Modelling receptor-controlled intracellular calcium oscillators.

This paper presents mathematical models for the hepatocyte calcium oscillator which follow the concepts in a class of informal models developed to account for the striking dependence on the receptor type of several features of the calcium oscillations, in particular the shape and duration of the free calcium transients. The essence of these models is that the transients should be timed by a build-up of activated GTP-binding proteins, which, combined with positive feedback processes and perhaps with cooperative effects, leads to a sudden activation of phospholipase C (PLC), followed by negative feedback processes which switch off the calcium rise and lead to a fall in free calcium back to resting levels. These models predict pulsatile oscillations in inositol (1,4,5)P3 as well as in free calcium. We show that receptor-controlled intracellular calcium oscillators involving an unknown positive feedback pathway onto PLC and negative feedback from protein kinase C (PKC) onto G-proteins and receptors, or negative feedback by stimulation of GTPase activity can simulate many of the features of observed intracellular calcium oscillations. These oscillators exhibit a dependence of frequency on agonist concentration and a dependence of transient duration on receptor and G-protein type. We also show that a PLC-dependent GTPase activating factor (GAF) could provide explanations for some otherwise puzzling features of intracellular calcium oscillations.     

Dissecting calcium oscillators in plant cells.

To understand Ca2+ signaling, we need to identify all the Ca2+ transporters and their regulatory components. The first Ca2+ transporters to be cloned from plants and shown to have regulated activity were calmodulin-dependent Ca2+ -pumps. The regulation of these pumps suggests that being able to change the rate of Ca2+ efflux is important for Ca2+ signaling. The identification of pumps and antiporters in different subcellular locations is helping to dissect the complexities of Ca2+ signaling in plants.     

Subcellular calcium oscillators and calcium influx support agonist-induced calcium waves in cultured astrocytes

We have analysed Ca²⁺ waves induced by norepinephrine in rat cortical astrocytes in primary culture using fluorescent indicators fura-2 or fluo-3. The temporal pattern of the average [Ca²⁺]_i responses were heterogeneous from cell to cell and most cells showed an oscillatory response at concentrations of agonist around EC₅₀ (200 nM). Upon receptor activation, [Ca²⁺]_i signals originated from a single cellular locus and propagated throughout the cell as a wave. Wave propagation was supported by specialized regenerative calcium release loci along the length of the cell. The periods of oscillations, amplitudes, and the rates of [Ca²⁺]_i rise of these subcellular oscillators differ from each other. These intrinsic kinetic properties of the regenerative loci support local waves when stimulation is continued over long periods of time. The presence of local waves at specific, invariant cellular sites and their inherent kinetic properties provide for the unique and reproducible pattern of response seen in a given cell. We hypothesize that these loci are local specializations in the endoplasmic reticulum where the magnitude of the regenerative Ca²⁺ release is higher than other regions of the cell. Removal of extracellular Ca²⁺ or blockade of Ca²⁺ channels by inorganic cations (Cd²⁺ and Ni²⁺) during stimulation of adrenergic receptors alter the sustained plateau component of the [Ca²⁺]_i response. In the absence of Ca²⁺ release, due to store depletion with thapsigargin, agonist occupation alone does not induce Ca²⁺ influx in astrocytes. This finding suggests that, under these conditions, receptor-operated Ca²⁺ entry is not operative. Furthermore, our experiments provide evidence for local Ca²⁺ oscillations in cells which can support both wave propagation as well as spatially discrete Ca²⁺ signalling.     

Cytosolic free calcium and ATP in synaptosomes after ischemia

Elevations in cytosolic free calcium ([Ca2+]i) precede electrophysiological alterations due to ischemia in vivo. An in vitro model of these changes would help to elucidate their molecular basis. A model of postdecapitative ischemia was used to study these interactions. Nerve endings (i.e. synaptosomes) were isolated either immediately after decapitation or at various time periods after decapitation. Synaptosomal [Ca2+]i and ATP concentrations were determined during a basal period and following depolarization. K(+)-depolarization produced an initial spike of [Ca2+]i that was followed by a new equilibrium value. Ischemia elevated the basal [Ca2+]i and the new equilibrium [Ca2+]i after KCl but suppressed the [Ca2+]i spike. However, the difference between the basal [Ca2+]i and the new equilibrium [Ca2+]i after K(+)-depolarization did not vary with ischemia. Although ischemia reduced ATP, K(+)-depolarization did not alter ATP concentrations in either the controls or the ischemia group, which suggests that synaptosomal mitochondria can meet an energy demand after ischemia. ATP was inversely related to the basal or the new equilibrium [Ca2+]i following depolarization. These changes in [Ca2+]i may underlie the alterations in neurotransmitter release and cell death following ischemia. This appears to be a useful model in which to study the molecular basis of ischemia induced changes in [Ca2+]i.     

