Characterization of muscarinic receptor subtypes inhibiting Ca2+ current and M current in rat sympathetic neurons.

Muscarinic receptors mediating suppression of Ca2+ current and of M-type K+ current in rat superior cervical ganglion neurons were subclassified pharmacologically by using the muscarinic receptor antagonists pirenzepine and himbacine. Our voltage clamp experiments previously distinguished fast and slow intracellular signaling pathways coupling muscarinic receptors to calcium channels. We now establish that the fast, pertussis toxin-sensitive suppression of Ca2+ current is mediated primarily by muscarinic receptors of the M4 subtype, whereas the slow, bis(2-aminophenoxy)-ethane-N,N,N',N'-tetraacetate (BAPTA)-sensitive suppression of Ca2+ current is mediated primarily by muscarinic receptors of the M1 subtype. Both actions on Ca2+ current are blocked by guanosine 5'-[beta-thio]diphosphate. Muscarinic suppression of M current is slow, BAPTA-sensitive, and mediated by receptors of the M1 subtype. Hence the two muscarinic pathways use different receptors and different guanine nucleotide binding proteins to produce different actions on channels.     

Activation of a muscarinic receptor selectively inhibits a rapidly inactivated Ca2+ current in rat sympathetic neurons.

Sympathetic neurons dissociated from the superior cervical ganglion of 2-day-old rats were studied by whole-cell patch clamp and by fura-2 measurements of the cytosolic free Ca2+ concentration, [Ca2+]i. Step depolarizations in the presence of tetrodotoxin and hexamethonium triggered two Ca2+ currents that differed in the voltage dependence of activation and kinetics of inactivation. These currents resemble the L and N currents previously described in chicken sensory neurons [Nowycky, M. C., Fox, A. P. & Tsien, R. W. (1985) Nature (London) 316, 440-442]. Treatment with acetylcholine resulted in the rapid (within seconds), selective, and reversible inhibition of the rapidly inactivated, N-type current, whereas the long-lasting L-type current remained unaffected. The high sensitivity to blocker drugs (atropine, pirenzepine) indicated that this effect of acetylcholine was due to a muscarinic M1 receptor. Intracellular perfusion with nonhydrolyzable guanine nucleotide analogs or pretreatment of the neurons with pertussis toxin had profound effects on the Ca2+ current modulation. Guanosine 5'-[gamma-thio]triphosphate caused the disappearance of the N-type current (an effect akin to that of acetylcholine, but irreversible), whereas guanosine 5'-[beta-thio]diphosphate and pertussis toxin pretreatment prevented the acetylcholine-induced inhibition. In contrast, cAMP, applied intracellularly together with 3-isobutyl-1-methylxanthine, as well as activators and inhibitors of protein kinase C, were without effect. Acetylcholine caused shortening of action potentials in neurons treated with tetraethylammonium to partially block K+ channels. Moreover, when applied to neurons loaded with the fluorescent indicator fura-2, acetylcholine failed to appreciably modify [Ca2+]i at rest but caused a partial blunting of the initial [Ca2+]i peak induced by depolarization with high K+. This effect was blocked by muscarinic antagonists and pertussis toxin and was unaffected by protein kinase activators. Thus, muscarinic modulation of the N-type Ca2+ channels appears to be mediated by a pertussis toxin-sensitive guanine nucleotide-binding protein and independent of both cAMP-dependent protein kinase and protein kinase C.     

Intracellular Ca2+ signaling and store-operated Ca2+ entry are required in Drosophila neurons for flight

Neuronal Ca²⁺ signals can affect excitability and neural circuit formation. Ca²⁺ signals are modified by Ca²⁺ flux from intracellular stores as well as the extracellular milieu. However, the contribution of intracellular Ca²⁺ stores and their release to neuronal processes is poorly understood. Here, we show by neuron-specific siRNA depletion that activity of the recently identified store-operated channel encoded by dOrai and the endoplasmic reticulum Ca²⁺ store sensor encoded by dSTIM are necessary for normal flight and associated patterns of rhythmic firing of the flight motoneurons of Drosophila melanogaster. Also, dOrai overexpression in flightless mutants for the Drosophila inositol 1,4,5-trisphosphate receptor (InsP₃R) can partially compensate for their loss of flight. Ca²⁺ measurements show that Orai gain-of-function contributes to the quanta of Ca²⁺-release through mutant InsP₃Rs and elevates store-operated Ca²⁺ entry in Drosophila neurons. Our data show that replenishment of intracellular store Ca²⁺ in neurons is required for Drosophila flight.     

