ATP inhibits Ins(1,4,5)P3-evoked Ca2+ release in smooth muscle via P2Y1 receptors.

Adenosine 5'-triphosphate (ATP) mediates a variety of biological functions following nerve-evoked release, via activation of either G-protein-coupled P2Y- or ligand-gated P2X receptors. In smooth muscle, ATP, acting via P2Y receptors (P2YR), may act as an inhibitory neurotransmitter. The underlying mechanism(s) remain unclear, but have been proposed to involve the production of inositol 1,4,5-trisphosphate [Ins(1,4,5)P(3)] by phospholipase C (PLC), to evoke Ca(2+) release from the internal store and stimulation of Ca(2+)-activated potassium (K(Ca)) channels to cause membrane hyperpolarization. This mechanism requires Ca(2+) release from the store. However, in the present study, ATP evoked transient Ca(2+) increases in only ∼10% of voltage-clamped single smooth muscle cells. These results do not support activation of K(Ca) as the major mechanism underlying inhibition of smooth muscle activity. Interestingly, ATP inhibited Ins(1,4,5)P(3)-evoked Ca(2+) release in cells that did not show a Ca(2+) rise in response to purinergic activation. The reduction in Ins(1,4,5)P(3)-evoked Ca(2+) release was not mimicked by adenosine and therefore, cannot be explained by hydrolysis of ATP to adenosine. The reduction in Ins(1,4,5)P(3)-evoked Ca(2+) release was, however, also observed with its primary metabolite, ADP, and blocked by the P2Y(1)R antagonist, MRS2179, and the G protein inhibitor, GDPßS, but not by PLC inhibition. The present study demonstrates a novel inhibitory effect of P2Y(1)R activation on Ins(1,4,5)P(3)-evoked Ca(2+) release, such that purinergic stimulation acts to prevent Ins(1,4,5)P(3)-mediated increases in excitability in smooth muscle and promote relaxation.

The phospholipase C inhibitor U-73122 inhibits Ca(2+) release from the intracellular sarcoplasmic reticulum Ca(2+) store by inhibiting Ca(2+) pumps in smooth muscle.

BACKGROUND AND PURPOSE: The sarcoplasmic reticulum (SR) releases Ca(2+) via inositol 1,4,5-trisphosphate receptors (IP(3)R) in response to IP(3)-generating agonists. Ca(2+) release subsequently propagates as Ca(2+) waves. To clarify the role of IP(3) production in wave generation, the contribution of a key enzyme in the production of IP(3) was examined using a phosphoinositide-specific phospholipase C (PI-PLC) inhibitor, U-73122. EXPERIMENTAL APPROACH: Single colonic myocytes were voltage-clamped in whole-cell configuration and cytosolic Ca(2+) concentration ([Ca(2+)](cyto)) measured using fluo-3. SR Ca(2+) release was evoked either by activation of IP(3)Rs (by carbachol or photolysis of caged IP(3)) or ryanodine receptors (RyRs; by caffeine). KEY RESULTS: U-73122 inhibited carbachol-evoked [Ca(2+)](cyto) transients. The drug also inhibited [Ca(2+)](cyto) increases, evoked by direct IP(3)R activation (by photolysis of caged IP(3)) and RyR activation (by caffeine), which do not require PI-PLC activation. U-73122 also increased steady-state [Ca(2+)](cyto) and slowed the rate of Ca(2+) removal from the cytoplasm. An inactive analogue of U-73122, U-73343, was without effect on either IP(3)R- or RyR-mediated Ca(2+) release. CONCLUSIONS AND IMPLICATIONS: U-73122 inhibited carbachol-evoked [Ca(2+)](cyto) increases. However, the drug also reduced Ca(2+) release when evoked by direct activation of IP(3)R or RyR, slowed Ca(2+) removal and increased steady-state [Ca(2+)](cyto). These results suggest U-73122 reduces IP(3)-evoked Ca(2+) transients by inhibiting the SR Ca(2+) pump to deplete the SR of Ca(2+) rather than by inhibiting PI-PLC.

Regulation by FK506 and rapamycin of Ca2+ release from the sarcoplasmic reticulum in vascular smooth muscle: the role of FK506 binding proteins and mTOR.

