High external Ca2+ levels trigger membrane potential oscillations in mouse pancreatic beta-cells during blockade of K(ATP) channels.

Glucose depolarizes the pancreatic beta-cell and induces membrane potential oscillations, but the nature of the underlying oscillatory conductance remains unknown. We have now investigated the effects of the Ca2+ ionophore ionomycin and high external Ca2+ concentration ([Ca2+]o) on glucose-induced electrical activity and whole islet intracellular free Ca2+ concentration ([Ca2+]i), under conditions where the K(ATP) channel was blocked (100 microM tolbutamide or 4 microM glibenclamide). Raising [Ca2+]o to 10.2 or 12.8 mM, but not to 5.1 or 7.7 mM, turned continuous electrical activity into bursting activity. High [Ca2+]o (12.8 mM) regenerated a pattern of fast [Ca2+]i oscillations overshooting the levels recorded in tolbutamide. Ionomycin (10 microM) raised the [Ca2+]i and synergized with 5.1 mM Ca2+ to hyperpolarize the beta-cell membrane. The data indicate that a [Ca2+]i-sensitive and sulphonylurea-insensitive oscillatory conductance underlies the beta-cell bursting activity.     

Cytosolic Ca2+ oscillations by gastrin releasing peptide in single HIT-T15 cells.

In single, superfused, FURA-2AM loaded insulin producing HIT-T15 cells, gastrin releasing peptide (GRP) induced a peak in cytoplasmnic Cu2+ ([Ca2+]i) followed by a sustained (high GRP concentrations) or oscillatory (low GRP concentrations) [Ca2+]i pattern. The GRP (25-50 microM)-induced [Ca2+]i oscillations ceased upon removal of glucose or addition of thapsigargin (1 microM), EGTA (2 mM), or diazoxide (200 microM), whereas nifedipine (10 microM) reduced their amplitude (by 35%). Both protein kinase C (PKC)-activation or PKC-inhibition disrupted GRP induced [Ca2+]i oscillations. GRP induced [Ca2+]i oscillations in insulin producing cells therefore rely on intracellular Ca2+ mobilization, voltage-dependent and voltage-independent Ca2+ entry mechanisms and the integrity of protein kinase C.     

Immunoglobulin E receptor cross-linking induces oscillations in intracellular free ionized calcium in individual tumor mast cells

Fura-2 fluorescence in single rat basophilic leukemia cells was monitored to study the rise in intracellular free ionized calcium ([Ca2+]i) produced by aggregation of immunoglobulin E receptors. Repetitive transient increases in [Ca2+]i were induced by antigen stimulation and were measured using digital video imaging microscopy at high time resolution. The [Ca2+]i oscillations were not dependent upon changes in the membrane potential of the cells and were observed in cells stimulated with antigen either with or without extracellular Ca2+. Transient oscillations in [Ca2+]i were also observed when calcium influx was blocked with La3+. These results suggested that during antigen stimulation of cells under normal physiological conditions, release of Ca2+ from intracellular stores makes an important contribution to the initial increase in [Ca2+]i. Oscillations in [Ca2+]i are not induced by elevating [Ca2+]i with the calcium ionophore ionomycin. Mitochondrial calcium buffering is not required for [Ca2+]i oscillations to occur. The results show that rat basophilic leukemia cells have significant stores of calcium and that release of calcium from these stores can participate in both the initial rise and the oscillations in [Ca2+]i.     

Cell-specific patterns of oscillating free Ca2+ in carbamylcholine-stimulated insulinoma cells

The effect of the muscarinic agonist carbamylcholine on cytoplasmic Ca2+ concentration ([Ca2+]i was examined at the single cell level in clonal pancreatic beta-cells (HIT). Cells were loaded with the indicator dye fura 2, and [Ca2+]i was measured by microfluorimetry. Carbamylcholine induced changes in Ca2+ that differed from cell to cell and provoked in some cells oscillatory Ca2+ fluctuations. During a transient, free Ca2+ rose to a peak within 1-3 s. The frequency of the oscillations increased with agonist concentration. Oscillations in [Ca2+]i occurred in the absence of external Ca2+. When cells were perifused for a sufficient period of time without carbamylcholine, near identical Ca2+ responses were elicited in each cell by successive applications of the agonist. Thus, individual cells displayed characteristic and reproducible Ca2+ responses with respect to amplitude, frequency, and shape of the transients as well as latency in onset of the initial Ca2+ rise. We propose that the biological response to a Ca2+ agonist in a given cell is not only determined by the frequency and amplitude of Ca2+ oscillations but is governed by the unique pattern of the Ca2+ signal of each cell, which may be termed "Ca2+ fingerprint."     

Phase-dependent contributions from Ca2+ entry and Ca2+ release to caffeine-induced [Ca2+]i oscillations in bullfrog sympathetic neurons.

