Isolation and properties of plasma membrane from smooth muscle

A generalized approach to obtain relatively pure fractions of plasma membrane from smooth muscle tissues for studying calcium transport is described. The use of various markers for cellular membranes to establish the purity of various fractions is critically considered. Plasma membranes from rat myometrium have been isolated in a purity estimated to be 95-99%. Plasma membrane purifications to 70-80% have been achieved from rat mesenteric arteries and veins, canine tracheal smooth muscle, rabbit intestinal muscle, rat vas deferens, rat fundus, and dog gastric corpus. The ATP-dependent transport of Ca is correlated with the distribution of plasma membrane markers. Ca gradient of greater than 1000-fold have been achieved. ATP-dependent active Ca transport by plasma membranes could sometimes be stimulated by oxalate or phosphate. Anion activation of Ca active transport is not a marker for endoplasmic reticulum. In some smooth muscles (e.g., rat vas deferens) ATP-dependent Ca uptake did not correlate exclusively with the distribution of plasma membrane markers. Instead, the correlation seemed to be with NADPH-cytochrome reductase EC 1.6.2.5 activity (putative endoplasmic reticulum marker) as well as with plasma membrane markers. In all smooth muscles, active Ca transport appears to be a property of the plasma membrane; in some it may also be a property of the endoplasmic reticulum. Mitochondria actively transport Ca, but in most systems studied to date, the Km for Ca2+ for this transport is higher than that for plasma membrane. Thus the plasma membrane may be the major physiological mechanism of active transport for Ca out of cytoplasm of smooth muscle cells. In two plasma membrane fractions (from rat myometrium and mesenteric arteries) it has been possible to demonstrate the existence of an Na-Ca exchange system. Its contribution to lowering cytoplasmic Ca is unknown.     

Identification and characterization of "basal" Ca2+-independent Mg2+-dependent ATP-hydrolase enzymatic activity in smooth muscle cell plasma membrane fractions

It is shown, that for correct definition of "basal" Ca(2+)-independent Mg(2+)-dependent ATPase ac-activity (10-13 mmol Pi/hour on 1 mg of protein) in a fraction of uterus smooth muscle cell plasma membranes is necessary to use in medium without calcium of an incubation not only EGTA and digitonin--of the factor of infringement in activity by this subcellular structure, but inhibitors of others Mg(2+)-dependent ATP-hydrolyse enzymatic systems localized as in plasma membrane (Na+, K(+)-ATPase) and in others subcellular frames, first of all, in mitochondria (Mg(2+)-ATPase) and endoplasmic reticulum (transport Ca2+, Mg(2+)-ATPase). In the case of a sacolemal fraction of a smooth muscle the contribution of others Mg(2+)-dependent ATP-hydrolyse systems in a common enzymatic hydrolysis ATP, which unconnected to functioning "basal" Ca(2+)-independent Mg(2+)-dependent ATPase, is very appreciable and achieves 35%. The researches, carried out in the frameworks of definition of initial velocity of enzymatic reaction, have enabled to define its some properties--cationic and anionic specificity, and also sensitivity to action of some inhibitors. It has appeared, that the "basal" Ca(2+)-independent Mg(2+)-dependent ATP-hydrolyse reaction is nonspecific rather both in relation to cations of divalent metals Me2+, and cations of monovalent metals and anions, which were utilized for support of ionic strength. The cations La--antagonist of cations Ca--practically did not influence enzymatic activity. The non-specific inhibitors transport of ATPases--p-chloromercuribenzoate, o-vanadate and eosine Y with a various degree of efficiency inhibited "basal" Ca(2+)-independent Mg(2+)-dependent ATP-hydrolyse reaction. On the basis of the analysis of the own and literary data the conclusion is made that "basal" Ca(2+)-independent Mg(2+)-dependent ATPase of a smooth muscle cell plasma membrane is considerably less sensitive to action of nonspecific inhibitors of the Ca(2+)-transporting systems, than these systems.     