Bradykinin inhibits M current via phospholipase C and Ca2+ release from IP3-sensitive Ca2+ stores in rat sympathetic neurons

A variety of intracellular signaling pathways can modulate the properties of voltage-gated ion channels. Some of them are well characterized. However, the diffusible second messenger mediating suppression of M current via G protein-coupled receptors has not been identified. In superior cervical ganglion neurons, we find that the signaling pathways underlying M current inhibition by B₂ bradykinin and M₁ muscarinic receptors respond very differently to inhibitors. The bradykinin pathway was suppressed by the phospholipase C inhibitor U-73122, by blocking the IP₃ receptor with pentosan polysulfate or heparin, and by buffering intracellular calcium, and it was occluded by allowing IP₃ to diffuse into the cytoplasm via a patch pipette. By contrast, the muscarinic pathway was not disrupted by any of these treatments. The addition of bradykinin was accompanied by a [Ca²⁺]_i rise with a similar onset and time to peak as the inhibition of M current. The M current inhibition and the rise of [Ca²⁺]_i were blocked by depletion of Ca²⁺ internal stores by thapsigargin. We conclude that bradykinin receptors inhibit M current of sympathetic neurons by activating phospholipase C and releasing Ca²⁺ from IP₃-sensitive Ca²⁺ stores, whereas muscarinic receptors do not use the phospholipase C pathway to inhibit M current channels.     

An apamin-sensitive Ca2+-activated K+ current in hippocampal pyramidal neurons

In hippocampal and other cortical neurons, action potentials are followed by afterhyperpolarizations (AHPs) generated by the activation of small-conductance Ca2+-activated K+ channels (SK channels). By shaping the neuronal firing pattern, these AHPs contribute to the regulation of excitability and to the encoding function of neurons. Here we report that CA1 pyramidal neurons express an AHP current that is suppressed by apamin and is involved in the control of repetitive firing. This current presents distinct kinetic and pharmacological features, and it is modulated differently than the apamin-insensitive slow AHP current. Furthermore, our in situ hybridizations show that the apamin-sensitive SK subunits are expressed in CA1 pyramidal neurons, providing a potential molecular correlate to the apamin-sensitive AHP current. Altogether, these results clarify the discrepancy between the reported high density of apamin-binding sites in the CA1 region and the apparent lack of an apamin-sensitive current in CA1 pyramidal neurons, and they may explain the effects of this toxin on hippocampal synaptic plasticity and learning.     

Functional dependence of Ca(2+)-activated K+ current on L- and N-type Ca2+ channels: differences between chicken sympathetic and parasympathetic neurons suggest different regulatory mechanisms.

The influx of Ca2+ ions controls many important processes in excitable cells, including the regulation of the gating of Ca(2+)-activated K+ channels (the current IK[Ca]). Various IK[Ca] channels contribute to the regulation of the action-potential waveform, the repetitive discharge of spikes, and the secretion of neurotransmitters. It is thought that large-conductance IK[Ca] channels must be closely colocalized with Ca2+ channels (ICa) to be gated by Ca2+ influx. We now report that IK[Ca] channels can be preferentially colocalized with pharmacologically distinct subtypes of voltage-activated Ca2+ channel and that this occurs differently in embryonic chicken sympathetic and parasympathetic neurons. The effects of various dihydropyridines and omega-conotoxin on voltage-activated Ca2+ currents (ICa) and Ca(2+)-activated K+ currents (IK[Ca]) were examined by using perforated-patch whole-cell recordings from embryonic chicken ciliary and sympathetic ganglion neurons. Application of nifedipine or omega-conotoxin each caused a 40-60% reduction in ICa, whereas application of S-(-)-BAY K 8644 potentiated ICa in ciliary ganglion neurons. But application of omega-conotoxin had little or no effect on IK[Ca], whereas nifedipine and S-(-)-BAY K 8644 inhibited and potentiated IK[Ca], respectively. These results indicate that IK[Ca] channels are preferentially coupled to L-type, but not to N-type, Ca2+ channels on chicken ciliary ganglion neurons. Chicken sympathetic neurons also express dihydropyridine-sensitive and omega-conotoxin-sensitive components of ICa. However, in those cells, application of omega-conotoxin caused a 40-60% reduction in IK[Ca], whereas nifedipine reduced IK[Ca] but only in a subpopulation of cells. Therefore, IK[Ca] in sympathetic neurons is either coupled to N-type Ca2+ channels or is not selectively coupled to a single Ca(2+)-channel subtype. The preferential coupling of IK[Ca] channels with distinct ICa subtypes may be part of a mechanism to allow for selective modulation of neurotransmitter release. Preferential coupling may also be important for the differentiation and development of vertebrate neurons.     