Sympathetic neurons display robust [Ca2+]i oscillations in response to caffeine and mild depolarization. Oscillations occur at constant membrane potential, ruling out voltage-dependent changes in plasma membrane conductance. They are terminated by ryanodine, implicating Ca(2+)-induced Ca2+ release. Ca2+ entry is necessary for sustained oscillatory activity, but its importance varies within the oscillatory cycle: the slow interspike rise in [Ca2+]i requires Ca2+ entry, but the rapid upstroke does not, indicating that it reflects internal Ca2+ release. Sudden alterations in [Ca2+]o, [K+]o, or [caffeine]o produce immediate changes in d[Ca2+]i/dt and provide information about the relative rates of surface membrane Ca2+ transport as well as uptake and release by internal stores. Based on our results, [Ca2+]i oscillations can be explained in terms of coordinated changes in Ca2+ fluxes across surface and store membranes.     

Intracellular calcium oscillations regulate ciliary beat frequency of airway epithelial cells

The effect of ATP-induced Ca2+ oscillations on ciliary activity was examined in airway epithelial cells by simultaneously measuring the ciliary beat frequency (CBF) and the intracellular Ca2+ concentration ([Ca2+]i) near the base of the cilia. Exposure to extracellular ATP (ATPo) induces a rapid and large increase in both [Ca2+]i and CBF, followed by oscillations in [Ca2+]i and a sustained elevation in CBF. After each Ca2+ oscillation, the [Ca2+]i returned to near basal values. By contrast, the CBF remained elevated during these Ca2+ oscillations, although each Ca2+ oscillation induced small variations in CBF. During Ca2+ oscillations, increases in CBF closely followed the rising phase of increases in [Ca2+]i, but declines in CBF lagged behind declines in [Ca2+]i. Higher frequency Ca2+ oscillations reduced variations in CBF, producing a stable and sustained elevation in CBF. The maximal CBF was induced by Ca2+ oscillations and was 15% greater than the CBF induced by the substantially larger initial [Ca2+]i increase. These data demonstrate that the rate of CBF is not directly dependent on the absolute [Ca2+]i, but is dependent on the differential changes in [Ca2+]i and suggest that CBF in airway epithelial cells is regulated by frequency-modulated Ca2+ signaling.     

Spontaneous and agonist-induced calcium oscillations in pituitary gonadotrophs

Basal and receptor-regulated changes in cytoplasmic calcium concentration ([Ca2+]i) were monitored by fluorescence analysis in individual rat pituitary gonadotrophs loaded with the calcium-sensitive dye indo-1. Most gonadotrophs exhibited low amplitude spontaneous oscillations in basal [Ca2+]i that were interspersed by quiescent periods and abolished by removal of extracellular Ca2+ or addition of calcium channel blockers. Such random fluctuations in [Ca2+]i, which reflect the operation of a plasma membrane oscillator, were not coupled to basal gonadotropin secretion. The physiological agonist GnRH induced high amplitude [Ca2+]i oscillations; when a threshold [Ca2+]i level was reached, a cytoplasmic oscillator began to generate extremely regular Ca2+ transients. The time required to reach the threshold [Ca2+]i level was inversely correlated with agonist dose; the frequency, but not the amplitude, of agonist-induced Ca2+ spiking increased with agonist concentration. The duration of the latent period decreased and the frequency of Ca2+ spiking increased with the increase in ambient temperature. At high GnRH concentrations, the calcium transients merged into biphasic responses similar to those observed in cell suspensions at all GnRH concentrations. The presence of spontaneous fluctuations in basal [Ca2+]i did not significantly change the patterns of agonist-induced [Ca2+]i responses. Also, removal of extracellular Ca2+ did not interfere with the frequency or amplitude of Ca2+ spikes, but caused the loss of the plateau phase. Blockade of intracellular Ca(2+)-ATPase pumps by thapsigargin was usually accompanied by a subthreshold increase in [Ca2+]i. In such cells the agonist-induced oscillatory pattern was transformed into the biphasic response. In about 10% of the cells, however, high thapsigargin concentrations induced coarse [Ca2+]i oscillations; subsequent stimulation of such cells with GnRH was ineffective. The cytoplasmic oscillatory and biphasic responses may represent a mechanism for differential activation of Ca(2+)-dependent enzymes and their dependent cellular processes, including hormone secretion. The membrane oscillator is probably responsible for refilling of agonist-sensitive pools during and after agonist stimulation.     