BACKGROUND AND PURPOSE: The sarcoplasmic reticulum (SR), regulates the cytoplasmic Ca(2+) concentration ([Ca(2+)](cyto)) in vascular smooth muscle. Release from the SR is controlled by two intracellular receptor/channel complexes, the ryanodine receptor (RyR) and the inositol 1,4,5-trisphosphate receptor (IP(3)R). These receptors may be regulated by the accessory FK506-binding protein (FKBP) either directly, by binding to the channel, or indirectly via FKBP modulation of two targets, the phosphatase, calcineurin or the kinase, mammalian target of rapamycin (mTOR). EXPERIMENTAL APPROACH: Single portal vein myocytes were voltage-clamped in whole cell configuration and [Ca(2+)](cyto) measured using fluo-3. IP(3)Rs were activated by photolysis of caged IP(3) and RyRs activated by hydrostatic application of caffeine. KEY RESULTS: FK506 which displaces FKBP from each receptor (to inhibit calcineurin) increased the [Ca(2+)](cyto) rise evoked by activation of either RyR or IP(3)R. Rapamycin which displaces FKBP (to inhibit mTOR) also increased the amplitude of the caffeine-evoked, but reduced the IP(3)-evoked [Ca(2+)](cyto) rise. None of the phosphatase inhibitors, cypermethrin, okadaic acid or calcineurin inhibitory peptide, altered either caffeine- or IP(3)-evoked [Ca(2+)](cyto) release; calcineurin did not contribute to FK506-mediated potentiation of RyR- or IP(3)R-mediated Ca(2+) release. The mTOR inhibitor LY294002, like rapamycin, decreased IP(3)-evoked Ca(2+) release. CONCLUSIONS AND IMPLICATIONS: Ca(2+) release in portal vein myocytes, via RyR, was modulated directly by FKBP binding to the channel; neither calcineurin nor mTOR contributed to this regulation. However, IP(3)R-mediated Ca(2+) release, while also modulated directly by FKBP may be additionally regulated by mTOR. Rapamycin inhibition of IP(3)-mediated Ca(2+) release may be explained by mTOR inhibition.

Sarcolemma agonist-induced interactions between InsP3 and ryanodine receptors in Ca2+ oscillations and waves in smooth muscle.

Smooth muscle cells respond to InsP(3)-generating (sarcolemma-acting) neurotransmitters and hormones by releasing Ca(2+) from the internal store. However, the release of Ca(2+) does not occur uniformly throughout the cytoplasm but often into a localized area before being transmitted to other regions of the cell in the form of Ca(2+) waves and oscillations to actively spread information within and between cells. Yet, despite their significance, our understanding of the generation of oscillations to waves is incomplete. A major aspect of controversy centres on whether or not Ca(2+) released from the InsP(3) receptor activates RyRs (ryanodine receptors) to generate further release by Ca(2+)-induced Ca(2+) release and propagate waves or whether the entire process arises from InsP(3) receptor activity alone. Under normal physiological conditions the [Ca(2+)] required to activate RyR (approx. 15 microM) exceeds the bulk average [Ca(2+)](c) (cytoplasmic Ca(2+) concentration) generated by InsP(3) receptor activity (<1 microM). Progression of waves and oscillations by RyR activity would require a loss of control of RyR activity and an unrestrained positive feedback on Ca(2+) release. Under store-overload conditions, RyR Ca(2+) sensitivity is increased and this enables waves to be induced by RyR activity. However, the relevance of these Ca(2+)-release events to normal physiological functioning is unclear. The InsP(3) receptor, on the other hand, is activated by Ca(2+) over the physiological range (up to 300 nM) and deactivated by higher [Ca(2+)](c) (>300 nM), features that favour intermittent activity of the receptor as occurs in waves and oscillations. Experimental evidence for the involvement of RyR relies mainly on pharmacological approaches in the intact cell where poor drug specificity could have led to ambiguous results. In this brief review the possible interactions between InsP(3) receptors and RyR in the generation of oscillations and waves will be discussed. Evidence is presented that RyRs are not required for InsP(3)-mediated Ca(2+) transients. Notwithstanding, ryanodine can inhibit InsP(3)-mediated Ca(2+) responses after RyR activity has been induced by caffeine or by steady depolarization which evokes spontaneous transient outward currents (a sarcolemmal manifestation of RyR activity). Ryanodine inhibits InsP(3)-mediated Ca(2+) transients by depleting the store of Ca(2+) rather than by RyR involvement in the InsP(3)-mediated Ca(2+) increase.

