Two types of store-operated channels in A431 cells

Activation of phospholipase C-coupled receptors leads to the release of Ca2+ from Ca2+ stores, and subsequent activation of store-operated cation (SOC) channels, promoting sustained Ca2+ influx. The most studied SOC channels are CRAC ("calcium-release activated calcium") channels exhibiting a very high selectivity for Ca2+. However, there are many SOC channels permeable for Ca2+ but having a lower selectivity. And while Ca2+ influx is important for many biological processes, little is known about the types of SOC channels and mechanisms of SOC channel activation. Previously, we described store-operated Imin channels in A431 cells. Here, by whole-cell recordings, we demonstrated that the store depletion activates two types of current in A431 cells--highly selective for divalent cations (presumably, ICRAC), and moderately selective (ISOC supported by Imin channels). These currents can be registered separately and have different developing time and amplitude. Coexisting of two different types of SOC channels in A431 cells seems to facilitate the control of intracellular Ca(2+)-dependent processes.     

Dual pathways of calcium entry in spike and plateau phases of luteinizing hormone release from chicken pituitary cells: sequential activation of receptor-operated and voltage-sensitive calcium channels by gonadotropin-releasing hormone

It has previously been shown that, in pituitary gonadotrope cells, the initial rise in cytosolic Ca2+ induced by GnRH is due to a Ca2+ mobilization from intracellular stores. This raises the possibility that the initial transient spike phase of LH release might be fully or partially independent of extracellular Ca2+. We have therefore characterized the extracellular Ca2+ requirements, and the sensitivity to Ca2+ channel blockers, of the spike and plateau phases of secretion separately. In the absence of extracellular Ca2+ the spike and plateau phases were inhibited by 65 +/- 4% and 106 +/- 3%, respectively. Both phases exhibited a similar dependence on concentration of extracellular Ca2+. However, voltage-sensitive Ca2+ channel blockers D600 and nifedipine had a negligible effect on the spike phase, while inhibiting the plateau phase by approximately 50%. In contrast, ruthenium red, Gd3+ ions, and Co2+ ions inhibited both spike and plateau phases to a similar extent as removal of extracellular Ca2+. A fraction (35 +/- 4%) of spike phase release was resistant to removal of extracellular Ca2+. This fraction was abolished after calcium depletion of the cells by preincubation with EGTA in the presence of calcium ionophore A23187, indicating that it depends on intracellular Ca2+ stores. Neither absence of extracellular Ca2+, nor the presence of ruthenium red or Gd3+ prevented mobilization of 45Ca2+ from intracellular stores by GnRH. We conclude that mobilization of intracellular stored Ca2+ is insufficient by itself to account for full spike phase LH release.(ABSTRACT TRUNCATED AT 250 WORDS)     

Two functional states of sarcoplasmic reticulum ATPase.

The "total" ATPase activity of rabbit sarcoplasmic reticulum (SR) vesicles includes a Ca2+-independent component ("basic") and Ca2+-dependent component ("extra"). Only the "extra" ATPase is coupled to Ca2+ transport. These activities can be measured under conditions in which the observed rates approximate maximal velocities. The "basic" ATPase is predominant in one of the various SR fractions obtained by prolonged density-gradient centrifugation of SR preparations already purified by repeated differential centrifugations and extractions at high ionic strength. This fraction (low dnesity, high cholesterol) has a protein composition nearly identical with that of other SR fractions in which the "extra" ATPase is predominant. In these other fractions the ratio of "extra" to "basic" ATPase activities is temperature dependent, being approximately 9.0 at 40 degrees C and 0.5 at 4 degrees C. In all the fractions and at all temperatures studied, similar steady-state levels of phosphorylated SR protein are obtained in the presence of ATP and Ca2+. Furthermore, in all cases the "basic" (Ca2+-independent) ATPase acquires total Ca2+ dependence upon addition of the nonionic detergent Triton X-100. This detergent also transforms the complex substrate dependence of the SRATPase into a simple dependence, displaying a single value for the apparent Km. The experimental findings indicate that the ATPase of rabbit SR exists in two distinct functional states (E1 and E2), only one of which (E2) is coupled to Ca2+ transport. The E1 in equilibrium E2 equilibrium is temperature-dependent and entropy-driven, indicative of its relation to the physical state of the ATPase protein in its membrane environment. Thenonlinearity of Arrhenius plots of Ca2+-dependent ("extra") ATPase activity and Ca2+ transport is explained in terms of simultaneous contribtuions from both the free energy of activation of enzyme catalysis and the free energy of conversion of E1 to E2. Thermal equilibrium between the two functional states is drastically altered by factors which affect membrane structure and local viscosity.     