Cytosolic free calcium concentrations in synaptosomes during histotoxic hypoxia

Altered cytosolic free calcium concentrations ([Ca²⁺]_i) accompany impaired brain metabolism and may mediate subsequent effects on brain function and cell death. The current experiments examined whether hypoxia-induced elevations in [Ca²⁺]_i are from external or internal sources. In the absence of external calcium, neither KCl depolarization, histotoxic hypoxia (KCN), nor the combination changed [Ca²⁺]_i. However, with external CaCl₂ concentrations as small as 13 M, KCl depolarization increased [Ca²⁺]_i instantaneously while hypoxia gradually raised [Ca²⁺]_i. The combination of KCN and KCl was additive. Increasing external calcium concentrations up to 2.6 mM exaggerated the effects of K⁺ and KCN on [Ca²⁺]_i, but raising medium calcium to 5.2 mM did not further augment the rise. Diminishing the sodium in the media, which alters the activity and perhaps the direction of the Na/Ca exchanger, reduced the increase in [Ca²⁺]_i due to hypoxia, but enhanced the KCl response. The changes in ATP following K⁺ depolarization, KCN or their combination in the presence of physiological calcium concentrations did not parallel alterations in [Ca²⁺]_i, which suggests that diminished activity of the calcium dependent ATPase does not underlie the elevation in [Ca²⁺]_i. Valinomycin, an ionophore which reduces the mitochondrial membrane potential, elevated [Ca²⁺]_i and the effects were additive with K⁺ depolariration in a calcium dependent manner that paralleled the effects of hypoxia. Together these results suggest that hypoxia-induced elevations of synaptosomal [Ca²]_i are due to an inability of the synaptosome to buffer entering calcium.     

Cytosolic free calcium concentrations in avian growth plate chondrocytes

Isolated avian growth plate chondrocytes convert the acetoxymethyl ester (AM) form of Fura-2 quickly and efficiently to the Ca2(+)-sensitive pentacarboxylic acid (FA) form. Control experiments indicate that the Kd for intracellular Fura-2/FA is very close to that of extracellular Fura-2/FA at the same ionic strength and pH and that the Fura-2/FA fluorescence from indicator converted by intracellular organelles is quite small. Correcting for the effects of extracellular Fura-2/FA and partial hydrolysis products has improved the accuracy of determination of intracellular [Ca2+] over earlier measurements in chondrocytes. Cytosolic [Ca2+] in isolated growth plate chondrocytes (containing cells from each maturational stage) is found to require approximately 9 hours to recover from the isolation process. After this recovery period, cytosolic [Ca2+] in these cells converges to approximately 70 nM regardless of the [Ca2+] of the recovery medium, suggesting regulation of cytosolic [Ca2+] to a set point. Chondrocytes that are separated into maturationally distinct fractions using countercurrent centrifugal elutriation show an increase in cytosolic [Ca2+] with cellular maturation. The least mature resting cells have a [Ca2+] near 57 nM, while the most mature hypertrophic cells are around 95 nM.     

Cytosolic free calcium spiking affected by intracellular pH change

The characteristics underlying cytosolic free calcium oscillation were evaluated by superfused dual wave-length microspectrofluorometry of fura-2-loaded single acinar cells from rat pancreas. Application of a physiological concentration of cholecystokinin octapeptide (CCK) (20 pM) induced a small basal increase in cytosolic free calcium concentration ([Ca2+]i) averaging 34 nM above the prestimulation level (69 nM) with superimposed repetitive Ca2+ spike oscillation. The oscillation amplitude averaged 121 nM above the basal increase in [Ca2+]i and occurred at a frequency of one pulse every 49 s. Although extracellular Ca2+ was required for maintenance of high frequency and amplitude of the spikes with increase in basal [Ca2+]i, the primary source utilized for oscillation was intracellular. The threshold of the peak [Ca2+]i amplitude for causing synchronized and same-sized oscillations was less than 300 nM. The [Ca2+]i oscillation was sensitive to intracellular pH (pHi) change. This is shown by the fact that the large pHi shift toward acidification (delta pHi decrease, 0.95) led to a basal increase in [Ca2+]i to the spike peak level with inhibiting Ca2+ oscillation. The pHi shift toward alkalinization (delta pHi increase, 0.33) led to a basal decrease in [Ca2+]i to the prestimulation level, possibly due to reuptake of Ca2+ into the Ca2+ stores, with inhibiting Ca2+ oscillation. Whereas extracellular pH (pHo) change had only minimal effects on Ca2+ oscillation (and/or Ca2+ release from intracellular stores), the extra-Ca2+ entry process, which was induced by higher concentrations of CCK, was totally inhibited by decreasing pHo from 7.4 to 6.5. Thus the major regulatory sites by which H+ affects Ca2+ oscillation are accessible from the intracellular space.     

