Net calcium exchange in adult rat ventricular myocytes: an assessment of mitochondrial calcium accumulating capacity

Calcium movement in cardiac mitochondria

Existing theory suggests that mitochondria act as significant, dynamic buffers of cytosolic calcium ([Ca(2+)]i) in heart. These buffers can remove up to one-third of the Ca(2+) that enters the cytosol during the [Ca(2+)]i transients that underlie contractions. However, few quantitative experiments have been presented to test this hypothesis. Here, we investigate the influence of Ca(2+) movement across the inner mitochondrial membrane during both subcellular and global cellular cytosolic Ca(2+) signals (i.e., Ca(2+) sparks and [Ca(2+)]i transients, respectively) in isolated rat cardiomyocytes. By rapidly turning off the mitochondria using depolarization of the inner mitochondrial membrane potential (ΔΨm), the role of the mitochondria in buffering cytosolic Ca(2+) signals was investigated. We show here that rapid loss of ΔΨm leads to no significant changes in cytosolic Ca(2+) signals. Second, we make direct measurements of mitochondrial [Ca(2+)] ([Ca(2+)]m) using a mitochondrially targeted Ca(2+) probe (MityCam) and these data suggest that [Ca(2+)]m is near the [Ca(2+)]i level (∼100 nM) under quiescent conditions. These two findings indicate that although the mitochondrial matrix is fully buffer-capable under quiescent conditions, it does not function as a significant dynamic buffer during physiological Ca(2+) signaling. Finally, quantitative analysis using a computational model of mitochondrial Ca(2+) cycling suggests that mitochondrial Ca(2+) uptake would need to be at least ∼100-fold greater than the current estimates of Ca(2+) influx for mitochondria to influence measurably cytosolic [Ca(2+)] signals under physiological conditions. Combined, these experiments and computational investigations show that mitochondrial Ca(2+) uptake does not significantly alter cytosolic Ca(2+) signals under normal conditions and indicates that mitochondria do not act as important dynamic buffers of [Ca(2+)]i under physiological conditions in heart.

Mitochondrial calcium uptake

Calcium (Ca(2+)) uptake into the mitochondrial matrix is critically important to cellular function. As a regulator of matrix Ca(2+) levels, this flux influences energy production and can initiate cell death. If large, this flux could potentially alter intracellular Ca(2+) ([Ca(2+)]i) signals. Despite years of study, fundamental disagreements on the extent and speed of mitochondrial Ca(2+) uptake still exist. Here, we review and quantitatively analyze mitochondrial Ca(2+) uptake fluxes from different tissues and interpret the results with respect to the recently proposed mitochondrial Ca(2+) uniporter (MCU) candidate. This quantitative analysis yields four clear results: (i) under physiological conditions, Ca(2+) influx into the mitochondria via the MCU is small relative to other cytosolic Ca(2+) extrusion pathways; (ii) single MCU conductance is ∼6-7 pS (105 mM [Ca(2+)]), and MCU flux appears to be modulated by [Ca(2+)]i, suggesting Ca(2+) regulation of MCU open probability (P(O)); (iii) in the heart, two features are clear: the number of MCU channels per mitochondrion can be calculated, and MCU probability is low under normal conditions; and (iv) in skeletal muscle and liver cells, uptake per mitochondrion varies in magnitude but total uptake per cell still appears to be modest. Based on our analysis of available quantitative data, we conclude that although Ca(2+) critically regulates mitochondrial function, the mitochondria do not act as a significant dynamic buffer of cytosolic Ca(2+) under physiological conditions. Nevertheless, with prolonged (superphysiological) elevations of [Ca(2+)]i, mitochondrial Ca(2+) uptake can increase 10- to 1,000-fold and begin to shape [Ca(2+)]i dynamics.

Calcium signaling in cardiac mitochondria

Mitochondrial Ca signaling contributes to the regulation of cellular energy metabolism, and mitochondria participate in cardiac excitation-contraction coupling (ECC) through their ability to store Ca, shape the cytosolic Ca signals and generate ATP required for contraction. The mitochondrial inner membrane is equipped with an elaborate system of channels and transporters for Ca uptake and extrusion that allows for the decoding of cytosolic Ca signals, and the storage of Ca in the mitochondrial matrix compartment. Controversy, however remains whether the fast cytosolic Ca transients underlying ECC in the beating heart are transmitted rapidly into the matrix compartment or slowly integrated by the mitochondrial Ca transport machinery. This review summarizes established and novel findings on cardiac mitochondrial Ca transport and buffering, and discusses the evidence either supporting or arguing against the idea that Ca can be taken up rapidly by mitochondria during ECC.

Mitochondria in cardiomyocyte Ca2+ signaling

Ca(2+) signaling is of vital importance to cardiac cell function and plays an important role in heart failure. It is based on sarcolemmal, sarcoplasmic reticulum and mitochondrial Ca(2+) cycling. While the first two are well characterized, the latter remains unclear, controversial and technically challenging. In mammalian cardiac myocytes, Ca(2+) influx through L-type calcium channels in the sarcolemmal membrane triggers Ca(2+) release from the nearby junctional sarcoplasmic reticulum to produce Ca(2+) sparks. When this triggering is synchronized by the cardiac action potential, a global [Ca(2+)](i) transient arises from coordinated Ca(2+) release events. The ends of intermyofibrillar mitochondria are located within 20 nm of the junctional sarcoplasmic reticulum and thereby experience a high local [Ca(2+)] during the Ca(2+) release process. Both local and global Ca(2+) signals may thus influence calcium signaling in mitochondria and, reciprocally, mitochondria may contribute to the local control of calcium signaling. In addition to the intermyofibrillar mitochondria, morphologically distinct mitochondria are also located in the perinuclear and subsarcolemmal regions of the cardiomyocyte and thus experience a different local [Ca(2+)]. Here we review the literature in regard to several issues of broad interest: (1) the ultrastructural basis for mitochondrion - sarcoplasmic reticulum cross-signaling; (2) mechanisms of sarcoplasmic reticulum signaling; (3) mitochondrial calcium signaling; and (4) the possible interplay of calcium signaling between the sarcoplasmic reticulum and adjacent mitochondria. Finally, this review discusses experimental findings and mathematical models of cardiac calcium signaling between the sarcoplasmic reticulum and mitochondria, identifies weaknesses in these models, and suggests strategies and approaches for future investigations.