An insulin-sensitive cation channel controls [Na+]i via [Ca2+]o-regulated Na+ and Ca2+ entry.

The insulin-stimulated cation channel previously identified in patch-clamped muscle preparations is here shown to be responsible for bulk Na+ entry into the cell. The mainly Na+ current of the channel was shown to be accompanied by an inhibitory Ca2+ component responsible for oscillations. Here, using quantitative fluorescence imaging of Fura-2- and SBFI-loaded soleus muscle, we measure changes in [Na+]i and [Ca2+]i related to channel function. Insulin increased [Na+]i and [Ca+]i in a transient spike of < 1-min duration. There was a momentary dip in [Na+]i related to inhibition of the channel by the Ca2+ spike, and changes in external Ca2+ were shown to alter [Na+]i via the cation channel, all effects being blocked by the specific channel inhibitor mu-conotoxin, but not by tetrodotoxin. The [Ca2+]i spike could also be induced by 8-bromo cyclic-guanosine 5'-monophosphate, an analogue of the channel-activator cyclic-guanosine 5'-monophosphate (cGMP). In addition it was noted that insulin reduced the [Ca2+]i rise upon subsequent muscle depolarization by a factor of 3.5. Insulin could be substituted with phorbol ester for the same effect and HA1004, a protein kinase inhibitor, blocked the reduction.     

Endoplasmic reticulum and mitochondria as elements of mechanism of intracellular signaling in neurons

The temporal and spatial characteristics of a transitory increase in free Ca2+ ("calcium signals") concentration were determined in various types of the mice and rat neurones. Intracellular structures: endoplasmatic reticulum and mitochondria, were shown to play a major part in formation of these signals, the structures being able to absorb the Ca2+ ions from cytosol and release them back. The contribution of these processes proves rather varying depending on internal organisation and functional assignment of a neurone.     

Calmodulin regulates assembly and trafficking of SK4/IK1 Ca2+-activated K+ channels

Calmodulin (CaM) regulates gating of several types of ion channels but has not been implicated in channel assembly or trafficking. For the SK4/IK1 K+ channel, CaM bound to the proximal C terminus ("Ct1 " domain) acts as the Ca2+ sensor. We now show that CaM interacting with the C terminus of SK4 also controls channel assembly and surface expression. In transfected cells, removing free CaM by overexpressing the CaM-binding domain, Ct1, redistributed full-length SK4 protein from the plasma membrane to the cytoplasm and decreased whole-cell currents. Making more CaM protein available by overexpressing the CaM gene abrogated the dominant-negative effect of Ct1 and restored both surface expression of SK4 protein and whole-cell currents. The distal C-terminal domain ("Ct2") also plays a role in assembly, but is not CaM-dependent. Co-immunoprecipitation experiments demonstrated that multimerization of SK4 subunits was enhanced by CaM and inhibited by removal of CaM, indicating that CaM regulates trafficking of SK4 by affecting the assembly of channels. Our results support a model in which CaM-dependent association of SK4 monomers at their Ct1 domains regulates channel assembly and surface expression. This appears to represent a novel mechanism for controlling ion channels, and consequently, the cellular functions that depend on them.     

