Carbachol partially inhibits the plasma-membrane Ca2+-pump in microsomes from pig stomach smooth muscle

A plasmalemmal enriched membrane fraction, prepared from pig stomach smooth-muscle, contains a calmodulin-stimulated (Ca2+ + Mg2+)-ATPase and presents an ATP-dependent 45Ca-uptake. If these smooth-muscle strips are preincubated with 10(-3) M-carbachol, this Ca2+ + Mg2+)-ATPase and the 45Ca-uptake are reduced by 21.4% and 13.5%, respectively, as compared to controls. This inhibitory effect of carbachol can be completely blocked by atropine. Carbachol does neither affect the passive permeability of the microsomes to 45Ca, nor the passive 45Ca-binding to the vesicles. Neither does it exert an effect on the proportion of closed inside-out plasma-membrane vesicles. Likewise, preincubation of rat myometrium with 90 nM-oxytocin induces a 20.4% inhibition of the ATP-dependent 45Ca-uptake, without having an effect on the passive 45Ca-binding, the permeability to 45Ca or the sideness of the vesicles. From these results, it is concluded that some agonists as carbachol and oxytocin induce a decrease in the activity of the plasmalemmal Ca2+-pump.     

Calcium loading properties of carbachol-sensitive calcium store in calcium-depleted stomach smooth muscle of the newt

The amount of carbachol (CCh)-sensitive Ca store, which was loaded during Ca contracture in Ca-depleted stomach smooth muscle of the newt, was estimated from the amplitude of the CCh contracture induced in Ca-free high K solution. This store was loaded to nearly maximum level by simultaneous application of 2.8 X 10(-6)M Ca and 113.5 mM K, while Ca contracture induced at this time was less than 10% in amplitude of control (1.8 mM Ca). When the loading was interrupted after 5 sec of 1.8 mM Ca application, the amplitude of Ca contracture reached nearly its maximum, while the loading of the store was only about 30% of that after 90 sec. Contracture induced by Ca-free high K solution immediately after the brief (10 sec) exposure of the muscle to 1.8 mM Ca was about 50% that of K contracture, while little Ca was observed to be loaded. The [K]0-Ca contracture tension relation and the [K]0-Ca loading relation showed sigmoid and linear characteristics, respectively.     

The effects of EGTA on vascular smooth muscle contractility in calcium-free medium

The effect of EGTA, commonly present in Ca2+-free physiological saline solution, on the contractile responses induced by Ca2+ and phenylephrine was studied in dog mesenteric arteries and aortas of rats and rabbits. EGTA substantially enhanced the contractile responses of these vascular strips or rings to added Ca2+ after a prolonged preincubation period in the Ca2+-free medium. The maximal level of the enhanced contractile responses was independent of EGTA concentration, but the rate of the maximal responses was faster at higher EGTA concentration, presumably as a result of faster removal of intracellular Ca2+. Such a Ca2+-induced response was sensitive to the Ca2+ antagonist, nifedipine. EGTA present at low concentrations (50 and 400 microM) in Ca2+-free medium also inhibited the phenylephrine-induced contractile response more prominently for the longer preincubation periods of the vascular tissues in Ca2+-free medium. Our results suggest that EGTA, even when added at low concentrations to the vascular smooth muscle for a sufficiently long period in Ca2+-free medium, may cause destabilization of the cell membranes leading to increased permeability to subsequently added Ca2+. EGTA may also remove the superficially bound Ca2+ and subsequently reduce the intracellular Ca2+ pool via extraction of the intracellular Ca2+ at the cell membrane surfaces.     

Magnesium ion-dependent contraction of skinned frog muscle fibers in calcium-free solution