Characterization of oscillations in cytosolic free Ca2+ concentration and measurement of cytosolic Na+ concentration changes evoked by angiotensin II and vasopressin in individual rat aortic smooth muscle cells. Use of microfluorometry and digital imaging

Dual wavelength microfluorometry was used to characterize the changes in cytosolic free Ca2+ concentration [( Ca2+]i) in individual cultured rat aortic vascular smooth muscle cells (VSMC). Angiotensin II (ANG II) at 10(-8) M induced a transient rise in [Ca2+]i from 43 +/- 2 to 245 +/- 23 nM, lasting for approximately 60 s (n = 42). In half of the population, discrete oscillations in [Ca2+]i of smaller amplitude occurred after the initial [Ca2+]i peak, with a period of 58 +/- 8 s and a maximum height of 132 +/- 24 nM. A similar oscillatory pattern was observed with arginine vasopressin (AVP). The oscillations depended upon the presence of extracellular Ca2+. Cytosolic free Na+ concentration ([Na+]i) in VSMC was also measured using the fluorescent Na+ probe sodium-binding benzofuran isophthalate. ANG II induced a gradual and sustained elevation of [Na+]i, from 24.0 +/- 6.2 to 36 +/- 9.7 mM. In response to AVP, [Na+]i rose to 41.0 +/- 11.6 mM. Video imaging of individual VSMC, with on-line ratio calibration of [Ca2+]i, revealed an inhomogeneous distribution of Ca2+ within the cell. [Ca2+] in the nucleus was invariably lower than in the cytoplasm in resting cells. In the cytoplasm, there were small regions in which [Ca2+] was elevated, or "hot spots." In Ca(2+)-containing medium, the initial rise in [Ca2+]i triggered by ANG II and AVP appeared to emanate from the hot spots and to spread evenly throughout the cytoplasm. Between [Ca2+]i oscillations, Ca2+ retreated back to the original hot spots. This study demonstrates the cellular and subcellular heterogeneity of [Ca2+]i both in resting VSMC and during stimulation by ANG II and AVP and reports the direct measurement of [Na+]i in VSMC. The results suggest an action of Ca2+ in both the initial and sustained phases of the response in VSMC and a link between changes in [Ca2+]i and [Na+]i.     

Mouse mast cell secretory granules can function as intracellular ionic oscillators

Fluorescent Ca2+ probes and digital photo-sectioning techniques were used to directly study the dynamics of Ca2+ in isolated mast cell granules of normal (CB/J) and beige (Bg(j)/Bg(j)) mice. The resting intraluminal free Ca2+ concentration ([Ca2+]L) is 25 +/- 4.2 microM (mean +/- SD, n = 68). Exposure to 3 microM inositol 1,4,5-trisphosphate (InsP3) induced periodic oscillations of luminal Ca2+ ([Ca2+]L) of approximately 10 microM amplitude and a period around 8-10 s. The [Ca2+]L oscillations were accompanied by a corresponding oscillatory release of [Ca2+]L to the extraluminal space. Control experiments using ruthenium red (2 microM) and thapsigargin (100 nM) ruled out artifacts derived from the eventual presence of mitochondria or endoplasmic reticulum in the isolated granule preparation. Oscillations of [Ca2+]L and Ca2+ release result from a Ca2+/K+ exchange process whereby bound Ca is displaced from the heparin polyanionic matrix by inflow of K+ into the granular lumen via an apamin-sensitive Ca2+-sensitive K+ channel (ASK(Ca)), whereas Ca2+ release takes place via an InsP3-receptor-Ca2+ (InsP3-R) channel. These results are consistent with previous observations of [Ca2+]L oscillations and release in/from the endoplasmic reticulum and mucin granules, and suggest that a highly conserved common mechanism might be responsible for [Ca2+]L oscillations and quantal periodic Ca2+ release in/from intracellular Ca2+ storage compartments.     

Glucose sensing of individual pancreatic beta-cells involves transitions between steady-state and oscillatory cytoplasmic Ca2+.

Glucose stimulation of individual pancreatic beta-cells is associated with a rise of the cytoplasmic Ca2+ concentration ([Ca2+]i) manifested either as large amplitude oscillations (0.2-0.5/min) or as a sustained increase. Determinants for the transitions between the basal and the two stimulated states have now been studied using dual-wavelength fluorometric measurements on individual ob/ob mouse beta-cells loaded with the Ca2+ indicator Fura-2. The transition from the basal state to large amplitude oscillations was induced by raising the glucose concentration to 7 mM or above. The frequencies and shapes of the [Ca2+]i cycles remained largely unaffected when raising glucose as high as 40 mM. However, in some cells the oscillatory pattern was transformed into a sustained increase of [Ca2+]i at high glucose concentrations. Although the peak values for the oscillations exceeded the steady-state increase, the time average [Ca2+]i was higher during the latter phase. Both types of glucose-induced transitions were facilitated by the presence of 1-100 nM glucagon. Protein kinase C activation by 10 nM of the phorbol ester TPA resulted in a transformation of the glucose-induced oscillations into a sustained increase of [Ca2+]i but the levels reached were considerably lower than obtained with glucose alone. It is concluded that the glucose sensing of the individual beta-cell is based on sudden transitions between steady-state and oscillating cytoplasmic Ca2+. It is these transitions rather than alterations of the oscillatory characteristics which determine the average [Ca2+]i regulating insulin release.