Effects of selective K+-channel agonists and antagonists on myoelectrical activity of a locus of the small bowel

 Effects of Ca²⁺-activated K⁺ and voltage-activated K⁺-channel agonists and antagonists on the myoelectrical and contractile activity of a locus of the small bowel are simulated numerically. The model assumes that the electrical activity of smooth muscle syncytium is defined by kinetics of a mixture of L- and T-type Ca²⁺-channels, Ca²⁺-activated K⁺ and voltage-activated K⁺-channels, and leak Cl^--channels, and that the smooth muscle syncytium of the locus is a null-dimensional contractile system. The results of modelling, both qualitatively and quantitatively, reproduce the effects of forskolin, lemakalim, phencyclidine, charybdotoxin and high concentration of external K⁺ ions, on gastrointestinal motility. This is confirmed by comparison with experimental observations conducted on the smooth muscle preparations of different species. Received: 19 February 1996 / Accepted in revised form: 26 June 1996     

Numerical simulation of motility patterns of the small bowel. 1. formulation of a mathematical model

A complete mathematical model of the periodic myoelectrical activity of a functional unit of the small intestine is presented. Based on real morphological and electrophysiological data, the model assumes that: the functional unit is an electromyogenic syncytium; the kinetics of L-type Ca2+, T-type Ca2+, Ca2+-activated K+, voltage dependent K+and Cl-channels determine the electrical activity of the functional unit; the enteric nervous system is satisfactorily represented by an efferent cholinergic neuron that provides an excitatory input to the functional unit through receptor-linked L-type Ca2+channels and by an afferent pathway composed of the primary and secondary sensory neurons; the dynamics of propagation of the wave of depolarization along the unmyelinated nerve axons satisfy the Hodgkin-Huxley model; the electrical activity of the neural soma reflects the interaction of N-type Ca2+channels, Ca2+-activated K+and voltage dependent Na+, K+and Cl-channels; the smooth muscle syncytium of the locus is a null-dimensional contractile system. With the proposed model the dynamics of active force generation are determined entirely by the concentration of cytosolic calcium. The model describes: the mechanical excitation of the free nerve endings of the mechanoreceptor of the receptive field of the pathway; the electrical processes of the propagation of excitation along the afferent and efferent neural circuits; the chemical mechanisms of nerve-pulse transmission at the synaptic zones; the slow wave and bursting type electrical activity; cytosolic calcium concentration; the dynamics of active force generation. Numerical simulations have shown that the model can display different electrical patterns and mechanical responses of the locus. The results show good qualitative and quantitative agreement with the results of experiments conducted on the small intestine.     

Osmoregulatory reactions of frog erythrocytes under conditions of activation and blockade of Ca<Superscript>2+</Superscript>-channels

The kinetics of cell osmoregulatory reactions under conditions of activation and blockade of Ca²⁺-channels was studied on a model of frog polyfunctional nucleated erythrocytes. Both activation and blockade of Ca²⁺-channels has been established to promote swelling of nuclei and an increase of the nucleocytoplasmic ratios under conditions of hypotonic exposure. The osmoregulatory cell reactions after activation of Ca²⁺-channels are manifested as a decrease of the cell volume. The blocker of Ca²⁺-channels verapamil produces a transitory increase and decrease of the erythrocyte volume with time intervals of 30 and 60 s. The clearly expressed functional activity of the nuclear membrane in response to the hypotonic action under conditions of activation and blockade of Ca²⁺-channels indicates participation of Ca²⁺ ions in mechanisms of the nucleocytoplasmic transfer.     

Model predictions of myoelectrical activity of the small bowel

A mathematical model for the periodic electrical activity of a functional unit of the small intestine is developed. Based on real morphological and electrophysiological data, the model assumes that: the functional unit is an electromyogenic syncytium; the kinetics of L, T-type Ca²⁺, mixed Ca²⁺-dependent K⁺, potential sensitive K⁺ and Cl⁻ channels determines electrical activity of the functional unit; the basic neural circuit, represented by a single cholinergic neurone, provides an excitatory input to the functional unit via receptor-linked L-type Ca²⁺ channels. Numerical simulation of the model has shown that it is capable of displaying the slow waves and that slight modifications of some of the parameters result in different electrical responses. The effects of the variations of the main parameters have been analyzed for their ability to reproduce various electrical patterns. The results are in good qualitative and quantitative agreement with results of experiments conducted on the small intestine.     

