Juan Ureña

Ca2+ channel-sarcoplasmic reticulum coupling: a mechanism of arterial myocyte contraction without Ca2+ influx

Contraction of vascular smooth muscle cells (VSMCs) depends on the rise of cytosolic [Ca2+] owing to either Ca2+ influx through voltage‐gated Ca2+ channels of the plasmalemma or receptor‐mediated Ca2+ release from the sarcoplasmic reticulum (SR). We show that voltage‐gated Ca2+ channels in arterial myocytes mediate fast Ca2+ release from the SR and contraction without the need of Ca2+ influx. After sensing membrane depolarization, Ca2+ channels activate G proteins and the phospholipase C–inositol 1,4,5‐trisphosphate (InsP3) pathway. Ca2+ released through InsP3‐dependent channels of the SR activates ryanodine receptors to amplify the cytosolic Ca2+ signal. These observations demonstrate a new mechanism of signaling SR Ca2+‐release channels and reveal an unexpected function of voltage‐gated Ca2+ channels in arterial myocytes. Our findings may have therapeutic implications as the calcium‐channel‐induced Ca2+ release from the SR can be suppressed by Ca2+‐ channel antagonists.

K+ and Ca2+ channel activity and cytosolic [Ca2+] in oxygen-sensing tissues.

Ion channels are known to participate in the secretory or mechanical responses of chemoreceptor cells to changes in oxygen tension (P(O2)). We review here the modifications of K+ and Ca2+ channel activity and the resulting changes in cytosolic [Ca2+] induced by low P(O2) in glomus cells and arterial smooth muscle which are well known examples of O2-sensitive cells. Glomus cells of the carotid body behave as presynaptic-like elements where hypoxia produces a reduction of K+ conductance leading to enhanced membrane excitability, Ca2+ entry and release of dopamine and other neurotransmitters. In arterial myocytes, hypoxia can inhibit or potentiate Ca2+ channel activity, thus regulating cytosolic [Ca2+] and contraction. Ca2+ channel inhibition is observed in systemic myocytes and most conduit pulmonary myocytes, whereas potentiation is seen in a population of resistance pulmonary myocytes. The mechanism whereby O2 modulates ion channel activity could depend on either the direct allosteric modulation by O2-sensing molecules or redox modification by reactive chemical species.

Contrasting effects of hypoxia on cytosolic Ca2+ spikes in conduit and resistance myocytes of the rabbit pulmonary artery.

1. The effects of hypoxia on cytosolic Ca2+ ¿[Ca2+]i) and spontaneous cytosolic Ca2+ spikes were examined in fura 2‐loaded myocytes isolated from conduit and resistance branches of the rabbit pulmonary artery. In all myocyte classes, generation of the Ca2+ spikes was modulated by basal [Ca2+]i which, in turn, was influenced by the influx of Ca2+ through L‐type Ca2+ channels of the plasmalemma. 2. Conduit and resistance myocytes responded distinctly to hypoxia. In most conduit myocytes (approximately 82% of total; n = 23) exposure to hypoxia reduced basal [Ca2+]i. This effect was often associated with the abolition of the Ca2+ spikes. Hypoxia gave rise to two main responses in resistance myocytes. In a subset of resistance myocytes (41 % of total; n = 34) hypoxia incremented basal [Ca2+]i but reduced Ca2+ spike amplitude. This response mimicked the effect of membrane depolarization with K+ and was reverted by nifedipine or the removal of extracellular Ca2+. In a second subset of resistance myocytes (59% of total; n = 34) hypoxia decreased basal [Ca2+]i and, in most cases, increased spike amplitude; a response counteracted by depolarization with K+. 3. These results indicate that hypoxia can differentially modulate [Ca2+]i in smooth muscle cells from large and small diameter pulmonary vessels through a dual effect on transmembrane Ca2+ influx. Our observations further demonstrate the longitudinal heterogeneity of myocytes along the pulmonary arterial tree and help to explain the hypoxic vasomotor responses in the pulmonary circulation.

