Activation by Ca2+/calmodulin of an exogenous myosin light chain kinase in mouse arteries.

Activation of myosin light chain kinase (MLCK) and other kinases was studied in the arteries of transgenic mice that express an optical fluorescence resonance energy transfer (FRET) MLCK activity biosensor. Binding of Ca(2+)/calmodulin (Ca(2+)/CaM) induces an increase in MLCK activity and a change in FRET. After exposure to high external [K(+)], intracellular [Ca(2+)] (fura-2 ratio or fluo-4 fluorescence) and MLCK activity both increased rapidly to an initial peak and then declined, rapidly at first and then very slowly. After an initial peak ('phasic') force was constant or increased slowly (termed 'tonic' force). Inhibition of rho-kinase (Y-27632) decreased tonic force more than phasic, but had little effect on [Ca(2+)] and MLCK activation. Inhibition of PKCalpha and PKCbeta with Gö6976 had no effect. KN-93, an inhibitor of CaMK II, markedly reduced force, MLCK FRET and [Ca(2+)]. Applied during tonic force, forskolin caused a rapid decrease in MLCK FRET ratio and force, but no change in Ca(2+), suggesting a cAMP mediated decrease in affinity of MLCK for Ca(2+)/CaM. However, receptor (beta-adrenergic) activated increases in cAMP during KCl were ineffective in causing relaxation, changes in [Ca(2+)], or MLCK FRET. At the same tonic force, MLCK FRET ratio activated by alpha(1)-adrenoceptors was approximately 60% of that activated by KCl. In conclusion, MLCK activity of arterial smooth muscle during KCl-induced contraction is determined primarily by Ca(2+)/CaM. Rho-kinase is activated, by unknown mechanisms, and increases 'Ca(2+) sensitivity' significantly. Forskolin mediated increases in cAMP, but not receptor mediated increases in cAMP cause a rapid decrease in the affinity of MLCK for Ca(2+)/CaM.

Calcium transients during excitation-contraction coupling in mammalian heart: aequorin signals of canine Purkinje fibers.

Aequorin signals in mammalian heart muscle cells reveal the existence of two temporally distinct processes that increase cytoplasmic calcium ions after membrane excitation. The differential dependence of these processes on the pattern of stimulation suggests that the first process is, or is closely related to, calcium entry through the surface membrane and that the second is calcium release from intracellular storage sites.

Sodium-calcium exchange in heart: membrane currents and changes in [Ca2+]i.

Recordings have been made of changes in intracellular calcium ion concentration ([Ca2+]i) that can be attributed to the operation of an electrogenic, voltage-dependent sodium-calcium (Na-Ca) exchanger in mammalian heart cells. Guinea pig ventricular myocytes under voltage clamp were perfused internally with fura-2, a fluorescent Ca2+-indicator, and changes in [Ca2+]i and membrane current that resulted from Na-Ca exchange were identified through the use of various organic channel blockers and impermeant ions. Depolarization of cells elicited slow increases in [Ca2+]i, with the maximum increase depending on internal [Na+], external [Ca2+], and membrane voltage. Repolarization was associated with net Ca2+ efflux and a decline in the inward current that developed instantaneously upon repolarization. The relation between [Ca2+]i and current was linear, and the slope was made steeper by hyperpolarization.

Cellular and subcellular heterogeneity of [Ca2+]i in single heart cells revealed by fura-2.

Digital imaging of calcium indicator signals (fura-2 fluorescence) from single cardiac cells has revealed different subcellular patterns of cytoplasmic calcium ion concentration ([Ca2+]i) that are associated with different types of cellular appearance and behavior. In any population of enzymatically isolated rat heart cells, there are mechanically quiescent cells in which [Ca2+]i is spatially uniform, constant over time, and relatively low; spontaneously contracting cells, which have an increased [Ca2+]i, but in which the spatial uniformity of [Ca2+]i is interrupted periodically by spontaneous propagating waves of high [Ca2+]i; and cells that are hypercontracted (rounded up) and that have higher levels of [Ca2+]i than the other two types. The observed cellular and subcellular heterogeneity of [Ca2+]i in isolated cells indicates that experiments performed on suspensions of cells should be interpreted with caution. The spontaneous [Ca2+]i fluctuations previously observed without spatial resolution in multicellular preparations may actually be inhomogeneous at the subcellular level.

