Aequorin luminescence during activation of single isolated smooth muscle cells

The functional and molecular studies on involvement of hydrogen sulphide in myometrial activity of non-pregnant buffaloes (Bubalus bubalis)

Background

Hydrogen sulphide (H₂S), a member of the gasotransmitters family, is known to play patho-physiological role in different body systems including during pregnancy. But its involvement in myometrial spontaneity and associated signalling pathways in uterus in non-pregnant animals is yet to be studied. Present study describes the effect of L-cysteine, an endogenous H₂S donor, on isolated myometrial strips of non-pregnant buffaloes and the underlying signaling mechanism(s).

Results

L-cysteine (10 nM-30 mM) produced concentration-dependent contractile effect on buffalo myometrium which was extracellular Ca²⁺ and L-type calcium channels-dependent. Significant rightward shift of dose-response curve of L-cysteine was observed with significant decrease in maxima in the presence of amino-oxyacetic acid (AOAA; 100 μM) and d, l-propargylglycine (PAG; 100 μM), the specific blockers of cystathionine β-synthase (CBS) and cystathionine γ-lyase (CSE), respectively. Existence of CBS enzyme of 63 kDa and CSE of 45 kDa molecular weights was confirmed by western blot using specific antibodies and also by immunohistochemistry.

Conclusions

Endogenous H₂S along with its biosynthetic enzymes (CBS and CSE) is evidently present in uteri of non-pregnant buffaloes and it regulates spontaneity in uteri of non-pregnant buffaloes and this effect is dependent on extracellular Ca²⁺ influx through nifedipine-sensitive L-type calcium channels. Thus H₂S-signalling pathway may be a potential target to alter the uterine activities in physiology and patho-physiolgical states.

Reduced RhoA activity mediates acute alcohol intoxication-induced inhibition of lymphatic myogenic constriction despite increased cytosolic [Ca(2+) ]

OBJECTIVES

We previously showed that AAI reduces lymphatic myogenic constriction in response to step increases in luminal pressure. Because of the known role of Ca(2+) in smooth muscle contractile responses, we investigated how alcohol impacts cyclic Ca(2+) and whether changes in RhoA/ROCK-mediated Ca(2+) sensitivity underlie the alcohol-induced reduction of myogenic responsiveness.

METHODS

AAI was produced by intragastric administration of 30% alcohol in rats. Mesenteric lymphatics were cannulated and loaded with Fura-2 AM to [Ca(2+) ]i for 30 minutes after AAI. Active GTP-bound RhoA levels were determined by ELISA. To determine ROCK's ability to restore myogenic responsiveness following AAI, isolated lymphatics were transfected with constitutively active ca-ROCK protein.

RESULTS

Lymphatics from alcohol-treated rats displayed significantly larger Ca(2+) transients. Also, step increases in luminal pressure caused a gradual rise in the basal [Ca(2+) ]i between transients that was greater in lymphatics submitted to AAI, compared to vehicle control. RhoA-GTP was significantly reduced in lymphatics from the AAI group, compared to vehicle control. Transfection with ca-ROCK protein restored the myogenic response of lymphatic vessels isolated from AAI animals.

CONCLUSIONS

The data strongly suggest that the alcohol-induced inhibition of mesenteric lymphatic myogenic constriction is mediated by reduced RhoA/ROCK-mediated Ca(2+) sensitivity.

A three-dimensional chemo-mechanical continuum model for smooth muscle contraction

Based on two fields, namely the placement and the calcium concentration, a chemo-mechanically coupled three-dimensional model, describing the contractile behaviour of smooth muscles, is presented by means of a strain energy function. The strain energy function (Schmitz and Böl, 2011) is additively decomposed into a passive part, relating to elastin and collagen, and an active calcium-driven part related to the chemical contraction of the smooth muscle cells. For the description of the calcium phase the four state cross-bridge model of Hai and Murphy (Hai and Murphy, 1988) has been implemented into the finite element method. Beside three-dimensional illustrative boundary-value problems demonstrating the features of the presented modelling concept, simulations on an idealised artery document the applicability of the model to more realistic geometries.

Measurement of cytosolic Ca2+ in isolated contractile lymphatics

Lymphatic vessels comprise a multifunctional transport system that maintains fluid homeostasis, delivers lipids to the central circulation, and acts as a surveillance system for potentially harmful antigens, optimizing mucosal immunity and adaptive immune responses. Lymph is formed from interstitial fluid that enters blind-ended initial lymphatics, and then is transported against a pressure gradient in larger collecting lymphatics. Each collecting lymphatic is made up of a series of segments called lymphangions, separated by bicuspid valves that prevent backflow. Each lymphangion possesses a contractile cycle that propels lymph against a pressure gradient toward the central circulation. This phasic contractile pattern is analogous to the cardiac cycle, with systolic and diastolic phases, and with a lower contraction frequency. In addition, lymphatic smooth muscle generates tone and displays myogenic constriction and dilation in response to increases and decreases in luminal pressure, respectively. A hybrid of molecular mechanisms that support both the phasic and tonic contractility of lymphatics are thus proposed. Contraction of smooth muscle is generally regulated by the cytosolic Ca(2+) concentration ([Ca(2+)](i)) plus sensitivity to Ca(2+) of the contractile elements in response to changes in the environment surrounding the cell. [Ca(2+)](i) is determined by the combination of the movement of Ca(2+) through plasma membrane ligand or voltage gated Ca(2+) channels and the release and uptake of Ca(2+) from internal stores. Cytosolic Ca(2+) binds to calmodulin and activates enzymes such as myosin light chain (MLC) kinase (MLCK), which in turn phosphorylates MLC leading to actin-myosin-mediated contraction. However, the sensitivity of this pathway to Ca(2+) can be regulated by the MLC phosphatase (MLCP). MLCP activity is regulated by Rho kinase (ROCK) and the myosin phosphatase inhibitor protein CPI-17. Here, we present a method to evaluate changes in [Ca(2+)](i) over time in isolated, perfused lymphatics in order to study Ca(2+)-dependent and Ca(2+)-sensitizing mechanisms of lymphatic smooth muscle contraction. Using isolated rat mesenteric collecting lymphatics we studied stretch-induced changes in [Ca(2+)](i) and contractile activity. The isolated lymphatic model offers the advantage that pressure, flow, and the chemical composition of the bath solution can be tightly controlled. [Ca(2+)](i) was determined by loading lymphatics with the ratiometric, Ca(2+)-binding dye Fura-2. These studies will provide a new approach to the broader problem of studying the different molecular mechanisms that regulate phasic contractions versus tonic constriction in lymphatic smooth muscle.

