Localization of inositol 1,4,5-trisphosphate receptor-like protein in plasmalemmal caveolae

Activation of various receptors by extracellular ligands induces an influx of Ca2+ through the plasma membrane, but its molecular mechanism remains elusive and seems variable in different cell types. In the present study, we utilized mAbs generated against the cerebellar type I inositol 1,4,5-trisphosphate (InsP3) receptor and performed immunocytochemical and immunochemical experiments to examine its localization in several non-neuronal cells. By immunogold electron microscopy of ultrathin frozen sections as well as permeabilized tissue specimens, we found that a mAb to the type I InsP3 receptor (mAb 4C11) labels the plasma membrane of the endothelium, smooth muscle cell and keratinocyte in vivo. Interestingly, the labeling with the antibody was confined to caveolae, smooth vesicular inpocketings of the plasma membrane. The reactive protein, with an M(r) of 240,000 by SDS-PAGE, could be biotinylated with a membrane-impermeable reagent, sulfo-NHS-biotin, in intact cultured endothelial cells, and recovered by streptavidin-agarose beads, which result further confirmed its presence on the cell surface. The present findings indicate that a protein structurally homologous to the type I InsP3 receptor is localized in the caveolar structure of the plasma membrane and might be involved in the Ca2+ influx.     

A monoclonal antibody to the calmodulin-binding (Ca2+ + Mg2+)-dependent ATPase from pig stomach smooth muscle inhibits plasmalemmal (Ca2+ + Mg2+)-dependent ATPase activity.

A monoclonal antibody (2B3) directed against the calmodulin-binding (Ca2+ + Mg2+)-dependent ATPase from pig stomach smooth muscle was prepared. This antibody reacts with a 130,000-Mr protein that co-migrates on SDS/polyacrylamide-gel electrophoresis with the calmodulin-binding (Ca2+ + Mg2+)-ATPase purified from smooth muscle by calmodulin affinity chromatography. The antibody causes partial inhibition of the (Ca2+ + Mg2+)-ATPase activity in plasma membranes from pig stomach smooth muscle, in pig erythrocytes and human erythrocytes. It appears to be directed against a specific functionally important site of the plasmalemmal Ca2+-transport ATPase and acts as a competitive inhibitor of ATP binding. Binding of the antibody does not change the Km of the ATPase for Ca2+ and its inhibitory effect is not altered by the presence of calmodulin. No inhibition of (Ca2+ + Mg2+)-ATPase activity or of the oxalate-stimulated Ca2+ uptake was observed in a pig smooth-muscle vesicle preparation enriched in endoplasmic reticulum. These results confirm the existence in smooth muscle of two different types of Ca2+-transport ATPase: a calmodulin-binding (Ca2+ + Mg2+)-ATPase located in the plasma membrane and a second one confined to the endoplasmic reticulum.     

Functional differences of Na+/Ca2+ exchanger expression in Ca2+ transport system of smooth muscle of guinea pig stomach

The plasma membrane ATP-dependent Ca2+ pump and the Na+/Ca2+ exchanger (NCX) are the major means of Ca2+ extrusion in smooth muscle. However, little is known regarding distribution and function of the NCX in guinea pig gastric smooth muscle. The expression pattern and distribution of NCX isoforms suggest a role as a regulator of Ca2+ transport in cells. Na+ pump inhibition and the consequent to removal of K+ caused gradual contraction in fundus. In contrast, the response was significantly less in antrum. Western blotting analysis revealed that NCX1 and NCX2 are the predominant NCX isoforms expressed in stomach, the former was expressed strongly in antrum, whereas the latter displayed greater expression in fundus. Isolated plasma membrane fractions derived from gastric fundus smooth muscle were also investigated to clarify the relationship between NCX protein expression and function. Na+-dependent Ca2+ uptake increased directly with Ca2+ concentration. Ca2+ uptake in Na+-loaded vesicles was markedly elevated in comparison with K+-loaded vesicles. Additionally, Ca2+ uptake by the Na+- or K+-loaded vesicles was substantially higher in the presence of A23187 than in its absence. The result can be explained based on the assumption that Na+ gradients facilitate downhill movement of Ca2+. Na+-dependent Ca2+ uptake was abolished by the monovalent cationic ionophore, monensin. NaCl enhanced Ca2+ efflux from vesicles, and this efflux was significantly inhibited by gramicidin. Results documented evidence that NCX2 isoform functionally contributes to Ca2+ extrusion and maintenance of contraction-relaxation cycle in gastric fundus smooth muscle.     