The oppositely directed Ca2+ and Na+ transmembrane transport in algal cells

Summary The countertransport of Ca²⁺ and Na⁺ across the membranes of the unicellular fresh-water algaChlamydomonas reinhardtii CW-15 and twoDunaliella species differing in salt tolerance was studied. All algae used are devoid of cell walls. The calcium uptake by twoDunaliella species depended markedly on the intracellular sodium concentration. This calcium uptake was accompanied by Na⁺ release. For 15 and 30 s after artificial gradient formation (Na_int ⁺ greater than Na_ext ⁺) the ratio of released Na⁺ to absorbed Ca²⁺ was 31 and 41, respectively. For the extremely halotolerantD. salina, the apparent Michaelis constant of the Ca²⁺ uptake was 33 M, and for the marine halotolerant algaD. maritima, it was equal to 400 M, presuming more efficient Na⁺-for-Ca²⁺ exchange inD. salina cells. Ouabain, an inhibitor of Na⁺/K⁺-ATPase, suppressed Na⁺ transfer by 25%, whereas the agents blocking Ca²⁺-channels did not affect the transport of Ca²⁺ and Na⁺. The oppositely directed transmembrane Ca²⁺ and Na⁺ transfer was shown to depend on the external concentrations of Na⁺ and H⁺. In the fresh-water algaC. reinhardtii CW-15 (Na_ext ⁺ greater than Na_int ⁺), the direction of Ca²⁺ and Na⁺ fluxes across the plasma membrane was opposite to those described for Dunaliella cells. The results obtained point to the ability of the Na⁺-Ca²⁺ exchanger function in plasma membranes of algal cells.     

Excitation-Contraction Coupling in Zebrafish Ventricular Myocardium Is Regulated by Trans-Sarcolemmal Ca2+ Influx and Sarcoplasmic Reticulum Ca2+ Release

Zebrafish (Danio rerio) have become a popular model in cardiovascular research mainly due to identification of a large number of mutants with structural defects. In recent years, cardiomyopathies and other diseases influencing contractility of the heart have been studied in zebrafish mutants. However, little is known about the regulation of contractility of the zebrafish heart on a tissue level. The aim of the present study was to elucidate the role of trans-sarcolemmal Ca²⁺-flux and sarcoplasmic reticulum Ca²⁺-release in zebrafish myocardium. Using isometric force measurements of fresh heart slices, we characterised the effects of changes of the extracellular Ca²⁺-concentration, trans-sarcolemmal Ca²⁺-flux via L-type Ca²⁺-channels and Na⁺-Ca²⁺-exchanger, and Ca²⁺-release from the sarcoplasmic reticulum as well as beating frequency and β-adrenergic stimulation on contractility of adult zebrafish myocardium. We found an overall negative force-frequency relationship (FFR). Inhibition of L-type Ca²⁺-channels by verapamil (1 μM) decreased force of contraction to 22±7% compared to baseline (n=4, p<0.05). Ni²⁺ was the only substance to prolong relaxation (5 mM, time after peak to 50% relaxation: 73±3 ms vs. 101±8 ms, n=5, p<0.05). Surprisingly though, inhibition of the sarcoplasmic Ca²⁺-release decreased force development to 54±3% in ventricular (n=13, p<0.05) and to 52±8% in atrial myocardium (n=5, p<0.05) suggesting a substantial role of SR Ca²⁺-release in force generation. In line with this finding, we observed significant post pause potentiation after pauses of 5 s (169±7% force compared to baseline, n=8, p<0.05) and 10 s (198±9% force compared to baseline, n=5, p<0.05) and mildly positive lusitropy after β-adrenergic stimulation. In conclusion, force development in adult zebrafish ventricular myocardium requires not only trans-sarcolemmal Ca²⁺-flux, but also intact sarcoplasmic reticulum Ca²⁺-cycling. In contrast to mammals, FFR is strongly negative in the zebrafish heart. These aspects need to be considered when using zebrafish to model human diseases of myocardial contractility.     