Regulation of smooth muscle calcium sensitivity: KCl as a calcium-sensitizing stimulus

KCl has long been used as a convenient stimulus to bypass G protein-coupled receptors (GPCR) and activate smooth muscle by a highly reproducible and relatively “simple” mechanism involving activation of voltage-operated Ca2+channels that leads to increases in cytosolic free Ca2+([Ca2+]i), Ca2+-calmodulin-dependent myosin light chain (MLC) kinase activation, MLC phosphorylation and contraction. This KCl-induced stimulus-response coupling mechanism is a standard tool-set used in comparative studies to explore more complex mechanisms generated by activation of GPCRs. One area where this approach has been especially productive is in studies designed to understand Ca2+sensitization, the relationship between [Ca2+]iand force produced by GPCR agonists. Studies done in the late 1980s demonstrated that a unique relationship between stimulus-induced [Ca2+]iand force does not exist: for a given increase in [Ca2+]i, GPCR activation can produce greater force than KCl, and relaxant agents can produce the opposite effect to cause Ca2+desensitization. Such changes in Ca2+sensitivity are now known to involve multiple cell signaling strategies, including translocation of proteins from cytosol to plasma membrane, and activation of enzymes, including RhoA kinase and protein kinase C. However, recent studies show that KCl can also cause Ca2+sensitization involving translocation and activation of RhoA kinase. Rather than complicating the Ca2+sensitivity story, this surprising finding is already providing novel insights into mechanisms regulating Ca2+sensitivity of smooth muscle contraction. KCl as a “simple” stimulus promises to remain a standard tool for smooth muscle cell physiologists, whose focus is to understand mechanisms regulating Ca2+sensitivity.

A new view of K+ -induced contraction in rat aorta: the role of Ca2+ binding

Strong, K+ -induced contractions of rat aorta in Ca-free, Mg-free media were not accompanied by increased intracellular calcium concentration, [Ca2+](i), whereas such contractions in the presence of the divalent cations were correlated with rising [Ca2+](i) as assessed by fura-2. At the same time, calcium channel blockers, a modulator of Ca2+-binding proteins, and a modulator of actin polymerization, inhibited all types of K+ -induced contractions. Increasing the K+ in isotonic medium evoked a rise of (45)Ca2+ binding to the plasma membrane of freshly isolated aortic cells. Although Ca2+ -dependent events underlie the mechanism of K+ -induced vascular contractions in both the presence and absence of Ca2+, in contrast to the view that [Ca2+](i) is a key regulator of excitation-contraction coupling in smooth muscle, we suggest that the modulation of Mg2+ -dependent Ca2+ binding, probably within/at the L-type calcium channel by K+, is a trigger for aortic contraction. This Ca2+ binding may then activate actin-myosin interaction.

Ca2+-dependent actin remodeling in the contracting A7r5 cell

Previous work has shown that stimulation of contraction in A7r5 smooth muscle cells with phorbol ester (PDBu) results in the disassembly and remodeling of the alpha-actin component of the cytoskeleton (Fultz et al., 2000, J Mus Res Cell Motil 21: 775-781). In the present study, we evaluated the effect of increasing intracellular calcium ion concentration [Ca2+]i by A23187 and thapsigargin on alpha- and beta-actin remodeling. The effects of A23187 and thapsigargin on cell contraction and actin remodeling were effectively identical. The two compounds caused contraction of A7r5 cells that was earlier in onset and more quickly completed than PDBu-induced contractions. Both the alpha- and beta-actin isoforms were incorporated into stress cables in the resting cell. During the interval of contraction, beta-actin cables shortened without evidence of disassembly. By comparison, the increase of [Ca2+]i resulted in partial or complete dissolution of alpha-actin cables without further remodeling. In addition, PDBu-mediated alpha-actin remodeling was blocked in the presence of A23187. Increased [Ca2+]i also caused dispersal of alpha-actinin but had no effect on the cellular distribution of talin suggesting the effect was selective for alpha-actin cytoskeletal structure. The incubation of cells in calcium-free media prevented alpha-actin dissolution by A23187/thapsigargin and also blocked PDBu-mediated remodeling. Finally, of six kinase inhibitors investigated, only ML-7 partially blocked the dissolution of alpha-actin cables by increased [Ca2+]i. The results suggest that the sustained elevation of [Ca2+]i beyond a threshold level initiates depolymerization of alpha-actin but not beta-actin. It further appears that PDBu-induced alpha-actin remodeling requires Ca2+ but increases of [Ca2+]i beyond a threshold level may inhibit this activity. The finding that ML-7 partially inhibits alpha-actin dissolution in the presence of A23187/thapsigargin may be suggesting that myosin light chain kinase (MLCK) plays a role in destabilizing alpha-actin structure in the activated cell.

Pharmacomechanical coupling: the role of calcium, G-proteins, kinases and phosphatases

The concept of pharmacomechanical coupling, introduced 30 years ago to account for physiological mechanisms that can regulate contraction of smooth muscle independently of the membrane potential, has since been transformed from a definition into what we now recognize as a complex of well-defined, molecular mechanisms. The release of Ca2+ from the SR by a chemical messenger, InsP3, is well known to be initiated not by depolarization, but by agonist-receptor interaction. Furthermore, this G-protein-coupled phosphatidylinositol cascade, one of many processes covered by the umbrella of pharmacomechanical coupling, is part of complex and general signal transduction mechanisms also operating in many non-muscle cells of diverse organisms. It is also clear that, although the major contractile regulatory mechanism of smooth muscle, phosphorylation/dephosphorylation of MLC20, is [Ca2+]-dependent, the activity of both the kinase and the phosphatase can also be modulated independently of [Ca2+]i. Sensitization to Ca2+ is attributed to inhibition of SMPP-1M, a process most likely dominated by activation of the monomeric GTP-binding protein RhoA that, in turn, activates Rho-kinase that phosphorylates the regulatory subunit of SMPP-1M and inhibits its myosin phosphatase activity. It is likely that the tonic phase of contraction activated by a variety of excitatory agonists is, at least in part, mediated by this Ca(2+)-sensitizing mechanism. Desensitization to Ca2+ can occur either through inhibitory phosphorylation of MLCK by other kinases or autophosphorylation and by activation of SMPP-1M by cyclic nucleotide-activated kinases, probably involving phosphorylation of a phosphatase activator. Based on our current understanding of the complexity of the many cross-talking signal transduction mechanisms that operate in cells, it is likely that, in the future, our current concepts will be refined, additional mechanisms of pharmacomechanical coupling will be recognized, and those contributing to the pathologenesis diseases, such as hypertension and asthma, will be identified.

Calcium transients and the effect of a photolytically released calcium chelator during electrically induced contractions in rabbit rectococcygeus smooth muscle

Intracellular Ca2+ was determined with the fura-2 technique during electrically induced contractions in the rabbit rectococcygeus smooth muscle at 22 degreesC. The muscles were electrically activated to give short, reproducible contractions. Intracellular [Ca2+] increased during activation; the increase in [Ca2+] preceded force development by approximately 2 s. After cessation of stimulation Ca2+ fell, preceding the fall in force by approximately 4 s. The fluorescence properties of fura-2 were determined with time-resolved spectroscopy using synchrotron light at the MAX-storage ring, Lund, Sweden. The fluorescence decay of free fura-2 was best described by two exponential decays (time constants approximately 0.5 and 1.5 ns) at low Ca2+ (pCa 9). At high Ca2+ (pCa 4.5), fluorescence decay became slower and could be fitted by one exponential decay (1.9 ns). Time-resolved anisotropy of free fura-2 was characteristic of free rotational motion (correlation time 0.3 ns). Motion of fura-2 could be markedly inhibited by high concentrations of creatine kinase. Time-resolved spectroscopy measurements of muscle fibers loaded with fura-2 showed that the fluorescence lifetime of the probe was longer, suggesting an influence of the chemical environment. Anisotropy measurements revealed, however, that the probe was mobile in the cells. The Ca2+-dependence of contraction and relaxation was studied using a photolabile calcium chelator, diazo-2, which could be loaded into the muscle cells in a similar manner as fura-2. Photolysis of diazo-2 leads to an increase in its Ca2+-affinity and a fall in free Ca2+. When muscles that had been loaded with diazo-2 were illuminated with UV light flashes during the rising phase of contraction, the rate of contraction became slower, suggesting a close relation between intracellular Ca2+ and the cross-bridge interaction. In contrast, photolysis during relaxation did not influence the rate of force decay, suggesting that relaxation of these contractions is not determined by the rate of Ca2+ removal or due to an increased Ca2+ sensitivity, but instead is limited by other processes such as deactivation by dephosphorylation or detachment of tension-bearing cross-bridges, possibly regulated by thin filament systems.