Striatal neurones show sustained recovery from severe hypoglycaemic insult.

Glucose deprivation provides a reliable model to investigate cellular responses to metabolic dysfunction, and is reportedly associated with permanent cell death in many paradigms. Consistent with previous studies, primary cultures of rat striatal neurones exposed to 24-h hypoglycaemia showed dramatically decreased sodium 2,3-bis(2-methoxy-4-nitro-5-sulfophenyl)-2H-tetrazolium-5-carboxanilide (XTT) metabolism (used as a marker of cell viability) and increased TUNEL staining, suggesting widespread DNA damage typical of apoptotic cell death. Remarkably, restoration of normal glucose levels initiated a sustained recovery in XTT staining, along with a concomitant decrease in TUNEL staining, even after 24 h of hypoglycaemia, suggesting recovery of damaged neurones and repair of nicked DNA. No alterations in the levels of four DNA repair proteins could be detected during hypoglycaemia or recovery. A reduction in intracellular calcium concentration was seen in recovered cells. These data suggest that striatal cells do not die after extended periods of glucose deprivation, but survive in a form of suspended animation, with sufficient energy to maintain membrane potential.

Functionally separate intracellular Ca2+ stores in smooth muscle.

In smooth muscle, release via the inositol 1,4,5-trisphosphate (Ins(1,4,5)P(3)R) and ryanodine receptors (RyR) on the sarcoplasmic reticulum (SR) controls oscillatory and steady-state cytosolic Ca(2+) concentrations ([Ca(2+)](c)). The interplay between the two receptors, itself determined by their organization on the SR, establishes the time course and spatial arrangement of the Ca(2+) signal. Whether or not the receptors are co-localized or distanced from each other on the same store or whether they exist on separate stores will significantly affect the Ca(2+) signal produced by the SR. To date these matters remain unresolved. The functional arrangement of the RyR and Ins(1,4,5)P(3)R on the SR has now been examined in isolated single voltage-clamped colonic myocytes. Depletion of the ryanodine-sensitive store, by repeated application of caffeine, in the presence of ryanodine, abolished the response to Ins(1,4,5)P(3), suggesting that Ins(1,4,5)P(3)R and RyR share a common Ca(2+) store. Ca(2+) release from the Ins(1,4,5)P(3)R did not activate Ca(2+)-induced Ca(2+) release at the RyR. Depletion of the Ins(1,4,5)P(3)-sensitive store, by the removal of external Ca(2+), on the other hand, caused only a small decrease ( approximately 26%) in caffeine-evoked Ca(2+) transients, suggesting that not all RyR exist on the common store shared with Ins(1,4,5)P(3)R. Dependence of the stores on external Ca(2+) for replenishment also differed; removal of external Ca(2+) depleted the Ins(1,4,5)P(3)-sensitive store but caused only a slight reduction in caffeine-evoked transients mediated at RyR. Different mechanisms are presumably responsible for the refilling of each store. Refilling of both Ins(1,4,5)P(3)-sensitive and caffeine-sensitive Ca(2+) stores was inhibited by each of the SR Ca(2+) ATPase inhibitors thapsigargin and cyclopiazonic acid. These results may be explained by the existence of two functionally distinct Ca(2+) stores; the first expressing only RyR and refilled from [Ca(2+)](c), the second expressing both Ins(1,4,5)P(3)R and RyR and dependent upon external Ca(2+) for refilling.

Two Ca2+ entry pathways mediate InsP3-sensitive store refilling in guinea-pig colonic smooth muscle.

Sarcolemma Ca2+ influx, necessary for store refilling, was well maintained, over a wide range (-70 to + 40 mV) of membrane voltages, in guinea-pig single circular colonic smooth muscle cells, as indicated by the magnitude of InsP3-evoked Ca2+ transients. This apparent voltage independence of store refilling was achieved by the activity of sarcolemma Ca2+ channels some of which were voltage gated while others were not. At negative membrane potentials (e.g. -70 mV), Ca2+ influx through channels which lacked voltage gating provided for store refilling while at positive membrane potentials (e.g. +40 mV) voltage-gated Ca2+ channels were largely responsible. Sarcolemma voltage-gated Ca2+ currents were not activated following store depletion. Removal of external Ca2+ or the addition of the Ca2+ channel blocker nimodipine (1 microM) inhibited store refilling, as assessed by the magnitude of InsP3-evoked Ca2+ transients, with little or no change in bulk average cytoplasmic Ca2+ concentration. One hypothesis for these results is that the store may refill from a high subsarcolemma Ca2+ gradient. Influx via channels, some of which are voltage gated and others which lack voltage gating, may permit the establishment of a subsarcolemma Ca2+ gradient. Store access to the gradient allows InsP3-evoked Ca2+ signalling to be maintained over a wide voltage range in colonic smooth muscle.

