Role of phosphate and other proton-donating anions in respiration-coupled transport of Ca2+ by mitochondria

An integrative approach to the regulation of mitochondrial respiration during exercise: Focus on high-intensity exercise

During exercise, muscle ATP demand increases with intensity, and at the highest power output, ATP consumption may increase more than 100-fold above the resting level. The rate of mitochondrial ATP production during exercise depends on the availability of O₂, carbon substrates, reducing equivalents, ADP, P_i, free creatine, and Ca²⁺. It may also be modulated by acidosis, nitric oxide and reactive oxygen and nitrogen species (RONS). During fatiguing and repeated sprint exercise, RONS production may cause oxidative stress and damage to cellular structures and may reduce mitochondrial efficiency. Human studies indicate that the relatively low mitochondrial respiratory rates observed during sprint exercise are not due to lack of O₂, or insufficient provision of Ca²⁺, reduced equivalents or carbon substrates, being a suboptimal stimulation by ADP the most plausible explanation. Recent in vitro studies with isolated skeletal muscle mitochondria, studied in conditions mimicking different exercise intensities, indicate that ROS production during aerobic exercise amounts to 1-2 orders of magnitude lower than previously thought. In this review, we will focus on the mechanisms regulating mitochondrial respiration, particularly during high-intensity exercise. We will analyze the factors that limit mitochondrial respiration and those that determine mitochondrial efficiency during exercise. Lastly, the differences in mitochondrial respiration between men and women will be addressed.

Mitochondrial calcium transport and the redox nature of the calcium-induced membrane permeability transition

Mitochondria possess a Ca²⁺ transport system composed of separate Ca²⁺ influx and efflux pathways. Intramitochondrial Ca²⁺ concentrations regulate oxidative phosphorylation, required for cell function and survival, and mitochondrial redox balance, that participates in a myriad of signaling and damaging pathways. The interaction between Ca²⁺ accumulation and redox imbalance regulates opening and closing of a highly regulated inner membrane pore, the membrane permeability transition pore (PTP). In this review, we discuss the regulation of the PTP by mitochondrial oxidants, reactive nitrogen species, and the interactions between these species and other PTP inducers. In addition, we discuss the involvement of mitochondrial redox imbalance and PTP in metabolic conditions such as atherogenesis, diabetes, obesity and in mtDNA stability.

Brain mitochondrial calcium transport: Origins of the set-point concept and its application to physiology and pathology

The transport of calcium across the inner mitochondrial membrane plays a key role in neuronal physiology and pathology. The kinetic responses of the uniporter and efflux pathways are such that a cytosolic free calcium 'set-point' can be established - above which there is net calcium accumulation into the matrix that is reversed when plasma membrane transport lowers cytosolic calcium. Pathological activation of N-methyl-d-aspartate receptor mediated sodium and calcium entry into the neuron, as occurs in stroke and spreading depression, places severe demands on both the ATP-generating and calcium loading capacities of the neuronal mitochondria as the set-point is exceeded. Experiments that led to the concept of the set-point are reviewed.

Contribution of inorganic polyphosphate towards regulation of mitochondrial free calcium

BACKGROUND

Calcium signaling plays a key role in the regulation of multiple processes in mammalian mitochondria, from cellular bioenergetics to the induction of stress-induced cell death. While the total concentration of calcium inside the mitochondria can increase by several orders of magnitude, the concentration of bioavailable free calcium in mitochondria is maintained within the micromolar range by the mitochondrial calcium buffering system. This calcium buffering system involves the participation of inorganic phosphate. However, the mechanisms of its function are not yet understood. Specifically, it is not clear how calcium-orthophosphate interactions, which normally lead to formation of insoluble precipitates, are capable to dynamically regulate free calcium concentration. Here we test the hypothesis that inorganic polyphosphate, which is a polymerized form of orthophosphate, is capable to from soluble complexes with calcium, playing a significant role in the regulation of the mitochondrial free calcium concentration.

METHODS

We used confocal fluorescence microscopy to measure the relative levels of mitochondrial free calcium in cultured hepatoma cells (HepG2) with variable levels of inorganic polyphosphate (polyP).

RESULTS

The depletion of polyP leads to the significantly lower levels of mitochondrial free calcium concentration under conditions of pathological calcium overload. These results are coherent with previous observations showing that inorganic polyphosphate (polyP) can inhibit calcium-phosphate precipitation and, thus, increase the amount of free calcium.

CONCLUSIONS

Inorganic polyphosphate plays an important role in the regulation of mitochondrial free calcium, leading to its significant increase.

GENERAL SIGNIFICANCE

Inorganic polyphosphate is a previously unrecognized integral component of the mitochondrial calcium buffering system.

Dual Effect of Phosphate Transport on Mitochondrial Ca2+ Dynamics

The large inner membrane electrochemical driving force and restricted volume of the matrix confer unique constraints on mitochondrial ion transport. Cation uptake along with anion and water movement induces swelling if not compensated by other processes. For mitochondrial Ca(2+) uptake, these include activation of countertransporters (Na(+)/Ca(2+) exchanger and Na(+)/H(+) exchanger) coupled to the proton gradient, ultimately maintained by the proton pumps of the respiratory chain, and Ca(2+) binding to matrix buffers. Inorganic phosphate (Pi) is known to affect both the Ca(2+) uptake rate and the buffering reaction, but the role of anion transport in determining mitochondrial Ca(2+) dynamics is poorly understood. Here we simultaneously monitor extra- and intra-mitochondrial Ca(2+) and mitochondrial membrane potential (ΔΨm) to examine the effects of anion transport on mitochondrial Ca(2+) flux and buffering in Pi-depleted guinea pig cardiac mitochondria. Mitochondrial Ca(2+) uptake proceeded slowly in the absence of Pi but matrix free Ca(2+) ([Ca(2+)]mito) still rose to ~50 μm. Pi (0.001-1 mm) accelerated Ca(2+) uptake but decreased [Ca(2+)]mito by almost 50% while restoring ΔΨm. Pi-dependent effects on Ca(2+) were blocked by inhibiting the phosphate carrier. Mitochondrial Ca(2+) uptake rate was also increased by vanadate (Vi), acetate, ATP, or a non-hydrolyzable ATP analog (AMP-PNP), with differential effects on matrix Ca(2+) buffering and ΔΨm recovery. Interestingly, ATP or AMP-PNP prevented the effects of Pi on Ca(2+) uptake. The results show that anion transport imposes an upper limit on mitochondrial Ca(2+) uptake and modifies the [Ca(2+)]mito response in a complex manner.