Physiological features of visceral smooth muscle cells, with special reference to receptors and ion channels

Visceral smooth muscle cells (VSMC) play an essential role, through changes in their contraction-relaxation cycle, in the maintenance of homeostasis in biological systems. The features of these cells differ markedly by tissue and by species; moreover, there are often regional differences within a given tissue. The biophysical features used to investigate ion channels in VSMC have progressed from the original extracellular recording methods (large electrode, single or double sucrose gap methods), to the intracellular (microelectrode) recording method, and then to methods for recording from membrane fractions (patch-clamp, including cell-attached patch-clamp, methods). Remarkable advances are now being made thanks to the application of these more modern biophysical procedures and to the development of techniques in molecular biology. Even so, we still have much to learn about the physiological features of these channels and about their contribution to the activity of both cell and tissue. In this review, we take a detailed look at ion channels in VSMC and at receptor-operated ion channels in particular; we look at their interaction with the contraction-relaxation cycle in individual VSMC and especially at the way in which their activity is related to Ca2+ movements and Ca2+ homeostasis in the cell. In sections II and III, we discuss research findings mainly derived from the use of the microelectrode, although we also introduce work done using the patch-clamp procedure. These sections cover work on the electrical activity of VSMC membranes (sect. II) and on neuromuscular transmission (sect. III). In sections IV and V, we discuss work done, using the patch-clamp procedure, on individual ion channels (Na+, Ca2+, K+, and Cl-; sect. IV) and on various types of receptor-operated ion channels (with or without coupled GTP-binding proteins and voltage dependent and independent; sect. V). In sect. VI, we look at work done on the role of Ca2+ in VSMC using the patch-clamp procedure, biochemical procedures, measurements of Ca2+ transients, and Ca2+ sensitivity of contractile proteins of VSMC. We discuss the way in which Ca2+ mobilization occurs after membrane activation (Ca2+ influx and efflux through the surface membrane, Ca2+ release from and uptake into the sarcoplasmic reticulum, and dynamic changes in Ca2+ within the cytosol). In this article, we make only limited reference to vascular smooth muscle research, since we reviewed the features of ion channels in vascular tissues only recently.

Hypoxia and smooth muscle function: key regulatory events during metabolic stress

Hypoxia rapidly reduces force in many smooth muscles and we review recent data that shed light on the mechanisms involved. As many regulated cellular processes are integrated to co-ordinate smooth muscle contractility, the processes responsible for decreased force output with altered metabolism are also likely to be many, acting in concert, rather than the actions of one altered parameter. Nevertheless the aim of this study is to elucidate the hierarchical series of events that contribute to reduced smooth muscle force production during altered metabolism. We conclude that in many phasic smooth muscles the decrease in force can be attributed to impaired electro-mechanical coupling whereby the Ca2+ transient is reduced. A direct effect of hypoxia on the Ca2+ channel may be of key importance. In tonic vascular smooth muscles KATP channels may also play a role in the integrated functional responses to hypoxia. There are also many examples of force being reduced, in tonically activated preparations, without a fall in steady-state Ca2+; indeed it usually increases. We examine the roles of altered [ATP], pH, myosin phosphorylation, inorganic phosphate and proteolytic activity on the [Ca2+]-force relationship during hypoxia. We find no defining force-inhibitory role for any one factor acting alone, and suggest that force most probably falls as a result of the combination of myriad factors.

Effects of putative modulators of relaxation microinjected into intact amphibian smooth muscle cells

1. Single smooth muscle cells were isolated intact from the stomach of the toad Bufo marinus. The relaxation of cells following cessation of electrical stimulation was compared with those relaxed by pressure microinjection of either metal ion chelators or cyclic nucleotides. 2. Injection of either a Ca2+ chelator or 3',5'-cyclic AMP slowed or halted shortening and promoted re-extension of a cell or collapse of membrane evaginations (blebs) in a manner similar to that following cessation of electrical stimulation. Collapse of blebs occurred first and was then followed smoothly by the next stage with cells re-extending at maximum rates in one of three ranges at 22 degrees C. These rates, in order of increasing speed, were 0.005, 0.009 and 0.03 cell lengths s-1 after electrical stimulation, 3',5'-cyclic AMP and EDTA injection, respectively. On the other hand, shortening began at a maximum rate of about 0.1 cell lengths s-1 unless a Ca2+ chelator or 3',5'-cyclic AMP was injected about 30 s or less before electrical stimulation. Injection of these agents reduced the speed of shortening by about half. 3. Injection of a liquid per se (e.g. 140 mM-KCl) neither altered action potentials nor duplicated the changes produced by the aforementioned relaxing agents. Large, sustained injections of substances that were not relaxing agents (e.g. dilute KCl) ruptured the membrane without producing any bleb collapse or re-extension of a contracted cell. Blebs not only collapsed rapidly when a relaxing agent was injected but bleb collapse was a much more sensitive indication of relaxation than cell re-extension; small injections of relaxing agents could clearly collapse blebs with no associated measurable change in cell length. This supports the idea previously inferred from fixed or permeabilized cells, that filaments in smooth muscle are organized to produce force over short distances at points along the cell membrane, in addition to shortening along the long axis. 4. Physiological relaxation of smooth muscle can evidently be mimicked by 3',5'-cyclic AMP elevation. Restoring forces may develop during shortening of isolated smooth muscle cells in elements of their cytoskeleton, surface membrane, or contractile filaments. However, these putative forces may not be able to produce physiological re-extension in the absence of a rise in cyclic AMP and/or a fall in [Ca2+].

Properties of sympathetic neuromuscular transmission and smooth muscle cell membranes in vascular beds

In vascular smooth muscle tissues, the cycle of contraction-relaxation is mainly regulated by the cytosolic Ca, and many other factors, such as substances released from endothelial cells and perivascular nerve terminals (mainly sympathetic nerves). In this article, we introduce regional differences in specific features of ionic channels in vascular smooth muscle membranes (mainly on features of Ca, Na and K channels) in relation to mobilization of the cytosolic Ca. In many vascular tissues, neurotransmitters released from sympathetic nerve terminals activate post-junctional receptors, and subsequently modify ion channels (receptor-activated cation channel and voltage-dependent Ca channel), whereas in some tissues, ionic channels are not modified by receptor activations (pharmaco-mechanical coupling). However, activation of receptors, with or without modulation of ionic channels, regulates the cytosolic Ca through synthesis of second messengers. In addition, receptors distributed on prejunctional nerve terminals positively or negatively regulate the release of transmitters. Roles of neurotransmitters (mainly ATP and noradrenaline) are also discussed in relation to the generation of excitatory junction potentials.