Mitochondrial regulation of the cytosolic Ca2+ concentration and the InsP3-sensitive Ca2+ store in guinea-pig colonic smooth muscle.

1. Mitochondrial regulation of the cytosolic Ca2+ concentration ([Ca2+]c) in guinea-pig single colonic myocytes has been examined, using whole-cell recording, flash photolysis of caged InsP3 and microfluorimetry. 2. Depolarization increased [Ca2+]c and triggered contraction. Resting [Ca2+]c was virtually restored some 4 s after the end of depolarization, a time when the muscle had shortened to 50 % of its fully relaxed length. The muscle then slowly relaxed (t = 17 s). 3. The decline in the Ca2+ transient was monophasic but often undershot or overshot resting levels, depending on resting [Ca2+]c. The extent of the overshoot or undershoot increased with increasing peak [Ca2+]c. 4. Carbonyl cyanide m-chlorophenyl hydrazone (CCCP; 5 microM), which dissipates the mitochondrial proton electrochemical gradient and therefore prevents mitochondrial Ca2+ accumulation, slowed Ca2+ removal at high ( > 300 nM) but not at lower [Ca2+]c and abolished [Ca2+]c overshoots. Oligomycin B (5 microM), which prevents mitchondrial ATP production, affected neither the rate of decline nor the magnitude of the overshoot. 5. During depolarization, the global rhod-2 signal (which represents the mitochondrial matrix Ca2+ concentration, [Ca2+]m) rose slowly in a CCCP-sensitive manner during and for about 3 s after depolarization had ended. [Ca2+]m then slowly decreased over tens of seconds. 6. Inhibition of sarcoplasmic reticulum Ca2+ uptake with thapsigargin (100 nM) reduced the undershoot and increased the overshoot. 7. Flash photolysis of caged InsP3 (20 microM) evoked reproducible increases in [Ca2+]c. CCCP (5 microM) reduced the magnitude of the [Ca2+]c transients evoked by flash photolysis of caged InsP3. Oligomycin B (5 microM) did not reduce the inhibition of the InsP3-induced Ca2+ transient by CCCP thus minimizing the possibility that CCCP lowered ATP levels by reversing the mitochondrial ATP synthase and so reducing SR Ca2+ refilling. 8. While CCCP reduced the magnitude of the InsP3-evoked Ca2+ signal, the internal Ca2+ store content, as assessed by the magnitude of ionomycin-evoked Ca2+ release, did not decrease significantly. 9. [Ca2+]c decline in smooth muscle, following depolarization, may involve mitochondrial Ca2+ uptake. Following InsP3-evoked Ca2+ release, mitochondrial uptake of Ca2+ may regulate the local [Ca2+]c near the InsP3 receptor so maintaining the sensitivity of the InsP3 receptor to release Ca2+ from the SR.

Ca2+ removal mechanisms in rat cerebral resistance size arteries.

Tissue blood flow and blood pressure are each regulated by the contractile behavior of resistance artery smooth muscle. Vascular diseases such as hypertension have also been attributed to changes in vascular smooth muscle function as a consequence of altered Ca2+ removal. In the present study of Ca2+ removal mechanisms, in dissociated single cells from resistance arteries using fura-2 microfluorimetry and voltage clamp, Ca2+ uptake by the sarcoplasmic reticulum and extrusion by the Ca2+ pump in the cell membrane were demonstrably important in regulating Ca2+. In contrast, the Na+-Ca2+ exchanger played no detectable role in clearing Ca2+. Thus a voltage pulse to 0 mV, from a holding potential of -70 mV, triggered a Ca2+ influx and increased intracellular Ca2+ concentration ([Ca2+]i). On repolarization, [Ca2+]i returned to the resting level. The decline in [Ca2+]i consisted of three phases. Ca2+ removal was fast immediately after repolarization (first phase), then plateaued (second phase), and finally accelerated just before [Ca2+]i returned to resting levels (third phase). Thapsigargin or ryanodine, which each inhibit Ca2+ uptake into stores, did not affect the first but significantly inhibited the third phase. On the other hand, Na+ replacement with choline+ did not affect either the phasic features of Ca2+ removal or the absolute rate of its decline. Ca2+ removal was voltage-independent; holding the membrane potential at 120 mV, rather than at -70 mV, after the voltage pulse to 0 mV, did not attenuate Ca2+ removal rate. These results suggest that Ca2+ pumps in the sarcoplasmic reticulum and the plasma membrane, but not the Na+-Ca2+ exchanger, are important in Ca2+ removal in cerebral resistance artery cells.