Ca2+ currents and acid secretion in the isolated parietal cell involved in response to gastrin, compound 48/80, and ethylenediamine tetraacetic acid

In intact guinea pig parietal cells, gastrin or compound 48/80 caused an initial increase in cytosolic Ca2+ concentration and subsequent acid secretion, owing to release of intracellulary stored Ca2+ besides the Ca2+ entry from the extracellular space. However, the maximum gastrin-induced Ca2+ entry into the cell was delayed by 60 min, a time which coincided with sustained acid secretion (by gastrin) that was dependent on medium Ca2+. On the other hand, there are two ATP-dependent Ca2+-removal systems detected in either plasmalemma or smooth surfaced membrane besides that of mitochondria. The plasmalemmal Ca2+-removal system was dependent on calmodulin. Smooth surfaced membrane vesicles caused an ATP-dependent Ca2+ uptake that was almost similar to that taken by saponin-permiabilized cell. In this system (permeable cell), myo-inositol 1,4,5-triphosphate (InsP3) caused the release of ATP-accumulated Ca2+ into the cytosol, suggesting an ATP-dependent and InsP3-sensitive Ca2+ pool(s) is in or near the smooth surfaced membranes. The ATP-dependent Ca2+ uptake by vesicles was markedly enhanced by the stimulation of cells with gastrin, compound 48/80, or EDTA. The increase of this Ca2+ uptake in stimulated cells by plasmalemmal vesicles exceeded that by smooth surfaced ones. The increase of the Ca2+ uptake by plasmalemmal vesicles was abolished by the cease of intracellular Ca2+ release without Ca2+ entry. In addition, gastrin or compound 48/80 evoked an early Ca2+ efflux across the plasma membrane owing to a pump that was independent of medium Ca2+ in intact cells. These results suggest that in the first acid secretion by gastrin or others, the Ca2+ released, which may be derived from an ATP-dependent and InsP3-sensitive Ca2+ pool, is mainly pumped out by the plasmalemmal Ca2+-removal system rather than the intracellular Ca2+-removal system; whereas the sustained acid secretion by gastrin required medium Ca2+ and in this phase, Ca2+ efflux across the plasma membrane became lower, suggesting that an ATP-dependent Ca2+ pool may be replenished by Ca2+ entering from the extracellular space.     

The Ca2+-pumping ATPase and the major substrates of the cGMP-dependent protein kinase in smooth muscle sarcolemma are distinct entities

It has been proposed that the plasma membrane Ca2+ pump of smooth muscle tissues may be regulated by cGMP-dependent phosphorylation [Popescu, L. M., Panoiu, C., Hinescu, M. & Nutu, O. (1985) Eur. J. Pharmacol. 107, 393-394; Furukawa, K. & Nakamura, H. (1987) J. Biochem. (Tokyo) 101, 287-290]. This hypothesis has been tested on a smooth muscle sarcolemma preparation from pig thoracic aorta. The actomyosin-extracted membranes showed ATP-dependent Ca2+ uptake as well as cGMP-dependent protein kinase (G-kinase) activity. The molecular masses of the major protein substrates of the G-kinase (G1) and that of the Ca2+ pump were compared. Electrophoretic analysis of the phosphorylated intermediate of the sarcolemmal Ca2+-ATPase and the G1 phosphoprotein showed that these two proteins are not identical. The results were confirmed by using a 125I-calmodulin overlay technique and an antibody against human erythrocyte Ca2+-ATPase. Ca2+-uptake experiments with prephosphorylated membrane vesicles were carried out to elucidate possible effects of cGMP-dependent phosphorylation of membrane proteins on the activity of the Ca2+ pump. The cGMP-dependent phosphorylation was found to be extremely sensitive to temperature leading to very low steady-state phosphorylation levels at 37 degrees C. The difficulty was overcome by ATP[gamma S], which produced full and stable thiophosphorylation of G1 during the Ca2+-uptake experiments at 37 degrees C. However, the cGMP-dependent thiophosphorylation failed to influence the Ca2+-uptake properties of sarcolemmal vesicles. The results show that the Ca2+ pump of smooth muscle plasma membrane is not a direct target of the cGMP-dependent protein kinase and is not regulated by the cGMP-dependent phosphorylation of membrane proteins.     