Calcium transients evoked by electrical stimulation of smooth muscle from guinea-pig ileum recorded by the use of Fura-2

1. Intracellular free calcium levels were recorded in strips of longitudinal smooth muscle from guinea-pig ileum, by the use of the fluorescent calcium indicator Fura-2. 2. The resting intracellular free calcium concentration was estimated to be 210 nM. Many muscle strips showed spontaneous bursts of contractions, accompanied by bursts of calcium transients. Following these the calcium level often fell transiently below the resting level. The spontaneous transients were unaffected by tetrodotoxin (TTX) and atropine. 3. Field electrical stimulation of muscle strips evoked a series of calcium transients comprising: (i) an initial rise in free calcium, reaching a peak within 20-30 ms of stimulation, (ii) a second rise in calcium, beginning after a few hundred milliseconds, and finally (iii) a decline in calcium to below the resting level, persisting for a few seconds. The mean peak increase in free calcium above the resting level during components (i) and (ii) was, respectively, 130 and 200 nM. The mean decrease in free calcium during the third component was to 20 nM below the resting level. 4. The short-latency calcium transient required relatively long stimuli for activation, and was not blocked by TTX and atropine. The long-latency transient was selectively activated by brief stimuli, and was abolished by TTX and atropine. Thus, the short-latency component probably arose because of direct electrical stimulation of muscle fibres, while the long-latency component was due to stimulation of muscarinic nerves. 5. The first detectable increase in tension began about 100 ms after the peak of the initial calcium transient. Contractions associated with the long-latency calcium transient were much larger than those associated with the short-latency transient, even in muscle strips where the calcium levels were similar for both transients. 6. Removal of calcium in the bathing solution caused the resting intracellular calcium level to fall, following an initial rise accompanied by increased spontaneous transients. Electrically evoked contractions and calcium transients were abolished in calcium-free solution, and by the addition of verapamil or diltiazem to normal Krebs solution.

Inositol trisphosphate, calcium and muscle contraction

The identity of organelles storing intracellular calcium and the role of Ins(1,4,5)P3 in muscle have been explored with, respectively, electron probe X-ray microanalysis (EPMA) and laser photolysis of 'caged' compounds. The participation of G-protein(s) in the release of intracellular Ca2+ was determined in saponin-permeabilized smooth muscle. The sarcoplasmic reticulum (SR) is identified as the major source of activator Ca2+ in both smooth and striated muscle; similar (EPMA) studies suggest that the endoplasmic reticulum is the major Ca2+ storage site in non-muscle cells. In none of the cell types did mitochondria play a significant, physiological role in the regulation of cytoplasmic Ca2+. The latency of guinea pig portal vein smooth muscle contraction following photolytic release of phenylephrine, an alpha 1-agonist, is 1.5 +/- 0.26 s at 20 degrees C and 0.6 +/- 0.18 s at 30 degrees C; the latency of contraction after photolytic release of Ins(1,4,5)P3 from caged Ins(1,4,5)P3 is 0.5 +/- 0.12 s at 20 degrees C. The long latency of alpha 1-adrenergic Ca2+ release and its temperature dependence are consistent with a process mediated by G-protein-coupled activation of phosphatidylinositol 4,5 bisphosphate (PtdIns(4,5)P2) hydrolysis. GTP gamma S, a non-hydrolysable analogue of GTP, causes Ca2+ release and contraction in permeabilized smooth muscle. Ins(1,4,5)P3 has an additive effect during the late, but not the early, phase of GTP gamma S action, and GTP gamma S can cause Ca2+ release and contraction of permeabilized smooth muscles refractory to Ins(1,4,5)P3. These results suggest that activation of G protein(s) can release Ca2+ by, at least, two G-protein-regulated mechanisms: one mediated by Ins(1,4,5)P3 and the other Ins(1,4,5)P3-independent. The low Ins(1,4,5)P3 5-phosphatase activity and the slow time-course (seconds) of the contractile response to Ins(1,4,5)P3 released with laser flash photolysis from caged Ins(1,4,5)P3 in frog skeletal muscle suggest that Ins(1,4,5)P3 is unlikely to be the physiological messenger of excitation-contraction coupling of striated muscle. In contrast, in smooth muscle the high Ins(1,4,5)P3-5-phosphatase activity and the rate of force development after photolytic release of Ins(1,4,5)P3 are compatible with a physiological role of Ins(1,4,5)P3 as a messenger of pharmacomechanical coupling.

Insulin-induced myosin light-chain phosphorylation during receptor capping in IM-9 human B-lymphoblasts

We have examined further the interaction between insulin surface receptors and the cytoskeleton of IM-9 human lymphoblasts. Using immunocytochemical techniques, we determined that actin, myosin, calmodulin and myosin light-chain kinase (MLCK) are all accumulated directly underneath insulin-receptor caps. In addition, we have now established that the concentration of intracellular Ca2+ (as measured by fura-2 fluorescence) increases just before insulin-induced receptor capping. Most importantly, we found that the binding of insulin to its receptor induces phosphorylation of myosin light chain in vivo. Furthermore, a number of drugs known to abolish the activation properties of calmodulin, such as trifluoperazine (TFP) or W-7, strongly inhibit insulin-receptor capping and myosin light-chain phosphorylation. These data imply that an actomyosin cytoskeletal contraction, regulated by Ca2+/calmodulin and MLCK, is involved in insulin-receptor capping. Biochemical analysis in vitro has revealed that IM-9 insulin receptors are physically associated with actin and myosin; and most interestingly, the binding of insulin-receptor/cytoskeletal complex significantly enhances the phosphorylation of the 20 kDa myosin light chain. This insulin-induced phosphorylation is inhibited by calmodulin antagonists (e.g. TFP and W-7), suggesting that the phosphorylation is catalysed by MLCK. Together, these results strongly suggest that MLCK-mediated myosin light-chain phosphorylation plays an important role in regulating the membrane-associated actomyosin contraction required for the collection of insulin receptors into caps.

Relationship between force and Ca2+ concentration in smooth muscle as revealed by measurements on single cells

The role of Ca2+ in regulating smooth muscle contraction was investigated by measuring isometric force and [Ca2+] simultaneously in individual single smooth-muscle cells. [Ca2+] was measured with fura-2 and a high time-resolution dual-wavelength digital microfluorimeter, and force was measured with an ultrasensitive force transducer attached to a probe around which was tied one end of the cell. Both [Ca2+] and force increase after maximal electrical stimulus, with [Ca2+] increasing considerably before the first detectable increase in force. Force development exhibited maximal sensitivity to [Ca2+] between 150 and 500 nM Ca2+. This Ca2+ sensitivity can account for the fact that many physiological stimuli produce full contraction even though such stimuli only increase Ca2+ to 600-800 nM. When Ca2+ was induced to increase rapidly, the relation between [Ca2+] and force exhibited hysteresis. During the onset of contraction, force at a given [Ca2+] was lower than during the muscle's return to rest, thus suggesting the existence of a slow step(s) linking Ca2+ and force development in smooth muscle. The direction of this hysteresis reversed during contractions in which Ca2+ increased slowly, suggesting that the contractile process becomes desensitized to [Ca2+] with time. These relations between calcium and force in intact single smooth-muscle cells differ in many respects from the relation found previously in chemically permeabilized multicellular preparations of smooth muscle.