EF-hand protein Ca2+ buffers regulate Ca2+ influx and exocytosis in sensory hair cells

EF-hand Ca²⁺-binding proteins are thought to shape the spatiotemporal properties of cellular Ca²⁺ signaling and are prominently expressed in sensory hair cells in the ear. Here, we combined genetic disruption of parvalbumin-α, calbindin-D28k, and calretinin in mice with patch-clamp recording, in vivo physiology, and mathematical modeling to study their role in Ca²⁺ signaling, exocytosis, and sound encoding at the synapses of inner hair cells (IHCs). IHCs lacking all three proteins showed excessive exocytosis during prolonged depolarizations, despite enhanced Ca²⁺-dependent inactivation of their Ca²⁺ current. Exocytosis of readily releasable vesicles remained unchanged, in accordance with the estimated tight spatial coupling of Ca²⁺ channels and release sites (effective “coupling distance” of 17 nm). Substitution experiments with synthetic Ca²⁺ chelators indicated the presence of endogenous Ca²⁺ buffers equivalent to 1 mM synthetic Ca²⁺-binding sites, approximately half of them with kinetics as fast as 1,2-Bis(2-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid (BAPTA). Synaptic sound encoding was largely unaltered, suggesting that excess exocytosis occurs extrasynaptically. We conclude that EF-hand Ca²⁺ buffers regulate presynaptic IHC function for metabolically efficient sound coding.Intracellular Ca²⁺ signaling regulates a multitude of cellular processes. In sensory hair cells, Ca²⁺ is crucial for electrical frequency tuning, afferent synaptic transmission, and efferent modulation (reviewed in ref. 1). To separate these signaling pathways and maintain high temporal fidelity of neurotransmission, Ca²⁺ signals must be temporally limited and spatially confined to the site of action. Cells typically achieve this by localizing Ca²⁺ entry and by rapidly removing free Ca²⁺ ions via binding to cytosolic “buffers” and finally Ca²⁺ extrusion (2–4). Of the various EF-hand Ca²⁺-binding proteins, some seem to function primarily as Ca²⁺-dependent signaling proteins (e.g., calmodulin and Ca²⁺-binding proteins 1–8, CaBP1–8), whereas others [parvalbumin-α (PVα), calbindin-D28k (CB), and calretinin (CR)] are thought to mainly serve as mobile Ca²⁺ buffers.Hair cells of various species strongly express the Ca²⁺-binding proteins PV, CB, and, in some cases, CR. This possibly reflects the need for buffers with different biophysical properties to functionally isolate different Ca²⁺ signaling mechanisms, which are spatially not well separated in these compact epithelial cells. Ca²⁺-binding proteins are particularly abundant in frog and chicken hair cells, which contain millimolar concentrations of parvalbumin-3 (5) as well as of CR (6, 7). An immune-EM study in rats indicated hundreds of micromolar of proteinaceous Ca²⁺-binding sites in inner hair cells (IHCs) (8). A patch-clamp study in gerbil IHCs reported endogenous buffers equivalent to approximately 0.4 mM 1,2-Bis(2-aminophenoxy)ethane-N,N,N′,N′-tetraacetic acid (BAPTA) (9). Genetic deletion of the EF-hand Ca²⁺-binding proteins PVα, CB, and CR in mice has facilitated the analysis of their function (10–13; reviewed in ref. 14), but the combined deletion of these proteins remains to be studied. IHCs provide an experimentally well-accessible presynaptic preparation that uses all three. Here, we studied IHC function and hearing in mice lacking the three buffers [triple buffer KO (TKO); Pv^−/−Cb^−/−Cr^−/−]. By using perforated and ruptured-patch recordings, we analyzed voltage-gated Ca²⁺ currents and exocytosis of Pv^−/−Cb^−/−Cr^−/− IHCs, in which we also substituted the deleted endogenous buffers with the synthetic Ca²⁺ chelators EGTA or BAPTA. Auditory systems function was probed by measuring otoacoustic emissions and auditory brainstem responses (ABRs) as well as by recordings from single spiral ganglion neurons (SGNs). We performed mathematical modeling to estimate concentrations of the endogenous mobile Ca²⁺ buffers and to better understand how these proteins control exocytosis at IHC synapses. We conclude that the endogenous buffer capacity of IHCs is well approximated by 1 mM synthetic Ca²⁺-binding sites with different kinetics. A tight spatial coupling between Ca²⁺ channels and sensors of exocytosis (Ca²⁺ channel-exocytosis coupling) precludes interference of PVα, CB, and CR with fusion of the readily releasable pool of vesicles (RRP). Instead, we suggest that these buffers jointly regulate IHC presynaptic function by restricting neurotransmitter release to active zones (AZs).     