Caveolae from canine airway smooth muscle contain the necessary components for a role in Ca(2+) handling

To explain that bronchial smooth muscle undergoes sustained agonist-induced contractions in a Ca(2+)-free medium, we hypothesized that caveolae in the plasma membrane (PM) contain protected Ca(2+). We isolated caveolae from canine tracheal smooth muscle by detergent treatment of PM-derived microsomes. Detergent-resistant membranes were enriched in caveolin-1, a specific marker for caveolae as well as for L-type Ca(2+) channels and Ca(2+) binding proteins (calsequestrin and calreticulin) as determined by Western blotting. Also, the PM Ca(2+) pump was present but not connexin 43 (a noncaveolae PM protein), the sarcoplasmic reticulum (SR) Ca(2+) pump, or the type 1 inositol 1,4, 5-trisphosphate receptor, supporting the idea that SR-derived membranes were not present. Antibodies to caveolin coimmunoprecipitated caveolin with calsequestrin or calreticulin. Thus some of the cellular calsequestrin and calreticulin associated with caveolin on the cytoplasmic face of each caveola. Immunohistochemistry of tracheal smooth muscle crysosections confirmed the localization of caveolin and the PM Ca(2+) pump to the cell periphery, whereas the SR Ca(2+) pump was located deeper in the cell. The presence of L-type Ca(2+) channels, the PM Ca(2+) pump, and the Ca(2+) bindng proteins calsequestrin and calreticulin in caveolin-enriched membranes supports caveola involvement in airway smooth muscle Ca(2+) handling.     

Modulation of plasma membrane Ca2+ pump by membrane potential in cultured vascular smooth muscle cells

We examined the effect of membrane potential (Em) on the activity of the plasma membrane Ca2+ pump in cultured rat aortic smooth muscle cells (VSMCs). Inside-negative K+ diffusion potential higher or lower than the resting Em (-46 mV) was artificially imposed on VSMCs with various concentrations of extracellular K+ (K+o) and 1 microM valinomycin. We found that the recovery phase of the intracellular Ca2+ transient elicited with 1 microM ionomycin was accelerated by depolarizing Em, whereas it was retarded by hyperpolarizing Em. The rate of extracellular Na+ (Na+o)-independent 45Ca2+ efflux from VSMCs stimulated with 1 microM ionomycin increased almost linearly with a change in Em from -98 to -3 mV. This effect of Em was abolished by extracellularly added LaCl3 or a combination of high pH (pH 8.8) and high Mg2+ (20 mM), conditions that presumably inhibit the plasma membrane Ca2+ pump (Furukawa, K.-I., Tawada, Y., & Shigekawa, M. (1988) J. Biol. Chem. 263, 8058-8065). Intracellular contents of Na+ and K+ and intracellular pH, on the other hand, were not influenced by the change in Em under the conditions used. These results indicate that alteration in Em can modulate the intracellular Ca2+ concentration in intact VSMCs by changing the rate of Ca2+ extrusion by the plasma membrane Ca2+ pump. The data strongly suggest that the plasma membrane Ca2+ pump in VSMCs is electrogenic.     