Smooth muscle intracellular pH: measurement, regulation, and function

Smooth muscle performs many functions that are essential for the normal working of the human body. Changes in pH are thought to affect many aspects of smooth muscle. Despite this, until recently little was known about either intracellular pH (pHi) values or pHi regulation in smooth muscle. Recent work measuring pHi with either microelectrodes or nuclear magnetic resonance spectroscopy is now providing some of this much needed information for smooth muscles. From these studies, it can be concluded tentatively that pHi is the same in different smooth muscles, approximately 7.06 (37 degrees C). This value is very close to those obtained in cardiac and skeletal muscle. It is clear that H+ is not in equilibrium across the smooth muscle membrane; i.e., pHi is regulated. Preliminary results in smooth muscle suggest that certain aspects of this regulation are different from that described for other muscle types. Changes in pHi have been found to produce marked effects on contraction in smooth muscle. Of particular interest is the fact that, unlike striated muscles, some smooth muscles can product more force during an intracellular acidification.

Effects of caffeine and tetracaine on outer hair cell shortening suggest intracellular calcium involvement

Outer hair cell (OHC) shortening has previously been induced in vitro by the application of solutions containing high potassium (a depolarizing agent), acetylcholine (a suggested efferent transmitter) and cationized ferritin (a positively charged macromolecule), as well as by electrical current. The application of caffeine, which causes contractures in skeletal and smooth muscle by releasing calcium from intracellular stores to activate actin and myosin interaction, also causes shortening of OHCs. Tetracaine, which interferes with calcium movement in muscle and non-muscle cells, blocks potassium-induced and caffeine-induced shortening of OHCs, but does not block electrically-induced shortening. Sodium dantrolene which is an inhibitor of intracellular calcium release in skeletal muscle does not block potassium-induced OHC shortening. Immunocytochemical studies using antibodies to muscle-like contractile and regulatory proteins on unfixed, freeze-dried OHCs demonstrate the co-localization of calmodulin with actin throughout the OHC cytoplasm. These results support the ideas that in OHCs, intracellular calcium release is involved in the activation of shortening and that an actin-mediated cell shape change may be regulated by calmodulin in a manner similar to that which occurs in contraction of smooth muscle.

Free-calcium and force transients during depolarization and pharmacomechanical coupling in guinea-pig smooth muscle

1. Fura2 was loaded by permeation and hydrolysis of the acetoxymethyl ester into smooth muscle cells of intact thin sheets of the longitudinal layer of the small intestine of the guinea-pig, to record Ca2+ transients during contraction. 2. Cytoplasmic Ca2+ ([Ca2+]i) was monitored by computing the ratio of the fluorescence signal excited at 340 and 380 nm wavelengths. The dye loading and the exposure to UV light required for the experiments had no significant effect on the contractile parameters observed. 3. Spontaneous, rhythmic increases in [Ca2+]i were often observed, preceding the onset of force. Removal of extracellular Ca2+ caused a very transient increase in [Ca2+]i accompanied by a phasic force transient; this was followed by a decline in [Ca2+]i and tension below control levels. Elevated Ca2+ from 1.2 to 15 mM also caused a fall in [Ca2+]i and a relaxation of basal tension. 4. Elevation of [K+]o increased [Ca2+]i. Graded concentrations of K+ caused graded changes in both fluorescence ratio and tension. 5. Carbachol evoked a transient increase in [Ca2+]i and contraction. Thereafter, in spite of the continued presence of the drug, both signals declined, presumably as the result of cholinergic desensitization. The initial phasic force response to carbachol was usually followed by an 'after-contraction', that was only occasionally accompanied by a similar (small) secondary rise in the fluorescence signal. 6. In depolarized smooth muscle, both in the presence and in the absence of extracellular Ca2+, carbachol induced a transient increase in [Ca2+]i, indicating that Ca2+ release from intracellular stores is a major mechanism of pharmacomechanical coupling. 7. In some preparations an applied stretch caused, after a few seconds, a rise in [Ca2+]i and force development.

Re-acceleration of the down-regulated contraction kinetics in the rat tracheal smooth muscle

The contraction kinetics of smooth muscle show a down-regulation after the transient rise found during sustained contraction. We tried to find out therefore if the contraction kinetics of rat tracheal smooth muscle can be re-accelerated during sustained activation. A 2 s length vibration (100 Hz sinusoidal; amplitude = 6% of the muscle length) produces an immediate fall in the force developed by the activated muscle. A biexponential function was fitted to the force recovery. The reciprocal of the time constant, t2, describing the slow component of force recovery, reflects the kinetics of contraction. The contraction kinetics reach their highest levels (t2 = 4.9 +/- 0.1 s,n = 166) about 30 s after the onset of electrical field stimulation. Three experimental groups were activated by either 10 microM serotonin (5-HT), 100 microM acetylcholine (ACh), or by 2 microM ACh for 50 min. Approximately 10 vibrations were applied to each preparation after an 8 min activation in order to observe stabilized down-regulated contraction kinetics. t2 values were calculated from the force recovery after vibration and averaged 11.2 +/- 0.2 s (n = 141), 11.5 +/- 0.2 s (n = 137), and 11.1 +/- 0.3 s (n = 84), respectively. After 50 min of continuous chemical activation, the preparation was stimulated additionally by the neurogenic release of acetylcholine. The t2 of post-vibration force recovery, as measured after 30 s of neural activation, showed no change in the specimens basically activated by 100 microM ACh (11.0 +/- 0.4 s, n = 51).(ABSTRACT TRUNCATED AT 250 WORDS)

Preparation of single smooth muscle cells from guinea pig taenia coli by combinations of purified collagenase and papain

Procedures for isolation of single smooth muscle cells from taenia coli of guinea pigs have been developed. The preparation was performed with a combination of highly purified collagenase prepared by Amano Pharmaceutical Co. (Japan) and papain obtained from Sigma Chemical Co. (Type III). This combination resulted in very high yield of the single cells (39.2 +/- 4.5 X 10(3) cells/mg tissue wet wt) and less cell debris. In the ordinary procedure, commercially available collagenase preparations contaminated with various peptidases have been used. With these enzyme preparations, however, the yield of single cells was dependent on the batch of the preparations, and a large amount of cell debris was contaminated. Combination of the highly purified collagenase and papain resulted in higher yields constantly. Cells, isolated with these enzymes in a medium consisting of 140 mM KCl, 1.0 mM MgCl2, 4.2 mM Hepes, and 5.6 mM glucose (pH 7.4), were spindle shaped. The length of the cells was 185.9 +/- 5.2 micron (n = 90) and the diameter was approximately 12.6 micron. The diameter was not dependent on the cell length. More than 80% of the single cells were viable when examined by trypan blue exclusion technique. Under the depolarized condition, cells remained viable longer because of lower energy consumption, and these cells were contracted by Ca dose dependently. The dose-response relationship was similar to that obtained with intact tissue. Because the cells are constantly available with higher yield, the preparation might be applicable for biochemical research such as ion flux. Details of cell properties under the physiological conditions are under investigation.