Reduction of Ca2+ channel activity by hypoxia in human and porcine coronary myocytes

OBJECTIVE Oxygen (O(2)) tension is a major regulator of blood flow in the coronary circulation. Hypoxia can produce vasodilation through activation of ATP regulated K(+) (K(ATP)) channels in the myocyte membrane, which leads to hyperpolarization and closure of voltage-gated Ca(2+) channels. However, there are other O(2)-sensitive mechanisms intrinsic to the vascular smooth muscle since hypoxia can relax vessels precontracted with high extracellular K(+), a condition that prevents hyperpolarization following opening of K(+) channels. The objective of the present study was to determine whether inhibition of Ca(2+) influx through voltage-dependent channels participates in the response of coronary myocytes to hypoxia. METHODS Experiments were performed on porcine anterior descendent coronary arterial rings and on enzymatically dispersed human and porcine myocytes of the same artery. Cytosolic [Ca(2+)] was measured by microfluorimetry and whole-cell currents were recorded with the patch clamp technique. RESULTS Hypoxia (O(2) tension approximately 20 mmHg) dilated endothelium-denuded porcine coronary arterial rings precontracted with high K(+) in the presence of glibenclamide (5 microM), a blocker of K(ATP) channels. In dispersed human and porcine myocytes, low O(2) tension decreased basal cytosolic [Ca(2+)] and transmembrane Ca(2+) influx independently of K(+) channel activation. In patch clamped cells, hypoxia reversibly inhibited L-type Ca(2+) channels. RT-PCR indicated that rHT is the predominant mRNA variant of the alpha(1C) Ca(2+) channel subunit in human coronary myocytes. CONCLUSION Our study demonstrates, for the first time in a human preparation, that voltage-gated Ca(2+)channels in coronary myocytes are under control of O(2) tension.

Metabotropic Regulation of RhoA/Rho-Associated Kinase by L-type Ca2+ Channels New Mechanism for Depolarization-Evoked Mammalian Arterial Contraction

Background: Sustained vascular smooth muscle contraction is mediated by extracellular Ca2+ influx through L-type voltage-gated Ca2+ channels (VGCC) and RhoA/Rho-associated kinase (ROCK)-dependent Ca2+ sensitization of the contractile machinery. VGCC activation can also trigger an ion-independent metabotropic pathway that involves G-protein/phospholipase C activation, inositol 1,4,5-trisphosphate synthesis, and Ca2+ release from the sarcoplasmic reticulum (calcium channel-induced Ca2+ release). We have studied the functional role of calcium channel-induced Ca2+ release and the inter-relations between Ca2+ channel and RhoA/ROCK activation. Methods and Results: We have used normal and genetically modified animals to study single myocyte electrophysiology and fluorimetry as well as cytosolic Ca2+ and diameter in intact arteries. These analyses were complemented with measurement of tension and RhoA activity in normal and reversibly permeabilized arterial rings. We have found that, unexpectedly, L-type Ca2+ channel activation and subsequent metabotropic Ca2+ release from sarcoplasmic reticulum participate in depolarization-evoked RhoA/ROCK activity and sustained arterial contraction. We show that these phenomena do not depend on the change in the membrane potential itself, or the mere release of Ca2+ from the sarcoplasmic reticulum, but they require the simultaneous activation of VGCC and the downstream metabotropic pathway with concomitant Ca2+ release. During protracted depolarizations, refilling of the stores by a residual extracellular Ca2+ influx through VGCC helps maintaining RhoA activity and sustained arterial contraction. Conclusions: These findings reveal that calcium channel-induced Ca2+ release has a major role in tonic vascular smooth muscle contractility because it links membrane depolarization and Ca2+ channel activation with metabotropic Ca2+ release and sensitization (RhoA/ROCK stimulation). # Novelty and Significance {#article-title-45}Background: Sustained vascular smooth muscle contraction is mediated by extracellular Ca2+ influx through L-type voltage-gated Ca2+ channels (VGCC) and RhoA/Rho-associated kinase (ROCK)-dependent Ca2+ sensitization of the contractile machinery. VGCC activation can also trigger an ion-independent metabotropic pathway that involves G-protein/phospholipase C activation, inositol 1,4,5-trisphosphate synthesis, and Ca2+ release from the sarcoplasmic reticulum (calcium channel-induced Ca2+ release). We have studied the functional role of calcium channel-induced Ca2+ release and the inter-relations between Ca2+ channel and RhoA/ROCK activation. Methods and Results: We have used normal and genetically modified animals to study single myocyte electrophysiology and fluorimetry as well as cytosolic Ca2+ and diameter in intact arteries. These analyses were complemented with measurement of tension and RhoA activity in normal and reversibly permeabilized arterial rings. We have found that, unexpectedly, L-type Ca2+ channel activation and subsequent metabotropic Ca2+ release from sarcoplasmic reticulum participate in depolarization-evoked RhoA/ROCK activity and sustained arterial contraction. We show that these phenomena do not depend on the change in the membrane potential itself, or the mere release of Ca2+ from the sarcoplasmic reticulum, but they require the simultaneous activation of VGCC and the downstream metabotropic pathway with concomitant Ca2+ release. During protracted depolarizations, refilling of the stores by a residual extracellular Ca2+ influx through VGCC helps maintaining RhoA activity and sustained arterial contraction. Conclusions: These findings reveal that calcium channel-induced Ca2+ release has a major role in tonic vascular smooth muscle contractility because it links membrane depolarization and Ca2+ channel activation with metabotropic Ca2+ release and sensitization (RhoA/ROCK stimulation).