Cytosolic calcium, calcium fluxes, and regulation of alveolar macrophage superoxide anion production

The recently available compound quin-2, which acts as a high affinity fluorescent indicator for calcium in the cytosol, was used to examine the role of calcium mobilization in the alveolar macrophage during the stimulation of 0-2 production by the tripeptide N-formyl norleucyl leucyl phenylalanine (FNLLP). After preloading with quin-2, the production of 0-2 was measured in conjunction with the transfer of 45Ca+2 and changes in quin-2 fluorescence upon stimulation with FNLLP. When cells were maintained in low (10 microM) extracellular calcium medium the presence of 1.5 mM quin-2 in the cytosolic space partially inhibited the rate of 0-2 production upon stimulation by FNLLP. Addition of 1 mM Ca+2 to the medium prior to stimulation rapidly restored the cell's capability to produce 0-2 upon stimulation at rates equal to control and extended the duration of stimulated 0-2 production as well. Quin-2 fluorescence measurements indicated an increase in cytosolic Ca+2 upon stimulation with FNLLP. This increase was lowest under conditions in which 0-2 production was inhibited. The addition of 1 mM Ca+2 to the medium caused by itself a rapid but transient increase in cytosolic Ca+2 as measured with quin-2 without stimulating 0-2 production. This intracellularly redistributed calcium was determined to be the source of the greater increase in cytosolic calcium during stimulation in the presence of high extracellular calcium. Measurements of 45Ca+2 transfer demonstrated a buffering of cytosolic Ca+2 changes by quin-2, which in low calcium medium could deplete calcium stores. It is suggested that this effect, prior to stimulation, was responsible for the mitigated 0-2 response for those cells maintained in low calcium medium, wherein calcium stores could not be replenished. These results suggested that the cell's mechanism for regulating cytosolic and bound calcium concentrations may also play an integral role in its normal mechanism for stimulated 0-2 production. They further support the postulate that the commonly observed rise in the concentration of calcium in the cytosol upon formyl peptide stimulation is a concomitant but nonregulatory event only.     

Cytosolic free calcium concentration and intracellular calcium distribution in lymphocytes from cystic fibrosis patients

Lymphocytes prepared from normal individuals and patients with cystic fibrosis (CF) were compared with regard to intercellular Ca²⁺ concentration, distribution, and handling. No difference between control and CF was found in the concentration of cytosolic free Ca²⁺ ($\text{98 ± 5}\text{vs}\text{102 ± 7}\text{nM}$), and no difference was observed in the kinetics with which control and CF cells restored cytoplasmic Ca²⁺ toward normal following a perturbation induced by cold-exposure. However, total intracellular Ca²⁺ is about 25% higher in CF lymphocytes than in control. Of this excess Ca²⁺, about 50% appears to be sequested in mitochondria. This suggests that some difference in Ca²⁺ handling does exist, but the significance of this cystic fibrosis remains to be determined.     

Cytosolic free calcium dependent regulation of osteoclast bone resorbing activity

Osteoclasts are sensitive to KCl-induced depolarization and to increased extracellular calcium concentration, and respond to these treatments with cytosolic calcium increase. In this study we evaluated the possibility that these experimental conditions could affect osteoclast bone resorption. We found that, incubating osteoclasts with 3H-proline previously labeled bone particles the resorbing activity was inhibited by both depolarization and extracellular calcium concentration increase. The released radioactivity was, in fact, 48% and 52% respectively compared to the untreated cultures. These data demonstrated that cytosolic calcium increase is one of the messengers of the pathway that inhibits, in this condition, bone resorption. Furthermore, as in parathyroid cells, extracellular calcium acts with a negative direct feedback mechanism that controls osteoclast activity.     