The role of cytoplasmic nanospaces in smooth muscle cell Ca2+ signalling

We address the importance of cytoplasmic nanospaces in Ca(2+) transport and signalling in smooth muscle cells and how quantitative modelling can shed significant light on the understanding of signalling mechanisms. Increasingly more convincing evidence supports the view that these nanospaces--nanometre-scale spaces between organellar membranes, hosting cell signalling machinery--are key to Ca(2+) signalling as much as Ca(2+) transporters and Ca(2+) storing organelles. Our research suggests that the origin of certain diseases is to be sought in the disruption of the proper functioning of cytoplasmic nanospaces. We begin with a historical perspective on the study of smooth muscle cell plasma membrane-sarcoplasmic reticulum nanospaces, including experimental evidence of their role in the generation of asynchronous Ca(2+) waves. We then summarize how stochastic modelling approaches have aided and guided our understanding of two basic functional steps leading to healthy smooth muscle cell contraction. We furthermore outline how more sophisticated and realistic quantitative stochastic modelling is now being employed not only to deepen our understanding but also to aid in the hypothesis generation for further experimental investigation.     

Subcellular fractionation of pig stomach smooth muscle. A study of the distribution of the (Ca2+ + Mg2+)-ATPase activity in plasmalemma and endoplasmic reticulum

Isolated membrane vesicles from pig stomach smooth muscle (antral part) were subfractionated by a density gradient procedure modified in order to obtain an efficient extraction of extrinsic proteins. By using this method in combination with digitonin-treatment, an endoplasmic reticulum fraction contaminated with maximally 10 to 20% of plasma membranes was isolated, together with a plasma membrane fraction containing at most 30% endoplasmic reticulum. The endoplasmic reticulum and plasma membrane fractions differed in protein composition, reaction to digitonin, binding of wheat germ agglutinin, activities of marker enzymes and in the characteristics of the Ca2+ uptake. The Ca2+ uptake by the endoplasmic reticulum was much more stimulated by oxalate than the uptake by plasma membranes. Both fractions showed a (Ca2+ + Mg2+)-ATPase activity, but the largest amount of this enzyme was present in the plasma membranes. The study of the phosphorylated intermediates of the (Ca2+ + Mg2+)-ATPase by polyacrylamide gel electrophoresis revealed two phosphoproteins one of 130 kDa and one of 100 kDa (Wuytack, F., Raeymaekers, L., De Schutter, G. and Casteels, R. (1982) Biochim. Biophys. Acta 693, 45-52). The 130 kDa enzyme was predominant in the fraction enriched in plasma membrane whereas the distribution of the 100 kDa polypeptide correlated with the endoplasmic reticulum markers. The 130 kDa ATPase was the main 125I-calmodulin binding protein detected on nitrocellulose blots of proteins separated by gel electrophoresis. The (Ca2+ + Mg2+)-ATPase activity of the plasma membranes was higher than the (Na+ + K+)-ATPase activity, suggesting that the Ca2+ extrusion from these cells depends much more on the activity of the (Ca2+ + Mg2+)-ATPase than on Na+-Ca2+ exchange.     

A sulfated polysaccharide from the sarcoplasmic reticulum of sea cucumber smooth muscle is an endogenous inhibitor of the Ca(2+)-ATPase

Vesicles derived from the endoplasmic reticulum of sea cucumber smooth muscle retain a membrane bound Ca(2+)-ATPase that is able to transport Ca(2+) into the vesicles at the expense of ATP hydrolysis. In contrast with vesicles obtained from rabbit muscles, the activity of the Ca(2+)-dependent ATPase from sea cucumber is dependent on monovalent cations (K(+)>Na(+)>Li(+)). With the addition of highly sulfated polysaccharide to vesicle preparations from rabbit muscle, Ca(2+) uptake decreases sharply and becomes highly sensitive to monovalent cations, as observed with vesicles from sea cucumber muscle. These results led us to investigate the possible occurrence of a highly sulfated polysaccharide on vesicles from the endoplasmic reticulum of sea cucumber smooth muscle, acting as an "endogenous" Ca(2+)-ATPase inhibitor. In fact, vesicles derived from the invertebrate, but not from rabbit muscle, contain a highly sulfated polysaccharide. This compound inhibits Ca(2+) uptake in vesicles obtained from rabbit muscle and the inhibition is antagonized by monovalent cation. In addition, sea cucumber muscles contain high concentrations of another polysaccharide, which surrounds the muscle fibers, and was characterized as a fucosylated chondroitin sulfate. Possibly the occurrence of sulfated polysaccharides in the sea cucumber muscles is related with unique properties of the invertebrate body wall, which can rapidly and reversibly alter its mechanical properties, with change in length by more than 200%.     