Alkylacetylglycerophosphocholine stimulates Na+-Ca2+ exchange, protein phosphorylation and polyphosphoinositide turnover in rat ileal plasmalemmal vesicles

The novel ether phospholipid, 1-O-alkyl-2-acetyl-sn-glycero-3-phosphocholine (AGEPC), isometrically contracted helically cut rat ileal smooth muscle strips in a dose- and time-dependent manner. Utilizing an enriched plasma membrane vesicular preparation from rat ileal longitudinal smooth muscle, AGEPC specifically stimulated Na+-Ca2+ exchange in a dose- and time-dependent manner. Concomitant with the AGEPC stimulation of Na+-dependent Ca2+ influx in plasma membrane vesicles is an enhanced turnover of the polyphosphoinositides, an elevated concentration of phosphatidic acid and also an enhanced phosphorylation of an Mr 40,000 plasmalemmal protein. The mechanisms by which AGEPC may regulate ileal plasmalemmal Ca2+ flux and contractility are considered.     

The three-dimensional organization of smooth endoplasmic reticulum in capillary endothelia: its possible role in regulation of free cytosolic calcium

A rise in cytosolic free Ca in capillary endothelia leads to increased permeability. It has been proposed that this Ca(2+)-regulated modulation of junctional permeability of vascular endothelia involves structural elements comparable to those involved in stimulus-contraction coupling in smooth muscle. To explore this analogy the three-dimensional organization of smooth-surfaced cisternae, vesicular membrane profiles, and tight junctions was examined in endothelia of diaphragm and heart capillaries of the rat. Three-dimensional reconstructions, based on consecutive sections of the capillaries, have demonstrated a population of small, irregular membrane profiles, occurring in individual thin sections of the endothelial cytoplasm. These profiles represent an elaborate system of smooth-surfaced cisternae, structurally similar to the sarcoplasmic reticulum (SR) of smooth muscle cells. Slender processes from the cisternae are often situated in parallel to the tight junctions at a distance of about 100 nm. The great majority of the characteristic circular membrane profiles represents caveolae and racemose invaginations of the endothelial plasma membrane, often in close relation to the cisternae. It is hypothesized that the endothelial cisternae and invaginations of the cell membrane are involved in regulation of free cytosolic calcium in the same way as the SR and caveolae in smooth muscle cells. The junction-related cisternal processes may play a role in the Ca(2+)-regulated modulation of junctional permeability.     

Caveolae-associated signalling in smooth muscle

Caveolae are flask-shaped invaginations in the membrane that depend on the contents of cholesterol and on the structural protein caveolin. The organisation of caveolae in parallel strands between dense bands in smooth muscle is arguably unique. It is increasingly recognised, bolstered in large part by recent studies in caveolae deficient animals, that caveolae sequester and regulate a variety of signalling intermediaries. The role of caveolae in smooth muscle signal transduction, as inferred from studies on transgenic animals and in vitro approaches, is the topic of the current review. Both G-protein coupled receptors and tyrosine kinase receptors are believed to cluster in caveolae, and the exciting possibility that caveolae provide a platform for interactions between the sarcoplasmic reticulum and plasmalemmal ion channels is emerging. Moreover, messengers involved in Ca2+ sensitization of myosin phosphorylation and contraction may depend on caveolae or caveolin. Caveolae thus appear to constitute an important signalling domain that plays a role not only in regulation of smooth muscle tone, but also in proliferation, such as seen in neointima formation and atherosclerosis.     

Visualizing caveolin-1 and HDL in cholesterol-loaded aortic endothelial cells

Caveolae are vesicular invaginations of the plasma membranes that regulate signal transduction and transcytosis, as well as cellular cholesterol homeostasis. Our previous studies indicated that the removal of cholesterol from aortic endothelial cells and smooth muscle cells in the presence of HDL is associated with plasmalemmal invaginations and plasmalemmal vesicles. The goal of the present study was to investigate the location and distribution of caveolin-1, the main structural protein component of caveolae, in cholesterol-loaded aortic endothelial cells after HDL incubation. Confocal microscopic analysis demonstrated that the caveolin-1 appeared to colocalize with HDL-fluorescein 1,1'-dioctadecyl 3,3,3',3'-tetramethylindocarbocyanine perchlorate (DiI) conjugates on the cell surface. No free HDL-DiI conjugates were revealed in the cytoplasm. Immunoelectron microscopy further demonstrated that caveolin-1 gold (15 nm) conjugates colocalized with HDL gold (10 nm) conjugates in the plasmalemmal invaginations. These morphological results indicated that caveolae are the major membrane domains facilitating the transport of excess cholesterol to HDL on the cell surface of aortic endothelial cells.     