Controlling metabolism and cell death: at the heart of mitochondrial calcium signalling

Transient increases in intracellular calcium concentration activate and coordinate a wide variety of cellular processes in virtually every cell type. This review describes the main homeostatic mechanisms that control Ca(2+) transients, focusing on the mitochondrial checkpoint. We subsequently extend this paradigm to the cardiomyocyte and to the interplay between cytosol, endoplasmic reticulum and mitochondria that occurs beat-to-beat in excitation-contraction coupling. The mechanisms whereby mitochondria decode fast cytosolic calcium spikes are discussed in the light of the results obtained with recombinant photoproteins targeted to the mitochondrial matrix of contracting cardiomyocytes. Mitochondrial calcium homeostasis is then highlighted as a crucial point of convergence of the environmental signals that mediate cardiac cell death, both by necrosis and by apoptosis. Altogether we point to a role of the mitochondrion as an integrator of calcium signalling and a fundamental decision maker in cardiomyocyte metabolism and survival.

Mitochondrial Ca2+ uptake: tortoise or hare?

Mitochondria are equipped with an efficient machinery for Ca(2+) uptake and extrusion and are capable of storing large amounts of Ca(2+). Furthermore, key steps of mitochondrial metabolism (ATP production) are Ca(2+)-dependent. In the field of cardiac physiology and pathophysiology, two main questions have dominated the thinking about mitochondrial function in the heart: 1) how does mitochondrial Ca(2+) buffering shape cytosolic Ca(2+) levels and affect excitation-contraction coupling, particularly the Ca(2+) transient, on a beat-to-beat basis, and 2) how does mitochondrial Ca(2+) homeostasis influence cardiac energy metabolism. To answer these questions, a thorough understanding of the kinetics of mitochondrial Ca(2+) transport and buffer capacity is required. Here, we summarize the role of mitochondrial Ca(2+) signaling in the heart, discuss the evidence either supporting or arguing against the idea that Ca(2+) can be taken up rapidly by mitochondria during excitation-contraction coupling and highlight some interesting new areas for further investigation.

Excitation-contraction coupling and mitochondrial energetics

Cardiac excitation-contraction (EC) coupling consumes vast amounts of cellular energy, most of which is produced in mitochondria by oxidative phosphorylation. In order to adapt the constantly varying workload of the heart to energy supply, tight coupling mechanisms are essential to maintain cellular pools of ATP, phosphocreatine and NADH. To our current knowledge, the most important regulators of oxidative phosphorylation are ADP, Pi, and Ca2+. However, the kinetics of mitochondrial Ca2+-uptake during EC coupling are currently a matter of intense debate. Recent experimental findings suggest the existence of a mitochondrial Ca2+ microdomain in cardiac myocytes, justified by the close proximity of mitochondria to the sites of cellular Ca2+ release, i. e., the ryanodine receptors of the sarcoplasmic reticulum. Such a Ca2+ microdomain could explain seemingly controversial results on mitochondrial Ca2+ uptake kinetics in isolated mitochondria versus whole cardiac myocytes. Another important consideration is that rapid mitochondrial Ca2+ uptake facilitated by microdomains may shape cytosolic Ca2+ signals in cardiac myocytes and have an impact on energy supply and demand matching. Defects in EC coupling in chronic heart failure may adversely affect mitochondrial Ca2+ uptake and energetics, initiating a vicious cycle of contractile dysfunction and energy depletion. Future therapeutic approaches in the treatment of heart failure could be aimed at interrupting this vicious cycle.

Integration of rapid cytosolic Ca2+signals by mitochondria in cat ventricular myocytes

Decoding of fast cytosolic Ca2+concentration ([Ca2+]i) transients by mitochondria was studied in permeabilized cat ventricular myocytes. Mitochondrial [Ca2+] ([Ca2+]m) was measured with fluo-3 trapped inside mitochondria after removal of cytosolic indicator by plasma membrane permeabilization with digitonin. Elevation of extramitochondrial [Ca2+] ([Ca2+]em) to >0.5 μM resulted in a [Ca2+]em-dependent increase in the rate of mitochondrial Ca2+accumulation ([Ca2+]emresulting in half-maximal rate of Ca2+accumulation = 4.4 μM) via Ca2+uniporter. Ca2+uptake was sensitive to the Ca2+uniporter blocker ruthenium red and the protonophore carbonyl cyanide p-trifluoromethoxyphenylhydrazone and depended on inorganic phosphate concentration. The rates of [Ca2+]mincrease and recovery were dependent on the extramitochondrial [Na+] ([Na+]em) due to Ca2+extrusion via mitochondrial Na+/Ca2+exchanger. The maximal rate of Ca2+extrusion was observed with [Na+]emin the range of 20–40 mM. Rapid switching (0.25–1 Hz) of [Ca2+]embetween 0 and 100 μM simulated rapid beat-to-beat changes in [Ca2+]i(with [Ca2+]itransient duration of 100–500 ms). No [Ca2+]moscillations were observed, either under conditions of maximal rate of Ca2+uptake (100 μM [Ca2+]em, 0 [Na+]em) or with maximal rate of Ca2+removal (0 [Ca2+]em, 40 mM [Na+]em). The slow frequency-dependent increase of [Ca2+]margues against a rapid transmission of Ca2+signals between cytosol and mitochondria on a beat-to-beat basis in the heart. [Ca2+]mchanges elicited by continuous or pulsatile exposure to elevated [Ca2+]emshowed no difference in mitochondrial Ca2+uptake. Thus in cardiac myocytes fast [Ca2+]itransients are integrated by mitochondrial Ca2+transport systems, resulting in a frequency-dependent net mitochondrial Ca2+accumulation.