Cytosolic calcium and pH signaling in plants under salinity stress

Calcium is one of the essential nutrients for growth and development of plants. It is an important component of various structures in cell wall and membranes. Besides some fundamental roles under normal condition, calcium functions as a major secondary-messenger molecule in plants under different developmental cues and various stress conditions including salinity stress. Also changes in cytosolic pH, pH_cyt, either individually, or in coordination with changes in cytosolic Ca²⁺ concentration, [Ca²⁺]_cyt, evoke a wide range of cellular functions in plants including signal transduction in plant-defense responses against stresses. It is believed that salinity stress, like other stresses, is perceived at cell membrane, either extra cellular or intracellular, which then triggers an intracellular-signaling cascade including the generation of secondary messenger molecules like Ca²⁺ and protons. The variety and complexity of Ca²⁺ and pH signaling result from the nature of the stresses as well as the tolerance level of the plant species against that specific stress. The nature of changes in [Ca²⁺]_cyt concentration, in terms of amplitude, frequency and duration, is likely very important for decoding the specific downstream responses for salinity stress tolerance in planta. It has been observed that the signatures of [Ca²⁺]_cyt and pH differ in various studies reported so far depending on the techniques used to measure them, and also depending on the plant organs where they are measured, such as root, shoot tissues or cells. This review describes the recent advances about the changes in [Ca²⁺]_cyt and pH_cyt at both cellular and whole-plant levels under salinity stress condition, and in various salinity-tolerant and -sensitive plant species.Key words: cytosolic calcium, ionic toxicity, osmotic stress, pH, salinity stress, salt tolerance, signaling     

Cytosolic calcium regulation in rat afferent vagal neurons during anoxia

Sensory neurons are able to detect tissue ischaemia and both transmit information to the brainstem as well as release local vasoactive mediators. Their ability to sense tissue ischaemia is assumed to be primarily mediated through proton sensing ion channels, lack of oxygen however may also affect sensory neuron function. In this study we investigated the effects of anoxia on isolated capsaicin sensitive neurons from rat nodose ganglion. Acute anoxia triggered a reversible increase in [Ca²⁺]_i that was mainly due to Ca²⁺-efflux from FCCP sensitive stores and from caffeine and CPA sensitive ER stores. Prolonged anoxia resulted in complete depletion of ER Ca²⁺-stores. Mitochondria were partially depolarised by acute anoxia but mitochondrial Ca²⁺-uptake/buffering during voltage-gated Ca²⁺-influx was unaffected. The process of Ca²⁺-release from mitochondria and cytosolic Ca²⁺-clearance following Ca²⁺ influx was however significantly slowed. Anoxia was also found to inhibit SERCA activity and, to a lesser extent, PMCA activity. Hence, anoxia has multiple influences on [Ca²⁺]_i homeostasis in vagal afferent neurons, including depression of ATP-driven Ca²⁺-pumps, modulation of the kinetics of mitochondrial Ca²⁺ buffering/release and Ca²⁺-release from, and depletion of, internal Ca²⁺-stores. These effects are likely to influence sensory neuronal function during ischaemia.     

Cytosolic calcium regulates phorbol diester binding affinity in intact phagocytes

The mobilization of internally sequestered stores of Ca2+ and activation of protein kinase C appear to be involved in neutrophil activation. We have examined the inter-relationship of these two pathways by investigating the effects of modulating Ca2+ activity on the binding of [3H]phorbol 12,13-dibutyrate (PDBU) to protein kinase C in intact phagocytes. Differentiated HL-60 cells were equilibrated with [3H]PDBU prior to stimulation with various agents known to alter Ca2+ homeostasis in cells. Agents that elevated cytosolic Ca2+, such as f-Met-Leu-Phe and A23187, up-regulated radioligand binding by increasing the affinity of the PDBU/protein kinase C interaction. These effects were time- and agonist concentration-dependent and temperature-sensitive. The kinetics of the up-regulation of binding by f-Met-Leu-Phe coincided with the kinetics of Ca2+ mobilization (by quin2 fluorescence measurements). The putative intracellular Ca2+ antagonist 8-(N,N-diethylamino)-octyl 3,4,5-trimethoxybenzoate alone down-regulated [3H]PDBU binding and inhibited the up-regulation of ligand binding by f-Met-Leu-Phe and A23187. Low concentrations of La3+ (0.1-10 microM) also inhibited up-regulation of radioligand binding to f-Met-Leu-Phe and A23187, whereas higher concentrations (0.1-1 mM) alone increased [3H] PDBU binding and supported further up-regulation of ligand binding by the Ca2+-mobilizing agents. These data suggest a role for Ca2+ in the regulation of phorbol diester binding to protein kinase C in intact cells.     