Role of acetylcholine in Ca<Superscript>2+</Superscript>-dependent regulation of functional activity of the frog <Emphasis Type="Italic">Rana temporaria</Emphasis> myocardium

To study role of acetylcholine (ACh) in Ca²⁺-dependent regulation of rhythm and strength of cardiac contractions in the frog Rana temporaria, we studied in parallel experiments the ACh chrono- and inotropic effects on the background of action of blockers of the potential-controlled Ca²⁺-channels, ryanodine and muscarine receptors. The obtained results indicate participation of acetylcholine in the Ca²⁺-dependent regulation of the rhythm and strength of the frog cardiac contractions.     

Electrophysiology of pancreatic β-cells in intact mouse islets of Langerhans

When exposed to intermediate glucose concentrations (6–16 mol/l), pancreatic β-cells in intact islets generate bursts of action potentials (superimposed on depolarised plateaux) separated by repolarised electrically silent intervals. First described more than 40 years ago, these oscillations have continued to intrigue β-cell electrophysiologists. To date, most studies of β-cell ion channels have been performed on isolated cells maintained in tissue culture (that do not burst). Here we will review the electrophysiological properties of β-cells in intact, freshly isolated, mouse pancreatic islets. We will consider the role of ATP-regulated K⁺-channels (K_ATP-channels), small-conductance Ca²⁺-activated K⁺-channels and voltage-gated Ca²⁺-channels in the generation of the bursts. Our data indicate that K_ATP-channels not only constitute the glucose-regulated resting conductance in the β-cell but also provide a variable K⁺-conductance that influence the duration of the bursts of action potentials and the silent intervals. We show that inactivation of the voltage-gated Ca²⁺-current is negligible at voltages corresponding to the plateau potential and consequently unlikely to play a major role in the termination of the burst. Finally, we propose a model for glucose-induced β-cell electrical activity based on observations made in intact pancreatic islets.     

The role of the sarcoplasmic reticulum in various types of cardiomyocytes

The relative importance of the sarcoplasmic reticulum (SR) as a source of Ca²⁺ in the excitation-contraction coupling of mammalian myocytes was tested. Shortening and intracellular Ca²⁺ transients of electrically paced, isolated,adult rat myocytes were found to be absolutely dependent on the presence of a functional SR and were completely abolished by the SR Ca²⁺-ATPase inhibitors cyclopiazonic acid and thapsigargin or by the Ca²⁺-release channel opener ryanodine.Neonatal rat cardiomyocytes, on the other hand, elicited consistent intracellular Ca²⁺-transients even after complete functional inhibition of the SR. The transients, however, were markedly prolonged. Also isolatedadult guinea pig myocytes maintained the ability to shorten after a complete inhibition of the SR Ca²⁺-ATPase by either thapsigargin or cyclopiazonic acid. The twitches and the intracellular Ca²⁺-transients, however, were considerably longer after inhibition of the SR Ca²⁺-ATPase. Different results were obtained after preincubation of the cells with 10 M ryanodine to induce emptying of the SR Ca²⁺ pool. In this case, Ca²⁺ spikes and twitches were also markedly reduced in size, in addition to being prolonged. When a SR Ca²⁺-pump inhibitor was added to ryanodine-treated cells, the size of the Ca²⁺-transients and the capacity of the cells to shorten increased. Ryanodine leaves the activity of the Ca²⁺-pump of the SR intact and thus leads to an underestimation of the amount of excitatory Ca²⁺-flowing into the cell.The results show that, while the significance of the SR in regulating the Ca²⁺-transients and shortening of cardiomyocytes varies depending on the species and the stage of development, SR function is of paramount importance for the occurrence of rapid twitches.Abbreviations EGTA ethylene glycol-bis-(beta amino ethyl ether)N,N,N,N tetraacetic acid - MOPS morpholinopropane sulfonic acid - SR sarcoplasmic reticulum - BSA bovine serum albumin - HEPES N-2-hydroxyethylpiperazine-N-2-ethanesulfonic acid     

Characterization of calcium fluxes across the envelope of intact spinach chloroplasts