A kinetic model of single and clustered IP3 receptors in the absence of Ca2+ feedback

Ca2+ liberation through inositol 1,4,5-trisphosphate receptor (IP3R) channels generates complex patterns of spatiotemporal cellular Ca2+ signals owing to the biphasic modulation of channel gating by Ca2+ itself. These processes have been extensively studied in Xenopus oocytes, where imaging studies have revealed local Ca2+ signals ("puffs") arising from clusters of IP3R, and patch-clamp studies on isolated oocyte nuclei have yielded extensive data on IP3R gating kinetics. To bridge these two levels of experimental data, we developed an IP3R model and applied stochastic simulation and transition matrix theory to predict the behavior of individual and clustered IP3R channels. The channel model consists of four identical, independent subunits, each of which has an IP3-binding site together with one activating and one inactivating Ca2+-binding site. The channel opens when at least three subunits undergo a conformational change to an "active" state after binding IP3 and Ca2+. The model successfully reproduces patch-clamp data; including the dependence of open probability, mean open duration, and mean closed duration on [IP3] and [Ca2+]. Notably, the biexponential distribution of open-time duration and the dependence of mean open time on [Ca2+] are explained by populations of openings involving either three or four active subunits. As a first step toward applying the single IP3R model to describe cellular responses, we then simulated measurements of puff latency after step increases of [IP3]. Assuming that stochastic opening of a single IP3R at basal cytosolic [Ca2+] and any given [IP3] has a high probability of rapidly triggering neighboring channels by calcium-induced calcium release to evoke a puff, optimal correspondence with experimental data of puff latencies after photorelease of IP3 was obtained when the cluster contained a total of 40-70 IP3Rs.     

Calcium release in smooth muscle

In smooth muscle, maintenance of the contractile response is due to Ca2+ influx through two types of Ca2+ channel, a voltage-dependent Ca2+ channel and a receptor-linked Ca2+ channel. However, a more transient contraction can be obtained by release of Ca2+ from a cellular store, possibly the sarcoplasmic reticulum. In spike generating smooth muscle (e.g., guinea-pig taenia caeci), spike discharges may trigger the release of cellular Ca2+ by activating a Ca2+-induced Ca2+ release mechanism. Caffeine directly activates this mechanism in the absence of a triggered Ca2+ influx. In contrast to this, maintained depolarization may not only release but also refill the Ca2+ store. Drug-receptor interactions also release Ca2+ from a cellular store. This release may be elicited with inositol trisphosphate produced by receptor-linked phosphoinositide turnover. In non-spike generating smooth muscle (e.g., rabbit thoracic aorta), maintained membrane depolarization does not release but, instead, fills the Ca2+ store. However, caffeine and receptor-agonists release the Ca2+ store - possibly by activating the Ca2+-induced Ca2+ release mechanism and phosphoinositide turnover, respectively. The Ca2+ store in smooth muscle is filled by Ca2+ entry through voltage dependent Ca2+ channels and also by resting Ca2+ influx in the absence of receptor-agonists. The Ca2+ entering the cells through these pathways may be accumulated by the Ca2+ store and may activate the contractile filaments.     

Sustained subthreshold-for-twitch depolarization in rat single ventricular myocytes causes sustained calcium channel activation and sarcoplasmic reticulum calcium release

Single rat ventricular myocytes, voltage-clamped at -50 to -40 mV, were depolarized in small steps in order to define the mechanisms that govern the increase in cytosolic [Ca2+] (Cai) and contraction, measured as a reduction in myocyte length. Small (3-5 mV), sustained (seconds) depolarizations that caused a small inward or no detectable change in current were followed after a delay by small (less than 2% of the resting length), steady reductions in cell length measured via a photodiode array, and small, steady increases in Cai measured by changes in Indo-1 fluorescence. Larger (greater than -30 and less than -20 mV), sustained depolarizations produced phasic Ca2+ currents, Cai transients, and twitch contractions, followed by a steady current and a steady increase in Cai and contraction. Nitrendipine (or Cd, verapamil, or Ni) abolished the steady contraction and always produced an outward shift in steady current. The steady, nitrendipine-sensitive current and sustained increase in Cai and contraction exhibited a similar voltage dependence over the voltage range between -40 and -20 mV. 2 microM ryanodine in the presence of intact Ca2+ channel activity also abolished the steady increase in Cai and contraction over this voltage range. We conclude that when a sustained depolarization does not exceed about -20 mV, the resultant steady, graded contraction is due to SR Ca2+ release graded by a steady ("window") Ca2+ current. The existence of appreciable, sustained, graded Ca2+ release in response to Ca2+ current generated by arbitrarily small depolarizations is not compatible with any model of Ca2(+)-induced Ca2+ release in which the releasing effect of the Ca2+ channel current is mediated solely by Ca2+ entry into a common cytosolic pool. Our results therefore imply a distinction between the triggering and released Ca2+ pools.     