Calcium-calmodulin-dependent mechanisms accelerate calcium decay in gastric myocytes from Bufo marinus.

1. [Ca2+] was recorded in voltage-clamped gastric myocytes from Bufo marinus. Repolarization to -110 mV following a 300 ms depolarization to +10 mV led to triphasic [Ca2+]i decay, with a fast-slow-fast pattern. After a conditioning train of repetitive depolarizations the duration of the second, slow phase of decay was shortened, while the rate of decay during the third, faster phase was increased by 34 +/- 6% (mean +/- S.E.M., n = 21) when compared with unconditioned transients. 2. [Ca2+]i decay was biphasic in cells injected with the calmodulin-binding peptide RS20, with a prolonged period of fast decay followed by a slow phase. There was no subsequent increase in decay rate during individual transients and no acceleration of decay following the conditioning train (n = 8). Decline of [Ca2+]i in cells injected with the control peptide NRS20 was triphasic and the decay rate during the third phase was increased by 50 +/- 19% in conditioned transients (n = 6). 3. Cell injection with CK3AA, a pseudo-substrate inhibitor of calmodulin-dependent protein kinase II, prevented the increase in the final rate of decay following the conditioning train (n = 6). In cells injected with an inactive peptide similar to CK3AA, however, there was a 45 +/- 17% increase after the train (n = 5). 4. Inhibition of Ca2+ uptake by the sarcoplasmic reticulum with cyclopiazonic acid or thapsigargin did not prevent acceleration of decay. 5. These results demonstrate that [Ca2+]i decay is accelerated by Ca(2+)-calmodulin and calmodulin-dependent protein kinase II. This does not depend on Ca2+ uptake by the sarcoplasmic reticulum but may reflect upregulation of mitochondrial Ca2+ removal.

Modulation of high- and low-voltage-activated calcium currents in smooth muscle by calcium.

Ca2+ currents (ICa) and cytoplasmic Ca2+ concentration ([Ca2+]c) were measured in isolated gastric myocytes from Bufo marinus using whole cell voltage clamp and fura 2, respectively. After a conditioning train of depolarizing pulses, high-voltage-activated ICa (test potential of +10 mV) was increased, returning to control values after approximately 85 s. This enhancement was [Ca2+]c dependent, with a maximal increase at approximately 600 nM [Ca2+]c. During the conditioning train, ICa measured at 70 ms, which provides a measure of high-voltage-activated current, initially decreased with each successive pulse to a minimum of 56 +/- 5% of the first pulse in the train. Thereafter, the 70-ms current showed considerable recovery. Blockade of calmodulin activity with a peptide (RS20) or calmidazolium did not affect the early inhibition but did abolish current recovery. A peptide inhibitor of calmodulin-dependent protein kinase II (CK3AA) had similar effects. Substraction of currents measured in the presence and absence of RS20 revealed a 2-s delay between the start of the train and the onset of current enhancement. It was also observed that low-voltage-activated current (test potential of -17 mV) was reduced to 76 +/- 7% of control 5 s after the conditioning train; this inhibition recovered to 92 +/- 4% after 35 s and was not dependent on [Ca2+]c elevation.

Regulation of the cytosolic Ca2+ concentration by Ca2+ stores in single smooth muscle cells from rat cerebral arteries.