A quantitative model of myosin phosphorylation and the photomechanical response of the isolated sphincter pupillae of the frog iris

The time courses of isometrically recorded photomechanical responses of isolated sphincter pupillae of Rana pipiens can be accurately predicted by a set of differential equations derived from phosphorylation theory of smooth muscle contraction. We compared actual light-stimulated contractions with calculated ones over a wide range of stimulus intensities (56-fold) and durations (0.4-4.0 s). The hypothetical Ca++-calmodulin-myosin light chain kinase cascade acts as a "valve" to control the flow of ATP through a phosphorylation-dephosphorylation cycle. When the rate of flow of ATP through the phosphorylation-dephosphorylation cycle is increased, the percentage of phosphorylated myosin increases. The time courses of the concentrations of phosphorylated myosin during different responses are seen to be functions of the time courses of the opening and closing of the coupling cascade "valve." The calculations predict experimentally measurable intermediate variables, which can aid the investigation of the application of quantitative phosphorylation theory to amphibian sphincter pupillae and to smooth muscle in general.

Myosin light chain phosphorylation during phasic contractions of tracheal smooth muscle

Rapid, coordinated contractions of tracheal smooth muscle were elicited by either direct electrical depolarization of muscle cells or treatment with tetraethylammonium which produced spontaneous phasic contractile activity. Both types of contraction were blocked by the calcium channel antagonist verapamil, indicating that these contractions are supported primarily by calcium of extracellular origin. With direct electrical stimulation, force was biphasic and phosphate content of the phosphorylatable light chain (P-light chain) of myosin increased rapidly (approximately 2.5 s) from 0.1 to 0.4 mol phosphate/mol P-light chain, then decreased to levels above resting values. Phosphorylation increased more rapidly than force. Under conditions of spontaneous activity, phasic contractions occurred above a level of basal tone significantly greater than resting force, and minimum values of phosphorylation measured at the base of contraction were significantly greater than those observed in the resting muscle. Phosphorylation oscillated with force (from 0.2 to 0.4 mol phosphate/mol P-light chain) and peak values occurred during the rising phase of contraction. Time courses of phosphorylation and force showed evidence of a prolonged state of activation of myosin following dephosphorylation. These results suggest that phosphorylation and dephosphorylation of myosin P-light chain are sufficiently rapid to participate in regulation of contractility during phasic mechanical activity.

Regional changes in calcium underlying contraction of single smooth muscle cells

The role of calcium in regulating the contractile state of smooth muscle has been investigated by measuring calcium and contraction in single smooth muscle cells with the calcium-sensitive dye fura-2 and the digital imaging microscope. The concentration of free calcium in the cytoplasm increased after stimulation of the cells by depolarization with high potassium or by application of carbachol. Changes in calcium always preceded contraction. The increase in calcium induced by these stimuli was limited to less than 1 microM. Calcium within the nucleus was also subject to a limitation of its rise during contraction. Intranuclear calcium rose from 200 nM at rest to no more than 300 nM while cytoplasmic calcium rose to over 700 nM. These apparent ceilings for both cytoplasmic and intranuclear calcium may result either from negative feedback of calcium on cytoplasmic and nuclear calcium channel gating mechanisms, respectively, or from the presence of calcium pumps that are strongly activated at the calcium ceilings.

The involvement of fast calcium channel activity in the selective activation of phasic contractions by partial depolarization in rat vas deferens smooth muscle

In the prostatic portion of the rat vas deferens, 65% of the preparations studied developed pronounced rapid twitch activity in response to slight depolarization by 15 mM K+ salines. The mechanism underlying this response was studied using treatments designed to inhibit the influence of endogenous transmitters and using recognized calcium antagonist drugs. Although the action of phentolamine was inconclusive, experiments employing guanethidine, reserpine, 6-hydroxydopamine, atropine and alpha,beta-methylene ATP suggest that endogenous transmitter release was not responsible for the observed twitch activity. Twitch activity was strongly dependent upon [Ca]0. The 15 mM K+ twitch activity was inhibited by verapamil (5 X 10(-5) M) but was resistant to 10(-3) M lanthanum. Twitch activity was, however, abolished by 10(-3) M Mn2+ ions and was markedly potentiated by 2 X 10(-3) M TEA. The rapid twitch activity exhibited a strong voltage-dependency, being abolished by [K]0 elevations of 25 mM and above. It is concluded that this phasic activity of the vas deferens smooth muscle may depend upon fast calcium channel activity which, in contrast to voltage-dependent slow calcium channel activity, shows ready voltage-inactivation on substantial depolarization.

Measurement by Quin2 of changes of the intracellular calcium concentration in strips of the rabbit ear artery and of the guinea-pig ileum

Ca2+ transient and force development were investigated in smooth muscle strips of the rabbit ear artery and the longitudinal layer of the guinea-pig ileum by using the fluorescent indicator Quin2. Agonists only transiently increased the fluorescence intensity despite the enhanced contraction while excess potassium resulted in a maintained light signal. In Ca2+ free solutions the release by an agonist of Ca2+ from an intracellular store can be demonstrated. These observations illustrate the usefulness of the Ca2+ indicator Quin2 in the study of the excitation-contraction coupling in smooth muscle under various conditions.

The role of cyclic GMP in cells with the properties of smooth muscle cultured from the rat myometrium

Cells growing in culture with previously described properties of rat uterine smooth muscle accumulated 45Ca2+ from the medium. Ca2+ uptake by these cells was stimulated by the addition to the medium of 8-bromo-cGMP but not by 8-bromo-cAMP. Ca2+ uptake was also stimulated by carbachol and by the nitro-vasodilator nitroprusside. Although cholinergic agonists have been shown previously to stimulate contraction but not cGMP synthesis in the rat myometrium, both carbachol and nitroprusside stimulated cGMP production by the cultured cells. These results suggested the cells had cholinergic receptor-mediated functions that reflected some neurotransmitter-sensitive properties of uterine smooth muscle in situ. When determined by a specific radioligand binding assay, subcellular fractions of the cultured cells bound muscarinic cholinergic agonists and antagonists with affinities expected of the muscarinic receptor. The cells were also sensitive to the beta-adrenergic catecholamine agonist isoproterenol, which stimulated cAMP production but not Ca2+ uptake. Carbachol failed to inhibit isoproterenol-dependent cAMP production, which is an important property of the cholinergic receptor in uterine smooth muscle in situ. These results suggest some but not all acetylcholine-sensitive properties of uterine smooth muscle may be retained in cell culture.

Isolation of smooth muscle cells from swine carotid artery by digestion with papain

A new method is described for the preparation of viable, elongated smooth muscle cells from the swine carotid artery. Cells were prepared by papain digestion of pressurized arteries in calcium-free solution. After digestion, the arteries were everted, and fine strips were teased from the intimal surface of the media in calcium-free solution, releasing single cells. Viability was assessed by exclusion of trypan blue and by appearance under phase-contrast microscopy. By these criteria, approximately 20% of the isolated cells were viable. The most distinguishing and unexpected characteristic of these cells was their length. Mean length of the relaxed viable cells was 240.4 +/- 47.4 microns (SD, n = 76), which is much longer than previously reported for arterial smooth muscle cells. Calcium (1.6 mM) caused most of the viable cells to contract slightly, and the mean cell length in calcium was 194.4 +/- 57.7 microns. Cells in 1.6 mM calcium contracted substantially in response to 10 microM histamine or the calcium ionophore A23187 (10 microM), demonstrating that histamine receptors and the contractile apparatus were still functional.

