prolonged the duration and increased the amplitude of the action potential of the Retzius cell, and supported action potentials without requiring TEA in Na-free solutions. The overshoots of the Sr- and Ba-dependent action potentials varied with a slope of 40 mM and 75 mV, respectively per 10-fold change in divalent cation concentration. Mn and La selectively blocked that portion of the action potential resulting from an inward movement of Ca, Sr or Ba without affecting the Na-dependent depolarization. The actions of Ca 1 mM on Sr-dependent action potentials were compatible with reversible competitive antagonism. In conclusion the findings: 1. support the proposition that outward K current must be blocked in order for divalent cations to dominate the Retzius cell's behavior during excitation. 2. characterize the divalent cation conductance channel as pharmacologically distinct from the Na conductance channel in the Retzius cell and similar to those described in several other excitable membranes. 3. suggest that the current carrying divalent cations probably flow through the same channel.     

Mechanism of action of magnesium on acetylcholine-evoked secretory responses in isolated rat pancreas.

This study investigates the effects of magnesium (Mg2+) on acetylcholine (ACh)-evoked secretory responses and calcium (Ca2+) mobilization in the isolated rat pancreas. ACh induced marked dose-dependent increases in total protein output and amylase release from superfused pancreatic segments in zero, normal (1 x 1 mM) and elevated (10 mM) extracellular Mg2+. Elevated Mg2+ attenuated the ACh-evoked secretory responses compared to zero and normal Mg2+. In the absence of extracellular Ca2+, but presence of 1 mM-EGTA (ethylene glycol bis(beta-aminoethylether)-N,N,N',N'-tetraacetic acid), ACh elicited a small transient release of protein from pancreatic segments compared to a larger and more sustained secretion in the absence of both Ca2+ and Mg2+. Incubation of pancreatic segments with 45Ca2+ resulted in time-dependent uptake with maximum influx of 45Ca2+ occurring after 20 min of incubation period. ACh stimulated markedly the 45Ca2+ uptake compared to control tissues. In elevated extracellular Mg2+ the ACh-induced 45Ca2+ influx was significantly (P less than 0.001) reduced compared to zero and normal Mg2+. ACh also evoked dose-dependent increases in cytosolic free Ca2+ concentrations ([Ca2+]i) in pancreatic acinar cells loaded with the fluorescent dye Fura-2 AM. In elevated Mg2+ the ACh-induced cytosolic [Ca2+]i was significantly (P less than 0.001) reduced compared to zero and normal Mg2+. These results indicate that Mg2+ can influence ACh-evoked secretory responses possibly by controlling both Ca2+ influx and release in pancreatic acinar cells.     

Isolation and kinetic analysis of inward currents in neuroblastoma cells

The suction pipette method for combined voltage clamp and intracellular dialysis was applied to isolate the two components of voltage-gated inward current across membranes of NIE-115 neuroblastoma cells. In order to analyze the kinetic behavior of the Na+ and Ca2+ channels responsible for generating these components, current through K+ channels was effectively blocked by substituting impermeant Cs+ for internal and external K+. Block was confirmed independently by examining the effects of the application of external tetraethylammonium or Cd2+; and comparing the time course of Ca2+ tail currents with the decay of current during a maintained depolarization. Na+ currents studied at 8-10 degrees C, developed as a fourth order process giving a maximum e-fold conductance change for a 3 mV depolarization, with half activation occurring at -10 mV. The instantaneous current-voltage relationship was linear. Time constants of the activation parameter (m) varied from 0.5 ms (-50 mV) to 3-4 ms (-10 to -40 mV) at 10 degrees C. Inactivation (h) was a first order process having a time constant between 4 ms (+10 to +60 mV) and 225 ms (-60 mV). Steady-state inactivation for Na+ channels attained a value of 0.5 at -50 mV. A slow inactivation process, however, also is involved in gating of Na+ channels, and has a time course at least two orders of magnitude slower than that for h. The temperature sensitivity of Na+ currents was found to be similar to that found for other preparations. Ca2+ currents were studied at 24-29 degrees C in the presence of internal ethyleneglycolbis-(aminoethylether)-tetra-acetate (EGTA) and an external Ca2+ concentration of 20 mM. Ca2+ channel activation could also be described by a fourth order process giving an e-fold conductance change for a 5-6 mV change in potential and the half activation potential of -13 mV. Internal EGTA (20 mM) did not abolish inactivation of Ca2+ currents and no recovery from inactivation caused by a prepulse could be measured as the prepulse potential approached the null potential for Ca2+ influx. Time constants of both activation and inactivation of Ca2+ channels were measured between -20 and +50 mV. Currents through K+ channels could be completely eliminated by substitution of K+ with Cs+, although a residual non-linear leakage current remained, in addition to currents through the Na+ and Ca2+ channels.(ABSTRACT TRUNCATED AT 400 WORDS)     

Calcium mediation of cholinergic-stimulated amylase release from mouse parotid gland.

Amylase release from mouse parotid fragments was stimulated independently by cholinergic and beta-adrenergic agents. The cholinergic agonist, carbachol, significantly increased release of amylase only in Ca2+ containing medium whereas isoproterenol-stimulated amylase release was unaffected by Ca2+ removal. The ionophore, A23187, mimicked the effect of cholinergic stimulation when Ca2+ was present in the medium. Uptake of 45Ca2+ into tissue fragments was enhanced by carbachol and A23187 but not by isoproterenol; atropine blocked the effect of carbachol. Diphenylhydantoin (DPH) and verapamil partially inhibited carbachol-stimulated amylase release and 45Ca2+ uptake, whereas diazoxide potentiated these effects; in all cases there was good parallelism between 45Ca2+ uptake and amylase release. It was concluded that the primary step in the release of amylase from mouse parotid gland in response to cholinergic agents is an increased influx of Ca2+.     

Pancreatic acinar cells: ionic dependence of the membrane potential and acetycholine-induced depolarization

1. Intracellular recordings of membrane potentials have been made in vitro from the exocrine acinar cells of the mouse pancreas using glass micro-electrodes.2. The mean membrane potential of the acinar cells during superfusion with Krebs-Henseleit solution was -39.2 mV. Increasing [K](o) tenfold decreased the membrane potential by 28 mV when [K](o) was above 10 mM. This depolarization was not affected by atropine (1.4 x 10(-6)M). Strophanthin-G (10(-3)M) slowly depolarized the cells at about 10 mV hr(-1).3. Brief exposure to acetylcholine (ACh), 5.5 x 10(-5)M, or pancreozymin resulted in a short lasting depolarization of the acinar cells. Atropine (1.4 x 10(-6)M) blocked the depolarizing action of ACh but not that of pancreozymin. Adrenaline (5.5 x 10(-5)M) or cyclic AMP (10(-3)-10(-4)M) did not influence the membrane potential.4. The amplitude of the ACh-induced depolarization was not dependent on the presence of CO(2)/HCO(3) in the bathing fluid, but it was closely dependent on the extracellular Na concentration. However, ACh was still able to evoke a small depolarization even after prolonged exposure of the tissue to a Na-free solution.5. During exposure of the tissue to a Ca-free solution the resting membrane potential was decreased and the ACh-induced depolarization was significantly reduced. Some substances which are known in other tissues to inhibit membrane Ca(2+) currents, i.e. La(3+), D-600 and tetracaine, were able to reduce, but never abolish, the ACh-induced depolarization.6. These results suggest that the effect of ACh on the pancreatic acinar cell is to increase the permeability of the membrane to commonly occurring ions with a consequent Na-influx and a small Ca-influx.