The relationship between intracellular [Ca(2+)] and Ca(2+) wave characteristics in permeabilised cardiomyocytes from the rabbit

Spontaneous sarcoplasmic reticulum (SR) Ca(2+) release and propagated intracellular Ca(2+) waves are a consequence of cellular Ca(2+) overload in cardiomyocytes. We examined the relationship between average intracellular [Ca(2+)] and Ca(2+) wave characteristics. The amplitude, time course and propagation velocity of Ca(2+) waves were measured using line-scan confocal imaging of beta-escin-permeabilised cardiomyocytes perfused with 10 microM Fluo-3 or Fluo-5F. Spontaneous Ca(2+) waves were evident at cellular [Ca(2+)] > 200 nM. Peak [Ca(2+)] during a wave was 2.0-2.2 microM; the minimum [Ca(2+)] between waves was 120-160 nM; wave frequency was approximately 0.1 Hz. Raising mean cellular [Ca(2+)] caused increases in all three parameters, particularly Ca(2+) wave frequency. Increases in the rate of SR Ca(2+) release and Ca(2+) uptake were observed at higher cellular [Ca(2+)], indicating calcium-sensitive regulation of these processes. At extracellular [Ca(2+)] > 2 microM, the mean [Ca(2+)] inside the permeabilised cell did not increase above 2 microM. This extracellular-intracellular Ca(2+) gradient could be maintained for periods of up to 5 min before the cardiomyocyte developed a sustained and irreversible hypercontraction. Inclusion of mitochondrial inhibitors (2 microM carbonyl cyanide m-chlorophenylhydrazone and 2 microM oligomycin) while perfusing with > 2 microM Ca(2+) abolished the extracellular-intracellular Ca(2+) gradient through the generation of Ca(2+) waves with a higher peak [Ca(2+)] compared to control conditions. Under these conditions, cardiomyocytes rapidly (< 2 min) developed a sustained and irreversible contraction. These results suggest that mitochondrial Ca(2+) uptake acts to delay an increase in [Ca(2+)] by blunting the peak of the Ca(2+) wave.

Beat-to-beat oscillations of mitochondrial [Ca2+] in cardiac cells

The Ca2+-sensitive photoprotein aequorin and the new green fluorescent protein-based fluorescent Ca2+ indicators 'ratiometric-pericam' were selectively expressed in the mitochondria, cytosol and/or nucleus of spontaneously beating ventricular myocytes from neonatal rats. This combined strategy reveals that mitochondrial [Ca2+] oscillates rapidly and in synchrony with cytosolic and nuclear [Ca2+]. The Ca2+ oscillations were reduced in frequency and/or amplitude by verapamil and carbachol and were enhanced by isoproterenol and elevation of extracellular [Ca2+]. An increased frequency and/or amplitude of cytosolic Ca2+ spikes was rapidly mirrored by similar changes in mitochondrial Ca2+ spikes and more slowly by elevations of the interspike Ca2+ levels. The present data unequivocally demonstrate that in cardiac cells mitochondrial [Ca2+] oscillates synchronously with cytosolic [Ca2+] and that mitochondrial Ca2+ handling rapidly adapts to inotropic or chronotropic inputs.

Calcium signal transmission between ryanodine receptors and mitochondria

Control of energy metabolism by increases of mitochondrial matrix [Ca(2+)] ([Ca(2+)](m)) may represent a fundamental mechanism to meet the ATP demand imposed by heart contractions, but the machinery underlying propagation of [Ca(2+)] signals from ryanodine receptor Ca(2+) release channels (RyR) to the mitochondria remains elusive. Using permeabilized cardiac (H9c2) cells we investigated the cytosolic [Ca(2+)] ([Ca(2+)](c)) and [Ca(2+)](m) signals elicited by activation of RyR. Caffeine, Ca(2+), and ryanodine evoked [Ca(2+)](c) spikes that often appeared as frequency-modulated [Ca(2+)](c) oscillations in these permeabilized cells. Rapid increases in [Ca(2+)](m) and activation of the Ca(2+)-sensitive mitochondrial dehydrogenases were synchronized to the rising phase of the [Ca(2+)](c) spikes. The RyR-mediated elevations of global [Ca(2+)](c) were in the submicromolar range, but the rate of [Ca(2+)](m) increases was as large as it was in the presence of 30 microm global [Ca(2+)](c). Furthermore, RyR-dependent increases of [Ca(2+)](m) were relatively insensitive to buffering of [Ca(2+)](c) by EGTA. Therefore, RyR-driven rises of [Ca(2+)](m) appear to result from large and rapid increases of perimitochondrial [Ca(2+)]. The falling phase of [Ca(2+)](c) spikes was followed by a rapid decay of [Ca(2+)](m). CGP37157 slowed down relaxation of [Ca(2+)](m) spikes, whereas cyclosporin A had no effect, suggesting that activation of the mitochondrial Ca(2+) exchangers accounts for rapid reversal of the [Ca(2+)](m) response with little contribution from the permeability transition pore. Thus, rapid activation of Ca(2+) uptake sites and Ca(2+) exchangers evoked by RyR-mediated local [Ca(2+)](c) signals allow mitochondria to respond rapidly to single [Ca(2+)](c) spikes in cardiac cells.

Mitochondrial calcium in heart cells: beat-to-beat oscillations or slow integration of cytosolic transients?