Metabotropic Regulation of RhoA/Rho-Associated Kinase by L-type Ca2+ Channels

Background: Sustained vascular smooth muscle contraction is mediated by extracellular Ca2+ influx through L-type voltage-gated Ca2+ channels (VGCC) and RhoA/Rho-associated kinase (ROCK)-dependent Ca2+ sensitization of the contractile machinery. VGCC activation can also trigger an ion-independent metabotropic pathway that involves G-protein/phospholipase C activation, inositol 1,4,5-trisphosphate synthesis, and Ca2+ release from the sarcoplasmic reticulum (calcium channel-induced Ca2+ release). We have studied the functional role of calcium channel-induced Ca2+ release and the inter-relations between Ca2+ channel and RhoA/ROCK activation. Methods and Results: We have used normal and genetically modified animals to study single myocyte electrophysiology and fluorimetry as well as cytosolic Ca2+ and diameter in intact arteries. These analyses were complemented with measurement of tension and RhoA activity in normal and reversibly permeabilized arterial rings. We have found that, unexpectedly, L-type Ca2+ channel activation and subsequent metabotropic Ca2+ release from sarcoplasmic reticulum participate in depolarization-evoked RhoA/ROCK activity and sustained arterial contraction. We show that these phenomena do not depend on the change in the membrane potential itself, or the mere release of Ca2+ from the sarcoplasmic reticulum, but they require the simultaneous activation of VGCC and the downstream metabotropic pathway with concomitant Ca2+ release. During protracted depolarizations, refilling of the stores by a residual extracellular Ca2+ influx through VGCC helps maintaining RhoA activity and sustained arterial contraction. Conclusions: These findings reveal that calcium channel-induced Ca2+ release has a major role in tonic vascular smooth muscle contractility because it links membrane depolarization and Ca2+ channel activation with metabotropic Ca2+ release and sensitization (RhoA/ROCK stimulation). # Novelty and Significance {#article-title-45}Background: Sustained vascular smooth muscle contraction is mediated by extracellular Ca2+ influx through L-type voltage-gated Ca2+ channels (VGCC) and RhoA/Rho-associated kinase (ROCK)-dependent Ca2+ sensitization of the contractile machinery. VGCC activation can also trigger an ion-independent metabotropic pathway that involves G-protein/phospholipase C activation, inositol 1,4,5-trisphosphate synthesis, and Ca2+ release from the sarcoplasmic reticulum (calcium channel-induced Ca2+ release). We have studied the functional role of calcium channel-induced Ca2+ release and the inter-relations between Ca2+ channel and RhoA/ROCK activation. Methods and Results: We have used normal and genetically modified animals to study single myocyte electrophysiology and fluorimetry as well as cytosolic Ca2+ and diameter in intact arteries. These analyses were complemented with measurement of tension and RhoA activity in normal and reversibly permeabilized arterial rings. We have found that, unexpectedly, L-type Ca2+ channel activation and subsequent metabotropic Ca2+ release from sarcoplasmic reticulum participate in depolarization-evoked RhoA/ROCK activity and sustained arterial contraction. We show that these phenomena do not depend on the change in the membrane potential itself, or the mere release of Ca2+ from the sarcoplasmic reticulum, but they require the simultaneous activation of VGCC and the downstream metabotropic pathway with concomitant Ca2+ release. During protracted depolarizations, refilling of the stores by a residual extracellular Ca2+ influx through VGCC helps maintaining RhoA activity and sustained arterial contraction. Conclusions: These findings reveal that calcium channel-induced Ca2+ release has a major role in tonic vascular smooth muscle contractility because it links membrane depolarization and Ca2+ channel activation with metabotropic Ca2+ release and sensitization (RhoA/ROCK stimulation).