Calcium fluxes across the envelope of intact spinach chloroplasts (Spinacia oleracea L.) in the light and in the dark were investigated using the metallochromic indicator arsenazo III. Light induces Ca²⁺ influx into chloroplasts. The action spectrum of light-induced Ca²⁺ influx and the inhibitory effect of 3-(3',4'-dichlorophenyl)-1,1-dimethylurea (DCMU) indicate an involement of photosynthetic electron transport in this process. The driving force for light-induced Ca²⁺ influx is most likely a change in the membrane potential component of the proton motive force. This was demonstrated by the use of agents modifying the membrane potential (lipophilic cations, ionophores, different KCl concentrations). The activation energy of the observed Ca²⁺ influx is about 92 kJ mol^-1. Verapamil and nifedipine, two Ca²⁺-channel blockers, have no inhibitory effect on light-induced Ca²⁺ influx, but enhance ferricyanide-dependent oxygen evolution. Inhibition of Ca²⁺ influx by ruthenium red reduces the light-dependent decrease in stromal NAD⁺ level.Abbreviations and symbols Chl chlorophyll - DCMU 3-(3',4'-dichlorophenyl)-1,1-dimethylurea - FCCP earbonyl cyanide p-trifluoromethoxyphenylhydrazone - PGA 3-phosphoglyceric acid - ABA⁺ tetrabutylammonium chloride - TPP⁺ tetraphenylphosphonium chloride - E membrane potential     

Cytoplasmic free calcium in Riccia fluitans L. and Zea mays L.: Interaction of Ca2+ and pH?

In cells of Zea mays (root hairs, coleoptiles) and Riccia fluitans (rhizoids, thalli) intracellular Ca²⁺ and pH have been measured with double-barrelled microelectrodes. Free Ca²⁺ activities of 109–187 nM (Riccia rhizoids), 94–160 nM (Riccia thalli), 145–231 nM (Zea root hairs), 84–143 nM (Zea coleoptiles) were found, and therefore identified as cytoplasmic. In a few cases (Riccia rhizoids), free Ca²⁺ was in the lower millimolar range (2.3±0.8 mM). A change in external Ca²⁺ from 0.1 to 10 mM caused an initial and short transient increase in cytoplasmic free Ca²⁺ which finally levelled off at about 0.2 pCa unit below the control, whereas in the presence of cyanide the Ca²⁺ activity returned to the control level. It is suggested that this behaviour is indicative of active cellular Ca²⁺ regulation, and since it is energy-dependent, may involve a Ca²⁺-ATPase. Acidification of the cytoplasmic pH and alkalinization of the vacuolar pH lead to a simultaneous increase in cytoplasmic free Ca²⁺, while alkalinization of pH_c decreased the Ca²⁺ activity. Since this is true for such remote organisms as Riccia and Zea, it may be concluded that regulation of cytoplasmic pH and free Ca²⁺ are interrelated. It is further concluded that double-barrelled microelectrodes are useful tools for investigations of intracellular ion activities in plant cells.Symbols and abbreviations _m, _m membrane potential difference, changes thereof - PVC polyvinylchloride     

F?rster Resonance Energy Transfer Structural Kinetic Studies of Cardiac Thin Filament Deactivation