Acetate transiently inhibits myocardial contraction by increasing mitochondrial calcium uptake

Background

There is a close relationship between cardiovascular disease and cardiac energy metabolism, and we have previously demonstrated that palmitate inhibits myocyte contraction by increasing K_v channel activity and decreasing the action potential duration. Glucose and long chain fatty acids are the major fuel sources supporting cardiac function; however, cardiac myocytes can utilize a variety of substrates for energy generation, and previous studies demonstrate the acetate is rapidly taken up and oxidized by the heart. In this study, we tested the effects of acetate on contractile function of isolated mouse ventricular myocytes.

Results

Acute exposure of myocytes to 10 mM sodium acetate caused a marked, but transient, decrease in systolic sarcomere shortening (1.49 ± 0.20% vs. 5.58 ± 0.49% in control), accompanied by a significant increase in diastolic sarcomere length (1.81 ± 0.01 μm vs. 1.77 ± 0.01 μm in control), with a near linear dose response in the 1–10 mM range. Unlike palmitate, acetate caused no change in action potential duration; however, acetate markedly increased mitochondrial Ca²⁺ uptake. Moreover, pretreatment of cells with the mitochondrial Ca²⁺ uptake blocker, Ru-360 (10 μM), markedly suppressed the effect of acetate on contraction.

Conclusions

Lehninger and others have previously demonstrated that the anions of weak aliphatic acids such as acetate stimulate Ca²⁺ uptake in isolated mitochondria. Here we show that this effect of acetate appears to extend to isolated cardiac myocytes where it transiently modulates cell contraction.

Genetic deletion of the mitochondrial phosphate carrier desensitizes the mitochondrial permeability transition pore and causes cardiomyopathy

The mitochondrial phosphate carrier (PiC) is critical for ATP synthesis by serving as the primary means for mitochondrial phosphate import across the inner membrane. In addition to its role in energy production, PiC is hypothesized to have a role in cell death as either a component or a regulator of the mitochondrial permeability transition pore (MPTP) complex. Here, we have generated a mouse model with inducible and cardiac-specific deletion of the Slc25a3 gene (PiC protein). Loss of PiC protein did not prevent MPTP opening, suggesting it is not a direct pore-forming component of this complex. However, Slc25a3 deletion in the heart blunted MPTP opening in response to Ca(2+) challenge and led to a greater Ca(2+) uptake capacity. This desensitization of MPTP opening due to loss or reduction in PiC protein attenuated cardiac ischemic-reperfusion injury, as well as partially protected cells in culture from Ca(2+) overload induced death. Intriguingly, deletion of the Slc25a3 gene from the heart long-term resulted in profound hypertrophy with ventricular dilation and depressed cardiac function, all features that reflect the cardiomyopathy observed in humans with mutations in SLC25A3. Together, these results demonstrate that although the PiC is not a direct component of the MPTP, it can regulate its activity, suggesting a novel therapeutic target for reducing necrotic cell death. In addition, mice lacking Slc25a3 in the heart serve as a novel model of metabolic, mitochondrial-driven cardiomyopathy.

Mitochondrial phosphate transport during nutrient stimulation of INS-1E insulinoma cells

Here, we have investigated the role of inorganic phosphate (Pi) transport in mitochondria of rat clonal β-cells. In α-toxin-permeabilized INS-1E cells, succinate and glycerol-3-phosphate increased mitochondrial ATP release which depends on exogenous ADP and Pi. In the presence of substrates, addition of Pi caused mitochondrial matrix acidification and hyperpolarisation which promoted ATP export. Dissipation of the mitochondrial pH gradient or pharmacological inhibition of Pi transport blocked the effects of Pi on electrochemical gradient and ATP export. Knock-down of the phosphate transporter PiC, however, neither prevented Pi-induced mitochondrial activation nor glucose-induced insulin secretion. Using (31)P NMR we observed reduction of Pi pools during nutrient stimulation of INS-1E cells. Interestingly, Pi loss was less pronounced in mitochondria than in the cytosol. We conclude that matrix alkalinisation is necessary to maintain a mitochondrial Pi pool, at levels sufficient to stimulate energy metabolism in insulin-secreting cells beyond its role as a substrate for ATP synthesis.

Enhancing mitochondrial Ca2+ uptake in myocytes from failing hearts restores energy supply and demand matching

Mitochondrial ATP production is continually adjusted to energy demand through coordinated increases in oxidative phosphorylation and NADH production mediated by mitochondrial Ca2+([Ca2+]m). Elevated cytosolic Na+ impairs [Ca2+]m accumulation during rapid pacing of myocytes, resulting in a decrease in NADH/NAD+ redox potential. Here, we determined 1) if accentuating [Ca2+]m accumulation prevents the impaired NADH response at high [Na+]i; 2) if [Ca2+]m handling and NADH/NAD+ balance during stimulation is impaired with heart failure (induced by aortic constriction); and 3) if inhibiting [Ca2+]m efflux improves NADH/NAD+ balance in heart failure. [Ca2+]m and NADH were recorded in cells at rest and during voltage clamp stimulation (4Hz) with either 5 or 15 mmol/L [Na+]i. Fast [Ca2+]m transients and a rise in diastolic [Ca2+]m were observed during electric stimulation. [Ca2+]m accumulation was [Na+]i-dependent; less [Ca2+]m accumulated in cells with 15 Na+ versus 5 mmol/L Na+ and NADH oxidation was evident at 15 mmol/L Na+, but not at 5 mmol/L Na+. Treatment with either the mitochondrial Na+/Ca2+ exchange inhibitor CGP-37157 (1 micromol/L) or raising cytosolic Pi (2 mmol/L) enhanced [Ca2+]m accumulation and prevented the NADH oxidation at 15 mmol/L [Na+]i. In heart failure myocytes, resting [Na+]i increased from 5.2+/-1.4 to 16.8+/-3.1mmol/L and net NADH oxidation was observed during pacing, whereas NADH was well matched in controls. Treatment with CGP-37157 or lowering [Na+]i prevented the impaired NADH response in heart failure. We conclude that high [Na+]i (at levels observed in heart failure) has detrimental effects on mitochondrial bioenergetics, and this impairment can be prevented by inhibiting the mitochondrial Na+/Ca2+ exchanger.