Epinephrine enhances Ca2+ current-regulated Ca2+ release and Ca2+ reuptake in rat ventricular myocytes.

The voltage dependence of the intracellular Ca2+ transients was measured in single rat ventricular myocytes with the fluorescent Ca2+ indicator dye fura-2. The whole-cell voltage clamp technique was used to measure the membrane current, and 0.9 mM fura-2 was loaded into the cell by including it in the dialyzing solution of the patch electrode. A mechanical light chopper operating at 1200 Hz was used to obtain simultaneous measurements of the intracellular Ca2+ activity with fluorescence excitation on either side of the isosbestic point (330 nm and 410 nm). The symmetry of the two optical Ca2+ signals was used as a criterion to guard against artifacts resulting, for instance, from motion. The voltage dependence of peak Ca2+ current and the Ca2+ transient measured 25 ms after depolarizing clamps from a holding potential of -40 mV were bell-shaped and virtually identical. The Ca2+ entry estimated from the integral of the Ca2+ current (0 mV, 25 ms) corresponds to a 5-10 microM increase in the total intracellular Ca2+ concentration, whereas the optical signal indicated a 100 microM increase in total intracellular Ca2+. Repolarization of clamp pulses from highly positive potentials were accompanied by a second Ca2+ transient, the magnitude of which, when summed with that measured during depolarization, was nearly constant. Ryanodine (10 microM) had little or no effect on the peak Ca2+ current but reduced the magnitude of the early Ca2+ transients by 70-90%. Epinephrine (1 microM) increased the Ca2+ current and the Ca2+ transients, accelerated the rate of decline of the Ca2+ transients at potentials between -30 and +70 mV, and reduced the intracellular [Ca2+] below baseline at potentials positive to +80 or negative to -40 mV, where clamp pulses did not elicit any Ca2+ release. Elevation of intracellular cAMP mimicked the relaxant effect of epinephrine at depolarizing potentials, whereas elevation of extracellular [Ca2+] did not. These results suggest that most of the activator Ca2+ in rat ventricular cells is released from the sarcoplasmic reticulum as a graded response to sarcolemmal Ca2+ influx. Consistent with a graded Ca2+-induced Ca2+ release we find that epinephrine increases the internal Ca2+ release by increasing the Ca2+ current. Epinephrine may also increase the Ca2+ content of the sarcoplasmic reticulum that may, in turn, increase the Ca2+-induced Ca2+ release. The relaxant effect of epinephrine appears to be caused by enhanced rate of Ca2+ resequestration and is mediated by adenylate cyclase system.     

Intracellular injection of Ca2+ chelators blocks induction of long-term depression in rat visual cortex.

In a variety of brain structures repetitive activation of synaptic connections can lead to long-term potentiation (LTP) or long-term depression (LTD) of synaptic transmission, and these modifications are held responsible for memory formation. Here we examine the role of postsynaptic Ca2+ concentration in the induction of LTD in the neocortex. In layer III cells of the rat visual cortex, LTD can be induced by tetanic stimulation of afferent fibers ascending from the white matter. We show that LTD induction is reliably blocked by intracellular injection of either EGTA or BAPTA [bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetate], two different Ca2+ chelators. This confirms that the processes underlying the induction of LTD in neocortex are located postsynaptically and indicates that they depend on intracellular Ca2+ concentration. Thus, both LTP and LTD induction appear to involve calcium-mediated processes in the postsynaptic neuron. We propose that LTD is caused by a surge of calcium either through voltage-gated Ca2+ conductances and/or by transmitter-induced release of calcium from intracellular stores.     