Mitochondria have been implicated in intracellular Ca2+ signaling in many cell types. The inner mitochondrial membrane contains Ca2+-transporting proteins, which catalyze Ca2+ uptake and extrusion. Intramitochondrial (matrix) Ca2+, in turn, regulates the activity of Krebs cycle dehydrogenases and, ultimately, the rate of ATP synthesis. In the myocardium, controversy remains whether the fast cytosolic Ca2+ transients underlying excitation-contraction coupling in beating cells are rapidly transmitted into the matrix compartment or slowly integrated by the mitochondrial Ca2+ transporters. This mini-review critically summarizes the recent experimental work in this field.

Role of mitochondria in calcium regulation of spontaneously contracting cardiac muscle cells

Mitochondrial involvement in the regulation of cytosolic calcium concentration ([Ca2+]i) in cardiac myocytes has been largely discounted by many authors. However, recent evidence, including the results of this study, has forced a reappraisal of this role. [Ca2+]i and Ca2+ in the mitochondria ([Ca2+]m) were measured in this study with specific fluorescent probes, fluo-3 and di-hydro-rhod-2, respectively; mitochondrial membrane potential (DeltaPsim) was monitored with JC-1. Addition of uncouplers or inhibitors of the mitochondrial respiratory chain was found to cause a twofold decrease in the rate of removal of Ca2+ from the cytosol after a spontaneously generated Ca2+ wave. These agents also caused a progressive elevation of [Ca2+]i, an increase in the number of hotspots of Ca2+ release (Ca2+ sparks), and depression of mitochondrial potential. The Ca2+-indicative fluorophore dihydro-rhod-2 has a net positive charge that contributes to selective accumulation by mitochondria, as supported by its co-localization with other mitochondrial-specific probes (MitoTracker Green). Treatment of dihydro-rhod-2-loaded cells with NaCN resulted in rapid formation of "black holes" in the otherwise uniformly banded pattern. These are likely to represent individual or small groups of mitochondria that have depressed mitochondrial potential, or have lost accumulated rhod-2 and/or Ca2+; all of these eventualities are possible upon onset of the mitochondrial permeability transition. Release of Ca2+ from the sarcoplasmic reticulum and the resultant spontaneous contractility of cardiac muscle are proposed to be triggered by the induction of the mitochondrial permeability transition and the subsequent loss of [Ca2+]m.

Cytosolic and mitochondrial Ca2+ signals in patch clamped mammalian ventricular myocytes

1. Ventricular myocytes isolated from ferret or cat were loaded with the acetoxymethyl ester form of indo-1 (indo-1 AM) such that approximately 75% of cellular indo-1 was mitochondrial. The intramitochondrial indo-1 concentration was 0.5-2 mM. 2. Myocytes were also voltage clamped (membrane capacitance, Cm = 100 pF) and a typical wash-out time constant of cytosolic indo-1 by a patch pipette was found to be approximately 300 s. Depolarizations to +110 mV produced graded and progressive cellular Ca2+ load via Na(+)-Ca2+ exchange. 3. During these relatively slow Ca2+ transients, cell contraction (delta L) paralleled fluorescence ratio signals (R) such that delta L could be used as a bioassay of cytosolic [Ca2+] ([Ca2+]c), where [Ca2+]CL is the inferred signal which is delayed by approximately 200 ms from true [Ca2+]c. 4. In myocytes without Mn2+ quench, the kinetics of the total cellular indo-1 signal, delta R (including cytosolic and mitochondrial components), match delta L during stimulations at low basal [Ca2+]i. However, after progressive Ca2+ loading, delta R kinetics deviate from delta L dramatically. The deviation can be completely blocked by a potent mitochondrial Ca2+ uniport blocker, Ru360. 5. When cytosolic indo-1 is quenched by Mn2+, initial moderate stimulation triggers contractions (delta L), but no change in indo-1 signal, indicating both the absence of cytosolic Ca(2+)-sensitive indo-1 and unchanged mitochondrial [Ca2+] (delta [Ca2+]m). Subsequent stronger stimulation evoked larger delta L and also delta R. The threshold [Ca2+]c for mitochondrial Ca2+ uptake was 300-500 nM, similar to that without Mn2+ quench. 6. At high Ca2+ loads where delta [Ca2+]m is detected, the time course of [Ca2+]m was different from that of [Ca2+]c. Peak [Ca2+]m after stimulation has an approximately 1 s latency with respect to [Ca2+]c, and [Ca2+]m decline is extremely slow. 7. Upon a Ca2+ influx which increased [Ca2+]c by 0.4 microM and [Ca2+]m by 0.2 microM, total mitochondrial Ca2+ uptake was approximately 13 mumol (1 mitochondria)-1. 8. With Mn2+ quench of cytosolic indo-1, there was no mitochondrial uptake of Mn2+ until the point at which mitochondrial Ca2+ uptake became apparent. However, after mitochondrial Ca2+ uptake starts, mitochondria continually take up Mn2+ even during relaxation, when [Ca2+]c is low. 9. It is concluded that mitochondria in intact myocytes do not take up detectable amounts of Ca2+ during individual contractions, unless resting [Ca2+]c exceeds 300-500 nM. At high cell Ca2+ loads and [Ca2+]c, mitochondrial Ca2+ transients occur during the twitch, but with much slower kinetics than those of [Ca2+]c.