Skinned frog fibers were reversibly activated in Ca-free solutions containing 0 mM KCl, 23 microM free Mg, and having an ionic strength of approximately 50 mM. Contractile force was nearly maximal at 22 degrees - 25 degrees C and decreased at lower temperatures. Maximal force in Ca-free solution at 50 mM ionic strength was close to twice the calcium-activated force with pCa 5 and 190 mM ionic strength. The force in Ca-free solution could be reduced to zero by raising the concentration of free Mg from 23 microM to 1.0 mM at the same ionic strength (50 mM). On stretching the fiber from 2.0 to 3.2 micron the force decreased; this effect was similar to that seen with Ca-activated fiber and the data support the idea that Ca-free tension is made at the cross-bridge level. Isotonic contraction during Ca-free activation showed a velocity transient as in Ca-activated fiber at 190 mM ionic strength, but the transient in the present case was very much prolonged. This finding suggests that contraction mechanisms for force generation and for shortening are essentially the same in the two conditions, but that certain rate constants of cross-bridge turnover are slower for the Ca-free contraction. Also, the results indicate that, in low ionic strength, Ca binding to thin filaments is not essential for unmasking the cross-bridge attachment sites, which suggests that the steric blocking mechanism is modified under these conditions.     

Sodium flux in the smooth muscle of frog stomach

Sodium efflux from rings of frog stomach muscle was measured at 5° and 15°C in three different steady states. After incubation in normal, K-free, or ouabain (10^-4 M) solutions, intracellular cations stabilized at markedly differing levels. At 5°C, inhibition of Na extrusion was shown in the rate coefficients for ²²Na efflux, which were slightly smaller in K-free than in normal solutions, and much smaller in ouabain. Due to the intracellular Na concentration differences, total Na efflux was similar in K-free and ouabain solutions, and only ⅕ as large in normal solution. At 15°C, normal total Na flux was only 1/7;–1/10 inhibitors, and may be underestimated. The total flux differences may involve dependence of the Na pump and Na permeation on internal Na concentration. The Q ₁₀ of the steady-state fluxes was 3.7 in ouabain, 2.8 in K-free solution, and 1.9 in normal solution. The high temperature dependence of influx as well as efflux suggests transport mechanisms other than simple diffusion. Sodium turnover in the cell water was 46–66 mM/hr in inhibitors at 15°C, and a high rate of Na extrusion in normal muscle is suggested. However, cell volume:surface ratio is only 1.6 µ and all estimates of Na flux were under 3 pmoles/cm² per sec, indicating low Na permeability.     

Cation regulation in the smooth muscle of frog stomach

Cation composition of frog smooth muscle cells was investigated. Fresh stomach muscle rings resembled skeletal muscle, but marked Na gain and K loss followed immersion. Mean Na (49.8–79.7 mM/kg tissue) and K (61.8–80.1 mM/kg tissue) varied between batches, but were stable for long periods in vitro. Exchange of 6–30 mM Na/kg tissue with ²²Na was extremely slow and distinct. Extracellular water was estimated from sucrose-¹⁴C uptake. Calculated exchangeable intracellular Na was 9 mM/kg cell water, and varied little. Thus steady-state transmembrane cation gradients appeared to be steep. K-free solution had only slight effects. Ouabain (10^-4 M) caused marked Na gain and reciprocal K loss; at 30°C, Na and K varied linearly with time over a wide range of contents, indicating constant net fluxes. Net fluxes decreased with temperature decrease. ²²Na exchange in ouabain-treated tissue at 20–30°C was rapid and difficult to analyze. The best minimum estimates of unidirectional Na fluxes at 30°C were 10–12 times the constant net flux; constant pump efflux may explain these findings. The rapidity of Na exchange may not reflect very high permeability, but it does require a high rate of transport work.     

Depolarization of electroplax membrane in calcium-free ringer's solution

Summary Electrical stimulation, either cathodal or anodal, of the monocellular electroplax preparation in Ca-free Ringer's solution results in a sustained depolarization which is determined by the amount of current passed through the cell. The membrane potential recovers only when Ca is added again. These changes take place at the innervated side of the electroplax only. This depolarization of the membrane is pH-dependent; it depolarizes more at pH 6.0 than at pH 9.0. The membrane does not depolarize and the action potential is not blocked within an hour in Ca-free solution unless the cell is stimulated. The sustained depolarization is not prevented or reversed by curare, tetracaine, physostigmine, tetrodotoxin, and tetraethylammonium.After stimulation, the outward K current remains unchanged regardless of whether Ca is present. In contrast, the inward current is dependent on Ca in the outside solution on the innervated membrane; in the absence of Ca following stimulation, the inward K current is decreased.The depolarization by carbamylcholine is reduced in Ca-free and increased in Mgfree Ringer's solution. In contrast to the depolarization induced by electrical stimulation, these carbamylcholine depolarizations may be reversed by washing with Ca-free or Ca- and Mg-free Ringer's solution.     