Coupled Ca2+/H+ transport by cytoplasmic buffers regulates local Ca2+ and H+ ion signaling

Ca²⁺ signaling regulates cell function. This is subject to modulation by H⁺ ions that are universal end-products of metabolism. Due to slow diffusion and common buffers, changes in cytoplasmic [Ca²⁺] ([Ca²⁺]_i) or [H⁺] ([H⁺]_i) can become compartmentalized, leading potentially to complex spatial Ca²⁺/H⁺ coupling. This was studied by fluorescence imaging of cardiac myocytes. An increase in [H⁺]_i, produced by superfusion of acetate (salt of membrane-permeant weak acid), evoked a [Ca²⁺]_i rise, independent of sarcolemmal Ca²⁺ influx or release from mitochondria, sarcoplasmic reticulum, or acidic stores. Photolytic H⁺ uncaging from 2-nitrobenzaldehyde also raised [Ca²⁺]_i, and the yield was reduced following inhibition of glycolysis or mitochondrial respiration. H⁺ uncaging into buffer mixtures in vitro demonstrated that Ca²⁺ unloading from proteins, histidyl dipeptides (HDPs; e.g., carnosine), and ATP can underlie the H⁺-evoked [Ca²⁺]_i rise. Raising [H⁺]_i tonically at one end of a myocyte evoked a local [Ca²⁺]_i rise in the acidic microdomain, which did not dissipate. The result is consistent with uphill Ca²⁺ transport into the acidic zone via Ca²⁺/H⁺ exchange on diffusible HDPs and ATP molecules, energized by the [H⁺]_i gradient. Ca²⁺ recruitment to a localized acid microdomain was greatly reduced during intracellular Mg²⁺ overload or by ATP depletion, maneuvers that reduce the Ca²⁺-carrying capacity of HDPs. Cytoplasmic HDPs and ATP underlie spatial Ca²⁺/H⁺ coupling in the cardiac myocyte by providing ion exchange and transport on common buffer sites. Given the abundance of cellular HDPs and ATP, spatial Ca²⁺/H⁺ coupling is likely to be of general importance in cell signaling.Most cells are exquisitely responsive to calcium (Ca²⁺) (1) and hydrogen (H⁺) ions (i.e., pH) (2). In cardiac myocytes, Ca²⁺ ions trigger contraction and control growth and development (3), whereas H⁺ ions, which are generated or consumed metabolically, are potent modulators of essentially all biological processes (4). By acting on Ca²⁺-handling proteins directly or via other molecules, H⁺ ions exert both inhibitory and excitatory effects on Ca²⁺ signaling. For example, in the ventricular myocyte, H⁺ ions can reduce Ca²⁺ release from sarcoplasmic reticulum (SR) stores, through inhibition of the SR Ca²⁺ ATPase (SERCA) pump and ryanodine receptor (RyR) Ca²⁺ channels (5, 6). In contrast, H⁺ ions can enhance SR Ca²⁺ release by stimulating sarcolemmal Na⁺/H⁺ exchange (NHE), which raises intracellular [Na⁺] and reduces the driving force for Ca²⁺ extrusion on Na⁺/Ca²⁺ exchange (NCX), leading to cellular retention of Ca²⁺ (7, 8). Ca²⁺ signaling is thus subservient to pH.Cytoplasmic Ca²⁺ and H⁺ ions bind avidly to buffer molecules, such that <1% of all Ca²⁺ ions and <0.001% of all H⁺ ions are free. Some of these buffers bind H⁺ and Ca²⁺ ions competitively, and this has been proposed to be one mechanism underlying cytoplasmic Ca²⁺/H⁺ coupling (9). Reversible binding to buffers greatly reduces the effective mobility of Ca²⁺ and H⁺ ions in cytoplasm (10, 11) and can allow for highly compartmentalized ionic microdomains, and hence a spatially heterogeneous regulation of cell function. In cardiac myocytes under resting (diastolic) conditions, the cytoplasm-averaged concentration of free [Ca²⁺] ([Ca²⁺]_i) and [H⁺] ([H⁺]_i) ions is kept near 10⁻⁷ M by membrane transporter proteins. Thus, [H⁺]_i is regulated by the balance of flux among acid-extruding and acid-loading transporter proteins at the sarcolemma [e.g., NHE and Cl⁻/OH⁻ (CHE) exchangers, respectively] (4). Similarly, the activity of SERCA and NCX proteins returns [Ca²⁺]_i to its diastolic level after evoked signaling events (3, 12). Despite these regulatory mechanisms, cytoplasmic gradients of [H⁺]_i and [Ca²⁺]_i do occur in myocytes and are an important part of their physiology. Gradients arise from local differences in transmembrane fluxes that alter [H⁺]_i or [Ca²⁺]_i. For example, spatial [H⁺]_i gradients are produced when NHE transporters, expressed mainly at the intercalated disk region, are activated (4, 13) or when membrane-permeant weak acids, such as CO₂, are presented locally (14). Similarly, release of Ca²⁺ through a cluster of RyR channels in the SR produces [Ca²⁺]_i nonuniformity in the form of Ca²⁺ sparks (15). Given the propensity of cytoplasm to develop ionic gradients, it is important to understand their underlying mechanism and functional role.The present work demonstrates a distinct form of spatial interaction between Ca²⁺ and H⁺ ions. We show that cytoplasmic [H⁺] gradients can produce stable [Ca²⁺]_i gradients, and vice versa, and that this interaction is mediated by low-molecular-weight (mobile) buffers with affinity for both ions. We demonstrate that the diffusive counterflux of H⁺ and Ca²⁺ bound to these buffers comprises a cytoplasmic Ca²⁺/H⁺ exchanger. This acts like a “pump” without a membrane, which can, for instance, recruit Ca²⁺ to acidic cellular microdomains. Cytoplasmic Ca²⁺/H⁺ exchange adds a spatial paradigm to our understanding of Ca²⁺ and H⁺ ion signaling.     