1. There is no general agreement on the presence or role of Ca(2+)-induced Ca2+ release in smooth muscle. In this paper, Ca(2+)-induced Ca2+ release has been investigated in rat resistance-sized superior cerebral arteries to determine its role in regulating the cytosolic Ca2+ concentration ([Ca2+]i). 2. Pressurized superior cerebral arteries developed spontaneous oscillations in diameter. These oscillations were abolished by ryanodine (an inhibitor of Ca(2+)-induced Ca2+ release) and removal of extracellular Ca2+. This suggests, indirectly, that Ca(2+)-induced Ca2+ release may regulate [Ca2+]i in the resistance arteries. 3. To determine if Ca(2+)-induced Ca2+ release could regulate [Ca2+]i, single smooth muscle cells were isolated from the superior cerebral artery, voltage clamped in the whole cell configuration and high temporal resolution [Ca2+]i measurements made. The relationship between the Ca2+ current (ICa) and rise in [Ca2+]i was examined. 4. Depolarization triggered ICa and increased [Ca2+]i. The time course of the measured increase in [Ca2+]i closely followed the increase in [Ca2+]i expected from the time-integrated ICa, although about 140-fold more Ca2+ entered the cytosol than appeared as free Ca2+. When the cells were dialysed with ryanodine (30 microM), the Ca2+ transient evoked by the ICa was substantially reduced indicating that Ca2+ influx triggered Ca2+ release from an internal store. 5. Voltage pulses to negative membrane potentials were more effective in triggering Ca2+ release than pulses to positive potentials suggesting that the Ca(2+)-induced Ca2+ release was voltage dependent. However, the release of Ca2+ from the internal store triggered by caffeine was voltage independent. These results suggest that the voltage dependence of Ca2+ release is indirect and possibly related to the plasmalemma unitary Ca2+ current magnitude. 6. The results establish that Ca(2+)-induced Ca2+ release contributes to depolarization-evoked increases in [Ca2+]i in rat resistance-sized superior cerebral arteries over the physiological [Ca2+]i range (100-200 nM). Compared with more positive membrane potentials the efficacy of Ca2+ in triggering release is high at physiological membrane potentials.

Myogenic contraction by modulation of voltage-dependent calcium currents in isolated rat cerebral arteries.

1. Tissue blood flow and blood pressure are regulated by the spontaneous, myogenic, contraction developed by resistance arteries. However, the cellular mechanisms underlying myogenic contraction are not understood. In this study, the mechanisms of myogenic contraction in cerebral resistance arteries were investigated. 2. The vasoconstriction observed in response to increased pressure in cerebral resistance arteries (myogenic reactivity) was dependent on Ca2+ entry through voltage-dependent Ca2+ channels, since it was abolished by Ca2+ removal and by dihydropyridine antagonists of voltage-dependent Ca2+ channels. 3. Myogenic reactivity persisted in a high-K+ saline, with reduced Ca2+, where membrane potential is presumed to be clamped. Therefore, membrane depolarization alone does not fully account for the increased voltage-dependent Ca2+ channel opening. 4. Voltage-dependent Ca2+ currents in single smooth muscle cells isolated from the resistance artery were substantially increased by applying positive pressure to the patch electrode evoking membrane stretch. 5. Myogenic reactivity remained unaffected by ryanodine and therefore was independent of internal ryanodine-sensitive Ca2+ stores. 6. The myofilament Ca2+ sensitivity was not increased by elevated pressure in alpha-toxin-permeabilized arteries. However, pharmacological activation of protein kinase C or G proteins did increase the myofilament Ca2+ sensitivity. 7. Myogenic contraction over the pressure range 30-70 mmHg could be accounted for by an increase in [Ca2+]i from 100 to 200 nM. 8. It is concluded that modest increases in [Ca2+]i within the range 100-200 nM can account for that myogenic contraction, and that stretch-evoked modulation of Ca2+ currents may contribute to the myogenic response.

The temporal profile of calcium transients in voltage clamped gastric myocytes from Bufo marinus.