cav-p60 expression in rat muscle tissues

Caveolae are plasmalemmal invaginations of uncertain function. In view of the large number of hypotheses on caveolar functions, it is important to identify which components of caveolae are tissue specific and which are general. The only well-characterized major protein of caveolae is caveolin, which exists in three tissue-specific isoforms: caveolin-1, -2, and -3. Recently cav-p60 was characterized as a 60-kDa caveola-specific protein in adipocytes. The distributions of cav-p60 and caveolin isoforms in different rat muscle tissues were examined by immunofluorescence and immunoelectron microscopy. Cav-p60 was present in caveolae of skeletal and heart muscle, in vascular and intestinal smooth muscle, and in adipocyte caveolae. Furthermore cav-p60 was present in endothelial cells and cells of perineural sheaths. Caveolin-1 and -2 were present in adipocytes, endothelial cells, and cells of perineural sheaths. In all kinds of vascular and intestinal smooth muscle, caveolin-1 and -2 were present at high levels, whereas caveolin-3 expression was low or undetectable, depending on the specific smooth muscle subtype. High levels of caveolin-3 were found only in caveolae and T tubules of skeletal and heart muscle. We conclude that cav-p60 is a highly specific marker of caveolae in many if not all cell types having caveolae.     

A Mg2+-independent high-affinity Ca2+-stimulated adenosine triphosphatase in the plasma membrane of rat stomach smooth muscle. Subcellular distribution and inhibition by Mg2+

Plasma membrane enriched fraction isolated from the fundus smooth muscle of rat stomach displayed Ca2+-stimulated ATPase activity in the absence of Mg2+. The Ca2+ dependence of such an ATPase activity can be resolved into two hyperbolic components with a high affinity (Km = 0.4 microM) and a low affinity (Km = 0.6 mM) for Ca2+. Distribution of these high-affinity and low-affinity Ca2+-ATPase activities parallels those of several plasma membrane marker enzyme activities but not those of endoplasmic reticulum and mitochondrial membrane marker enzyme activities. Mg2+ also stimulates the ATPase in the absence of Ca2+. Unlike the Mg2+-ATPase and low-affinity Ca2+-ATPase, the plasmalemmal high-affinity Ca2+-ATPase is not sensitive to the inhibitory effect of sodium azide or Triton X-100 treatment. The high-affinity Ca2+-ATPase is noncompetitively inhibited by Mg2+ with respect to Ca2+ stimulation. Such an inhibitory effect of Mg2+ is potentiated by Triton X-100 treatment of the membrane fraction. Calmodulin has little effect on the high-affinity Ca2+-ATPase activity of the plasma membrane enriched fraction with or without EDTA pretreatment. Findings of this novel, Mg2+-independent, high-affinity Ca2+-ATPase activity in the rat stomach smooth muscle plasma membrane are discussed with those of Mg2+-dependent, high-affinity Ca2+-ATPase activities previously reported in other smooth muscle plasma membrane preparations in relation to the plasma membrane Ca2+-pump.     

Sub cellular Fractionation of the Longitudinal Smooth Muscle/Myenteric Plexus of Dog Ileum: Dissociation of the Distribution of Two Plasma Membrane Marker Enzymes

The distribution of plasma membrane markers, the sodium pump [evaluated as ouabain-sensitive, potassium-stimulated p-nitrophenyl phosphatase (K+-pNPPase)], [3H]saxitoxin binding, and 5'-AMPase, was studied in the subcellular fractions prepared from the homogenates of the longitudinal smooth muscle/myenteric plexus of dog ileum. The K+-pNPPase activity and [3H]-saxitoxin binding were found to be predominantly associated with the synaptosomal fraction as indicated by the high level of these activities in the crude synaptosomal fraction and by the copurification of K+-pNPPase and [3H]saxitoxin binding, but not 5'-AMPase, with several synaptosomal markers during the fractionation of the crude synaptosomal fraction on density gradients. In contrast to the K+-pNPPase activity and [3H]saxitoxin binding, the 5'-AMPase activity was found to be concentrated in the microsomal pellet. Further fractionation of microsomes on density gradient resulted in copurification of 5'-AMPase but not K+-pNPPase or [3H]saxitoxin binding, with other smooth muscle plasma membrane-bound enzymes, such as high-affinity Ca2+-ATPase, Mg2+-ATPase, and Ca2+-ATPase. It was concluded that in the longitudinal smooth muscle/myenteric plexus, the sodium pump activity is present in higher density in the neuronal plasma membranes whereas 5'-AMPase activity is concentrated in the smooth muscle plasma membranes.     