Changes in cell-to-cell electrical coupling associated with left ventricular hypertrophy

The impedance to current flow in the intracellular compartment of guinea pig left ventricular myocardium was measured at 20 degrees C and 37 degrees C using tissue from hypertrophied hearts subjected to aortic constriction. Alternating current of varying frequency was passed longitudinally along myocardial preparations, which revealed two time constants: one attributed to the surface membrane at the ends of the preparation and a second lying in the intracellular pathway. The longitudinal impedance was quantitatively analyzed in terms of a parallel intracellular and extracellular pathway; the former had two series components, one attributable to the sarcoplasm and the other to the low-resistance junctions between adjacent cells. This interpretation was consistent (1) with control experiments using n-heptanol, which increased the component attributed to intercellular junctions but not sarcoplasmic resistivity, and (2) with suspensions of isolated myocytes, which yielded a similar value for the sarcoplasmic resistivity. Aortic constriction increased the heart weight-to-body weight ratio of experimental animals from a mean value of 3.10 +/- 0.28 to 5.05 +/- 0.83 g/kg after 50 days of constriction and 5.60 +/- 0.95 g/kg after 150 days of constriction. An increase of heart weight-to-body weight ratio at 150 days of constriction was associated with an increased intracellular resistivity, which could be attributed solely to an increase of the junctional resistance between adjacent cells by approximately 44% at 20 degrees C and 140% at 37 degrees C; the sarcoplasmic resistivity was unchanged. The results are discussed in terms of altered conduction in hypertrophied myocardium as a possible basis for arrhythmias in this tissue.

Passive Ca buffering and SR Ca uptake in permeabilized rabbit ventricular myocytes

Passive Ca binding was measured with a Ca-selective minielectrode in suspensions of permeabilized rabbit ventricular myocytes equilibrated with 5 microM thapsigargin and 30 microM ruthenium red to prevent sarcoplasmic reticulum (SR) or mitochondrial Ca uptake. Passive Ca binding was obtained by titration of the myocytes with Ca and subtraction of Ca binding in a blank titration without myocytes. Passive Ca binding could be described by a Michaelis binding curve with two sites: K1 = 0.42 microM n1 = 1.27 nmol/mg cell protein and K2 = 79 microM, n2 = 4.13 nmol/mg cell protein. The passive Ca buffering over the physiological Ca concentration was approximately twice the value expected from the values compiled by Fabiato [A. Fabiato. Am. J. Physiol. 245 (Cell Physiol. 14): C1-C14, 1983]. The maximal SR Ca uptake in the presence of 30 microM ruthenium red was fit by an uptake curve with a maximal uptake of 5.16 nmol/mg cell protein and a K 1/2 of 1.0 microM. In the presence of 5 microM thapsigargin and no ruthenium red, a significant Ca uptake attributed to mitochondria was measured between 10 and 100 microM free Ca. Rapid changes in free Ca concentration ([Ca]) measured with a Ca electrode were slower than simultaneous measurements of free [Ca] with indo-1 in permeabilized myocytes. However, oxalate, which buffers Ca and maximizes SR Ca uptake, increased the uptake rate and eliminated the difference in free [Ca] measured with Ca electrode and indo-1. This suggests that spatial gradients of [Ca] exist in permeabilized myocytes without Ca buffering. The new estimates of the buffering of intracellular Ca in cardiac myocytes should be valuable in developing quantitative insights into cardiac Ca regulation.

Ca2+ cycling between sarcoplasmic reticulum and mitochondria in rabbit cardiac myocytes

1. Shortening and intracellular Ca2+ (Ca2+i) transients were measured in isolated rabbit ventricular myocytes during paired contractures induced by rapid application of 10 mM caffeine. 2. Caffeine-induced contractures relax despite maintained presence of caffeine. In control solution, a second phasic caffeine contracture failed to appear, unless the sarcoplasmic reticulum (SR) was refilled by a series of electrically stimulated twitches during the interval between caffeine exposures. 3. The relaxation of caffeine-induced contractures in 0 Na(+)-0 Ca2+ solution has previously been shown to rely on mitochondrial Ca2+ uptake and sarcolemmal Ca2(+)-ATPase. Thus, a second caffeine contracture (T2) while still in 0 Na(+)-0 Ca2+ was greatly reduced compared to the first one (T1). However, the amplitude of T2 increased exponentially with the time interval, attaining a maximum of approximately 50% of T1 for an interval of 180-300 s, with a time constant (tau) of 41.2 s. Similar results were found for Ca2+i transients (tau = 45 s). 4. Inhibition of the mitochondrial Ca2+ uptake by the oxidative phosphorylation uncoupler, FCCP during T1 dramatically depressed T2. On the other hand, inhibition of the sarcolemmal Ca2(+)-ATPase (by increasing extracellular Ca2+ concentration, [Ca2+]o) resulted in increase of T2. Spermine inclusion during T1 also increased T2, possibly by an increase of mitochondrial Ca2+ uptake. 5. We conclude that Ca2+ taken up by mitochondria during the decline of T1 moves back to the SR after caffeine is removed, with a tau approximately 40 s. 6. Partial intracellular Na+ depletion by prolonged (3 min) perfusion with 0 Na(+)-0 Ca2+ solution before T1 (a) accelerated relaxation and [Ca2+]i decline during T1, and (b) slowed, but did not abolish, the recovery of T2 as the interval was increased. This effect was particularly pronounced when choline was used instead of Li+ as the Na+ substitute. 7. We further conclude that the mitochondrial Na(+)-Ca2+ antiporter influences the rate of net Ca2+ uptake by mitochondria and is also important in Ca2+ efflux from mitochondria during rest.