Delayed rectifying and calcium-activated K+ channels and their significance for action potential repolarization in mouse pancreatic beta-cells

The contribution of Ca2(+)-activated and delayed rectifying K+ channels to the voltage-dependent outward current involved in spike repolarization in mouse pancreatic beta-cells (Rorsman, P., and G. Trube. 1986. J. Physiol. 374:531-550) was assessed using patch-clamp techniques. A Ca2(+)-dependent component could be identified by its rapid inactivation and sensitivity to the Ca2+ channel blocker Cd2+. This current showed the same voltage dependence as the voltage-activated (Cd2(+)-sensitive) Ca2+ current and contributed 10-20% to the total beta-cell delayed outward current. The single-channel events underlying the Ca2(+)-activated component were investigated in cell-attached patches. Increase of [Ca2+]i invariably induced a dramatic increase in the open state probability of a Ca2(+)-activated K+ channel. This channel had a single-channel conductance of 70 pS [( K+]o = 5.6 mM). The Ca2(+)-independent outward current (constituting greater than 80% of the total) reflected the activation of an 8 pS [( K+]o = 5.6 mM; [K+]i = 155 mM) K+ channel. This channel was the only type observed to be associated with action potentials in cell-attached patches. It is suggested that in mouse beta-cells spike repolarization results mainly from the opening of the 8-pS delayed rectifying K+ channel.     

Two kinds of calcium channels in canine atrial cells. Differences in kinetics, selectivity, and pharmacology

Currents through Ca channels were recorded in single canine atrial cells using whole-cell recording with patch pipettes. Two components of Ca channel current could be distinguished. One ("Ifast") was present only if cells were held at negative potentials, was most prominent for relatively small depolarizations, and inactivated within tens of milliseconds. The other ("Islow"), corresponding to the Ca current previously reported in single cardiac cells, persisted even at relatively positive holding potentials, required stronger depolarizations for maximal current, and inactivated much more slowly. Both currents were unaffected by tetrodotoxin and both were reduced by Co. Ifast had the same size and kinetics when Ca was exchanged for Ba, while Islow was bigger and slower with Ba as the charge carrier. In isotonic BaCl2, fluctuation analysis showed that Ifast had a smaller single channel current than Islow. Islow was much more sensitive to block by nitrendipine than was Ifast; also, Islow, but not Ifast, was increased by the dihydropyridine drug BAY K8644. Isoproterenol produced large increases in Islow but had no effect on Ifast.     

Organelle selection determines agonist-specific Ca2+ signals in pancreatic acinar and beta cells

How different extracellular stimuli can evoke different spatiotemporal Ca2+ signals is uncertain. We have elucidated a novel paradigm whereby different agonists use different Ca2+-storing organelles ("organelle selection") to evoke unique responses. Some agonists select the endoplasmic reticulum (ER), and others select lysosome-related (acidic) organelles, evoking spatial Ca2+ responses that mirror the organellar distribution. In pancreatic acinar cells, acetylcholine and bombesin exclusively select the ER Ca2+ store, whereas cholecystokinin additionally recruits a lysosome-related organelle. Similarly, in a pancreatic beta cell line MIN6, acetylcholine selects only the ER, whereas glucose mobilizes Ca2+ from a lysosome-related organelle. We also show that the key to organelle selection is the agonist-specific coupling messenger(s) such that the ER is selected by recruitment of inositol 1,4,5-trisphosphate (or cADP-ribose), whereas lysosome-related organelles are selected by NAADP.     