Visualization of quantal synaptic transmission by dendritic calcium imaging.

As changes in synaptic strength are thought to be critical for learning and memory, it would be useful to monitor the activity of individual identified synapses on mammalian central neurons. Calcium imaging of cortical neurons grown in primary culture was used to visualize the activation of individual postsynaptic elements by miniature excitatory synaptic currents elicited by spontaneous quantal release. This approach revealed that the probability of spontaneous activity differed among synapses on the same dendrite. Furthermore, synapses that undergo changes in activity induced by glutamate or phorbol ester treatment were identified.

Local calcium transients triggered by single L-type calcium channel currents in cardiac cells.

Excitation-contraction coupling was studied in mammalian cardiac cells in which the opening probability of L-type calcium (Ca2+) channels was reduced. Confocal microscopy during voltage-clamp depolarization revealed distinct local transients in the concentration of intracellular calcium ions ([Ca2+]i). When voltage was varied, the latency to occurrence and the relative probability of occurrence of local [Ca2+]i transients varied as predicted if Ca2+ release from the sarcoplasmic reticulum (SR) was linked tightly to Ca2+ flux through L-type Ca2+ channels but not to that through the Na-Ca exchanger or to average [Ca2+]i. Voltage had no effect on the amplitude of local [Ca2+]i transients. Thus, the most efficacious "Ca2+ signal" for activating Ca2+ release from the SR may be a transient microdomain of high [Ca2+]i beneath an individual, open L-type Ca2+ channel.

Mapping miniature synaptic currents to single synapses using calcium imaging reveals heterogeneity in postsynaptic output.

The amplitudes and kinetics of miniature excitatory synaptic currents (MESCs) in mammalian central neurons vary widely. It is unclear whether this variability occurs at each synapse or arises from differences among a heterogeneous population of synapses. Furthermore, it is not known how variability in these currents would affect their associated postsynaptic Ca2+ transients. To address these questions, we conducted simultaneous Ca2+ imaging and patch-clamp recordings from cultured cortical neurons and mapped individual MESCs to identified synapses displaying coincident dendritic miniature synaptic Ca2+ transients (MSCTs). Measurements of MSCTs at dendritic sites that displayed multiple events revealed that MSCT amplitude varied considerably at each site. Simultaneous measurement of MESCs and MSCTs at these sites indicated that variability in coincident synaptic currents contributes to the differences in Ca2+ transient amplitude. The ability of single synapses to exhibit variable output may enable them to engage intracellular signaling pathways at different levels of intracellular Ca2+.

Mechanisms of arrhythmogenic delayed and early afterdepolarizations in ferret ventricular muscle.

Drug-induced triggered arrhythmias in heart muscle involve oscillations of membrane potential known as delayed or early afterdepolarizations (DADs or EADs). We examined the mechanism of DADs and EADs in ferret ventricular muscle. Membrane potential, tension and aequorin luminescence were measured during exposure to elevated [Ca2+]0, strophanthidin and/or isoproterenol (to induce DADs), or cesium chloride (to induce EADs). Ryanodine (10(-9)-10(-6) M), an inhibitor of Ca2+ release from the sarcoplasmic reticulum, rapidly suppressed DADs and triggered arrhythmias. When cytoplasmic Ca2+-buffering capacity was enhanced by loading cells with the Ca2+ chelators BAPTA or quin2, DADs were similarly inhibited, as were contractile force and aequorin luminescence. In contrast to DADs, EADs induced by Cs were not suppressed by ryanodine or by loading with intracellular Ca2+ chelators. The possibility that transsarcolemmal Ca2+ entry might produce EADs was evaluated with highly specific dihydropyridine Ca channel agonists and antagonists. Bay K8644 (100-300 nM) potentiated EADs, whereas nitrendipine (3-20 microM) abolished EADs. We conclude that DADs and DAD-related triggered arrhythmias are activated by an increase in intracellular free Ca2+ concentration, whereas EADs do not require elevated [Ca2+]i but rather arise as a direct consequence of Ca2+ entry through sarcolemmal slow Ca channels.