Utilization of purified myometrium cell plasma membrane Ca2+, Mg2+-ATPase for comparative estimation of the efficiency of energy-dependent Ca2+-transport inhibitors

With the aim of comparative estimation of efficacy of well-known inhibitors of energy-dependent Ca(2+)-transporting systems their effects were investigated on the activity of purified Ca2+, Mg(2+)-ATPase of the myometrium cell plasma membranes. From the approved inhibitors (eosin Y, o-vanadate, thapsigargin, cyclopiazonic acid, ruthenium red, sodium azide) only eosin Y and o-vanadate are potent inhibitors of myometrium sarcolemma Ca(2+)-pump: the values of Ki equal 0.8 and 4.7 microM, respectively. Thapsigargin and cyclopiazonic acid as well as ruthenium red in concentrations inhibiting, respectively, endo(sarco)plasmic reticulum Ca(2+)-pump and energy-dependent Ca(2+)-transport in mitochondria had no effect on the Ca2+, Mg(2+)-ATPase of the uterus smooth muscle cell plasma membrane. Sodium azide (10 mM) blocking completely Ca(2+)-transport in mitochondria inhibited activity of the plasma membrane Ca(2+)-transporting ATPase by 14%.     

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.     

Invited review: mechanisms of calcium handling in smooth muscles.

The concentration of cytoplasmic Ca(2+) regulates the contractile state of smooth muscle cells and tissues. Elevations in global cytoplasmic Ca(2+) resulting in contraction are accomplished by Ca(2+) entry and release from intracellular stores. Pathways for Ca(2+) entry include dihydropyridine-sensitive and -insensitive Ca(2+) channels and receptor and store-operated nonselective channels permeable to Ca(2+). Intracellular release from the sarcoplasmic reticulum (SR) is accomplished by ryanodine and inositol trisphosphate receptors. The impact of Ca(2+) entry and release on cytoplasmic concentration is modulated by Ca(2+) reuptake into the SR, uptake into mitochondria, and extrusion into the extracellular solution. Highly localized Ca(2+) transients (i.e., sparks and puffs) regulate ionic conductances in the plasma membrane, which can provide feedback to cell excitability and affect Ca(2+) entry. This short review describes the major transport mechanisms and compartments that are utilized for Ca(2+) handling in smooth muscles.     

Membrane crystals of Ca2+-ATPase in sarcoplasmic reticulum of fast and slow skeletal and cardiac muscles

Crystalline arrays of Ca2+ transport ATPase develop in sarcoplasmic reticulum membranes after treatment with Na3VO4 in a calcium-free medium [ Dux , L. and Martonosi , A. (1983) J. Biol. Chem. 258, 2599-2603]. The proportion of vesicles containing Ca2+-ATPase crystals in microsome preparations isolated from rat muscle of different fiber types (semimembranosus, levator ani, extensor digitorum longus, diaphragm, soleus, and heart) correlates well with the Ca2+-ATPase content and Ca2+-modulated ATPase activity. This implies that the concentration of Ca2+-ATPase in sarcoplasmic reticulum membranes of fast and slow skeletal or cardiac muscles differs only slightly, and the low Ca2+ transport activity of 'sarcoplasmic reticulum' preparations isolated from slow-twitch skeletal and cardiac muscles is due to the presence of large amount of non-sarcoplasmic-reticulum membrane elements. This is in accord with the relatively small differences in the density of 8.5-nm intramembranous particles seen by freeze-etch electron microscopy in sarcoplasmic reticulum of red and white muscles. The dimensions of the Ca2+-ATPase crystal lattice are similar in sarcoplasmic reticulum membranes of different fiber types; therefore if structural differences exist between 'isoenzymes' of Ca2+-ATPase, these are not reflected in the crystal-lattice.     