Recording of intracellular Ca2+ from smooth muscle cells by sub-micron tip, double-barrelled CA2+-selective microelectrodes

Novel, double-barrelled Ca2+-selective microelectrodes with tip diameters of approximately 0.1 micron were constructed by using Simon's neutral Ca2+ ligand (ETH 1001). Concentric micropipettes were utilized for the first time for Ca2+-selective microelectrodes in which the Ca2+ ligand was incorporated into a protruding inner pipette, surrounded by an outer reference electrode. In addition, they were made from high resistance aluminosilicate glass tubing (Corning Code 1724). These Ca2+-selective electrodes had linear responses from pCa 3 to pCa 7 in the presence of constant [K+]. They provided on-line observation of changes in intracellular [Ca2+] and in the resting membrane potential in single smooth muscle cells isolated from toad stomach. The mean concentration of intracellular Ca2+ in resting cells was 163.6 +/- 20 nM (+/- SEM, n = 16). Doubling the intracellular Ca2+ level by exposure of cells to elevated [K+] was sufficient to cause shortening.

Myoplasmic calcium, myosin phosphorylation, and regulation of the crossbridge cycle in swine arterial smooth muscle

Our objective was to test the hypothesis that changes in crossbridge phosphorylation in the swine carotid media are due to changes in the myoplasmic calcium concentration. The photoprotein aequorin was loaded intracellularly by incubation in a series of calcium-free solutions. This loading procedure did not affect subsequent stress development, myosin light chain phosphorylation, or ultrastructure. The time course of light production, myosin light chain phosphorylation, shortening velocity at zero load, and active stress were measured in three stimulus protocols: depolarization with 109 mM potassium chloride at 22 degrees C, 37 degrees C, and 37 degrees C, followed by a reduction in potassium chloride to 20 mM to induce stress maintenance with basal phosphorylation (latch). Light-predicted intracellular calcium concentration was found to correlate with myosin phosphorylation and unloaded shortening velocity. The calcium concentration required for half-maximal myosin phosphorylation was approximately twice that for stress maintenance. These estimates depend on many assumptions, but they compared favorably with the half-maximal myosin phosphorylation values obtained for the calcium-dependence of stress maintenance and phosphorylation in Triton X-100 skinned carotid media preparations. This supports the hypothesis that myoplasmic calcium is the determinant of myosin phosphorylation and mean crossbridge cycling rates in intact smooth muscle depolarized by potassium chloride.

Cytosolic calcium during contraction of isolated mammalian gastric muscle cells

During activation of visceral smooth muscle there is an increase in cytosolic-free calcium, but the source (intracellular calcium release or calcium influx), kinetics, and stoichiometry of this increase have not been determined. Here, the fluorescent indicator, quin2-acetoxymethyl ester, was used to measure directly cytosolic-free calcium during contraction of isolated stomach muscle cells induced by the two neuropeptides cholecystokinin-octapeptide and Met-enkephalin as well as acetylcholine. An increase in cytosolic-free calcium was seen that was (i) dependent on the concentration of contractile agonist, (ii) derived from intracellular sources (that is, not significantly affected by removal of ambient calcium or addition of a calcium channel blocker), and (iii) kinetically and stoichiometrically related to net calcium efflux and contraction. In contrast, the increase in cytosolic-free calcium induced by depolarizing concentrations of potassium was caused by influx of calcium through voltage-dependent calcium channels.

Mobilization of free Ca2+ measured during contraction-relaxation cycles in smooth muscle cells of the porcine coronary artery using quin2

Ca2+ mobilization in dispersed smooth muscle cells of the porcine coronary artery was investigated using the fluorescent Ca2+ indicator, quin2. The resting [Ca2+]i was 113 +/- 8 nM (a mean +/- SE), and was independent of intracellular quin2 concentrations. Acetylcholine (ACh; over 10 nM) or caffeine (over 3 mM) transiently increased the intensity of fluorescence, thereby reflecting the elevation of intracellular free Ca2+ (Ca2+ transient), while excess K+ gradually increased and maintained the intensity of fluorescence. Application of EGTA reduced the resting intensity of the fluorescence and blocked the K+-induced Ca2+ transient, but did not suppress the ACh- or caffeine-induced ones. Nisoldipine (0.1 microM) did not affect the resting intensity of the fluorescence. This agent blocked the K+ induced but not the ACh- or caffeine- induced Ca2+ transient. Thus, sources of Ca2+ contributing to the K+ -induced Ca2+ transient differ from those evoked by other agents. The amount of Ca2+, as estimated from the increased Ca2+ transient by caffeine or ACh, was increased in proportion to the excess K+-induced influx of Ca2+.

Na+/Ca2+ exchange in isolated smooth muscle cells demonstrated by the fluorescent calcium indicator fura-2

Fura-2, a novel fluorescent indicator of cytoplasmic calcium concentrations ([Ca2+i]), was 'loaded' into smooth muscle cells isolated from guinea pig taenia coli. Resting cells maintained a stable [Ca2+i] of 107 +/- 26 nM (n = 13), which could be perturbed with ionomycin. [Ca2+i] was elevated by stimulation of the cells with carbachol or 50 mM KCl. Reduction of the plasmalemmal Na+ concentration gradient by inhibition of the Na+/K+-ATPase with ouabain markedly elevated [Ca2+i]; this elevation was dependent on extracellular Ca2+. [Ca2+i] was also increased by replacement of the extracellular Na+ with an organic cation.

Calcium gradients in single smooth muscle cells revealed by the digital imaging microscope using Fura-2

Calcium is believed to control a variety of cellular processes, often with a high degree of spatial and temporal precision. For a cell to use Ca2+ in this manner, mechanisms must exist for controlling the ion in a localized fashion. We have now gained insight into such mechanisms from studies which measured Ca2+ in single living cells with high resolution using a digital imaging microscope and the highly fluorescent Ca2+-sensitive dye, Fura-2. Levels of Ca2+ in the cytoplasm, nucleus and sarcoplasmic reticulum (SR) are clearly different. Free [Ca2+] in the nucleus and SR was greater than in the cytoplasm and these gradients were abolished by Ca2+ ionophores. When external Ca2+ was raised above normal in the absence of ionophores, free cytoplasmic Ca2+ increased but nuclear Ca2+ did not. Thus, nuclear [Ca2+] appears to be regulated independently of cytoplasmic [Ca2+] by gating mechanisms in the nuclear envelope. The observed regulation of intranuclear Ca2+ in these contractile cells may thus be seen as a way to prevent fluctuation in Ca2+-linked nuclear processes during the rise in cytoplasmic [Ca2+] which triggers contraction. The approach described here offers the opportunity of following changes in Ca2+ in cellular compartments in response to a wide range of stimuli, allowing new insights into the role of local changes in Ca2+ in the regulation of cell function.