Alpha1-adrenergic signaling mechanisms in contraction of resistance arteries.

Our goal in this review is to provide a comprehensive, integrated view of the numerous signaling pathways that are activated by alpha(1)-adrenoceptors and control actin-myosin interactions (i.e., crossbridge cycling and force generation) in mammalian arterial smooth muscle. These signaling pathways may be categorized broadly as leading either to thick (myosin) filament regulation or to thin (actin) filament regulation. Thick filament regulation encompasses both "Ca(2+) activation" and "Ca(2+)-sensitization" as it involves both activation of myosin light chain kinase (MLCK) by Ca(2+)-calmodulin and regulation of myosin light chain phosphatase (MLCP) activity. With respect to Ca(2+) activation, adrenergically induced Ca(2+) transients in individual smooth muscle cells of intact arteries are now being shown by high resolution imaging to be sarcoplasmic reticulum-dependent asynchronous propagating Ca(2+) waves. These waves differ from the spatially uniform increases in [Ca(2+)] previously assumed. Similarly, imaging during adrenergic activation has revealed the dynamic translocation, to membranes and other subcellular sites, of protein kinases (e.g., Ca(2+)-activated protein kinases, PKCs) that are involved in regulation of MLCP and thus in "Ca(2+) sensitization" of contraction. Thin filament regulation includes the possible disinhibition of actin-myosin interactions by phosphorylation of CaD, possibly by mitogen-activated protein (MAP) kinases that are also translocated during adrenergic activation. An hypothesis for the mechanisms of adrenergic activation of small arteries is advanced. This involves asynchronous Ca(2+) waves in individual SMC, synchronous Ca(2+) oscillations (at high levels of adrenergic activation), Ca(2+) sparks, "Ca(2+)-sensitization" by PKC and Rho-associated kinase (ROK), and thin filament mechanisms.

Excitation-contraction coupling in cardiac Purkinje fibers. Effects of cardiotonic steroids on the intracellular [Ca2+] transient, membrane potential, and contraction.

The [Ca2+]-activated photoprotein aequorin was used to measure [Ca2+] in canine cardiac Purkinje fibers during the positive inotropic and toxic effects of ouabain, strophanthidin, and acetylstrophanthidin. The positive inotropic effect of these substances was associated with increases in the two components of the aequorin signal, L1 and L2. On the average, strophanthidin at 10(-7) M produced steady, reversible increases in L1, L2, and peak twitch tension of 20, 91, and 240%, respectively. This corresponds to increases in the upper-limit spatial average [Ca2+] from 1.9 X 10(-6) M to 2.1 X 10(-6) M at L1 and from 1.4 X 10(-6) M to 1.8 X 10(-6) M at L2. Elevation of diastolic luminescence above the control level was not detected. At higher concentrations (5 X 10(-7) M), strophanthidin produced aftercontractions, diastolic depolarization, and transient depolarizations, all of which were associated with temporally similar changes in [Ca2+]. During these events, diastolic [Ca2+] rose from the normal level of approximately 3 X 10(-7) M up to 1-2 X 10(-6) M. The negative inotropic effect of 5 X 10(-7) M strophanthidin was not associated with a corresponding decrease in the [Ca2+] transient but was associated with a change in the relationship between [Ca2+] and tension. Assuming the Na+-lag mechanism of cardiotonic steroid action, we conclude the following: at low concentrations of drug, increased Ca2+ uptake by the sarcoplasmic reticulum prevents a detectable rise in cytoplasmic [Ca2+] during diastole, but this increased Ca2+ uptake results in increased release of Ca2+ during the action potential. At higher drug concentrations, observable [Ca2+] changes during diastole activate tension and membrane conductance changes.

Excitation-contraction coupling in cardiac Purkinje fibers. Effects of caffeine on the intracellular [Ca2+] transient, membrane currents, and contraction.