Calcium and cell death: the mitochondrial connection

Physiological stimuli causing an increase of cytosolic free Ca2+ [Ca2+], or the release of Ca2+ from the endoplasmic reticulum invariably induce mitochondrial Ca2+ uptake, with a rise of mitochondrial matrix free [Ca2+] ([Ca2+]m). The [Ca2+]m rise occurs despite the low affinity of the mitochondrial Ca2+ uptake systems measured in vitro and the often limited amplitude of the cytoplasmic [Ca2+]c increases. The [Ca2+]m increase is typically in the 0.2-3 microM range, which allows the activation of Ca2(+)-regulated enzymes of the Krebs cycle; and it rapidly returns to the resting level if the [Ca2+], rise recedes due to activation of mitochondrial efflux mechanisms and matrix Ca2+ buffering. Mitochondria thus accumulate Ca2+ and efficiently control the spatial and temporal shape of cellular Ca2+ signals, yet this situation exposes them to the hazards of Ca2+ overload. Indeed, mitochondrial Ca2+, which is so important for metabolic regulation, can become a death factor by inducing opening of the permeability transition pore (PTP), a high conductance inner membrane channel. Persistent PTP opening is followed by depolarization with Ca2+ release, cessation of oxidative phosphorylation, matrix swelling with inner'membrane remodeling and eventually outer membrane rupture with release of cytochrome c and other apoptogenic proteins. Understanding the mechanisms through which the Ca2+ signal can be shifted from a physiological signal into a pathological effector is an unresolved problem of modern pathophysiology that holds great promise for disease treatment.

Instrumental role of Na+ in NMDA excitotoxicity in glucose-deprived and depolarized cerebellar granule cells

In glucose-deprived cerebellar granule cells, substitution of extracellular Na+ with Li+ or Cs+ prevented N-methyl-D-aspartate (NMDA)-induced excitotoxicity. NMDA stimulated 45Ca2+ accumulation and ATP depletion in a Na-dependent manner, and caused neuronal death, even if applied while Na,K-ATPase was inhibited by 1 mM ouabain. The cells treated with NMDA in the presence of ouabain accumulated sizable 45Ca2+ load but most of them failed to elevate cytosolic [Ca2+] upon mitochondrial depolarization. Na/Ca exchange inhibitor, KB-R7943, inhibited Na-dependent and NMDA-induced 45Ca2+ accumulation but only if Na,K-ATPase activity was compromised by ouabain. In cells energized by glucose and exposed to NMDA without ouabain, KB-R7943 reduced NMDA-elicited ionic currents by 19% but failed to inhibit 45Ca2+ accumulation. It appears that a large part of NMDA-induced Ca2+ influx in depolarized and glucose-deprived cells is mediated by reverse Na/Ca exchange. A high level of reverse Na/Ca exchange operation is maintained by a sustained Na+ influx via NMDA channels and depolarization of the plasma membrane. In cells energized by glucose, however, most Ca2+ enters directly via NMDA channels because Na,K-ATPase regenerating Na+ and K+ concentration gradients prevents Na/Ca exchange reversal. Since under these conditions Na/Ca exchange extrudes Ca2+, its inhibition destabilizes Ca2+ homeostasis.

Acidosis promotes the permeability transition in energized mitochondria: implications for reperfusion injury

We have studied the influence of pH on opening of the mitochondrial permeability transition pore (PTP) in both deenergized and energized mitochondria in the presence of Pi. In deenergized mitochondria from rat brain and heart, we observed the expected inhibition of Ca2+-induced PTP opening at increasingly acidic pH values. Unexpectedly, mitochondria energized with either electron transport complex I or complex II substrates displayed the opposite behavior, acidic pH promoting rather than inhibiting PTP opening. We show that the potentiating effect of acidic pH is due to an increased rate of Pi uptake. The data also revealed that brain mitochondria are more heterogeneous than heart or liver mitochondria in relation to onset of a permeability transition, and that this heterogeneity depends on their Pi transport capacity. Taken together, these results indicate that the inhibitory effects of acidic pH on the PTP may be overcome in situ by an increased rate of Pi uptake, and that ischemic and postischemic acidosis may worsen rather than relieve PTP-dependent tissue damage.

Quantitative evaluation of mitochondrial calcium content in rat cortical neurones following a glutamate stimulus

1. Recent observations showed that a mitochondrial Ca2+ increase is necessary for an NMDA receptor stimulus to be toxic to cortical neurones. In an attempt to determine the magnitude of the Ca2+ fluxes involved in this phenomenon, we used carbonylcyanide-p-(trifluoromethoxy)phenylhydrazone (FCCP), a mitochondrial proton gradient uncoupler, to release mitochondrial free calcium ([Ca2+]m) during and following a glutamate stimulus, and magfura-2 to monitor cytoplasmic free calcium ([Ca2+]c). 2. FCCP treatment of previously unstimulated neurones barely changed [Ca2+]c whereas when added after a glutamate stimulus it elevated [Ca2+]c to a much greater extent than did exposure to glutamate, suggesting a very large accumulation of Ca2+ in the mitochondria. 3. Mitochondrial Ca2+ uptake was dependent on glutamate concentration, whereas the changes in the overall quantity of Ca2+ entering the cell, obtained by simultaneously treating neurones with glutamate and FCCP, showed a response that was essentially all-or-none. 4. Mitochondrial Ca2+ uptake was also dependent on the nature and duration of a given stimulus as shown by comparing [Ca2+]m associated with depolarization and treatment with kainate, NMDA or glutamate. Large mitochondrial Ca2+ accumulation only occurred after a glutamate or NMDA stimulus. 5. These studies provide a method of estimating the accumulation of Ca2+ in the mitochondria of neurones, and suggest that millimolar concentrations of Ca2+ may be reached following intense glutamate stimulation. It was shown that substantially more Ca2+ enters neurones following glutamate receptor activation than is reflected by [Ca2+]c increases.