Cytosolic organelles shape calcium signals and exo-endocytotic responses of chromaffin cells

The concept of stimulus-secretion coupling was born from experiments performed in chromaffin cells 50 years ago. Stimulation of these cells with acetylcholine enhances calcium (Ca(2+)) entry and this generates a transient elevation of the cytosolic Ca(2+) concentration ([Ca(2+)](c)) that triggers the exocytotic release of catecholamines. The control of the [Ca(2+)](c) signal is complex and depends on various classes of plasmalemmal calcium channels, cytosolic calcium buffers, the uptake and release of Ca(2+) from cytoplasmic organelles, such as the endoplasmic reticulum, mitochondria, chromaffin vesicles and the nucleus, and Ca(2+) extrusion mechanisms, such as the plasma membrane Ca(2+)-stimulated ATPase, and the Na(+)/Ca(2+) exchanger. Computation of the rates of Ca(2+) fluxes between the different cell compartments support the proposal that the chromaffin cell has developed functional calcium tetrads formed by calcium channels, cytosolic calcium buffers, the endoplasmic reticulum, and mitochondria nearby the exocytotic plasmalemmal sites. These tetrads shape the Ca(2+) transients occurring during cell activation to regulate early and late steps of exocytosis, and the ensuing endocytotic responses. The different patterns of catecholamine secretion in response to stress may thus depend on such local [Ca(2+)](c) transients occurring at different cell compartments, and generated by redistribution and release of Ca(2+) by cytoplasmic organelles. In this manner, the calcium tetrads serve to couple the variable energy demands due to exo-endocytotic activities with energy production and protein synthesis.     

Cytosolic free calcium increases before and oscillates during frustrated phagocytosis in macrophages

When macrophages and neutrophils are allowed to settle onto an appropriate surface, they attach and spread in a frustrated attempt to phagocytose the substrate. Spreading is associated with extensive rearrangements of the actin cytoskeleton which resemble those occurring during phagocytosis. We have previously shown that spreading in human neutrophils is preceded by an increase in cytosolic-free calcium concentration [( Ca2+]i) (Kruskal, B. A., S. Shak, and F. R. Maxfield. 1986. Proc. Natl. Acad. Sci. USA. 83:2919-2923). To assess the generality of this signal, we measured [Ca2+]i in single thioglycollate- elicited mouse peritoneal macrophages as they spread on an immune complex-coated surface, using fura-2 microspectrofluorometry. A [Ca2+]i increase always precedes spreading. This increase can involve several (up to 8) [Ca2+]i spikes, with an average peak value of 387 +/- 227 nM (mean +/- SD, n = 92 peaks in 24 cells), before spreading is detected. Neither spreading nor the magnitude of these spikes is significantly altered by removal of extracellular calcium. Many of the spreading macrophages exhibit periodic [Ca2+]i increases before and during spreading. The proportion which does so varies among experiments from 0 to 90%, but it is frequently greater than 40%. The largest number of cells (approximately 25%) exhibited only a single peak. In 13 cells that showed more than 10 peaks, the median period was 29 s (range 19-69 s). The average peak [Ca2+]i was 385 +/- 266 nM (mean +/- SD, n = 208 peaks in 14 cells). The calcium producing these increases is derived from intracellular pools. The oscillations occur with spreading on either opsonized or nonopsonized surfaces. The function of these oscillations is not clear, but the large number of cells which exhibit them suggest that they may be important to macrophage function.     

Thrombin's effects on osteoblastic cells. I. Cytosolic calcium and phosphoinositides

Thrombin, a blood coagulation factor, has been shown to be a very effective in vitro bone resorbing agent whose mechanism of action on osteoblastic cells remains to be elucidated. In the present study, the effects of highly purified human thrombin on Saos-2 and G292 cells, two human osteoblast-like osteosarcoma cell lines, were investigated. Thrombin (0.6-16 U/ml) caused a significant, dose-dependent increase in osteoblastic cell proliferation. Thrombin also elicited a dose-dependent increase in cytosolic calcium concentration in both Saos-2 and G292 cells (maximal increases were 38% and 200% over baseline, respectively). Addition of thrombin to the osteoblast-like cells resulted in significant time- and dose-dependent changes in phosphoinositide levels: the percentage of inositol monophosphate levels were decreased, whereas the percentage of inositol bisphosphate, inositol trisphosphate and inositol tetrakisphosphate levels were increased. The relative magnitude of the changes in phosphoinositide levels was similar to the changes in cytosolic calcium concentration. These results suggest that thrombin's mechanism of action on bone cells may involve increases in cytosolic calcium levels and in phosphoinositide metabolism.