The role of caveolae and caveolin 1 in calcium handling in pacing and contraction of mouse intestine

In mouse intestine, caveolae and caveolin‐1 (Cav‐1) are present in smooth muscle (responsible for executing contractions) and in interstitial cells of Cajal (ICC; responsible for pacing contractions). We found that a number of calcium handling/dependent molecules are associated with caveolae, including L‐type Ca²⁺ channels, Na⁺‐Ca²⁺ exchanger type 1 (NCX1), plasma membrane Ca²⁺ pumps and neural nitric oxide synthase (nNOS), and that caveolae are close to the peripheral endo‐sarcoplasmic reticulum (ER‐SR). Also we found that this assemblage may account for recycling of calcium from caveolar domains to SR through L‐type Ca ⁺ channels to sustain pacing and contractions. Here we test this hypothesis further comparing pacing and contractions under various conditions in longitudinal muscle of Cav‐1 knockout mice (lacking caveolae) and in their genetic controls. We used a procedure in which pacing frequencies (indicative of functioning of ICC) and contraction amplitudes (indicative of functioning of smooth muscle) were studied in calcium‐free media with 100 mM ethylene glycol tetra‐acetic acid (EGTA). The absence of caveolae in ICC inhibited the ability of ICC to maintain frequencies of contraction in the calcium‐free medium by reducing recycling of calcium from caveolar plasma membrane to SR when the calcium stores were initially full. This recycling to ICC involved primarily L‐type Ca²⁺ channels; i.e. pacing frequencies were enhanced by opening and inhibited by closing these channels. However, when these stores were depleted by block of the sarco/endoplasmic reticulum Ca²⁺‐ATPase (SERCA) pump or calcium release was activated by carbachol, the absence of Cav‐1 or caveolae had little or no effect. The absence of caveolae had little impact on contraction amplitudes, indicative of recycling of calcium to SR in smooth muscle. However, the absence of caveolae slowed the rate of loss of calcium from SR under some conditions in both ICC and smooth muscle, which may reflect the loss of proximity to store operated Ca channels. We found evidence that these channels were associated with Cav‐1. These changes were all consistent with the hypothesis that a reduction of the extracellular calcium associated with caveolae in ICC of the myenteric plexus, the state of L‐type Ca²⁺ channels or an increase in the distance between caveolae and SR affected calcium handling.     

Calcium signal transduction from caveolae

Caveolae are specialized membrane microdomains that are found on the plasma membrane of most cells. Recent studies indicate that a variety of signaling molecules are highly organized in caveolae, where their interactions initiate specific signaling cascades. Molecules enriched in this membrane include G protein-coupled receptors, heterotrimeric GTP binding proteins, IP3 receptor-like protein, Ca2+ ATPase, eNOS, and several PKC isoforms. Direct measurements of calcium changes in endothelial cells suggest that caveolae may be sites that regulate intracellular Ca2+ concentration and Ca2+ dependent signal transduction. This review will focus on the role of caveolae in controlling the spatial and temporal pattern of intracellular Ca2+ signaling.     

Immunocytochemical localization of 67 KD Ca2+ binding protein (p67) in ventricular, skeletal, and smooth muscle cells.