Differential cellular regulation of the mitochondrial permeability transition in an in vitro model of 1,3-dinitrobenzene-induced encephalopathy

Exposure to 1,3-dinitrobenzene (DNB) is associated with neuropathologic changes in specific brainstem nuclei, mediated by oxidative stress and mitochondrial dysfunction. The expression of Bcl-2-family proteins as a function of sensitivity to 1, 3-dinitrobenzene (DNB)-induced mitochondrial permeability transition (MPT) was examined in C6 glioma and SY5Y neuroblastoma cells. Neuroblastoma cells were 10-fold more sensitive than glioma cells to DNB-induced decreases in mitochondrial reducing potential, measured by reduction of the tetrazolium compound, 3-[4, 5-dimethylthiazol-2-yl]-2,5-diphenyltetrazolium bromide (MTT). The IC(50) values for DNB-related inhibition of MTT reduction were 107+/-25 microM in SY5Y cells and 1047+/-101 microM in C6 cells. Levels of reactive oxygen species (ROS) were increased in both SY5Y and C6 cells following DNB exposure by 4.6- and 6.0-fold above control, respectively. DNB caused abrupt depolarization of mitochondria in both neuroblastoma and glioma cells that was inhibited by trifluoperazine. The first order rate constants for mitochondrial depolarization were: C6, k=0.31+/-0.02 min(-1); SY5Y, k=0.14+/-0.01 min(-1). Onset of MPT occurred at 10-fold lower concentration of DNB in SY5Y cells than in C6 cells. The antioxidants, deferoxamine and alpha-tocopherol, effectively prevented DNB-induced MPT in C6 and SY5Y cells, suggesting involvement of ROS in the initiation of MPT. Exposure to DNB resulted in decreased cellular ATP content in SY5Y cells and efflux of mitochondrial calcium in both SY5Y and C6 cells, concurrent with onset of MPT. The expression of Bcl-2, Bcl-X(L), and Bax was evaluated in both cell types by Western blot analysis. C6 glioma cells strongly expressed Bcl-X(L) and only weakly expressed Bcl-2 and Bax, whereas SY5Y neuroblastoma cells expressed lower levels of Bcl-X(L) and higher levels of both Bcl-2 and Bax. Collectively, these results suggest that higher constitutive expression of Bcl-X(L), rather than Bcl-2, correlates with resistance to DNB-induced MPT in SY5Y and C6 cells and that differential regulation of the permeability transition pore may underlie the cell-specific neurotoxicity of DNB.

Mitochondria and neuronal survival

Mitochondria play a central role in the survival and death of neurons. The detailed bioenergetic mechanisms by which isolated mitochondria generate ATP, sequester Ca(2+), generate reactive oxygen species, and undergo Ca(2+)-dependent permeabilization of their inner membrane are currently being applied to the function of mitochondria in situ within neurons under physiological and pathophysiological conditions. Here we review the functional bioenergetics of isolated mitochondria, with emphasis on the chemiosmotic proton circuit and the application (and occasional misapplication) of these principles to intact neurons. Mitochondria play an integral role in both necrotic and apoptotic neuronal cell death, and the bioenergetic principles underlying current studies are reviewed.

Subcellular Ca2+ distribution with varying Ca2+ load in neonatal cardiac cell culture

Recent work in our laboratory has investigated and modeled subcellular calcium compartmentation and Ca2+ movement under steady-state control conditions. This experimental study is directed to the further description and quantitation of cellular calcium compartmentation patterns and movements as correlated with contraction in neonatal rat cardiac myocytes in culture under a variety of calcium loading conditions. Compartmental contents were assessed after incubations in various [Ca2+]o, 0 Na+/1 mM Ca2+, and 10 microM ouabain/1.0 mM Ca2+ test solutions. The cellular components investigated include sarcolemmal bound, sarcoplasmic reticulum (SR), and mitochondrial calcium. The results indicate that 1) sarcolemmal calcium binding is insensitive to changes in [Ca2+]o in the range tested (0.25-6.0 mM) while highly sensitive to changes in [Na+]i; 2) SR is sensitive to both changes in [Ca2+]o and [Na+]i and exhibits a maximum loading capacity of approximately 750 micromol Ca2+/kg dw; 3) in the [Ca2+]o range between 0.25 and 2.0 mM, contractile amplitude is proportional to SR content; 4) the mitochondria comprise a high-capacity calcium-containing compartment that is sensitive to changes in [Ca2+]o but does not reach saturation under the conditions tested (0.25-8.0 mM [Ca2+]o); 5) SR calcium is divided into at least two functionally discrete pools, one of which is available for release to the myofilaments during a normal ICa-triggered contraction and other of which is caffeine releasable but unavailable for release to the myofilaments during a normal triggered release; and 6) mitochondrial calcium serves as a reservoir of calcium capable of replenishing and/or augmenting SR stores with anywhere from 10% to 50% of mitochondrial calcium cycling through SR calcium compartments.

Direct high affinity modulation of connexin channel activity by cyclic nucleotides

Connexin channels mediate molecular communication between cells. However, positive identification of biological ligands that directly and noncovalently modulate their activity has been elusive. This study demonstrates a high affinity inhibition of connexin channels by the purine cyclic monophosphates cAMP and cGMP. Purified homomeric connexin-32 and heteromeric connexin-32/connexin-26 channels were inhibited by exposure to nanomolar levels of the nucleotides prior to incorporation into membranes. Access to the site of action, or affinity for the nucleotides, was greatly reduced following incorporation of the connexin channels into membranes, where inhibition required millimolar concentrations of the nucleotides. The high affinity inhibition did not occur with similar concentrations of AMP, ADP, ATP, cTMP, or cCMP. This is the first report of a direct ligand effect on connexin channel function. The high affinity and specificity of the inhibition suggest a biological role in control of connexin channels and also may lead to the application of affinity reagents to study of connexin channel structure-function.