Some properties of transport ATPases in functionally different muscles]

The properties of Ca-transporting system in sarcoplasmic reticulum membranes in fast and slow frog muscles as well as some properties of sarcolemma Na, K-ATPase of the same object were investigated. The rate of Ca2+ uptake, Ca-ATPase activity and Ca/ATP ratio for the reticulum of fast muscle demonstrated higher values than those for the reticulum of slow muscle. The rate of Ca2+ accumulation by the fragments of the rectus reticulum and Ca/ATP ratio were found to decrease under the influence of acetylcholine (0.05-5 mM). The transport system of the sartorius reticulum was found to be less sensitive to acetylcholine. The peak activity of Na, K-ATPase in femoral muscles of the frog occurred at 80 mM NaCl and 60 mM KCl, whereas in the rectus abdominal muscle it equalled 100 mM NaCl and 40 mM KCl. Thus, Na, K-ATPase activity in the slow muscle was predominantly higher than that in the mixed (femoral) muscles. If the sarcolemma preparations of the muscles of both types the inhibitory effect of acetylcholine on Na; K-ATPase was registered. The enzyme of slow muscles exhibited higher sensibility to acetylcholine.     

Shape, size, and distribution of Ca(2+) release units and couplons in skeletal and cardiac muscles.

Excitation contraction (e-c) coupling in skeletal and cardiac muscles involves an interaction between specialized junctional domains of the sarcoplasmic reticulum (SR) and of exterior membranes (either surface membrane or transverse (T) tubules). This interaction occurs at special structures named calcium release units (CRUs). CRUs contain two proteins essential to e-c coupling: dihydropyridine receptors (DHPRs), L-type Ca(2+) channels of exterior membranes; and ryanodine receptors (RyRs), the Ca(2+) release channels of the SR. Special CRUs in cardiac muscle are constituted by SR domains bearing RyRs that are not associated with exterior membranes (the corbular and extended junctional SR or EjSR). Functional groupings of RyRs and DHPRs within calcium release units have been named couplons, and the term is also loosely applied to the EjSR of cardiac muscle. Knowledge of the structure, geometry, and disposition of couplons is essential to understand the mechanism of Ca(2+) release during muscle activation. This paper presents a compilation of quantitative data on couplons in a variety of skeletal and cardiac muscles, which is useful in modeling calcium release events, both macroscopic and microscopic ("sparks").     

Peroxide modification of skeletal muscle sarcoplasmic reticulum in antioxidant deficiency and under the action of ionol. I. Calcium transport into sarcoplasmic reticulum membranes]

It is shown that in case of antioxidant insufficiency (AOI) activation of NADPH- and ascorbate-dependent lipid peroxidation (LPO) in sarcoplasmic reticulum (SR) of skeletal muscles proceeds 1.7 and 4.1 times faster, respectively. Activation of lipid peroxidation in AOI leads to damage of Ca2+ transport processes in SR of skeletal muscles. Under these conditions ATP-dependent accumulation of 45Ca (by 88%) and Ca(2+)-ATPase (by 14%) activity in SR of skeletal muscles falls. In case of AOI a significant disturbance of passive Ca2+ transport in SR of skeletal muscles takes place, being characterized by an increased passive 45Ca output from vesicles due to breakage of the biomembrane permeability as a result of lipid peroxidation of membranes. Treatment of animals with ionol, a synthetic antioxidant, causes a decrease of activated NADPH- and ascorbate-dependent LPO in SR of skeletal muscles and stabilization of Ca2+ transport processes.     

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.     