By using immunocytochemical techniques, we examined the localization of a 67 kDa Ca2+ binding protein (p67) and calpactin I heavy chain (p36) in ventricular myocytes, skeletal myocytes, and intestinal smooth muscle cells. Immunofluorescence microscopy revealed that the p67 was expressed in all these muscle cells, whereas anti-p36 antibody stained cells in connective tissues but failed to stain these muscle cells. Immunogold electron microscopy was carried out to examine the subcellular localization of the p67 in muscle cells. The results showed that the p67 was exclusively confined to the plasma membrane of muscle cells and the presumptive transverse tubules of the striated myocytes. Immunoblot analysis with anti-p67 antibody showed that the p67 was indeed a constitutive protein of the sarcolemma isolated from rat hearts. These results indicate that the p67 is a sarcolemma-associated Ca2+ binding protein expressed in both striated myocytes and intestinal smooth muscle cells.     

Mechanisms involved in the cellular calcium homeostasis in vascular smooth muscle: calcium pumps

The regulation of cytosolic Ca2+ homeostasis is essential for cells, and particularly for vascular smooth muscle cells. In this regulation, there is a participation of different factors and mechanisms situated at different levels in the cell, among them Ca2+ pumps play an important role. Thus, Ca2+ pump, to extrude Ca2+; Na+/Ca2+ exchanger; and different Ca2+ channels for Ca2+ entry are placed in the plasma membrane. In addition, the inner and outer surfaces of the plasmalemma possess the ability to bind Ca2+ that can be released by different agonists. The sarcoplasmic reticulum has an active role in this Ca2+ regulation; its membrane has a Ca2+ pump that facilitates luminal Ca2+ accumulation, thus reducing the cytosolic free Ca2+ concentration. This pump can be inhibited by different agents. Physiologically, its activity is regulated by the protein phospholamban; thus, when it is in its unphosphorylated state such a Ca2+ pump is inhibited. The sarcoplasmic reticulum membrane also possesses receptors for 1,4,5-inositol trisphosphate and ryanodine, which upon activation facilitates Ca2+ release from this store. The sarcoplasmic reticulum and the plasmalemma form the superficial buffer barrier that is considered as an effective barrier for Ca2+ influx. The cytosol possesses different proteins and several inorganic compounds with a Ca2+ buffering capacity. The hypothesis of capacitative Ca2+ entry into smooth muscle across the plasma membrane after intracellular store depletion and its mechanisms of inhibition and activation is also commented.     

Endothelial cell Ca2+ increases are independent of membrane potential in pressurized rat mesenteric arteries

In rat mesenteric arteries, the ability of ACh to evoke hyperpolarization of smooth muscle cells and consummate dilatation relies on an increase in endothelial cell cytosolic free [Ca2+] and activation of Ca2+-activated K+ channels (KCa). The time course of average and spatially organized rises in endothelial cell [Ca2+]i and concomitant effects on membrane potential were investigated in individual cells of pressurized arteries and isolated sheets of native cells stimulated with ACh. In both cases, ACh stimulated a sustained and oscillating rise in endothelial cell [Ca2+]i. Overall, the oscillations remained asynchronous between cells, yet occasionally localized intercellular coordination became evident. In pressurized arteries, repetitive waves of Ca2+ moved longitudinally across endothelial cells, and depended on Ca2+-store refilling. The rise in endothelial cell Ca2+ was associated with sustained hyperpolarization of endothelial cells in both preparations. This hyperpolarization was also evident when recording from smooth muscle cells in pressurized arteries, and from resting membrane potential, selective inhibition of small-conductance K Ca (SK Ca) with apamin (50 nM) was sufficient to inhibit this response. In the presence of phenylephrine-tone, both apamin and the selective inhibitor of intermediate conductance K Ca (IK Ca) TRAM-34 (1 microM) were required to inhibit the non-nitric oxide-mediated dilatation to ACh. When hyperpolarization of endothelial cells was fully prevented either with inhibitors of K Ca or in KCl (35 mM)-depolarized cells, both the time course and frequency of oscillations in endothelial cell [Ca2+]i to ACh were unaffected. Together, these data show that although a rise in endothelial cell [Ca2+]i stimulates hyperpolarization, depletion of intracellular stores with ACh stimulates Ca2+-influx which is not significantly influenced by the increase in cellular electrochemical gradient for Ca2+ caused by that hyperpolarization.