Action potentials and net membrane currents of isolated smooth muscle cells (urinary bladder of the guinea-pig)

Cells were isolated by incubating chunks of tissue from the urinary bladder of the guinea-pig in a high potassium, low chloride medium containing 0.2 mM calcium plus the enzymes collagenase and pronase. After isolation, the cells were superfused with a physiological salt solution (PSS) containing 150 mM NaCl, 3.6 mM CaCl2 and 5.4 mM KCl (35 degrees C). Patch electrodes filled with an isotonic KCl-solution were used for whole cell recordings. With a single electrode voltage clamp we measured a capacitance of 50 +/- 5 pF per cell, an input resistance of 200 +/- 25 kOhm X cm2 and a series resistance of 44 +/- 4 Ohm X cm2. The cells had resting potentials of -52 +/- 2 mV. They did not beat spontaneously but responded to stimuli with single action potentials (APs) which rose from the threshold (-38 mV) with a maximal rate of 6.5 +/- 1.8 V/s to an overshoot of 22 +/- 3 mV. The AP lasted for 36 +/- 4 ms (measured between threshold and -40 mV). Continuous cathodal current produced repetitive activity, a pacemaker depolarization followed the AP and preceded the next upstroke. Net membrane currents evoked by clamp steps to positive potentials were composed of an inward and an outward component. The inward component generating the upstroke of the AP was carried by Ca ions (iCa, Klöckner and Isenberg 1985). The repolarization resulted from a potassium outward current iK. Ca-channel blockers (5 mM NiCl2) reduced iK suggesting that (part of) iK was Ca-activated. iK rose within about 100 ms to a peak of 40-200 muA/cm2 from which it inactivated slowly and incompletely. The inactivating iK followed a bell-shaped voltage-dependence, the noninactivating iK an outwardly rectifying one. Both parts had similar steady state inactivation curves with a half maximal inactivation potential at -36 mV and a slope of 9 mV. Repolarization to -50 mV induced outward tail currents which reversed polarity at -85 mV (the calculated potassium equilibrium potential). The amplitude and the time course of the envelope of the tail currents varied in proportion to iK during the prestep. Thus, the tail current is suggested to reflect the turning off of a potassium conductance which had been activated during the prepulse. iK was largely reduced but not blocked by 20 or 150 mM tetraethylammonium (TEA). TEA did not significantly change the resting potential, but it prolonged the AP and facilitated upstroke and overshoot.(ABSTRACT TRUNCATED AT 400 WORDS)

Calcium currents of cesium loaded isolated smooth muscle cells (urinary bladder of the guinea pig)

Single smooth muscle cells isolated from the urinary bladder of the guinea-pig were studied at 35 degrees C in a solution composed of 150 mM NaCl, 3.6 mM CaCl2, 1.2 mM MgCl2, 5.4 mM KCl, 20 mM TEA-Cl, 5 mM glucose, 10 mM HEPES/NaOH (pH 7.4). Whole cells were clamped with a single patch electrode. The clamp settled a step from -65 to -5 mV within 260 microseconds, and afterwards the voltage inhomogeneities were less than 2 mV (measured at the cell edge with a second electrode). The calcium inward current iCa was dissected from net currents by blocking potassium outward currents by means of patch electrodes filled with 130 mM CsCl (Klöckner and Isenberg 1985 a). Pyruvate, succinate and oxalacetate in the patch electrode stabilized iCa and prevented its "run down". 140 ms long clamp steps from -65 to -5 mV evoked a net inward current which could be reversibly blocked by 5 mM NiCl2. The "Ni-sensitive" difference current iCa peaked within 2-4 ms to about 1 nA per cell. Afterwards it completely inactivated; the inactivation could be fitted with three exponentials (time constants of 4, 30, and 250 ms, respectively). The half decay time of 16 ms suggests that most of the inactivation resulted from the fast exponential process. The reference current in the presence of Ni was nearly time independent and almost zero; therefore, iCa could be approximated from the net inward current using the zero current as a reference line.(ABSTRACT TRUNCATED AT 250 WORDS)

Velocity and myosin phosphorylation transients in arterial smooth muscle: effects of agonist diffusion

Transients in myoplasmic [Ca2+] and in phosphorylation of the 20,000 dalton light chain of myosin have been reported following stimulation of vascular smooth muscle by various agonists. Since these transients are rapid compared with the time required to attain a steady-state stress, agonist diffusion rates may be a significant limitation in activation. The purpose of this study was to estimate the effect of agonist diffusion rates on the time course of activation as assessed by mechanical measurements of stress development and isotonic shortening velocities and by determinations of the time course of myosin phosphorylation. The approach was to measure these parameters in K+ -stimulated preparations of the swine carotid media of varying thicknesses and to estimate the theoretical contributions imposed by diffusion rates and the presence of a diffusion boundary layer surrounding the tissue. The results show that the time course of parameters which are tissue averages such as stiffness, active stress, and myosin phosphorylation is dominated by agonist diffusion rates. The sequence of events involved in excitation-contraction coupling including agonist actions on the cell membrane, Ca2+ release, activation of myosin light chain kinase, and cross-bridge phosphorylation appear to be very rapid events compared with stress development. Estimates of unloaded or lightly loaded shortening velocities which are not simple tissue averages appear to provide an improved estimate of activation rates.

Kinetic model for isometric contraction in smooth muscle on the basis of myosin phosphorylation hypothesis

A kinetic model was proposed to simulate an isometric contraction curve in smooth muscle on the basis of the myosin phosphorylation hypothesis. The Ca2+-calmodulin-dependent activation of myosin light-chain kinase and the phosphorylation-dephosphorylation reaction of myosin were mathematically treated. Solving the kinetic equations at a steady state, we could calculate the relationship between the Ca2+ concentration and the myosin phosphorylation. Assuming that two-head-phosphorylated myosin has an actin-activated Mg2+-ATPase activity and that this state corresponds to an active state, we computed the time courses of the myosin phosphorylation and the active state for various Ca2+ transients. The time course of the active state was converted into that of isometric tension by use of Sandow's model composed of a contractile element and a series elastic component. The model could simulate not only the isometric contraction curves for any given Ca2+ transient but also the following experimental results: the calmodulin-dependent shift of the Ca2+ sensitivity of isometric tension observed in skinned muscle fibers, the disagreement between the Ca2+ sensitivity of myosin phosphorylation and that of isometric tension at a steady state, and the disagreement between the time course of myosin phosphorylation and that of isometric tension development.

Maintained contractions of rat uterine smooth muscle incubated in a Ca2+-free solution

The effects of acetylcholine (10(-4) M), prostaglandin E2 (10(-6) M), vanadate (5 X 10(-4) M) and fluoride (10(-2) M) have been studied on the mechanical and electrical activities of rat myometrial strips perfused in Ca2+-free EGTA-containing solutions. All four substances produced maintained contractions which could be initiated repeatedly after exposure to Ca2+-free solution for more than 1 h, without a significant decrease. The largest contractions were obtained with vanadate and the smallest ones with acetylcholine. The tension was usually 7-30% of the control contraction triggered by an action potential in Ca2+ containing solution. Maintained contractions induced by fluoride were unaffected by isoprenaline while those induced by acetylcholine, prostaglandin E2 and vanadate were completely relaxed. Prostaglandin E2- and vanadate-induced contractions were slightly reduced by Na+ removal or by adding Ca2+ antagonists. In contrast, contractions induced by acetylcholine were suppressed in Na+-free solution and largely inhibited in the presence of Ca2+ antagonists. The depolarization induced by acetylcholine in Ca2+-free solution was strongly dependent on the external Na+ concentration. The relationship between the size of the acetylcholine-induced depolarization and the membrane potential (shifted by constant currents) was linear, giving an apparent reversal potential for acetylcholine close to zero potential. In Ca-free solutions and in the presence of atropine, Na+ action potentials of long duration can be evoked which produced contractions of the same order of magnitude as those initiated by acetylcholine-induced depolarizations. 7 These results are consistent with the hypothesis that the maintained contractions in Ca2+-free solutions induced by several stimulants could be related to Ca2+-independent mechanisms (fluoride) or Ca2+ release from an intracellular store. This latter mechanism would include both pharmacomechanical (prostaglandin E2, vanadate) and electromechanical (acetylcholine) coupling.