Dysfunction of calcium handling by smooth muscle in hypertension

Dysfunction of ion handling, including binding and fluxes (passive and active transport) of physiologically important ions such as potassium, sodium, calcium, and magnesium, by vascular smooth muscle cell membranes has repeatedly been reported to be associated with the pathophysiology of hypertension. The specific purpose of this review is to summarize and evaluate the evidence for alterations of calcium ion (Ca2+) handling by vascular smooth muscle in various forms of hypertension in the animal model on the basis that regulation of cytoplasmic Ca2+ concentration is a complex and yet vitally important process for a normal function of vascular smooth muscle and that derangement of such a regulation may result in excessive retention of cytoplasmic Ca2+, contribute toward increase of total peripheral resistance, and ultimately lead to elevation of blood pressure. Emphasis is placed upon the consideration of the usefulness of the subcellular membrane fractionation technique in studies of binding and transport of Ca2+ by vascular and nonvascular smooth muscle membranes from genetic as well as experimental hypertensive rats. The limitations of the interpretation of data using such an approach are also considered. Decreased active transport of Ca2+ across isolated plasma membrane vesicles from large and small arteries occurs in several but not all forms of hypertension. This membrane abnormality also occurs in nonvascular smooth muscles and other tissues or cells not confined to the cardiovascular system in genetic hypertension, but not in experimental hypertension. A hypothesis of general membrane defects in spontaneous hypertension is proposed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Proteins of interstitial cells of Cajal and intestinal smooth muscle, colocalized with caveolin-1

The murine jejunum and lower esophageal sphincter (LES) were examined to determine the locations of various signaling molecules and their colocalization with caveolin-1 and one another. Caveolin-1 was present in punctate sites of the plasma membranes (PM) of all smooth muscles and diffusely in all classes of interstitial cells of Cajal (ICC; identified by c-kit immunoreactivity), ICC-myenteric plexus (MP), ICC-deep muscular plexus (DMP), ICC-serosa (ICC-S), and ICC-intramuscularis (IM). In general, all ICC also contained the L-type Ca(2+) (L-Ca(2+)) channel, the PM Ca(2+) pump, and the Na(+)/Ca(2+) exchanger-1 localized with caveolin-1. ICC in various sites also contained Ca(2+)-sequestering molecules such as calreticulin and calsequestrin. Calreticulin was present also in smooth muscle, frequently in the cytosol, whereas calsequestrin was present in skeletal muscle of the esophagus. Gap junction proteins connexin-43 and -40 were present in circular muscle of jejunum but not in longitudinal muscle or in LES. In some cases, these proteins were associated with ICC-DMP. The large-conductance Ca(2+)-activated K(+) channel was present in smooth muscle and skeletal muscle of esophagus and some ICC but was not colocalized with caveolin-1. These findings suggest that all ICC have several Ca(2+)-handling and -sequestering molecules, although the functions of only the L-Ca(2+) channel are currently known. They also suggest that gap junction proteins are located at sites where ultrastructural gap junctions are know to exist in circular muscle of intestine but not in other smooth muscles. These findings also point to the need to evaluate the function of Ca(2+) sequestration in ICC.     

Vanadyl and vanadate inhibit Ca2+ transport systems of the adipocyte plasma membrane and endoplasmic reticulum

Vanadate and vanadyl have many insulin-mimetic effects on cellular metabolism and also have been shown to alter cellular Ca2+ fluxes. In this report, vanadate and vanadyl, like insulin, are shown to inhibit the plasma membrane (Ca2+ + Mg2+)-ATPase/Ca2+ transport system as well as Ca2+ transport by endoplasmic reticulum from rat adipocytes. Ca2+ transport by the endoplasmic reticulum was inhibited half-maximally (I50) by vanadate and vanadyl at concentrations of 30 and 33 microM, respectively. Inhibition of the plasma membrane Ca2+ transport by vanadate and vanadyl was less sensitive, with I50 values of 144 and 92 microM, respectively. These I50 values for plasma membrane Ca2+ transport were similar when measured under conditions of calmodulin-stimulated and non-calmodulin-stimulated Ca2+ transport. The predominant effect of both ions on the kinetic parameters of Ca2+ transport was a substantial decrease in the Vmax by 43-46% for both transport systems. An increase in intracellular Ca2+ following the inhibition of the (Ca2+ + Mg2+)-ATPase/Ca2+ pump in the plasma membrane and endoplasmic reticulum by these vanadium ions may result, at least in part, in the observed insulin-mimetic alterations in cellular metabolism.     