Short Communication: Genetic Ablation of L-Type Ca2+ Channels Abolishes Depolarization-Induced Ca2+ Release in Arterial Smooth Muscle

Rationale: In arterial myocytes, membrane depolarization-induced Ca2+ release (DICR) from the sarcoplasmic reticulum (SR) occurs through a metabotropic pathway that leads to inositol trisphosphate synthesis independently of extracellular Ca2+ influx. Despite the fundamental functional relevance of DICR, its molecular bases are not well known. Objective: Biophysical and pharmacological data have suggested that L-type Ca2+ channels could be the sensors coupling membrane depolarization to SR Ca2+ release. This hypothesis was tested using smooth muscle–selective conditional Cav1.2 knockout mice. Methods and Results: In aortic myocytes, the decrease of Ca2+ channel density was paralleled by the disappearance of SR Ca2+ release induced by either depolarization or Ca2+ channel agonists. Cav1.2 channel deficiency resulted in almost abolition of arterial ring contraction evoked by DICR. Ca2+ channel–null cells showed unaltered caffeine-induced Ca2+ release and contraction. Conclusion: These data suggest that Cav1.2 channels are indeed voltage sensors coupled to the metabolic cascade, leading to SR Ca2+ release. These findings support a novel, ion-independent, functional role of L-type Ca2+ channels linked to intracellular signaling pathways in vascular myocytes.

Hypoxia inhibits vasoconstriction induced by metabotropic Ca2+ channel-induced Ca2+ release in mammalian coronary arteries

AIMS We have previously described in rat basilar arterial myocytes that in the absence of extracellular Ca(2+) influx, activation of L-type Ca(2+) channels stimulates a metabotropic cascade leading to Ca(2+) release from the sarcoplasmic reticulum (SR) and contraction [a calcium channel-induced Ca(2+) release (CCICR) mechanism]. On the other hand, it is known that hypoxia reduces Ca(2+) channel activity in coronary myocytes. In the present study, we have investigated whether CCICR is present in coronary arterial myocytes and whether arterial ring contraction induced by CCICR can be inhibited by hypoxia. METHODS AND RESULTS Isometric force, arterial diameter, cytosolic [Ca(2+)] and electrical activity were recorded on mammalian (porcine, rat, and human) coronary artery preparations (dispersed myocytes, arterial rings, and intact arterial segments). In the absence of extracellular Ca(2+), Ca(2+) channel activation increased cytosolic [Ca(2+)] in isolated myocytes and contracted arterial rings. This contraction was suppressed by antagonists of L-type Ca(2+) channels and by inhibiting Ca(2+) release from the SR. Hypoxia induced dilatation of coronary arterial rings pre-contracted by activation of Ca(2+) channels in the absence of extracellular Ca(2+). This effect was present although K(ATP) channels and Rho kinase were blocked by glibenclamide and Y27632, respectively. CONCLUSION We show that Ca(2+) channel activation can induce metabotropic coronary arterial ring contraction in the absence of extracellular Ca(2+) and that this CCICR mechanism is inhibited by hypoxia. Thus, besides reduction of Ca(2+) entry through Ca(2+) channels, hypoxia seems to induce coronary vasorelaxation by inhibition of metabotropic CCICR.