Energetics of heart muscle contraction under high K perfusion: verapamil and Ca effects

Tension-dependent (TDH) and tension-independent heat (TIH) release were measured during single isovolumetric contractions in the arterially perfused rat ventricle. Under perfusion with 7 mM K-0.5 mM Ca, TDH showed only one component (H3), whereas TIH could be divided into two components (H1 and H2) of short evolution (similar to the classically identified activation heat) and one component (H4) of long duration (dependent on mitochondrial respiration). Under 25 mM K, TIH components (i.e., H1, H2, and H4) increased with the increase in extracellular Ca concentration ([Ca]o) from 0.5 to 4 mM, and H3 correlated with pressure at all [Ca]o, with regression parameters similar to those observed under 7 mM K. Under 25 mM K-2 mM Ca, peak pressure development (P), H1, H2, and H3, plotted against the number of beats under 0.4 microM verapamil, exponentially decreased, but H4 decreased to 5.5 +/- 2.9% in the first contraction and remained constant thereafter. Under hypoxia, P, H1, H2, and H3 progressively decreased for about six contractions, but H4 was not detectable from the second contraction. The results suggest that increasing extracellular K concentration decreases contractile economy mainly by increasing energy expenditure related to a Ca-dependent (verapamil-sensitive) mitochondrial activity that is not related to force generation.

Ion homeostasis in rat brain in vivo: intra- and extracellular [Ca2+] and [H+] in the hippocampus during recovery from short-term, transient ischemia

Changes in intra- and extracellular [Ca2+] and [H+], together with alterations in tissue PO2 and local blood flow, were measured in areas CA1 and CA3 of the hippocampus during recovery (up to 8 h) after an 8-min period of low-flow ischemia. Restoration of blood supply was followed by an immediate rise in flow and tissue PO2 above normal, with large fluctuations in both persisting for up to 4 h. In area CA1, [Ca2+]i decreased rapidly from an ischemic mean value of 30 microM to a control mean level of 73.1 nM in 20-30 min, whereas normalization of [Ca2+]e took approximately 1 h. Recovery of [Ca2+]i was accelerated by preischemic administration of a calcium antagonist, nifedipine, and a free radical scavenger, N-tert-butyl-alpha-phenylnitrone (PBN), but not by MK-801, a blocker of N-methyl-D-aspartate receptors. There was a secondary rise in [Ca2+]i in many cells beginning approximately 2 h after reperfusion. This was attenuated somewhat by PBN but not clearly influenced by either nifedipine or MK-801. Changes of [Ca2+]i in area CA3 were much smaller and slightly slower than in area CA1 and were not affected by the drugs mentioned above. In both areas CA1 and CA3, pHe and pHi fell during ischemia to an average value of 6.2, from which there was a rapid initial recovery in the first 5-10 min when blood flow was restored. Thereafter tissue pH rose slowly and did not reach control levels for approximately 1 h, and in some microareas not at all. It is concluded that (a) effective mechanisms for restoring normal [Ca2+]i remain intact after 8 min of low-flow ischemia; (b) in neurons of area CA1, some insidious change in the homeostasis of calcium triggers a secondary rise in its free cytosolic concentration, which may be causally related to activation of irreversible cell damage; and (c) the changes in [Ca2+]i and [Ca2+]e during and following 8 min of ischemia can be adequately accounted for by movements of a fixed pool of Ca between intra- and extracellular compartments, and possible mechanisms are discussed.

Calcium transport by corn mitochondria : evaluation of the role of phosphate

Mitochondria from some plant tissues possess the ability to take up Ca(2+) by a phosphate-dependent mechanism associated with a decrease in membrane potential, H(+) extrusion, and increase in the rate of respiration (AE Vercesi, L Pereira da Silva, IS Martins, CF Bernardes, EGS Carnieri, MM Fagian [1989] In G Fiskum, ed, Cell Calcium Metabolism. Plenum Press, New York, pp 103-111). The present study reexamined the nature of the phosphate requirement in this process. The main observations are: (a) Respiration-coupled Ca(2+) uptake by isolated corn (Zea mays var Maya Normal) mitochondria or carbonyl cyanide p-trifluoromethoxyphenylhydrazone-induced efflux of the cation from such mitochondria are sensitive to mersalyl and cannot be dissociated from the silmultaneous movement of phosphate in the same direction. (b) Ruthenium red-induced efflux is not affected by mersalyl and can occur in the absence of phosphate movement. (c) In Ca(2+)-loaded corn mitochondria, mersalyl causes net Ca(2+) release unrelated to a decrease in membrane potential, probably due to an inhibition of Ca(2+) cycling at the level of the influx pathway. It is concluded that corn mitochondria (and probably other plant mitochondria) do possess an electrophoretic influx pathway that appears to be a mersalyl-sensitive Ca(2+)/inorganic phosphate-symporter and a phosphate-independent efflux pathway possibly similar to the Na(2+)-independent Ca(2+) efflux mechanism of vertebrate mitochondria, because it is not stimulated by Na(+).

Subcellular distribution of energy metabolites in the pre-ischaemic and post-ischaemic perfused working rat heart

Isolated working rat hearts were subjected to 20 min of global ischaemia and either 5 min or 15 min of reperfusion. The subcellular distribution of ATP, ADP, AMP, phosphocreatine and Pi were determined before and after ischaemia by the method of non-aqueous tissue fractionation. Ventricular function and the cytosolic, mitochondrial and ATPase-associated compartmentation of metabolites were measured. After 5 min of reperfusion, only 13 +/- 9% of the pre-ischaemic contractile function was restored compared to 67 +/- 8% after 15 min reperfusion. ATP was reduced in all cellular compartments after 5 min of reperfusion but was only decreased from pre-ischaemic values in the cytosolic compartment after 15 min of reperfusion (17.1 +/- 3.9 nmol/mg vs. 4.3 +/- 1.5 nmol/mg total protein; P less than 0.05). The mitochondrial [ATP]/[ADP] was reduced from a normal value of 4.36 to 1.79 after 5 min but recovered to 4.62 after 15 min of reperfusion. Most of the Pi was located in the mitochondria or with the ATPase fraction of the cell, with only 16% of the total Pi free in the cytosol. This study indicates that the capacity of the heart to recover function may be compromised during early reperfusion by a 59% increase in mitochondrial phosphate content and during late reperfusion by a reduced cytosolic/mitochondrial concentration ratio of both ATP (from 0.85 to 0.19) and phosphocreatine (from 3.9 to 1.24).