Cardiac thin filament deactivation is initiated by Ca²⁺ dissociation from troponin C (cTnC), followed by multiple structural changes of thin filament proteins. These structural transitions are the molecular basis underlying the thin filament regulation of cardiac relaxation, but the detailed mechanism remains elusive. In this study Förster resonance energy transfer (FRET) was used to investigate the dynamics and kinetics of the Ca²⁺-induced conformational changes of the cardiac thin filaments, specifically the closing of the cTnC N-domain, the cTnC-cTnI (troponin I) interaction, and the cTnI-actin interaction. The cTnC N-domain conformational change was examined by monitoring FRET between a donor (AEDANS) attached to one cysteine residue and an acceptor (DDPM) attached the other cysteine of the mutant cTnC(L13C/N51C). The cTnC-cTnI interaction was investigated by monitoring the distance changes from residue 89 of cTnC to residues 151 and 167 of cTnI, respectively. The cTnI-actin interaction was investigated by monitoring the distance changes from residues 151 and 167 of cTnI to residue 374 of actin. FRET Ca²⁺ titrations and stopped-flow kinetic measurements show that different thin filament structural transitions have different Ca²⁺ sensitivities and Ca²⁺ dissociation-induced kinetics. The observed structural transitions involving the regulatory region and the mobile domain of cTnI occurred at fast kinetic rates, whereas the kinetics of the structural transitions involving the cTnI inhibitory region was slow. Our results suggest that the thin filament deactivation upon Ca²⁺ dissociation is a two-step process. One step involves rapid binding of the mobile domain of cTnI to actin, which is kinetically coupled with the conformational change of the N-domain of cTnC and the dissociation of the regulatory region of cTnI from cTnC. The other step involves switching the inhibitory region of cTnI from interacting with cTnC to interacting with actin. The latter processes may play a key role in regulating cross-bridge kinetics.Cardiac muscle utilizes troponin to sense the concentration changes of myoplasmic Ca²⁺ and translate the transient Ca²⁺ signal into a cascade of events within the thin filament that ultimately leads to force generation or relaxation. The cardiac thin filament is composed of the heterotrimeric troponin complex and tropomyosin bound to the double helical actin filament (1, 2). The cardiac troponin is formed by three subunits: troponin C (cTnC),² troponin I (cTnI), and troponin T (cTnT). The subunit cTnC is the Ca²⁺-binding protein, cTnI binds actin and inhibits actomyosin ATPase in relaxed muscle, and cTnT anchors the troponin complex on the actin filament. A prominent feature of cardiac muscle regulation is the Ca²⁺-dependent dynamic interactions among the thin filament proteins and the multiple structural transitions at the interface between troponin and the actin filament. These structural transitions include opening/closing of the N-domain of cTnC (3, 4), changes in conformation of both the inhibitory region, and regulatory region of cTnI (5–7), switching of the inhibitory/regulatory regions of cTnI from interacting with actin to interacting with cTnC (8), and movement of tropomyosin on the actin surface (9), which permits cross-bridge cycling between actin and myosin. These Ca²⁺-induced structural transitions are the molecular basis of cardiac thin filament regulation. The strong cross-bridge formed between myosin heads and actin modulates the interactions among thin filament proteins and further affects thin filament regulation (10–12). This feedback has been identified as an important mechanism for the beat-to-beat regulation of cardiac output. However, the mechanism by which the thin filament regulation in cardiac muscle is fine tuned at a molecular level by cross-bridges remains to be determined.It has been suggested recently that the rate of myoplasmic Ca²⁺ removal does not rate limit contraction and relaxation of the muscle (13). For example, the mechanistic studies on cardiac trabeculae (14) and myofibrils (15, 16) suggest that Ca²⁺ binding to cTnC induced switching on of the thin filament regulatory unit well before force generation. In corroboration of the conclusion, de Tombe and co-workers (17) recently reported that changes in myofilament Ca²⁺ sensitivity do not affect the kinetics of myofibrillar contraction and relaxation, i.e. the cross-bridge cycling rate is independent of the dynamics of thin filament activation. This notion is consistent with findings from a recent study where Ca²⁺-induced conformational changes of cTnC were measured simultaneously with force development of myofibril (18). It was found that kinetics of the Ca²⁺-induced conformational change of cTnC was much faster than cross-bridge kinetics. However, one study using photolysis of caged Ca²⁺ reported that the rate of Ca²⁺-induced muscle contraction (k_Ca) was slower than the rate of force redevelopment (k_tr), suggesting the importance of the thin filament in regulating cross-bridge kinetics (19). These results raise questions as to how the thin filament regulation through Ca²⁺-cTnC interaction controls muscle contraction kinetics. If the kinetics of the cross-bridge formation and detachment determine the rate of cardiac muscle contraction and relaxation, what will be the regulatory role of thin filament in heart function? The fact is that a high percentage of cardiomyopathy mutations occur among the thin filament proteins, and some of these mutations can severely hinder the kinetics of heart contraction and relaxation (20). Without a link between Ca²⁺ regulation and dynamics of cross-bridge formation and detachment, it will be difficult to interpret the mechanism underlying how these mutations affect force development and relaxation in the diseased heart.Signal transduction of Ca²⁺ activation/deactivation along the thin filament involves multiple structural transitions of the thin filament proteins (21). Each structural transition may have different dynamics that can differ from Ca²⁺ exchange with cTnC. Therefore, the dynamics of these structural transitions within the thin filament may provide insight into the dynamic linkage between the Ca²⁺ binding to cTnC and the activation state of the cardiac thin filament. Time-resolved Förster resonance energy transfer (FRET), which can quantitate the distribution of inter-probe distances (22), provides a clear metric for study of Ca²⁺-induced structural changes (on Å scale) in the thin filament. FRET involves two fluorophores (one is the FRET donor and the other is an acceptor) attached to two different sites of proteins. Because FRET provides information on the conformational changes of proteins only around a specific region of interest, it is a unique approach for monitoring specific structural changes associated with the functional activities of the thin filament. Especially when combined with fast time-resolved techniques, FRET can provide dynamic and kinetic information associated with a specific structural transition in a multiple structural transition system (23–26).Accordingly, we focused our investigation on the relaxation kinetics of (a) cTnC N-domain closing, (b) cTnC-cTnI interaction, and (c) cTnI-actin interaction within the reconstituted thin filament upon Ca²⁺ removal from the regulatory binding site of cTnC. The kinetics of these structural transitions were measured using FRET stopped-flow to monitor structural changes associated with each transition in the reconstituted thin filament in the absence and presence of strongly bound myosin subfragment 1 (S1). Our results showed that all structural transitions occurred in two phases, one fast and the other slow. The fast phase transition accounted for more than two-thirds of the total FRET change, and the slow phase transition accounted for less than one-third of the total FRET change. Our study suggests that different structural transitions have different kinetics upon Ca²⁺ removal from cTnC. Structural transitions associated with the mobile domain and the regulatory region of cTnI occur at fast kinetic rates, whereas the structural transitions involving transversal movement of the inhibitory region of cTnI occur at slow rates.     