T-type Ca2+ current contribution to Ca2+-induced Ca2+ release in developing myocardium

In normal adult-ventricular myocardium, Ca2+-induced Ca2+ release (CICR) from the sarcoplasmic reticulum (SR) is activated via Ca2+ entry through L-type Ca2+ channels. However, embryonic-ventricular myocytes have a prominent T-type Ca2+ current (ICa,T). In this study, the contribution of ICa,T to CICR was determined in chick-ventricular development. Electrically stimulated Ca2+ transients were examined in myocytes loaded with fura-2 and Ca2+ currents with perforated patch-clamp. The results show that the magnitudes of the Ca2+ transient, L-type Ca2+ current (ICa,L) and ICa,T, decline with development with the majority of the decline of transients and ICa,L occurring between embryonic day (ED) 5 and 11. Compared to controls, the magnitude of the Ca2+ transient in the presence of nifedipine was reduced by 41% at ED5, 77% at ED11, and 78% at ED15. These results demonstrated that the overall contribution of ICa,T to the transient was greatest at ED5, while ICa,L was predominate at ED11 and 15. This indicated a decline in the contribution of ICa,T to the Ca2+ transient with development. Nifedipine plus caffeine was added to deplete the SR of Ca2+ and eliminate the occurrence of CICR due to ICa,T. Under these conditions, the transients were further reduced at all three developmental ages, which indicated that a portion of the Ca2+ transients present after just nifedipine addition was due to CICR stimulated by ICa,T. These results indicate that Ca2+ entry via T-type channels plays a significant role in excitation-contraction coupling in the developing heart that includes stimulation of CICR.     

Stimulation of muscarinic receptors raises free intracellular Ca2+ concentration in rat ventricular myocytes

The effect of carbachol on free intracellular calcium concentration, ([Ca2+]i) and on intracellular hydrogen concentration (pHi) was determined from fluorescence signals obtained from rat ventricular myocytes. Application of carbachol (300 mumol/l) to quin2-loaded myocytes bathed in 2 mmol/l Ca2+-containing solution caused [Ca2+]i to increase within 7-10 minutes from 182 +/- 9 to 212 +/- 11 nmol/l (n = 4). Carbachol acted via stimulation of muscarinic receptors because atropine (1 mumol/l) either prevented or abolished the increase in [Ca2+]i. Carbachol also produced a positive inotropic effect in rat papillary muscles contracting isometrically at a frequency of 0.5 Hz and enhanced contracture in resting preparations in the presence of high extracellular Ca2+ concentration ([Ca2+]o) (20 mmol/l). The effect of carbachol on [Ca2+]i was dependent on [Ca2+]o. In the presence of 10 mmol/l [Ca2+]o, the increase in [Ca2+]i was about two times that elicited by carbachol when bath [Ca2+]o was 2 mmol/l. Reduction of [Ca2+]o to 50 mumol/l abolished the carbachol effect but did not prevent caffeine-induced Ca2+ release. The carbachol-induced rise in [Ca2+]i remained unchanged in the presence of either 10 mmol/l caffeine or 1 mumol/l ryanodine. In the absence of extracellular Na+ concentration [( Na+]o), carbachol no longer produced an increase in [Ca2+]i of cardiomyocytes and failed to enhance Na+-withdrawal contracture of the rat papillary muscle. In contrast to the effect on [Ca2+]i, carbachol did not produce any change in pHi as determined from fluorescence signals obtained from rat ventricular myocytes loaded with 2',7'-bis(carboxyethyl)-5,6-carboxyfluorescein.(ABSTRACT TRUNCATED AT 250 WORDS)     