Phosphatidylinositol 4,5-bisphosphate enhances calcium release from sarcoplasmic reticulum of skeletal muscle

In the course of our study on the function of sarcoplasmic reticulum (SR) in skeletal muscle, the stimulatory action of phosphatidylinositol 4,5-bisphosphate (PIP2) on the Ca2+ release from SR was demonstrated by using chemically skinned fibers and fragmented SR vesicles. PIP2 induced a tension spike followed by sustained contraction in skinned fibers. PIP2 enhanced the caffeine-induced Ca2+ release from SR vesicles at low concentrations and triggered Ca2+ release by itself at high concentrations. PIP2 also enhanced 45Ca2+ efflux from SR vesicles. However, inositol 1,4,5-triphosphate never produced these effects. The Ca2+-releasing action of PIP2 was only weakly affected by ruthenium red or procaine. These observations suggest that PIP2 activates an SR Ca2+ release channel whose properties are different from those of the Ca2+-induced Ca2+ release channel.     

Effects of caffeine, verapamil, lithium, and KB-R7943 on mechanics and energetics of rat myocardial bigeminies

We examined the effects of pharmacological alteration of Ca2+ sources on mechanical and energetic properties of paired-pulse ("bigeminic") contractions. The fraction of heat release that is related to pressure development and pressure-independent heat release were measured during isovolumic contractions in arterially perfused rat ventricles. The heat released by regular and bigeminic contractions showed two brief pressure-independent components (H1 and H2) and a pressure-dependent component (H3). We used the ratio of active heat (Ha') to pressure-time integral (PtI) and the ratio of H3 to PtI to estimate the energetic cost of muscle contraction (overall economy) and pressure maintenance (contractile economy), respectively. Neither of these ratios was affected by stimulation pattern. Caffeine (an inhibitor of sarcoplasmic reticulum function) significantly decreased mechanical responses and increased the energetic cost of contraction (delta = 101 +/- 12.6%). Verapamil (an L-type Ca2+ channel blocker) decreased pressure maintenance of extrasystolic (delta = 43.4 +/- 3.7%) and postextrasystolic (delta = 37.5 +/- 3.5%) contractions without affecting postextrasystolic potentiation, suggesting that a verapamil-insensitive fraction is responsible for potentiation. The verapamil-insensitive fraction was further studied in the presence of lithium (45 mM) and KB-R7943 (5 microM), inhibitors of the Na+/Ca2+ exchanger. Both agents decreased all mechanical responses, including postextrasystolic potentiation (delta = 67.3 +/- 3.3%), without altering overall or contractile economies, suggesting an association of the verapamil-insensitive Ca2+ fraction to the sarcolemmal Na+/Ca2+ exchanger. The effect of the inhibitors of the Na+/Ca2+ exchanger on potentiation suggests an increased participation of extracellular Ca2+ (and, thus, a redistribution of the relative participation of the Ca2+ pools) during bigeminic contractions in rat myocardium.     

Differential activation by Ca2+, ATP and caffeine of cardiac and skeletal muscle ryanodine receptors after block by Mg2+

The block of rabbit skeletal ryanodine receptors (RyR1) and dog heart RyR2 by cytosolic [Mg2+], and its reversal by agonists Ca2+, ATP and caffeine was studied in planar bilayers. Mg2+ effects were tested at submaximal activating [Ca2+] (5 microM). Approximately one third of the RyR1s had low open probability ("LA channels") in the absence of Mg2+. All other RyR1s displayed higher activity ("HA channels"). Cytosolic Mg2+ (1 mM) blocked individual RyR1 channels to varying degrees (32 to 100%). LA channels had residual P(o) <0.005 in 1 mM Mg2+ and reactivated poorly with [Ca2+] (100 microM), caffeine (5 mM), or ATP (4 mM; all at constant 1 mM Mg2+). HA channels had variable activity in Mg2+ and variable degree of recovery from Mg2+ block with Ca2+, caffeine or ATP application. Nearly all cardiac RyR2s displayed high activity in 5 microM [Ca2+]. They also had variable sensitivity to Mg2+. However, the RyR2s consistently recovered from Mg2+ block with 100 microM [Ca2+] or caffeine application, but not when ATP was added. Thus, at physiological [Mg2+], RyR2s behaved as relatively homogeneous Ca2+/caffeine-gated HA channels. In contrast, RyR1s displayed functional heterogeneity that arises from differential modulatory actions of Ca2+ and ATP. These differences between RyR1 and RyR2 function may reflect their respective roles in muscle physiology and excitation-contraction coupling.     