The steady-state force–Ca<Superscript>2+</Superscript> relationship in intact lobster (<Emphasis Type="Italic">Homarus americanus</Emphasis>) cardiac muscle

The heart of the decapod crustacean is activated by regular impulse bursts from the cardiac ganglion. The cardiac pump function depends on ganglionic burst frequency, burst duration, and burst impulse frequency. Here, we activated isolated lobster cardiac ostial muscle (Orbicularis ostii muscle, OOM) by stimulus trains in vitro in order to characterize the response of the contractile apparatus to [Ca²⁺]_i . We employed stimulus trains that generate a steady state between the [Ca²⁺]_i and force in order to estimate the Ca²⁺ sensitivity of myofilaments. Force and [Ca²⁺]_i transients were simultaneously recorded using a silicon strain gauge and the fluorescence of iontophoretically microinjected fura-2 salt. We examined the effects of tetanus duration (TD), the interval between trains, and 6 M cyclopiazonic acid, an inhibitor of the SR Ca²⁺ pump, on the steady-state force–[Ca²⁺]_i relationship. The instantaneous force–[Ca²⁺]_i relationships appeared sigmoidal (EC₅₀ and Hill coefficient, 98.8±32.7 nM and 2.47±0.20, mean ± SD, respectively), as did the curves superimposed after 500 ms following the start of stimulation, indicating that the force–[Ca²⁺]_i relationship had reached a steady state at that time. Also, the maximum activated force (F_max) was estimated using the steady-state force–[Ca²⁺]_i relationship. Prolonged stimulus trains, decreasing the interval between recurrent trains from 5 to 2.5 s, and cyclopiazonic acid each increased the measured EC₅₀ without changing F_max. The EC₅₀ correlated strongly with averaged [Ca²⁺]_i over time. We conclude that the steady-state force–[Ca²⁺]_i relationships in the OOM indicate cooperation between force generation and Ca²⁺ binding by the myofilaments. Our data also suggest the existence of a novel Ca²⁺-dependent mechanism which reduces Ca²⁺ sensitivity and accelerates relaxation of lobster cardiac muscle myofilaments.Communicated by L.C.-H. Wang     