Molecular dynamics simulations of calcium-free calmodulin in solution

A 4-ns molecular dynamics simulation of calcium-free calmodulin in solution has been performed, using Ewald summation to treat electrostatic interactions. Our simulation results were mostly consistent with solution experimental studies, including NMR, fluorescence and x-ray scattering. The secondary structures within the N- and C-terminal domains were conserved in the simulation, with trajectory structures similar to the NMR-derived model structure 1CFD. However, the relative orientations of the domains, for which there are no NMR restraints, differed in details between the simulation and the 1CFD model. The most interesting information provided by the simulations is that the dynamics of calcium-free calmodulin in solution is dominated by slow rigid body reorientations of the domains. The interdomain distance fluctuated between 29 and 39 A, and interdomain orientation angle, defined as the pseudo-dihedral formed by the four calcium binding sites, varied between -2 degrees and 108 degrees. Similarly, the domain linker region also exhibited significant fluctuations, with its length varying in the 34-45 A range and its bend angle in the 10-100 degrees range. The simulations are in accord with fluorescence results suggesting that calcium-free calmodulin is more compact and more flexible than the calcium activated form. Surprisingly, quite similar solvent accessibilities of the hydrophobic patches were seen in the calcium-free trajectory described in this work and previously generated calcium-loaded calmodulin simulations. Thus, our simulations suggest a reexamination of the standard model of the structural change of calmodulin upon calcium binding, involving exposure of the hydrophobic patches to solvent.     

Human smooth muscle cell cultures of the stomach morphologic and biochemical studies

Summary Smooth muscle cell cultures were prepared from stomach explants obtained surgically from 10 patients with duodenal ulcer. The cultured cells grew in either overlapping layers in “hills and valleys” or in parallel arrays. The ultrastructure studies showed plasmalemmal vesicles, bundles of myofilaments associated with dense bodies, and gap junctions. The synthesis of contractile proteins illustrated the preponderance of actin on myosin and tropomyosin. The synthesis of contractile proteins in stomach smooth muscle cell cultures is significantly higher than in skin fibroblast cultures, i.e. 20 x higher for myosin, 10 x higher for actin, and 30 x higher for tropomyosin.     

Modulation of smooth muscle activity by excitatory and inhibitory nerves in the guinea-pig stomach

• 1.1. In smooth muscle of the guinea-pig stomach, intramural nerve stimulation evoked cholinergic excitatory junction potential in the fundus and non-adrenergic non-cholinergic inhibitory junction potential in the antrum, yet cholinergic contractions in both regions.
• 2.2. This dissociation between electrical and mechanical responses was mainly due to different sensitivity of the membrane for depolarization to acetylcholine.

     

Force: velocity relationship in single isolated toad stomach smooth muscle cells

The relationship between force and shortening velocity (F:V) in muscle is believed to reflect both the mechanics of the myosin cross-bridge and the kinetics of its interaction with actin. To date, the F:V for smooth muscle cells has been inferred from F:V data obtained in multicellular tissue preparations. Therefore, to determine F:V in an intact single smooth muscle cell, cells were isolated from the toad (Bufo marinus) stomach muscularis and attached to a force transducer and length displacement device. Cells were electrically stimulated at 20 degrees C and generated 143 mN/mm2 of active force per muscle cross-sectional area. At the peak of contraction, cells were subjected to sudden changes in force (dF = 0.10-0.90 Fmax) and then maintained at the new force level. The force change resulted in a length response in which the cell length (Lcell) rapidly decreased during the force step and then decreased monotonically with a time constant between 75 and 600 ms. The initial length change that coincided with the force step was analyzed and an active cellular compliance of 1.9% cell length was estimated. The maintained force and resultant shortening velocity (V) were fitted to the Hill hyperbola with constants a/Fmax of 0.268 and b of 0.163 Lcell/s. Vmax was also determined by a procedure in which the cell length was slackened and the time of unloaded shortening was recorded (slack test). From the slack test, Vmax was estimated as 0.583 Lcell/s, in agreement with the F:V data. The F:V data were analyzed within the framework of the Huxley model (Huxley. 1957. Progress in Biophysics and Biophysical Chemistry. 7:255-318) for contraction and interpreted to indicate that in smooth muscle, as compared with fast striated muscle, there may exist a greater percentage of attached force-generating cross-bridges.     