Potentiation of contraction as related to changes in free and total intracellular calcium

In voltage-clamped guinea-pig ventricular myocytes, we studied the potentiation of contraction in dependence on the concentration of intracellular calcium; ionized calcium [Ca2+]c was measured by Indo-1 microfluospectroscopy and total calcium (sigma Ca) by electronprobe microanalysis (EPMA). After a 15 min rest period, [Ca2+]c was approx. 90 nM and sigma Ca was below the detection limit (80 microM) in myoplasm (sigma Ca(myo)), junctional sarcoplasmic reticulum (sigma CaSR) and mitochondria (sigma Ca(Mito)). Post rest, repetitive clamp steps (1 Hz) potentiated extent and rate of shortening by 300%. In the literature, post-rest potentiation is attributed to the replenishment of SR with releasable calcium; by EPMA the postulated increase in sigma CaSR was measured directly. Post-rest, the peaks of systolic [Ca2+]c transients increased, however only by 40%. In addition, a moderate increase of end-diastolic [Ca2+]c was measured. In an other series of experiments, contraction was potentiated by 800% increase by means of paired voltage-clamp pulses (1 Hz, 36 degrees C, 2 mM [Ca2+]o). In the potentiated state, end-diastolic [Ca2+]c was 180 nM and sigma Ca(myo) was 0.65 mM. During systole, [Ca2+]c peaked within 20 ms to 950 nM. sigma Ca(myo) rose within 20 ms to 1.4 mM and fell within 40 ms to 1.1 and within 90 ms to 0.8 mM. In contrast, the time course of contraction was slow and peaked at a time (130 ms) when the [Ca2+]c and sigma Ca(myo) transients were finished. We suggest that Ca2+ bound to troponin C (TnC) controls only the onset but not the time course of myofilament interaction. From [Ca2+]c and sigma Ca(myo) we estimated a Ca2+ buffering capacitance of 1.5 mmol sigma Ca(myo) per pCa change, only a fraction of which can be attributed to Ca2+ binding sites on TnC. A model explaining the results requires the assumption of 0.6 mM additional slow, high affinity Ca2+ sites and 2 mM fast, low affinity Ca2+ sites. We discuss that end-diastolic Ca2+ binding to these sites contributes to the potentiation of contraction. Junctional SR. At the end of diastole sigma CaSR was 2.4 mM which is 4 times larger than sigma Ca(myo). This difference disappeared 20 ms after depolarization (sigma CaSR 1.1 mM), within another 20 ms it largely recovered (sigma CaSR 2.0 mM). These properties suggest that the junctional SR is a compartment suitable not only for Ca2+ release but also for rapid Ca2+ reuptake. Mitochondria. Paired-pulse potentiation increased end-diastolic sigma Ca(Mito) significantly (0.4 mM).(ABSTRACT TRUNCATED AT 400 WORDS)

The formation of free radicals by cardiac myocytes under oxidative stress and the effects of electron-donating drugs

The interaction of myoglobin with H2O2 leads via a two-electron oxidation process to the formation of ferryl myoglobin. Metmyoglobin is more readily activated than oxymyoglobin to the ferryl states, which are capable of inducing peroxidative damage to membranes. E.p.r. and optical spectroscopic studies show that the thiol-containing compounds N-(2-mercaptopropionyl) glycine and N-acetylcysteine and the trihydroxamate desferrioxamine attenuate these processes by reducing the ferryl myoglobin species to metmyoglobin, with the formation of thiyl radicals and the desferrioxamine nitroxide radical respectively. Biochemical investigations of the potential for myoglobin in ruptured myocytes to be involved in radical generation, when under oxidative stress, and of the nature of the resulting species, were also undertaken. E.p.r. spectroscopic studies revealed the formation of a radical species which is capable of inducing membrane lipid peroxidation. The interaction of the thiol compounds and desferrioxamine with components of myocardial tissue under these conditions results in the generation of thiol-derived radical species and the desferrioxamine nitroxide radical respectively. These data, along with those obtained using optical spectrocopy, support the assignment of the identity of the radical species generated from the myocytes as the ferryl myoglobin radical.

Total and free myoplasmic calcium during a contraction cycle: x-ray microanalysis in guinea-pig ventricular myocytes

1. At 36 degrees C and 2 mM [Ca2+]o single guinea-pig ventricular myocytes were voltage clamped with patch electrodes. With a paired-pulse protocol applied at 1 Hz, a first pulse to +5 mV was followed by a second pulse to +50 mV. When paired pulsing had potentiated the contraction to the maximum, the cells were shock-frozen for electron-probe microanalysis (EPMA). Shock-freezing was timed at the end of diastole (-80 mV) or at different times during systole (+5 mV). 2. The same paired-pulse protocol was applied to another group of myocytes from which contraction and [Ca2+]i was estimated by microfluospectroscopy (50 microM-Na5-Indo-1). Potentiation moderately reduced diastolic sarcomere length from 1.85 to 1.82 microns and increased diastolic [Ca2+]i from about 95 to 180 nM. In potentiated cells, during the first pulse, contraction peaked within 128 +/- 25 ms after start of depolarization. [Ca2+]i peaked within 25 ms to 890 +/- 220 nM (mean +/- S.E.M.) and fell within 100 ms to about 450 nM. 3. Sigma Camyo, the total calcium concentration in the overlapping myofilaments (A-band), was measured by EPMA in seventeen potentiated myocytes. During diastole, sigma Camyo was 2.6 +/- 0.4 mmol (kg dry weight (DW]-1 which can be converted to 0.65 mM (mmoles per litre myofibrillar space). Since [Ca2+]i was 180 nM, we estimate that 99.97% of total calcium is bound. 4. A time course for systolic sigma Camyo was determined by shock-freezing thirteen cells at different times after start of depolarization to +5 mV. Sigma Camyo was 5.5 +/- 0.3 mmol (kg DW)-1 (1.4 mM) after 15-25 ms, 4.6 +/- 0.5 mmol (kg DW)-1 (1.1 mM) after 30-45 ms, and 3.1 mmol (kg DW)-1 (0.8 mM) after 60-120 ms. The fast time course of sigma Camyo suggests that calcium binds to and unbinds from troponin C at a fast rate. Hence, it is the slow kinetics of the cross-bridges that determines the 130 ms time-to-peak shortening. 5. Mitochondria of potentiated cells contained during diastole a total calcium concentration, sigma Camito, of 1.3 +/- 0.2 mmol (kg DW)-1 (0.4 mM). During the initial 15-25 ms of systole, sigma Camito did not change, however, during 30-45 ms sigma Camito rose to 3.7 +/- 0.5 mmol (kg DW)-1 (1.2 mM). The data suggest that sigma Camito can follow sigma Camyo with some delay, thereby participating in both slow diastolic and fast systolic changes in total calcium (sigma Ca), at least under the given conditions.(ABSTRACT TRUNCATED AT 400 WORDS)