1. Decay in intracellular calcium concentration ([Ca2+]i) was recorded following step depolarizations in voltage clamped gastric myocytes from Bufo marinus. 2. Depolarizations (300 ms) to +10 mV were followed by three phases of [Ca2+]i decay with repolarization to both -110 and -50 mV. The decline was initially rapid (mean fractional decay rate = 81 +/- 11%s-1 at -110 mV), then slowed (decay rate = 14 +/- 2%s-1) and finally accelerated again (decay rate = 24 +/- 3%s-1; n = 19). 3. The initial phase of rapid decay became shorter as the length of the depolarizing pulse increased but was unaffected by changes in pulse voltage. 4. The delayed acceleration in [Ca2+]i decay was no longer seen when the duration of the depolarizing pulses was reduced to 100 ms, but was clearly evident following 500 ms pulses. This phase was abolished when the depolarizing voltage was altered to minimize the rise in [Ca2+]i. 5. Ryanodine and caffeine had no effect on the temporal profile of [Ca2+]i decay. 6. Removal of extracellular Na+ decreased the decay rate during all three phases at -110 mV, but this effect was particularly marked for the initial rapid phase of decay, the rate of which was reduced by 75%. A delayed increase in decay rate was still seen. 7. Inhibition of mitochondrial Ca2+ uptake with cyanide, carbonyl cyanide p-trifluoromethoxy-phenylhydrazone or Ruthenium Red had no effect on the initial rate of [Ca2+]i decay but blocked the delayed acceleration. 8. These results are discussed in terms of a model in which rapid influx of Ca2+ produces a high subsarcolemmal [Ca2+], favouring rapid Ca2+ removal by near-membrane mechanisms, particularly Na(+)-Ca2+ exchange. Mitochondrial Ca2+ removal produces a delayed increase in [Ca2+]i decay if the global [Ca2+]i is raised high enough for long enough.

Depolarization-evoked increases in cytosolic calcium concentration in isolated smooth muscle cells of rat portal vein.

1. Ca2+ current through voltage-dependent Ca2+ channels (ICa) and intracellular free Ca2+ concentration ([Ca2+]i) were measured simultaneously in rat portal vein smooth muscle cells using conventional whole-cell voltage clamp technique and high temporal resolution microfluorimetry. 2. The relationship between depolarization-evoked ICa and rise in [Ca2+]i was examined. The extracellular Ca2+ concentration dependence and the voltage dependence of the depolarization-evoked increases in ICa and [Ca2+]i were similar. Both ICa and increased [Ca2+]i were blocked to a similar extent by nimodipine and cadmium and augmented by Bay K 8644. Furthermore, the time course of the measured increase in [Ca2+]i, closely followed the increase in [Ca2+]i expected from the time-integrated ICa. These observations suggest that the depolarization-evoked rise in [Ca2+]i was tightly coupled to ICa. 3. The cytosolic Ca2+ buffering capacity, determined as the ratio of the expected increase in [Ca2+]i (from ICa) divided by the measured increase in [Ca2+]i, was over 100. Therefore, less than 1 out of 100 Ca2+ ions entering the cell appears as a free Ca2+. 4. Ryanodine (30 microM), a blocker of the Ca(2+)-induced Ca2+ release mechanism, had little effect on buffering capacity measured over the first 200 ms of the depolarizing voltage clamp pulse. Ryanodine also had little effect on the buffering capacity during 800-1000 ms of the depolarizing voltage clamp pulse. Therefore, it was concluded that there is little Ca(2+)-induced Ca2+ release from the stores in rat portal vein smooth muscle cells during depolarization-evoked Ca2+ entry. 5. During brief depolarizations, the largest [Ca2+]i increase and ICa occurred at 0 mV. However, during steady-state depolarization, the largest increase in [Ca2+]i occurred around -30 mV, and we estimate the peak steady-state ICa to be about 0.6 pA.

Sodium/calcium exchange regulates cytoplasmic calcium in smooth muscle.

The sodium/calcium (Na+/Ca2+) exchanger is often considered to be a key regulator of the cytoplasmic calcium concentration ([Ca2+]) in smooth muscle but neither its precise role in Ca2+ homeostasis nor even its existence in smooth muscle are generally agreed upon. Here we directly assessed the role Na+/Ca2+ exchange plays in regulating [Ca2+] in single voltage-clamped smooth muscle cells. Following an elevation of [Ca2+], its decline was found to have both voltage-dependent and voltage-independent components. The voltage-dependent component was abolished when Na+ was removed from the external bathing solution. During the fall of [Ca2+] a small and declining Na(+)-dependent inward current was observed of a magnitude predicted by 3:1 Na+/Ca2+ exchange stoichiometry. At [Ca2+] above 400 nM the principal efflux of Ca2+ above rest was attributed to this Na(+)-dependent removal mechanism. These results establish that a Na+/Ca2+ exchanger exists in smooth muscle and argue that it can regulate [Ca2+] at physiological Ca2+ concentrations.

Inward rectifier K+ currents in smooth muscle cells from rat resistance-sized cerebral arteries.