The effects of caffeine on tension, membrane potential, membrane currents, and intracellular [Ca2+], measured as the light emitted by the Ca2+-activated photoprotein aequorin, were studied in canine cardiac Purkinje fibers. An initial, transient, positive inotropic effect of caffeine was accompanied by a transient increase in the second component of the aequorin signal (L2) but not the first (L1). In the steady state, 4 or 10 mM caffeine always decreased twitch tension and greatly reduced both L1 and L2. At a concentration of 2 mM, caffeine usually reduced but occasionally increased the steady state twitch tension. However, 2 mM caffeine always reduced both L1 and L2. Caffeine eliminated the diastolic oscillations of intracellular [Ca2+] induced by high extracellular [Ca2+]. In voltage-clamp experiments, 10 mM caffeine reduced the transient outward current and the peak tension elicited by step depolarization from a holding potential of -45 mV. In the presence of 20 mM Cs+, 10 mM caffeine reduced slow inward current. However, the time course of this reduction was far slower than that in tension and light observed in separate experiments. The simplest explanation of the results is that caffeine inhibits the sequestration of Ca2+ by the sarcoplasmic reticulum. The results also suggest that in Purkinje fibers caffeine increases the sensitivity of the myofilaments to Ca2+.

Relationship between force and intracellular [Ca2+] in tetanized mammalian heart muscle.

To determine features of the steady state [Ca2+]-tension relationship in intact heart, we measured steady force and intracellular [Ca2+] ([Ca2+]i) in tetanized ferret papillary muscles. [Ca2+]i was estimated from the luminescence emitted by muscles that had been microinjected with aequorin, a Ca2+-sensitive, bioluminescent protein. We found that by raising extracellular [Ca2+] and/or by exposing muscles to the Ca2+ channel agonist Bay K 8644, tension development could be varied from rest to an apparently saturating level, at which increases in [Ca2+]i produced no further rise in force. 95% of maximal Ca2+-activated force was reached at a [Ca2+]i of 0.85 +/- 0.06 microM (mean +/- SEM; n = 7), which suggests that the sensitivity of the myofilaments to [Ca2+]i is far greater than anticipated from studies of skinned heart preparations (or from previous studies using Ca2+-sensitive microelectrodes in intact heart). Our finding that maximal force was reached by approximately 1 microM also allowed us to calculate that the steady state [Ca2+]i-tension relationship, as it might be observed in intact muscle, should be steep (Hill coefficient of greater than 4), which is consistent with the Hill coefficient estimated from the entire [Ca2+]i-tension relationship derived from families of variably activated tetani (6.08 +/- 0.68; n = 7). Finally, with regard to whether steady state measurements can be applied directly toward understanding physiological contractions, we found that the relation between steady force and [Ca2+]i obtained during tetani was steeper than that between peak force and peak [Ca2+]i observed during physiological twitches.

Caffeine-induced release of intracellular Ca2+ from Chinese hamster ovary cells expressing skeletal muscle ryanodine receptor. Effects on full-length and carboxyl-terminal portion of Ca2+ release channels.

The ryanodine receptor (RyR)/Ca2+ release channel is an essential component of excitation-contraction coupling in striated muscle cells. To study the function and regulation of the Ca2+ release channel, we tested the effect of caffeine on the full-length and carboxyl-terminal portion of skeletal muscle RyR expressed in a Chinese hamster ovary (CHO) cell line. Caffeine induced openings of the full length RyR channels in a concentration-dependent manner, but it had no effect on the carboxyl-terminal RyR channels. CHO cells expressing the carboxyl-terminal RyR proteins displayed spontaneous changes of intracellular [Ca2+]. Unlike the native RyR channels in muscle cells, which display localized Ca2+ release events (i.e., "Ca2+ sparks" in cardiac muscle and "local release events" in skeletal muscle), CHO cells expressing the full length RyR proteins did not exhibit detectable spontaneous or caffeine-induced local Ca2+ release events. Our data suggest that the binding site for caffeine is likely to reside within the amino-terminal portion of RyR, and the localized Ca2+ release events observed in muscle cells may involve gating of a group of Ca2+ release channels and/or interaction of RyR with muscle-specific proteins.

Ca(2+)-oscillations and Ca(2+)-waves in mammalian cardiac and vascular smooth muscle cells.