Interaction of intracellular ion buffering with transmembrane-coupled ion transport

The role of the Na/Ca exchanger in the control of cellular excitability and tension development is a subject of current interest in cardiac physiology. It has been suggested that this coupled transporter is responsible for rapid changes in intracellular calcium activity during single beats, generation of plateau currents, which control action potential duration, and control of intracellular sodium during Na/K pump suppression, which may occur during terminal states of ischemia. The actual behavior of this exchanger is likely to be complex for several reasons. First, the exchanger transports two ionic species and thus its instantaneous flux rate depends on both intracellular sodium and calcium activity. Secondly, the alteration in intracellular calcium activity, which is caused by a given transmembrane calcium flux, and which controls the subsequent exchanger rate, is a complex function of available intracellular calcium buffering. The buffers convert the ongoing transmembrane calcium fluxes into changes in activity that are a small and variable fraction of the change in total calcium concentration. Using a number of simple assumptions, we model changes in intracellular calcium and sodium concentration under the influence of Na/Ca exchange, Na/K ATPase and Ca-ATPase pumps, and passive sodium and calcium currents during periods of suppression and reactivation of the Na/K ATPase pump. The goal is to see whether and to what extent general notions of the role of the Na/Ca exchanger used in planning and interpreting experimental studies are consistent with its function as derived from current mechanistic assumptions about the exchanger. We find, for example, that based on even very high estimates of intracellular calcium buffering, it is unlikely that Na/Ca exchange alone can control intracellular sodium during prolonged Na/K pump blockade. It is also shown that Na/Ca exchange can contaminate measurements of Na/K pump currents under a variety of experimental conditions. The way in which these and other functions are affected by the dissociation constants and total capacity of the intracellular calcium buffers are also explored in detail.

The contribution of mitochondrial calcium ion exchange to relaxation of tension in cardiac muscle

The possible contribution of mitochondrial Ca2+ accumulation and release to contractile phenomena has been investigated. Two intracellular fractions of Ca2+ sequestration can be identified in cardiac myocytes, one ascribed to mitochondria. Two modes of Ca2+ transport exist within the mitochondrial fraction, one dependent upon mitochondrial respiration and the other upon extramitochondrial [Na+]. Experiments with trabeculae show that under appropriate conditions, the rate of relaxation and the amount of tension developed is dependent on these two modes of Ca2+ transport. A model is presented quantifying the contribution of the mitochondria to relaxation.

Non-mitochondrial calcium ion regulation in rat ventricular myocytes

Ca2+ exchange has been measured in a suspension of rat ventricular myocytes treated with digitonin or saponin to render the sarcolemma permeable to small molecules and ions. Two fractions of exchange were identified, one that was attributed to the mitochondrial component of the cell and the other to a non-mitochondrial fraction. Mitochondrial Ca2+ uptake was blocked by sodium azide and depended on respiratory substrates whereas non-mitochondrial uptake occurred independently of these molecules but was dependent on ATP and creatine phosphate. Non-mitochondrial Ca2+ uptake could be induced at a Ca2+ concentration below 1 microM and the initial rate increased with concentration up to 100 microM. Uptake could be reversed by sulmazole (a caffeine-like substance) and this reversal in turn inhibited by ryanodine. These properties suggest that the major locus for non-mitochondrial Ca2+ exchange is at the sarcoplasmic reticulum. Ca2+ exchange could be modulated by a number of agents, including carnosine, but was unaffected by others, including Na+, inositol trisphosphate and cyclic AMP. A kinetic model of the data is presented, which incorporates similar data of Ca2+ uptake into the mitochondrial fraction. The rates of Ca2+ exchange measured in these experiments suggest that these two components of the cell can reduce the sarcoplasmic Ca2+ concentration rapidly enough to account for the observed transient nature of the isometric twitch. Furthermore, it is suggested that both non-mitochondrial and mitochondrial fractions of the cell could significantly contribute to tension relaxation in rat cardiac muscle.

Caffeine contracture in guinea-pig ventricular muscle and the effect of extracellular sodium ions

1. The mechanisms underlying the virtual absence of caffeine contracture in guinea-pig heart in a Na+-rich external solution were reinvestigated in small (50-120 microns thick) bundles of intact and skinned papillary muscle fibres. 2. In Na+-free solution, the peak tension of 30 mM-caffeine contracture corresponded to the maximum tension of the skinned fibres, and was independent of changes in [Ca2+]o and [K+]o. In the presence of external Na+, the peak tension, which was at most several per cent of the maximum, was affected by [Ca2+]o, [Na+]o and [K+]o, and enhanced by Mn2+ and Ni2+. 3. In the absence of Ca2+, replacement of Na+ with K+ allowed caffeine to evoke a large contracture, showing that there was sufficient calcium stored in the cells under Na+-rich conditions. After treatment with 30 mM-caffeine in the Na+-rich, Ca2+-free solution, and upon replacement of all Na+ with Li+, caffeine was still able to produce a large contracture, which was dependent upon Ca2+ pre-loading of the cells before the first caffeine treatment and upon the subsequent duration in the Na+-free solution. 4. Replacement of Li+ with Na+ during the contracture led to rapid relaxation which was delayed by an increase in [Ca2+]o, depolarization by K+, and addition of La3+ and Mn2+. After Na+-induced complete relaxation in the absence of Ca2+, upon removal of the drugs and Na+, subsequent application of caffeine to the cells evoked a large contracture without Ca2+ reloading. 5. In the skinned fibres, 30 mM-caffeine increased the Ca2+ sensitivity of the contractile system and depressed the maximum tension. An increase in Na+ from 8.4 to 58.4 mM altered neither Ca2+ sensitivity nor the rate of tension development in the absence or presence of caffeine. 6. Increase in Na+ affected neither the rate nor the amount of Ca2+ uptake by the sarcoplasmic reticulum (SR) in the absence or presence of caffeine. Increasing Na+ slightly inhibited the caffeine-induced Ca2+ release from the SR, but more than 10 mM-caffeine produced SR Ca2+ depletion. 7. In the presence of a strong Ca2+ buffer, the steady level of Ca2+ uptake by the SR with 1 mM-caffeine was equal to the amount of Ca2+ remaining in the SR just after the application of caffeine, indicating that Ca2+ release was not inactivated.(ABSTRACT TRUNCATED AT 400 WORDS)