Inward rectifier K+ channels have been implicated in the control of membrane potential and external K(+)-induced dilations of small cerebral arteries. In the present study, whole cell K+ currents through the inward rectifier K+ channel were measured in single smooth muscle cells isolated from the posterior cerebral artery of Wistar-Kyoto rats. The whole cell K+ current-voltage relationship showed inward rectification. Inward currents were recorded negative to the K+ equilibrium potential, whereas outward currents were small. When extracellular K+ was elevated, the zero current potential shifted to the new K+ equilibrium potential, and the conductance of the inward current increased. Inward currents were reduced by external barium or cesium. Inhibition by barium and cesium increased with membrane hyperpolarization. The half-inhibition constant for barium was 2.2 microM at -60 mV, increasing e-fold for a 23-mV depolarization. We provide the first direct measurements of inward rectifier K+ currents in single smooth muscle cells and show that external barium ions are effective blockers of these currents.

Single calcium channels in resistance-sized cerebral arteries from rats.

Unitary currents through single calcium channels were measured from cell-attached patches on smooth muscle cells isolated from resistance-sized branches of posterior cerebral arteries from Wistar-Kyoto normotensive rats. Barium (80 and 10 mM) was used as the charge carrier, with and without the dihydropyridine calcium channel agonist BAY R 5417. Unitary currents decreased on membrane depolarization, with a slope conductance of 19.4 pS (80 mM barium). Channel open-state probability (Po) was steeply voltage dependent. Peak Po during test pulses from -70 mV increased e-fold per 4.5-mV depolarization. Mean peak Po at potentials positive to +10 mV was 0.44. Po at steady membrane potentials was also steeply voltage dependent, changing e-fold per 4.5 mV in the absence of inactivation. Steady-state Po at positive potentials was substantially lower than peak Po elicited by test pulses, suggesting that steady-state inactivation can reduce Po by as much as 10-fold. Membrane depolarization decreased the longest mean closed time but had little effect on the mean open time of single calcium channels measured during steady-state recordings. Lowering the external barium concentration from 80 to 10 mM reduced the single channel conductance to 12.4 pS and shifted the relationship between steady-state Po and membrane potential by about -30 mV. BAY R 5417 also shifted this relationship by about -15 mV.

Calcium-dependent enhancement of calcium current in smooth muscle by calmodulin-dependent protein kinase II.

Calcium entry through voltage-activated Ca2+ channels is important in regulating many cellular functions. Activation of these channels in many cell types results in feedback regulation of channel activity. Mechanisms linking Ca2+ channel activity with its downregulation have been described, but little is known of the events responsible for the enhancement of Ca2+ current that in many cells follows Ca2+ channel activation and an increase in cytoplasmic Ca2+ concentration. Here we investigate how this positive feedback is achieved in single smooth muscle cells. We find that in these cells voltage-activated calcium current is persistently but reversibly enhanced after periods of activation. This persistent enhancement of the Ca2+ current is mediated by activation of calmodulin-dependent protein kinase II because it is blocked when either the rise in cytoplasmic Ca2+ is inhibited or activation of calmodulin-dependent protein kinase II is prevented by specific peptide inhibitors of calcium-calmodulin or calmodulin-dependent protein kinase II itself. This mechanism may be important in different forms of Ca2+ current potentiation, such as those that depend on prior Ca2+ channel activation or are a result of agonist-induced release of Ca2+ from internal stores.

Cromakalim and pinacidil dilate small mesenteric arteries but not small cerebral arteries.

Small elevations in external K+ hyperpolarize and dilate small cerebral arteries. The hyperpolarization and dilation to K+ are blocked by barium (less than 0.1 mM). Since membrane hyperpolarization appears to be an important mechanism for dilation of these small cerebral arteries, we investigated the effects of the hyperpolarizing vasodilators, cromakalim and pinacidil, on isolated pressurized rat cerebral arteries (diameter of 158 +/- 5 microns at 50% of the systolic blood pressure). Cromakalim and pinacidil, which are potent relaxants of a variety of muscle types, were without effect on posterior cerebral arteries at concentrations that completely dilate similarly sized rat mesenteric arteries (diameter 134 +/- 6 microns at 50% of the systolic blood pressure). The mesenteric artery dilation to cromakalim and pinacidil was reversed by glibenclamide. However, unlike the cerebral arteries, mesenteric arteries did not exhibit a barium-sensitive dilation to external K+. Thus it appears that there may be differences in the types of K+ channels that are activated by dilating mechanisms in small cerebral and mesenteric arteries.