Stimulating effects of dopamine on chloride transport across the rat caudal epididymal epithelium in culture

The present study investigated the effects of dopamine on chloride transport across cultured rat caudal epididymal epithelium. The results showed that dopamine induced a biphasic short-circuit current (Isc) in a concentration-dependent manner. The dopamine-induced response consisted of an initial rapid spike followed by a sustained phase. The alpha and beta adrenoreceptor inhibitors, phentolamine and propranolol, inhibited the initial spike and the sustained phase, respectively, suggesting a contribution of adrenergic receptors. The response was almost abolished by removing the extracellular Cl-, suggesting that the dopamine-induced short-circuit current is primarily a Cl- current. The response was inhibited by the apical Cl- channel blocker, diphenylamine-dicarboxylic acid, and the Ca2+-activated Cl- channel blocker, disulfonic acid stilbene, indicating that Cl- may pass through two types of Cl- channels on the apical side. Preloading monolayers with the intracellular Ca2+ chelator BAPTA/AM abolished the initial spike and greatly reduced the second phase in the Isc response to dopamine. Pretreating the monolayers with an adenylate cyclase inhibitor, MDL12330A, inhibited all of the second Isc response and part of the initial spike. Also, characteristics of the Cl- currents induced by dopamine were observed in whole-cell patch-clamp recording. The increases of intracellular cAMP and Ca2+ induced by dopamine were also measured. The results suggest that extracellular dopamine activates Ca2+-dependent and cAMP-dependent regulatory pathways, leading to activation of both Ca2+-dependent and cAMP-dependent Cl- conductances in epididymal epithelial cells.     

Involvement of K(+)-channel opening in endothelin-1 induced suppression of spontaneous contractions in the guinea pig taenia coli.

Effects of porcine-human endothelin-1 on mechanical as well as electrical activities and on intracellular free Ca2+ levels in the guinea pig taenia coli were compared with those of nifedipine, a voltage-dependent Ca2+ channel blocker. Endothelin-1 (0.1-100 nM) caused a concentration-dependent suppression of spontaneous contractions but did not significantly affect the sustained contraction evoked by 40 mM KCl. However, nifedipine (0.1-100 nM) inhibited both types of contractions in a concentration-dependent manner. In electrophysiological studies, endothelin-1 (30 nM) or nifedipine (30 nM) eliminated spontaneous spike discharges. Endothelin-1 produced hyperpolarization, while nifedipine did not change the resting membrane potential. The endothelin-1 induced suppression of spontaneous contractions was dose-dependently antagonized by apamin (0.01-10 nM), an inhibitor of a small conductance Ca(2+)-dependent K+ channel, and D-tubocurarine (10-100 microM), an inhibitor of Ca(2+)-dependent K+ channel, but was unaffected by 4-aminopyridine (0.01-1 mM), an inhibitor of a voltage-dependent K+ channel. In the study with fura 2 excited at 340 nm, endothelin-1 abolished, from the tissue, the fluorescence signals that were coupled with spontaneous contraction. It is suggested that the inhibitory action of endothelin-1 on spontaneous contraction may be caused by hyperpolarization of the membrane that reduces the spontaneous generation of spike discharge coupled normally to an increase in the intracellular free Ca2+ levels in the guinea pig taenia coli. The hyperpolarization may be caused by activating apamin-sensitive Ca(2+)-dependent K+ channels.     