Isolation and characterization of subcellular membranes from canine stomach smooth muscle

Subcellular membrane fractions were isolated from the circular muscle of the corpus of canine stomach by differential and isopycnic sucrose density gradient centrifugation. Differential centrifugation gave a mitochondrial fraction enriched (fourfold) in cytochrome c oxidase and a microsomal fraction enriched (fourfold) in 5'-nucleotidase and NADPH-cytochrome c reductase over postnuclear supernatant. On the basis of a study using continuous gradient, a discontinuous sucrose density gradient was prepared to yield F1 to F5 fractions. The F3 fraction at the interface of 18-32% (w/w) sucrose was maximally enriched (13-fold) in 5'-nucleotidase. The fraction contained very low levels of cytochrome c oxidase but did contain NADPH-cytochrome c reductase (eightfold enrichment). The F4 fraction, at the interface of 32-40% (w/w) sucrose, was maximally enriched in NADPH-cytochrome c reductase (12-fold) and cytochrome c oxidase (6-fold). The distribution of the azide-insensitive. ATP-dependent Ca2+ uptake correlated very well with that of 5'-nucleotidase but less well with NADPH-cytochrome c reductase and not at all with cytochrome c oxidase. Sodium azide and ruthenium red inhibited the ATP-dependent Ca2+ uptake by the mitochondrial fraction and postnuclear supernatant, but not by the F3 fraction. ATP-dependent Ca2+ uptake by the F3 fraction was inhibited by calcium ionophores A23187 and ionomycin, but not by the sodium ionophore, monensin. These results are consistent with the hypothesis that the plasma membrane plays a major role ih regulating intracellular Ca2+ concentration in canine corpus circular muscle.     

Electron cytochemistry of oxalate-stimulated calcium uptake in microsomes from the smooth muscle of the pig stomach

Summary A microsomal fraction was isolated from the smooth muscle of the antrum of the pig stomach by differential centrifugation. Electron microscopy of the negatively stained material showed that this fraction is heterogeneous in composition. The microsomes accumulated calcium in the presence of ATP, magnesium and oxalate. The amount of calcium taken up per mg protein was in the same range as observed for other smooth muscle microsomal preparations. Although this amount is much smaller than that in the microsomal fraction of skeletal muscle, calcium oxalate crystals were formed in some vesicles, as occurs in the skeletal muscle fragmented sarcoplasmic reticulum. Through the presence of the calcium oxalate crystals, many of these vesicles acquired sufficient mass and density to allow them to be isolated by centrifugation. A purification of about 40 fold in terms of calcium content was reached.     

Demarcation of Ca2+ transport processes in guinea pig stomach smooth muscle

Summary Microsomal fractions were isolated from gastric antrum and fundus smooth muscle of guinea pigs. Ca²⁺ uptake into and Ca²⁺ release from the membrane vesicles were studied by a rapid filtration method, and Ca²⁺ transport properties of the different regions of the stomach were compared. ATP-dependent Ca²⁺ uptake was similar in microsomes isolated from both regions. This uptake was increased by oxalate and was not affected by NaN₃. Oxalate affected Ca²⁺ permeability of both antrum and fundus microsome vesicles similarly. Fundus microsome vesicles preincubated in 100mm NaCl and then diluted to 1/20 concentration with Na⁺-free medium had significantly higher ATP-independent Ca²⁺ uptake than vesicles preincubated in 100mm KCl and treated the same way. This was not true for antrum vesicles. Monensin abolished Na⁺-dependent Ca²⁺ uptake, and NaCl enhanced Ca²⁺ efflux from fundus microsome vesicles. The halflife values of Ca²⁺ loss from fundus vesicles in the presence of NaCl were significantly smaller than those in the presence of KCl. The release of Ca²⁺ from the vesicles within the first 3 min was accelerated by NaCl to three times that by KCl. However, NaCl had ro effect on Ca²⁺ release from antrum microsome vesicles.Results suggest two distinct mechanisms of stomach membrane Ca²⁺ transport: (1) ATP-dependent Ca²⁺ uptake and (2) Na⁺–Ca²⁺ exchange; the latter in the fundus only.