Intracellular calcium release mediated by noradrenaline and acetylcholine in mammalian pineal cells

Abstract: The effects of noradrenergic and cholinergic receptor agonists on intracellular Ca2+ concentration ([Ca2+]i) in single dissociated rat pineal cells were investigated by microfluorimetric measurements in Fura‐2 acetoxymethyl ester (Fura‐2/AM) loaded cells. Noradrenaline (NA) evoked characteristic biphasic increments of intracellular Ca2+ consisting of one or more leading spikes followed by a plateau, resulting from the release of Ca2+ from intracellular stores and from the influx of Ca2+ from the external medium, respectively. This response was reproduced by the α1 adrenoceptor agonist, phenylephrine (PE), in the presence of the β‐adrenoceptor antagonist, propranolol, and was abolished when NA or PE was applied in conjunction with the α1‐adrenoceptor antagonist, prazosin. The curve relating the peak amplitude of the Ca2+ increments to different PE concentrations (0.5–10 μM) showed a half‐maximum response at 0.6 μM PE, and saturation at concentrations greater than 2 μM. Acetylcholine (ACh) also elicited transient Ca2+ increments consisting of an abrupt rise to a maximum value which decayed exponentially to the basal Ca2+ level. A half‐maximum response was achieved at 59 μM ACh. The muscarinic cholinergic receptor agonist, carbachol (CCh), similarly activated Ca2+ increments while the muscarinic antagonist, atropine, abolished them. In the absence of extracellular Ca2+, repetitive stimuli with either α1‐adrenergic and muscarinic agonists produced a progressive decrement in the amplitude of the Ca2+ signals because of the depletion of intracellular stores. However, extinction of the response to muscarinic agonists did not preclude a response to adrenergic agonists, while the contrary was not true. These results suggest that these agonists liberate Ca2+ from two functionally distinct, caffeine‐insensitive, Ca2+ intracellular stores.

Metabotropic Regulation of RhoA/Rho–Associated Kinase by L-Type Ca2+ Channels

Sustained vascular smooth muscle contraction can be mediated by several mechanisms, including the influx of extracellular Ca(2+) through L-type voltage-gated Ca(2+) channels (LTCCs) and by RhoA/Rho-associated kinase (ROCK)-dependent Ca(2+) sensitization of the contractile machinery. Conformational changes in the LTCC following depolarization can also trigger an ion-independent metabotropic pathway that involves G protein/phospholipase C activation, giving rise to inositol 1,4,5-trisphosphate synthesis and subsequent Ca(2+) release from the sarcoplasmic reticulum (SR) (calcium channel-induced Ca(2+) release or calcium channel-induced calcium release [CCICR]). In this review, we summarize recent data suggesting that LTCC activation and subsequent metabotropic Ca(2+) release from the SR participate in depolarization-evoked RhoA/ROCK activity and sustained arterial contraction. During protracted depolarizations, refilling of the SR stores by a residual influx of extracellular Ca(2+) through LTCCs helps maintain RhoA activity and contractile activation. These findings suggest that CCICR plays a major role in tonic vascular smooth muscle contraction, providing a link between membrane depolarization-induced LTCC activation and metabotropic Ca(2+) release and RhoA/ROCK stimulation.