Neuronal Control of Exocytosis and Calcium Homeostasis

We showed that 5 M acetylcholine (ACh) and 100 M norepinephrine (NE) cause increases in the total Ca²⁺ content in acinar cells by 30 and 87% and in the exocytosis intensity by 15 and 20%, respectively. Application of 5 M ACh and 100 M NE increased the free cytosolic Ca²⁺ concentration ([Ca²⁺] _i ) by 87 ± 2 and 140 ± 7 nM, respectively. Application of ACh and NE in a Ca²⁺-free external solution caused a [Ca²⁺] _i increase that was 40 and 67% lower than in physiological solution. We postulate that the exocytosis developing upon neural stimulation of the gland results from generation of Ca²⁺ transients that are spreading from the basal to the apical region of the exocrine cell, where secretory granules are concentrated.     

The mechanism of voltage-sensitive dye responses on sarcoplasmic reticulum

Summary The mechanism of voltage-sensitive dye responses was analyzed on sarcoplasmic reticulum vesicles to assess the changes in membrane potential related to Ca²⁺ transport. The absorbance and fluorescence responses of 3,3-diethyl-2,2-thiadicarbocyanine, 3,3-dimethyl-2,2-indodicarbocyanine and oxonol VI during ATP-dependent Ca²⁺ transport are influenced by the effect of accumulated Ca²⁺ upon the surface potential of the vesicle membrane. These observations place definite limitations on the use of these probes as indicators of ion-diffusion potential in processes which involve large fluctuations in free Ca²⁺ concentrations. Nile Blue A appeared to produce the cleanest optical signal to negative transmembrane potential, with least direct interference from Ca²⁺, encouraging the use of Nile Blue A for measurement of the membrane potential of sarcoplasmic reticulumin vivo andin vitro. 1,3-dibutylbarbituric acid (5)-1-(p-sulfophenyl)-3 methyl, 5-pyrazolone pentamethinoxonol (WW 781) gave no optical response during ATP-induced Ca²⁺ transport and responded primarily to changes in surface potential on the same side of the membrane where the dye was applied. Binding of these probes to the membrane plays a major role in the optical response to potential, and changes in surface potential influence the optical response by regulating the amount of membrane-bound dye. The observations are consistent with the electrogenic nature of ATP-dependent Ca²⁺ transport and indicate the generation of about 10 mV inside-positive membrane potential during the initial phase of Ca²⁺ translocation. The potential generated during Ca²⁺ transport is rapidly dissipated by passive ion fluxes across the membrane.     

The role of phosphoinositide metabolism in Ca2+ signalling of skeletal muscle cells

• 1.1. The mobilization of Ca²⁺ from intracellular stores by d-myo-inositol 1,4,5-triphosphate[Ins(1,4,5)P₃] is now widely accepted as the primary link between plasma membrane receptors that stimulate phospholipase C and the subsequent increase in intracellular free Ca²⁺ that occurs when such receptors are activated (Berridge, 1993). Since the observations of VoIpe et al. (1985) which showed that Ins(1,4,5)P₃ could induce Ca²⁺ release from isolated terminal cisternae membranes and elicit contracture of chemically skinned muscle fibres, research has focused on the role of Ins(1,4,5)P₃ in the generation of SR Ca²⁺ transients and in the mechanism of excitation-contraction coupling (EC-coupling).
• 2.2. The mechanism of signal transduction at the triadic junction during EC-coupling is unknown. Asymmetric charge movement and mechanical coupling between highly specialized triadic proteins has been proposed as the primary mechanism for voltage-activated generation of SR Ca²⁺ signals and subsequent contraction. Ins(1,4,5)P₃ has also been proposed as the major signal transduction molecule for the generation of the primary Ca²⁺ transient produced during EC-coupling.
• 3.3. Investigations on the generation of Ca²⁺ transients by Ins(1,4,5)P₃ have been conducted on ion channels incorporated into lipid bilayers, skinned and intact fibres and isolated membrane vesicles. Ins(1,4,5)P₃ induces SR Ca²⁺ release and the enzymes responsible for its synthesis and degradation are present in muscle tissue. However, the sensitivity of the Ca²⁺ release mechanism to Ins(l,4,5)P₃ is highly dependent on experimental conditions and on membrane potential.
• 4.4. While Ins(1,4,5)P₃ may not be the major signal transduction molecule for the generation of the primary Ca²⁺ signal produced during voltage-activated contraction, this inositol polyphosphate may play a functional role as a modulator of EC-coupling and/or of the processes of myoplasmic Ca²⁺ regulation occurring on a time scale of seconds, during the events of contraction.