Functional and metabolic responses of the isolated rat heart to changes in circulating inorganic phosphate concentration

Normoxic isolated rat hearts were perfused for 30 or 60 min with Krebs-Henseleit bicarbonate buffer (KHB) (in which the Pi concentration was adjusted to 0, 1.2, 2.4, or 10 mM) in both the presence and the absence of glucose as exogenous substrate. Functional performance and coronary flow were monitored throughout the perfusion period, and at its conclusion tissue high-energy phosphates (HEP), glycogen, Pi, and calcium were determined. In the presence of glucose, both developed pressure and coronary flow were significantly (P less than 0.05) reduced by perfusion with 10 mM Pi, while heart rate and energy status were unchanged. Tissue Pi levels were directly related to perfusate concentrations, with an apparent loss of 34% from hearts perfused with 0 mM Pi and a gain of 27% in hearts perfused with 10 mM Pi (which also caused a highly significant [P less than 0.01] uptake of calcium). HEP (ATP and creatine phosphate [CP]) were decreased after 60 min of perfusion with 0 mM Pi. In the absence of glucose, coronary flow was again significantly reduced by perfusion with 10 mM Pi. HEP were significantly (P less than 0.05) conserved and uptake of Pi and calcium was greater than in the presence of glucose. Equivalent free-Ca2+/normal Pi controls for the 10 mM Pi showed that the observed functional effects were not due to a lowering of perfusate free-Ca2+ by the raised Pi level. The effect on coronary flow appears to involve, primarily, a vasomotor mechanism.

Effect of dietary acid and calcium on 25-hydroxyvitamin D metabolism by chick kidney

Studies of the effects of acidosis and dietary calcium on 25-hydroxyvitamin D3 (25OHD3) metabolism were conducted utilizing assays of mitochondrial 1-hydroxylase and 24-hydroxylase activity following 96 hours of acid loading. The results showed decreased 1-hydroxylase (206 +/- 6 vs. 132 +/- 22 fmol min-1 mg/mitochondrial protein-1, p less than 0.01), augmented 24-hydroxylase (48 +/- 14 vs. 180 +/- 30 fmol min-1 mg-1, p less than 0.001) and increments in plasma calcium and phosphate following acidosis. High calcium diet also increased 24-hydroxylase activity (48 +/- 14 vs. 160 +/- 24 fmol min-1 mg-1, p less than 0.001) and plasma calcium, but decreased plasma phosphate. The extramitochondrial concentrations of calcium, potassium, and phosphate which maximally stimulated the hydroxylases in vitro were not altered by the in vivo dietary perturbations. The increments in 1-hydroxylase and 24-hydroxylase resulting from the presence of calcium, potassium, or phosphate in optimal concentrations (10(-5) M, 100 mM, and 100 mM, respectively) were changed by both acid loading and high calcium diet, decreasing in the case of 1-hydroxylase and increasing in that of 24-hydroxylase. The data indicate that the suppression of 1-hydroxylase and augmentation of 24-hydroxylase following these dietary perturbations may depend on both changed total enzyme capacity and altered enzyme sensitivity to extramitochondrial ions and are consistent with mediation by calcium of the effects of acidosis.

Intracellular sodium-calcium dissociation in early contractile failure in hypoxic ferret papillary muscles

1. Intracellular sodium activity (aNai) and intracellular calcium activity (aCai) were measured in isolated quiescent right-ventricular ferret muscle: aNai = 9.8 +/- 2.2 mM and aCai = 71 +/- 19 nM. 2. When the muscles were exposed to 10(-5) M-ouabain, aNai increased to 20.4 +/- 3.1 mM while aCai increased to 260 +/- 99 nM. Twitch tension approximately doubled. 3. During prolonged hypoxia with glucose in the perfusate, aNai and twitch tension were unchanged. 4. During prolonged hypoxia with sucrose (substrate free) in the perfusate aNai increased to 18.9 +/- 3.1 mM, but aCai did not change. Twitch tension declined by 50%. 5. The addition of 10(-5) M-ouabain to the substrate-free hypoxic perfusate caused aNai to increase to 31.6 +/- 2.8 mM and aCai to increase to 150 +/- 35 nM. Twitch tension was unchanged. 6. These data indicate that only during prolonged substrate-free hypoxia does aNai increase. Despite the increase in aNai, no change in aCai is seen, unless the sodium-potassium pump is concomitantly inhibited. The lack of rise of aCai is consistent with inhibition of the sodium-calcium exchange, although other avenues of calcium exchange cannot be excluded.

Kinetic identification of an intracellular calcium compartment sensitive to phosphate and dinitrophenol in intact isolated rabbit aorta

Previous work from this laboratory revealed the presence of at least three distinct intracellular calcium compartments in intact segments of rabbit aorta. In this study one of these intracellular compartments is shown to be sensitive to dinitrophenol and to increased extracellular phosphate. Intact aortic segments were loaded with 45Ca in bicarbonate-buffered physiologic salt solution for 1 hour, and then transferred to a flow-through chamber perfused with physiologic salt solution. Effluent from the chamber was collected for 8 hours, and 45Ca efflux curves were analyzed using compartmental analysis. When aortic segments were loaded and washed out in dinitrophenol, the slowest component of the efflux curve was less prominent; in high phosphate it was more prominent. The rate constant changes required to account for these data were primarily in the exchange between the cytosolic and slowest intracellular calcium compartment, suggesting that the slowest calcium compartment resolved during the 8-hour washout was mitochondrial. This compartment contained 5.4 +/- 3.2 nmol calcium/g wet wt. tissue. The calcium flux across its membranes was 0.32 +/- 0.04 nmol min-1g-1. Because this flux is much smaller than the plasma-membrane calcium flux, we suggest that, in normal physiological circumstances, plasma-membrane extrusion is more important for the removal of Ca from the smooth muscle cytosol than is uptake into this slow intracellular compartment.