Stable interactions between mitochondria and endoplasmic reticulum allow rapid accumulation of calcium in a subpopulation of mitochondria

To better understand the functional role of the mitochondrial network in shaping the Ca2+ signals in living cells, we took advantage both of the newest genetically engineered green fluorescent protein-based Ca2+ sensors ("Cameleons," "Camgaroos," and "Pericams") and of the classical Ca(2+)-sensitive photoprotein aequorin, all targeted to the mitochondrial matrix. The properties of the green fluorescent protein-based probes in terms of subcellular localization, photosensitivity, and Ca2+ affinity have been analyzed in detail. It is concluded that the ratiometric pericam is, at present, the most reliable mitochondrial Ca2+ probe for single cell studies, although this probe too is not devoid of problems. The results obtained with ratiometric pericam in single cells, combined with those obtained at the population level with aequorin, provide strong evidence demonstrating that the close vicinity of mitochondria to the Ca2+ release channels (and thus responsible for the fast uptake of Ca2+ by mitochondria upon receptor activation) are highly stable in time, suggesting the existence of specific interactions between mitochondria and the endoplasmic reticulum.     

Relationship of thyrotropin-releasing hormone-induced spike and plateau phases in cytosolic free Ca2+ concentrations to hormone secretion. Selective blockade using ionomycin and nifedipine

In clonal rat pituitary cells (GH cells), thyrotropin-releasing hormone (TRH) induced a pattern of changes in cytosolic free calcium concentrations [( Ca2+]i) composed of two phases: an acute spike phase to micromolar levels which decayed (t1/2 = 8 s) to a near-basal concentration and then rose to a prolonged plateau phase of elevated [Ca2+]i (as measured using Quin 2). Closely following these changes in [Ca2+]i, TRH stimulated a rapid "spike phase" of pronounced, but brief, enhancement of the rate of prolactin and growth-hormone secretion and then a "plateau phase" of prolonged enhancement. These two phases were dissociated using two classes of pharmacologic agents: the ionophore ionomycin, and a calcium channel antagonist nifedipine. Ionomycin (100 nM) specifically blocked (less than 90%) the spike phase of TRH action by rapidly emptying the TRH-regulated reservoir of cellular Ca2+ to generate a TRH-like spike in [Ca2+]i; nifedipine inhibited (less than 50%) the plateau phase of TRH-induced changes in [Ca2+]i and hormone secretion by preventing Ca2+ influx through voltage-dependent Ca2+ channels. These agents demonstrated that the TRH-induced spike in [Ca2+]i in GH cells is caused by release of an ionomycin-sensitive pool of cellular Ca2+ with a small component (10%) due to influx of extracellular Ca2+. The TRH-induced plateau in [Ca2+]i is due to influx of extracellular Ca2+, about half of which enters through voltage-dependent calcium channels and half of which enters via nifedipine/verapamil-insensitive influx. The TRH-induced spike in [Ca2+]i led to a burst in hormone secretion, and the plateau in [Ca2+]i produced a prolonged enhancement of secretion; the spike and plateau phases were generated independently by TRH. A spike in [Ca2+]i is necessary, but not sufficient, to induce burst release of hormone, while the prolonged rate of hormone secretion is intimately related to the steady-state [Ca2+]i.     

Some properties of potassium-stimulated calcium influx in presynaptic nerve endings

Potassium-stimulated 45Ca entry into rat brain synaptosomes was measured at times ranging from 1 to 60 s. The K-rich solutions were used to depolarize the synaptosomes. Backflux of 45Ca from the synaptosomes was negligible during the first 10-20 s of incubation. An initial ("fast") phase of K-stimulated Ca entry, lasting from 1 to 2 s was observed. This phase was inhibited by low concentrations of La (KI approximately equal to 0.3 microM). It was also abolished ("inactivated") by incubating the synaptosomes in depolarizing solutions (containing veratridine, gramicidin, or elevated [K]o) before the addition of 45Ca. An additional long lasting ("slow") phase of K-stimulated Ca entry was also detected. This "slow" Ca entry was much less sensitive to La (KI > 100 microM) and was not affected by depolarizing the synaptosomes before the addition of 45Ca. The rate of influx during the fast phase was about four times the rate of Ca influx during the slow phase. Neither the fast nor slow phase of Ca entry was sensitive to tetrodotoxin (10 microM), a potent blocker of Na channels, but both phases were inhibited by Ni, Mn, Mg, and other agents that block Ca channels. The data are consistent with the presence of two distinct populations of voltage-regulated, divalent cation-selective pathways for Ca entry in presynaptic brain nerve endings.