     

Correlation between the activity of intracellular Ca<Superscript>2+</Superscript>-dependent proteinase and the content of membrane lipid components in mussel, <Emphasis Type="Italic">Mytilus edulis</Emphasis>, upon accumulation of heavy metals

The correlation between the activity of calpains and the content of membrane lipid components in the organs of mussels, Mytilus edulis L., is shown in the aquarium experiment on studying the response of mussels to the action of copper and cadmium ions. This correlation is most likely explained by the effector activity of membrane lipid components (arachidonic acid and phosphatidylinositol) with respect to Ca²⁺-channels. Thus, the correlation between the membrane lipid composition and the functional activity of proteins, which is defined by the level of intracellular Ca²⁺, is found in the experiment.     

In silico assessment of S100A12 monomer and dimer structural dynamics: implications for the understanding of its metal-induced conformational changes

Changes in the concentration of different ions modulate several cellular processes, such as Ca²⁺ and Zn²⁺ in inflammation. Upon activation of immune system effector cells, the intracellular Ca²⁺ concentration rises propagating the activation signal, leading to degranulation and generation of reactive oxygen species, which increases the Zn²⁺ intracellular concentration as a consequence of the cellular antioxidant machinery. In this context, S100A12 is of special interest because it is a pro-inflammatory protein expressed in neutrophils whose structure and function are modulated by both Ca²⁺ and Zn²⁺. The current hypothesis about its mechanism of action was built based on biochemical and crystallographic data. However, there are missing connections between molecular structure and the way in which many events are concatenated at the triggering and along the inflammatory process. In this work we use molecular dynamics simulations to describe how variations in Zn²⁺ and Ca²⁺ concentrations modulate the structural dynamics of the calcium-free S100A12 dimer and monomer, which was not considered a part of the mechanism of action before. Our results suggest that (i) Zn²⁺ have a determinant role in the dimerization step, as well as in the unbinding of the Na⁺ complexed to the N-terminal EF-hand; (ii) the N-terminal EF-hand domain is the first to bind Ca²⁺, and not the C-terminal, as usually accepted; and that (iii) Ca²⁺ modulates the structural dynamics of H-III.     

In situ visualization of the intracellular Ca2+ dynamics at the border of the acute myocardial infarct

Ischemic insult to the heart produces myocyte Ca²⁺ ([Ca²⁺]_i) overload. However, little is known about spatiotemporal changes in [Ca²⁺]_i within the ischemic heart in situ at the cellular level. Using real-time confocal microscopy, we successfully visualized [Ca²⁺]_i dynamics at the border zone on the subepicardial myocardium of the heart 2 h after coronary ligations followed by loading with fluo 3/AM. Three distinct regions were identified in the acute infarcted heart. In intact regions, the myocytes showed spatially uniform Ca²⁺ transients synchronously to QRS complex in the electrocardiogram. The myocytes at the infarcted regions showed no fluorescence intensity (FI). At the border zones between the intact and infarcted regions, Ca²⁺ waves emerged sporadically and randomly, instead of Ca²⁺ transients, at a mean frequency of 11.5 ± 8.5 min/cell with a propagation velocity of 151.0 ± 35.7 m/sec along the longitudinal axis of the individual myocytes. In addition, some myocytes within the border zone exhibited homogeneously high static FI, indicating severe Ca²⁺ overload. In summary, we provided the first direct evidence of abnormal [Ca²⁺]_i dynamics in acute infarcted hearts at the cellular level. The observed diversity in spatiotemporal [Ca²⁺]_i dynamics at the border zone may contribute to the arrhythmias or contractile failure in acute myocardial infarction.