Calcium and proton buffering and diffusion in isolated cytoplasm from Myxicola axons

Ion-selective electrodes recorded the pH (7.49 +/- 0.05, n = 8) and pCa (6.72 +/- 0.03, n = 40) in samples (approximately 1 microliter) of isolated Myxicola axoplasm mounted within 760-micron diameter plastic tubes. We determined the interactions between Ca2+ and H+ on axoplasmic buffers by microinjecting CaCl2 or HCl into the axoplasmic samples at a distance 75-125 micron from the tips of the electrodes (distance = r). When axoplasmic pH was lowered 0.97 +/- 0.095 from its resting value (measured at r = 125 micron) by injecting 4 nmol HCl, pCa dropped 0.30 +/- 0.05 (n = 6). When expressed in units of concentration, these data show that a HCl injection of approximately 4 mmol/l axoplasm increased H+ and Ca2+ activity by approximately 0.3 microM. Lowering axoplasmic pCa 2.20 +/- 0.43 (r = 75 micron) (n = 3) by injecting 40 pmol CaCl2 had only a small effect on pH. In other experiments, two Ca2+ electrodes measured the Ca2+ activity 125 and 375 micron from the site of CaCl2 injection. Evidence of Ca2+ buffering was obtained when the Ca2+ activity at these two locations was below that expected for simple Ca2+ diffusion away from the injection site. Centrifuged axoplasm (100,000 g) taken from the bottom of the centrifuge tube had a somewhat greater Ca2+ buffering capacity than that taken from the top of the tube. Electron microscopic studies of the centrifuged axoplasm showed a greater concentration of mitochondria and other axoplasmic vesicles in the bottom of the centrifuge tube. Ruthenium red (20-40 micrograms/ml) greatly reduced Ca2+ buffering. The mitochondrial inhibitors CN (2 mM) and oligomycin (a mixture of oligomycin A, B, and C, 5 micrograms/ml) also reduced Ca2+ buffering but were not as effective as ruthenium red. Axoplasm in which ATP and mitochondrial substrates were removed by dialysis was unable to lower free Ca2+ when the concentration of this ion was elevated to approximately 10 microM. In the presence of oligomycin to block mitochondrial ATPase, and with Mg2+ -ATP as the only source of energy, axoplasm lowered Ca2+ activity slowly; with succinate as the only metabolic substrate, axoplasm rapidly lowered the Ca2+ activity from approximately 10 microM to below 1 microM.

Calcium-dependent enhancement of myocardial diastolic tone and energy utilization dissociates systolic work and oxygen consumption during low sodium perfusion

The relationships and correlations among functional, metabolic, and ionic consequences of low sodium perfusion were studied in isovolumic, retrograde-aortic perfused working rat hearts by 31P nuclear magnetic resonance, oxygen consumption, and atomic absorption spectrometry. Reduction of perfusate sodium from 144 to 74, 51, 39, and 25 mM in four separate groups of hearts via lithium substitution for 15 minutes decreased cell sodium to mean values of 62, 51, 43, and 36 mumol/g dry weight, respectively (P less than 0.001 vs. control of 107). There was a transient rise and then a fall in developed pressure and a decline in phosphocreatine and adenosine triphosphate, all of which were graded and correlated with perfusate sodium (P less than 0.01 for all parameters vs. perfusate sodium). This was accompanied by a 2- to 7-fold elevation of diastolic pressure while oxygen consumption remained near control levels. All parameters except adenosine triphosphate returned toward baseline values when normal perfusate sodium was reintroduced. Although cell calcium as measured by atomic absorption spectrometry did not differ among the groups, the functional and metabolic changes did not occur if the sodium steps were performed in reduced perfusate calcium (0.08 mM). In hearts in which systolic function was obliterated by verapamil, exposure to zero sodium caused a 4-fold increase in oxygen consumption, an increase in diastolic pressure, and a reduction of high energy phosphates. In the presence of ryanodine, a specific inhibitor of sarcoplasmic reticulum calcium release, the metabolic changes did not occur, and the excess oxygen consumption in zero sodium was substantially reduced. Thus, the effect of lowered perfusate sodium in beating hearts, i.e., to dissociate oxygen consumption and systolic function, and to increase diastolic pressure and its effect in arrested hearts to increase oxygen consumption, are calcium dependent, energy consuming, and modulated by sarcoplasmic reticulum calcium cycling.

Effects of verapamil and diltiazem on acute stroke in cats

To test the effect of verapamil and diltiazem in acute stroke, three groups of mongrel cats of either sex underwent occlusion of the middle cerebral artery (MCA) via a transorbital approach under ketamine anesthesia. The first group served as controls, the second received an intravenous infusion of verapamil (0.1 microgram/kg/min), and the third received an intravenous infusion of diltiazem (0.1 to 1.0 microgram/kg/min). All drug infusions began 2 hours before MCA occlusion and continued for the remainder of the experiment. Before and for up to 24 hours after MCA occlusion, regional cerebral blood flow (rCBF), somatosensory evoked potentials (SSEP's), arterial blood gases, blood pressure, temperature, and hematocrit were measured at least every 2 hours. At the experiment's end, brains were perfused with India ink, removed, sliced, photographed for determination of nonperfused brain area, and weighed, dried, and reweighed for H2O content determination. In these studies, verapamil was associated with worsening of rCBF in ischemic regions and inappropriate increases in rCBF in nonischemic regions, indicating intracerebral steal. Diltiazem increased rCBF in marginally ischemic regions. Changes in SSEP's paralleled blood flow changes, with verapamil decreasing amplitude and conduction velocity while diltiazem slightly improved conduction in the ischemic brain. Verapamil increased the area of nonperfused brain and the content of cerebral H2O. Diltiazem-treated animals had decreased cerebral H2O content, but had a marked increase in the area of nonperfused brain, a finding associated with the high incidence of transtentorial herniation in the diltiazem-treated animals. These findings agree with in vitro studies demonstrating high sensitivity of cerebral blood vessels to calcium channel blockers. These studies further support the notion that calcium channel blockers probably affect several different classes of calcium channels, at different brain sites.

Renal preservation following severe ischemia and prophylactic calcium channel blockade

The ability of the calcium channel blocker verapamil to prevent renal ischemic damage was assessed in a randomized double blind study of 41 rats. Study animals received either intravenous verapamil or placebo prior to renal pedicle occlusion and contralateral nephrectomy. Rats receiving verapamil pretreatment demonstrated significantly greater functional preservation 48 hours after ischemia (p less than 0.005) and exhibited better overall survival rates. In this study verapamil provided protection against renal damage following ischemia.