The dimeric form of Ca2+-ATPase is involved in Ca2+ transport in the sarcoplasmic reticulum

To identify the functional unit of Ca(2+)-ATPase in the sarcoplasmic reticulum, we assessed Ca(2+)-transport activities occurring on sarcoplasmic reticulum membranes with different combinations of active and inactive Ca(2+)-ATPase molecules. We prepared heterodimers, consisting of a native Ca(2+)-ATPase molecule and a Ca(2+)-ATPase molecule inactivated by FITC labelling, by fusing vesicles loaded with each type of Ca(2+)-ATPase. The heterodimers exhibited neither Ca(2+) transport nor ATP hydrolysis, suggesting that Ca(2+) transport by the Ca(2+)-ATPase requires an interaction between functional Ca(2+)-ATPase monomers. This finding implies that the functional unit of the Ca(2+)-ATPase is a dimer.     

The distribution and properties of the Mg2(+)-ATPase in the membranes of functionally different muscles in the hen]

From striated (m. pectoralis and myocardium) and smooth (myometrium) muscle tissues of hen, by means of differential centrifugation with Ca-oxalate loading, membrane preparations were obtained with high activity of Mg(2+)-ATPase, i.e. a marker enzyme of tubular membranes of T-system of skeletal muscles. Some properties (pH and temperature optima) of this enzyme were investigated and compared to those of Ca(2+)-ATPase from membranes of the sarcoplasmic reticulum. It was shown that in all the investigated muscles, Mg(2+)-ATPase is associated with membrane fraction which in its density corresponds to tubular membranes of T-system. Activation of this enzyme is characterized by similar optimal levels of pH (7.2) and temperature (25 degrees C). The activity of Ca(2+)-ATPase in the membranes of the sarcoplasmic reticulum, in contrast to that of Mg(2+)-ATPase, is observed in more narrow bands of pH and temperature, exhibiting tissue specificity. The data obtained, indicating a possibility of chromatographic separation of these enzymes, confirm their biochemical individuality.     

Phosphorylated Ca2+-ATPase stable enough for structural studies

The atomic structure of sarcoplasmic reticulum Ca(2+)-ATPase, in a Ca(2+)-bound conformation, has recently been elucidated (Toyoshima, C., Nakasako, M., Nomura, H. & Ogawa, H. (2000) Nature 405, 647-655). Important steps for further understanding the mechanism of ion pumps will be the atomic structural characterization of different key conformational intermediates of the transport cycle, including phosphorylated intermediates. Following our previous report (Champeil, P., Henao, F., Lacapère, J.-J. & McIntosh, D. B. (2000) J. Biol. Chem. 276, 5795-5803), we show here that it is possible to prepare a phosphorylated form of sarcoplasmic reticulum Ca(2+)-ATPase (labeled with fluorescein isothiocyanate) with a week-long stability both in membranes and in mixed lipid-detergent micelles. We show that this phosphorylated fluorescein isothiocyanate-ATPase can form two-dimensional arrays in membranes, similar to those that were used previously to reconstruct from cryoelectron microscopy images the three-dimensional structure of Ca(2+)-free unphosphorylated ATPase. The results also provide hope that crystals of phosphorylated Ca(2+)-ATPase suitable for x-ray crystallography will be achieved.     

Uncontrolled calcium sparks act as a dystrophic signal for mammalian skeletal muscle

Most excitable cells maintain tight control of intracellular Ca(2+) through coordinated interaction between plasma membrane and endoplasmic or sarcoplasmic reticulum. Quiescent sarcoplasmic reticulum Ca(2+) release machinery is essential for the survival and normal function of skeletal muscle. Here we show that subtle membrane deformations induce Ca(2+) sparks in intact mammalian skeletal muscle. Spontaneous Ca(2+) sparks can be reversibly induced by osmotic shock, and participate in a normal physiological response to exercise. In dystrophic muscle with fragile membrane integrity, stress-induced Ca(2+) sparks are essentially irreversible. Moreover, moderate exercise in mdx muscle alters the Ca(2+) spark response. Thus, membrane-deformation-induced Ca(2+) sparks have an important role in physiological and pathophysiological regulation of Ca(2+) signalling, and uncontrolled Ca(2+) spark activity in connection with chronic activation of store-operated Ca(2+) entry may function as a dystrophic signal in mammalian skeletal muscle.