Intracellular vascular muscle Ca2+ modulation in genetic hypertension

Distribution of intracellular free calcium concentration (Ca2+) was compared in spontaneously hypertensive rat (SHR) and Wistar-Kyoto (WKY) rat isolated vascular muscle cells at rest and during stimulation by K+ with Ca2+ agonist or antagonist. Ca2+ activity was quantitated at each point within vascular muscle cells loaded with fura-2 at fluorescence excitation wavelengths of 340, 360, and 380 nm, and fluorescence emission at 510 nm (all filters were +/- 5 nm) quantitated by a digital photon-counting camera. Measurements of fluorescence intensity ratio in central and subsarcolemmal areas showed that calcium release, in response to 30 or 100 mM K+ with Ca2+ agonist or during spontaneous contractions, was principally from sarcoplasmic reticulum. Addition of the Ca2+ agonist Sdz 202-791, S (+) stereoisomer (SdzS), caused a dose-dependent increase of Ca2+ in both SHR and WKY rats. Intracellular calcium release sites were defined by "hot spots" of high fluorescence intensity ratio in both central and peripheral regions of the sarcoplasm. The size and intensity of hot spots increased, and there was an initial transient activation of subsarcolemmal calcium pools in response to high K+ with 1 microM Ca2+ agonist. In contrast, treatment of the cells with the R (-) stereoisomer of Sdz 202-791 (SdzR), a Ca2+ antagonist, prevented the increase in Ca2+ and the increase in hot spot size by either K+ alone or with agonist. Antagonist decreased central core Ca2+ release and fragmented the subsarcolemmal hot spots.(ABSTRACT TRUNCATED AT 250 WORDS)     

Intracellular pattern of cytosolic Ca2+ changes during adhesion and multiple phagocytosis in human neutrophils. Dynamics of intracellular Ca2+ stores

The subcellular pattern of cytosolic free Ca2+ ([Ca2+]i) changes in human polymorphonuclear neutrophils (PMNs) was studied using imaging of fura-2 fluorescence (time resolution 12.5 ratios/s) to determine whether PMNs could obtain directional information from the [Ca2+]i signal. [Ca2+]i changes were observed during initial adherence, the subsequent chemotactic movement, and the phagocytosis of opsonized yeast particles. Initial adherence was followed by a rapid increase in [Ca2+]i (from 90 +/- 10 to 290 +/- 40 nmol/L in 6.5 +/- 2.5 seconds; +/- SEM, n = 10), apparently homogeneously distributed over the entire cytoplasm, which preceded the spreading of the PMNs. [Ca2+]i increases after the contact of the PMNs with yeast particles were of lower mean amplitude; [Ca2+]i increased simultaneously throughout the cytosol. In the absence of extracellular Ca2+, multiple phagocytotic events could proceed normally without a mandatory [Ca2+]i transient. In PMNs polarized on phagocytosis, gradients in [Ca2+]i could be observed. [Ca2+]i was more elevated in the periphagosomal area than in the remaining parts. Taken together, these data show that [Ca2+]i waves do not provide the neutrophil with directional information during chemotaxis and phagocytosis. Sustained small inhomogeneity of [Ca2+]i levels are consistent with a proposed redistribution of releasable Ca2+ stores on phagocytosis.     

L- and T-type Ca2+ channels in canine cardiac Purkinje cells. Single-channel demonstration of L-type Ca2+ window current.