Biochemical modeling of an autonomously oscillatory circadian clock in Euglena

Eukaryotic microorganisms, as well as higher animals and plants, display many autonomous physiological and biochemical rhythmicities having periods approximating 24 hours. In an attempt to determine the nature of the timing mechanisms that are responsible for these circadian periodicities, two primary operational assumptions were postulated. Both the perturbation of a putative element of a circadian clock within its normal oscillatory range and the direct activation as well as the inhibition of such an element should yield a phase shift of an overt rhythm generated by the underlying oscillator. Results of experiments conducted in the flagellate Euglena suggest that nicotinamide adenine dinucleotide (NAD+), the mitochondrial Ca2+-transport system, Ca2+, calmodulin, NAD+ kinase, and NADP+ phosphatase represent clock "gears" that, in ensemble, might constitute a self-sustained circadian oscillating loop in this and other organisms.

Suppression of cellular injury during the calcium paradox in rat heart by factors which reduce calcium uptake by mitochondria

Isolated Langendorff perfused rat hearts were used to study changes in the Ca, Na and K content, contractile force and the loss of cellular material during the Ca paradox. Five minutes perfusion with Ca-free solution containing 1 mM EGTA, followed by 10 min of reperfusion in 1.8 mM Ca causes irreversible contracture, K loss, increase in Na and Ca and a massive release of myoglobin and other cellular material into the perfusate (the calcium paradox). During the Ca-free perfusion the ventricles gain Na but the K content decreases slightly. The size of the Na gain appears to depend upon the buffer used and is larger in bicarbonate than in Tris. When HCO3- or H2PO4- ions are omitted from the bathing solution (in Tris, HEPES, or TES buffered salines) the adverse effects of Ca readmission are reduced. Tris buffer gives the best protection. Metabolic inhibition with FCCP (5 X 10(-7) M), or with CN-(2 X 10(-3) M) together with iodoacetic acid (2 X 10(-3) M), decreases Ca uptake during the Ca paradox and inhibits the release of cellular material. In both cases a contracture is observed. Ruthenium red (10(-4) M) does not inhibit the Ca readmission contracture but reduces the release of cellular material and the gain of Ca and Na. The results suggest that the loss of cellular constituents during the calcium paradox, is related to an active uptake of Ca by the mitochondria and may lead to massive changes in the cellular ion concentration, during Ca-repletion.

Phosphate transport, membrane potential, and movements of calcium in rat liver mitochondria

The membrane potential and calcium accumulation of mitochondria were followed by ion-specific electrodes in the presence of the proton-donor anions phosphate, acetate, glutamate, and beta-hydroxybutyrate. Phosphate was the only anion which allowed rapid and complete restoration of both the membrane potential and the steady-state extramitochondrial calcium concentration after the uptake of 100-200 nmol calcium per mg protein. If there was no influx of any proton-donor anion, the extent of calcium uptake depended on the intramitochondrial phosphate content. Both the fall of the membrane potential and the increase of the external calcium concentration brought about by a given amount of uncoupler were counteracted by phosphate transported into the mitochondria.

Effect of extracellular phosphate on Ca2+ and K+ fluxes in pancreatic islets

The idea that a lowering in cytosolic Ca2+ concentration may cause a decrease in K+ conductance in the pancreatic B-cell was tested by investigating the effect of a high extracellular phosphate concentration on 45Ca and 86Rb efflux from prelabelled rat pancreatic islets. Whether in the absence or presence of glucose, 20 mM phosphate tended to decrease 45Ca efflux. This effect was not suppressed in the absence of extracellular Ca2+, at least in glucose-deprived islets, suggesting that it may reflect a fall in cytosolic Ca2+ concentration. The administration of phosphate failed, however, to decrease 86Rb efflux from the islets. In the presence of extracellular Ca2+, 20 mM phosphate also failed to stimulate insulin release from islets perifused at low glucose concentration and inhibited insulin release stimulated by a high glucose concentration. These data indicate that the sequestration of Ca2+ in intracellular organelles and concomitant decrease in cytosolic Ca2+ concentration, as presumably provoked by a rise in extracellular phosphate concentration, is not sufficient to simulate the effect of glucose on K+ conductance.

Involvement of intracellular calcium in the phosphate efflux from mammalian nonmyelinated nerve fibers

Phosphate efflux was measured as the fractional rate of loss of radioactivity from desheathed rabbit vagus nerves after loading with radiophosphate . The effects of strategies designed to increase intracellular calcium were investigated. At the same time, the exchangeable calcium content was measured using 45Ca. Application of calcium ionophore A23187 increased phosphate efflux in the presence of external calcium in parallel with an increase in calcium content. In the absence of external calcium, there was only a late, small increase in phosphate efflux. For nerves already treated with the calcium ionophore, the phosphate efflux was sensitive to small changes in external calcium, in the range 0.2 to 2 mM calcium, whereas similar increases in calcium in absence of ionophore gave much smaller increases in phosphate efflux. Removal of external sodium (choline substitution) produced an initial increase in phosphate efflux followed by a fall. The initial increase in phosphate efflux was much larger in the presence of calcium, than in its absence. The difference was again paralleled by an increase in calcium content of the preparation, thought to be due to inhibition of Na/Ca exchange by removal of external sodium. Measurements of ATP content and ATP, ADP, phosphate and creatine phosphate ratios did not indicate significant metabolic changes when the calcium content was increased. Stimulation of phosphate efflux by an increase in intracellular calcium may be due to stimulation of phospholipid metabolism. Alternatively, it is suggested that stimulation of phosphate efflux is associated with the stimulation of calcium efflux, possibly by cotransport of calcium and phosphate.

The effect of dichloroacetate and hydroxypyruvate on the entry of 14C from [1-14C]alanine into urea in rat hepatocytes

Entry of metabolic 14CO2 into urea is shown to be decreased by dichloroacetate although the production of 14CO2 is stimulated 2-fold. Hydroxypyruvate, a product of dichloroacetate metabolism, increases the incorporation of metabolic 14CO2 into urea. It is proposed that these effects result from changes in the cytoplasmic-mitochondrial pH gradient.