In this article, we review briefly the available theories and data on [Ca2+]i-waves and [Ca2+]i-oscillations in mammalian cardiac and vascular smooth muscles. In addition to our review, we also report: (i) the existence and characterization of rapid agonist-induced [Ca2+]i-waves in cultured vascular smooth muscle cells (A7r5 cells); and (ii a new method for studying rapid [Ca2+]i-waves in mammalian cardiac ventricular cells. In mammalian cardiac muscle several types of Ca(2+)-release from sarcoplasmic reticulum (SR) are known to occur and might be involved in Ca(2+)-waves and Ca(2+)-oscillations: (a) Ca(2+)-induced release of Ca2+, of the type thought to be important in normal excitation-contraction coupling; (b) spontaneous, cyclic release of Ca2+ related to a Ca(2+)-overload of the SR; and (c) Ins(1,4,5)P3-induced Ca(2+)-release. The available data support the idea that [Ca2+]i-waves in heart propagate by a mechanism somewhat different than that involved in normal excitation-contraction coupling (a, above), perhaps involving spontaneous release of Ca2+ from an overloaded SR (b, above). In mammalian vascular smooth muscle, our data support the idea that agonist-receptor interaction (vasopressin, in this case) initiates [Ca2+]i-waves that then propagate via some form of Ca(2+)-induced release of Ca2+, perhaps in a manner similar to that proposed by Berridge and Irvine [1].

High temporal resolution video imaging of intracellular calcium.

We have developed a system for imaging intracellular free calcium ion concentration ([Ca2+]i) at the highest rate possible with conventional video equipment. The system is intended to facilitate quantitative study of rapid changes in [Ca2+]i in cells that move. It utilizes intensified video cameras with nearly ideal properties and digital image processing to produce two images that can be ratioed without artifacts. Two dichroic mirrors direct images of cellular Indo-1 fluorescence at two different wavelengths to two synchronized video cameras, each consisting of a fast micro-channel plate image intensifier optically coupled with a tapered fiber optic bundle to a CCD image sensor. The critical technical issues in this dual-image system are: (1) minimization and correction of the small geometric and other types of differences in the images provided by the two cameras; and (2) the signal-to-noise ratio that can be achieved in single frames. We have used this system to obtain images of [Ca2+]i at 16.7 ms intervals in voltage-clamped single cardiac cells perfused internally with Indo-1 (pentapotassium salt). The images indicate that, except for the nuclear regions, [Ca2+]i is uniform during normal excitation-contraction coupling. In contrast, changes in [Ca2+]i propagate in rapid 'waves' during the spontaneous release of Ca2+ that accompanies certain 'Ca2(+)-overload conditions.'

Nitric oxide decreases [Ca2+]i in vascular smooth muscle by inhibition of the calcium current.

Endothelium derived relaxing factor (nitric oxide, or NO) activates cytoplasmic guanylate cyclase in vascular smooth muscle and decreases vascular tone through cGMP-dependent mechanisms that are not yet understood fully. In cultured vascular smooth muscle cells (A7r5 cell line) sodium nitroprusside (NP), a vasodilator that decomposes into nitric oxide, lowered [Ca2+]i in cells in which [Ca2+]i was elevated after depolarization. NP decreased current through voltage-gated calcium channels, but did not affect release of calcium from intracellular stores. Hemoglobin, a scavenger of NO, reversed the effect of NP on [Ca2+]i and 8-Br-cGMP, a membrane permeant form of cGMP, mimicked the effect of NP on [Ca2+]i and on calcium currents. Thus, the signal transduction mechanism of endothelium dependent relaxation of vascular smooth muscle involves a decrease in [Ca2+]i by inhibition of Ca2+ entry. Relaxation or vasodilation would then result from decreased activity of myosin light chain kinase, in addition to myosin light chain dephosphorylation.

A high-resolution, confocal laser-scanning microscope and flash photolysis system for physiological studies.

We describe the construction of a high-resolution confocal laser-scanning microscope, and illustrate its use for studying elementary Ca2+ signalling events in cells. An avalanche photodiode module and simple optical path provide a high efficiency system for detection of fluorescence signals, allowing use of a small confocal aperture giving near diffraction-limited spatial resolution (< 300 nm lateral and < 400 nm axial). When operated in line-scan mode, the maximum temporal resolution is 1 ms, and the associated computer software allows complete flexibility to record line-scans continuously for long (minutes) periods or to obtain any desired pixel resolution in x-y scans. An independent UV irradiation system permits simultaneous photolysis of caged compounds over either a uniform, wide field (arc lamp source) or at a tightly focussed spot (frequency-tripled Nd:YAG laser). The microscope thus provides a versatile tool for optical studies of dynamic cellular processes, as well as excellent resolution for morphological studies. The confocal scanner can be added to virtually any inverted microscope for a component cost that is only a small fraction of that of comparable commercial instruments, yet offers better performance and greater versatility.