Canine cardiac Purkinje cells contain both L- and T-type calcium currents, yet the single Ca2+ channels have not been characterized from these cells. Additionally, previous studies have shown an overlap between the steady-state inactivation and activations curves for L-type Ca2+ currents, suggesting the presence of L-type Ca2+ "window" current. We used the on-cell, patch-clamp technique to study Ca2+ channels from isolated cardiac Purkinje cells. Patches contained one or more Ca2+ channels 75% of the time. L-type channels were seen in 69% and T-type channels in 73% of these patches. With 110 mM Ba2+ as the charge carrier, the conductances of the L- and T-type Ca2+ channels were 24.2 +/- 0.8 pS (n = 9) and 9.0 +/- 0.5 pS (n = 8), respectively (mean +/- SEM). With 110 mM Ca2+ as the charge carrier, the conductance of the L-type Ca2+ channel decreased to 9.7 +/- 1.2 pS (n = 4), whereas the T-type Ca2+ channel conductance was unchanged. Voltage-dependent inactivation was shown for both L- and T-type Ca2+ channels, although for L-type Ca2+ channel with Ba2+ as the charge carrier, inactivation took at least 30 seconds at a potential of +40 mV. After channel inactivation was complete, L-type Ca2+ channel reopenings were observed following repolarizing steps into the window voltage range. Thus, our data identify both L- and T-type Ca2+ channels in cardiac Purkinje cells and demonstrate, at the single-channel level, L-type channel transitions expected for a window current. Window current may play an important role in shaping the action potential and in arrhythmogenesis.     

Mitogen-regulated Ca2+ current of T lymphocytes is activated by depletion of intracellular Ca2+ stores.

Stimulated influx of Ca2+ across the plasma membrane of T lymphocytes is an essential triggering signal for T-cell activation by antigen. Regulation of the T-cell Ca2+ conductance is not understood; conflicting evidence supports direct activation by inositol 1,4,5-trisphosphate (IP3) or by a signal generated by the depletion of intracellular Ca2+ stores. We have used the perforated-patch recording technique to compare the biophysical properties of Ca2+ currents activated by T-cell receptor stimulation and by thapsigargin, a Ca(2+)-ATPase inhibitor that depletes intracellular stores without generating IP3. Both currents are blocked by Ni2+, are inwardly rectifying, are highly Ca(2+)-selective, and exhibit voltage-independent gating with a unitary chord conductance of approximately 24 fS in isotonic Ca2+. Fluctuation analysis suggests that the underlying Ca2+ transporter is a channel rather than an iron carrier. Thus, in terms of ion permeation, gating, and unitary conductance, the Ca2+ current activated by thapsigargin is indistinguishable from the elicited by crosslinking of T-cell receptors. Moreover, the unitary Ca2+ conductance is > 100-fold smaller than that of previously described IP3-gated, Ca(2+)-permeable channels in T cells [Kuno, M. & Gardner, P. (1987) Nature (London) 326, 301-304]. These results demonstrate that mitogen-activated Ca2+ influx is controlled by the state of intracellular Ca2+ stores rather than by the direct action of IP3 on Ca2+ channels in the plasma membrane.     

A glutamate receptor regulates Ca2+ mobilization in hippocampal neurons.

We investigated the effect of various excitatory amino acids on intracellular free Ca2+ concentration ( [Ca2+]i) in single mouse hippocampal neurons in vitro by using the Ca2+-sensitive dye fura-2. In normal physiological solution, glutamate, kainate, N-methyl-D-aspartate, and quisqualate all produced increases in [Ca2+]i. When all extracellular Ca2+ was removed, kainate and N-methyl-D-aspartate were completely ineffective, but quisqualate and glutamate were able to produce a spike-like Ca2+ transient, presumably reflecting the release of Ca2+ from intracellular stores. Ca2+ transients of similar shape could also be produced by the alpha 1-adrenergic agonist phenylephrine. After the production of a Ca2+ transient a second addition of quisqualate was ineffective unless intracellular stores were refilled by loading the cell with Ca2+ following depolarization in Ca2+-containing medium. None of the conventional excitatory amino acid receptor antagonists inhibited the Ca2+-mobilizing effects of quisqualate. Furthermore alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA) was unable to produce Ca2+ mobilization in Ca2+-free medium, although it could produce Ca2+ influx in Ca2+-containing medium. Thus, glutamate can produce mobilization of Ca2+ from intracellular stores in hippocampal neurons by acting on a quisqualate-sensitive but AMPA-insensitive receptor. This receptor is therefore distinct from the quisqualate receptor that produces cell depolarization. The possibility that this Ca2+-mobilizing effect is mediated by inositol triphosphate production is discussed.