The effects of cyanide on intracellular ionic exchange in ferret and rat ventricular myocardium

The effects of cyanide on Ca2+ exchange in isolated ventricular myocytes and on the intracellular concentrations of Ca2+, Na+ and H+ have been investigated to assess the contribution that mitochondria might play in cellular Ca2+ metabolism. Ionic levels were measured with ion-selective electrodes. KCN (2.5 mM) inhibited a component of Ca2+ exchange in myocytes that could be attributed to mitochondrial exchange, but was without effect on non-mitochondrial Ca2+ exchange. NaCN (2.5 mM) caused a transient reduction of [H+]i, [Na+]i and [Ca2+]i when applied to the superfusate bathing ventricular trabeculae or papillary muscles. The transient changes of [Na+]i were accentuated when the preparation was exposed to a solution which would be expected to increase the cellular calcium content. The reduction of [Na+]i which accompanies a reduction of the extracellular sodium concentration, [Na]o, was attenuated in the presence of NaCN, but the intracellular acidosis resulting from a reduction of [Na]o was unaffected by NaCN. A small, but significant, rise of [Ca2+]i accompanied a reduction of [Na]o but only when NaCN was present in the superfusate. It is concluded that cyanide ions have a reasonably specific action on cardiac cellular ionic metabolism. Its primary action is to prevent mitochondrial Ca2+ sequestration. It is postulated that a Na+/H+ exchange, possibly at the sarcolemma, could account for some of the changes to sarcoplasmic ionic levels observed. In a solution of low [Na]o, it is concluded that mitochondria could sequester at least 30% of the calcium accumulated by the cell even though the sarcoplasmic [Ca2+] does not exceed 0.3 microM.

Characterization of the effects of Ca2+ on the intramitochondrial Ca2+-sensitive enzymes from rat liver and within intact rat liver mitochondria

The regulatory properties of the Ca2+-sensitive intramitochondrial enzymes (pyruvate dehydrogenase phosphate phosphatase, NAD+-isocitrate dehydrogenase and 2-oxoglutarate dehydrogenase) in extracts of rat liver mitochondria appeared to be essentially similar to those described previously for other mammalian tissues. In particular, the enzymes were activated severalfold by Ca2+, with half-maximal effects at about 1 microM-Ca2+ (K0.5 value). In intact rat liver mitochondria incubated in a KCl-based medium containing 2-oxoglutarate and malate, the amount of active, non-phosphorylated, pyruvate dehydrogenase could be increased severalfold by increasing extramitochondrial [Ca2+], provided that some degree of inhibition of pyruvate dehydrogenase kinase (e.g. by pyruvate) was achieved. The rates of 14CO2 production from 2-oxo-[1-14C]glutarate at non-saturating, but not at saturating, concentrations of 2-oxoglutarate by the liver mitochondria (incubated without ADP) were similarly enhanced by increasing extramitochondrial [Ca2+]. The rates and extents of NAD(P)H formation in the liver mitochondria induced by non-saturating concentrations of 2-oxoglutarate, glutamate, threo-DS-isocitrate or citrate were also increased in a similar manner by Ca2+ under several different incubation conditions, including an apparent 'State 3.5' respiration condition. Ca2+ had no effect on NAD(P)H formation induced by beta-hydroxybutyrate or malate. In intact, fully coupled, rat liver mitochondria incubated with 10 mM-NaCl and 1 mM-MgCl2, the apparent K0.5 values for extramitochondrial Ca2+ were about 0.5 microM, and the effective concentrations were within the expected physiological range, 0.05-5 microM. In the absence of Na+, Mg2+ or both, the K0.5 values were about 400, 200 and 100 nM respectively. These effects of increasing extramitochondrial [Ca2+] were all inhibited by Ruthenium Red. When extramitochondrial [Ca2+] was increased above the effective ranges for the enzymes, a time-dependent deterioration of mitochondrial function and ATP content was observed. The implications of these results on the role of the Ca2+-transport system of the liver mitochondrial inner membrane are discussed.

The effects of sodium, hydrogen and magnesium ions on mitochondrial calcium sequestration in adult rat ventricular myocytes

The effect of Na+, H+ and Mg2+ ions on net calcium exchange induced in digitonin-treated myocytes has been investigated. Raising the [Na] from 1.4 to 31.4 mM revealed a sodium-sensitive fraction of net calcium exchange with a K1/2 for Na+ ions of 12 mM, alongside the respiration-dependent accumulation of calcium. An acidosis, but not an alkalosis, was found to depress both of these processes. Mg2+ ions exerted an effect solely on the respiration-dependent calcium sequestration. A simple semi-empirical model based on the experimental data was formulated to assess the effects that altering sarcoplasmic [Na+] and [H+] would have on the calcium-handling properties of cardiac mitochondria. It is concluded that part of the inotropic effects of these ions could be mediated via this organelle.