Graded alpha1-adrenoceptor activation of arteries involves recruitment of smooth muscle cells to produce 'all or none' Ca(2+) signals.

Confocal laser scanning microscopy and Fluo-4 were used to visualize Ca(2+) transients within individual smooth muscle cells (SMC) of rat resistance arteries during alpha(1)-adrenoceptor activation. The typical spatio-temporal pattern of [Ca(2+)] in an artery after exposure to a maximally effective concentration of phenylephrine (PE, 10.0 microM) was a large, brief, relatively homogeneous Ca(2+) transient, followed by Ca(2+) waves, which then declined in frequency over the course of 5 min and which were asynchronous in different SMC. Concentration-Effect (CE) curves relating the concentration of PE (range: 0.1 microM to 10.0 microM) to the effects (fraction of cells producing at least one Ca(2+) wave, and number of Ca(2+) waves during 5 min) had EC(50) values of approximately 0.5 microM and approximately 1.0 microM respectively. The initial Ca(2+) transient and the subsequent Ca(2+) waves were abolished in the presence of caffeine (10.0 mM). A repeated exposure to PE, 1.5 min after the first had ended, elicited fewer Ca(2+) waves in fewer cells than did the initial exposure. Caffeine-sensitive Ca(2+) stores were not depleted at this time, however, as caffeine alone was capable of inducing a large release of Ca(2+)1.5 min after PE. In summary, the mechanism of a graded response to graded alpha(1)-adrenoceptor activation is the progressive 'recruitment' of individual SMC, which then respond in 'all or none' fashion (viz. asynchronous Ca(2+) waves). Ca(2+) signaling continues in the arterial wall throughout the time-course (at least 5 min) of activation of alpha(1)-adrenoceptors. The fact that the Ca(2+) waves are asynchronous accounts for the previously reported fall in 'arterial wall [Ca(2+)]' (i.e. spatial average [Ca(2+)] over all cells).

Intracellular calcium during excitation-contraction coupling in mammalian ventricle.

A rapid, transient, rise in cytoplasmic free calcium ion concentration ([Ca2+]i-transient) couples electrical excitation to contraction in muscle. Such [Ca2+]i-transients in muscle are actually subcellular spatio-temporal events that are determined dynamically by i) diffusional fluxes of Ca2+, ii) by the binding or unbinding of Ca2+ to ligands such as troponin c and calmodulin, and iii) by the various cellular processes, such as release of Ca2+ from sarcoplasmic reticulum, that produce fluxes of Ca2+ across the membranes bounding organelles or the cell. In heart muscle, a particularly large number of cellular processes contribute to the cytoplasmic [Ca2+]i-transient, compared with skeletal muscle. In addition, the actual change in cytoplasmic free [Ca2+]i is now known to be a small fraction of the total [Ca] transient (free plus bound) because most (98 to 99%) of the Ca2+ that enters the cytoplasm binds to ligands. In this article it is shown that under most physiological conditions the SR is the major determinant of the [Ca2+]i-transient in heart, that release of Ca2+ from the SR is induced by Ca2+ entering via L-type Ca(2+)-channels, and that the Na/Ca exchanger is the major route by which Ca2+ leaves the cell. The precise quantitative contribution of all these processes to the [Ca2+]i-transient still remains to be determined, however.

Confocal microscopy reveals local SR calcium release in voltage-clamped cardiac cells.

Confocal microscopy during voltage-clamp depolarization of mammalian heart cells revealed distinct local [Ca2+]i-transients that resulted from Ca2+ released through sarcoplasmic reticulum (SR) release channel(s). When voltage was varied, the latency to occurrence and the relative probability of local [Ca2+]i-transients varied as predicted if SR Ca(2+)-release is linked tightly to Ca2+ flux through co-associated L-type Ca(2+)-channels.