The regulation of extramitochondrial free calcium ion concentration by rat liver mitochondria

The mechanism whereby rat liver mitochondria regulate the extramitochondrial concentration of free Ca(2+) was investigated. At 30 degrees C and pH7.0, mitochondria can maintain a steady-state pCa(2+) (0) (the negative logarithm of the free extramitochondrial Ca(2+) concentration) of 6.1 (0.8mum). This represents a true steady state, as slight displacements in pCa(2+) (0) away from 6.1 result in net Ca(2+) uptake or efflux in order to restore pCa(2+) (0) to its original value. In the absence of added permeant weak acid, the steady-state pCa(2+) (0) is virtually independent of the Ca(2+) accumulated in the matrix until 60nmol of Ca(2+)/mg of protein has been taken up. The steady-state pCa(2+) (0) is also independent of the membrane potential, as long as the latter parameter is above a critical value. When the membrane potential is below this value, pCa(2+) (0) is variable and appears to be governed by thermodynamic equilibration of Ca(2+) across a Ca(2+) uniport. Permeant weak acids increase, and N-ethylmaleimide decreases, the capacity of mitochondria to buffer pCa(2+) (0) in the region of 6 (1mum-free Ca(2+)) while accumulating Ca(2+). Permeant acids delay the build-up of the transmembrane pH gradient as Ca(2+) is accumulated, and consequently delay the fall in membrane potential to values insufficient to maintain a pCa(2+) (0) of 6. The steady-state pCa(2+) (0) is affected by temperature, incubation pH and Mg(2+). The activity of the Ca(2+) uniport, rather than that of the respiratory chain, is rate-limiting when pCa(2+) (0) is greater than 5.3 (free Ca(2+) less than 5mum). When the Ca(2+) electrochemical gradient is in excess, the activity of the uniport decreases by 2-fold for every 0.12 increase in pCa(2+) (0) (fall in free Ca(2+)). At pCa(2+) (0) 6.1, the activity of the Ca(2+) uniport is kinetically limited to 5nmol of Ca(2+)/min per mg of protein, even when the Ca(2+) electrochemical gradient is large. A steady-state cycling of Ca(2+) through independent influx and efflux pathways provides a model which is kinetically and thermodynamically consistent with the present observations, and which predicts an extremely precise regulation of pCa(2+) (0) by liver mitochondria in vivo.     

The regulation of extramitochondrial steady state free Ca2+ concentration by rat insulinoma mitochondria

For the study of Ca2+ handling by mitochondria of an insulin secretory tissue, a method for the isolation of functionally intact insulinoma mitochondria is described. The mitochondria had a respiratory control ratio of 6.3 +/- 0.3 with succinate as a substrate. The regulation of extramitochondrial [Ca2+]o concentration by suspensions of insulinoma mitochondria was studied using Ca2+-selective minielectrodes. The mitochondria were found to maintain an ambient free Ca2+ concentration of about 0.3 and 0.9 microM in the absence or presence of Mg2+ (1 mM), respectively. The addition of Na+ resulted in a dose-dependent (half-maximal 4 mM Na+) increase in steady state [Ca2+]o. Na+ accelerated the ruthenium red-induced Ca2+ efflux, suggesting the existence of a Ca2+/2Na+ antiporter, as described in mitochondria of excitable tissues. Experiments were performed to study the effects of various agents on the steady state extramitochondrial free Ca2+. cAMP, 3-isobutyl-1-methylxanthine, and NADH were found to have no effect, whereas phosphoenolpyruvate induced a net Ca2+ efflux, the kinetic of which suggests deleterious effects on mitochondrial functions. A small decrease in pH (0.1 unit) of the incubation buffer resulted in an increase of the extramitochondrial Ca2+ steady state that was reversible upon restoration of the pH to its initial value. In conclusion, insulinoma mitochondria were able to maintain an extramitochondrial [Ca2+]o steady state in the submicromolar range that was markedly influenced by the ionic composition of the incubation medium. Thus, mitochondria may play a role in the regulation of cellular calcium homeostasis and insulin release.     

Na+-dependent regulation of extramitochondrial Ca2+ by rat-liver mitochondria

The presence and significance of Na+-induced Ca2+ release from rat liver mitochondria was investigated by the arsenazo technique. Under the experimental conditions used, the mitochondria, as expected, avidly extracted Ca2+ from the medium. However, when the uptake pathway was blocked with ruthenium red, only a small rate of 'basal' release of Ca2+ was seen (0.3 nmol Ca2+ X min-1 X mg-1), in marked contrast to earlier reports on a rapid loss of sequestered Ca2+ from rat liver mitochondria. The addition of Na+ in 'cytosolic' levels (20 mM) led to an increase in the release rate by about 1 nmol Ca2+ X min-1 X mg-1. This effect was specific for Na+. The significance of this Na+-induced Ca2+ release, in relation to the Ca2+ uptake mechanism, was investigated (in the absence of uptake inhibitors) by following the change in the extramitochondrial Ca2+ steady-state level (set point) induced by Na+. A five-fold increase in this level, from less than 0.2 microM to more than 1 microM, was induced by less than 20 mM Na+. The presence of K+ increased the sensitivity of the Ca2+ homeostat to Na+. The effect of Na+ on the extramitochondrial level was equally well observed in an K+/organic-anion buffer as in a sucrose buffer. Liver mitochondria incubated under these circumstances actively counteracted a Ca2+ or EGTA challenge by taking up or releasing Ca2+, so that the initial level, as well as the Na+-controlled level, was regained. It was concluded that liver mitochondria should be considered Na+-sensitive, that the capacity of the Na+-induced efflux pathway was of sufficient magnitude to enable it to influence the extramitochondrial Ca2+ level biochemically and probably also physiologically, and that the mitochondria have the potential to act as active, Na+-dependent regulators of extramitochondrial ('cytosolic') Ca2+. It is suggested that changes of cytosolic Na+ could be a mediator between certain hormonal signals (notably alpha 1-adrenergic) and changes in this extramitochondrial ('cytosolic') Ca2+ steady state level.     

The regulation of cell proliferation by calcium and cyclic AMP

Calcium, in partnership with cyclic AMP, controls the proliferation of non-tumorigenic cells in vitro and in vivo. While it does not seem to be involved in the proliferative activation of cells such as hepatocytes (in vivo) or small lymphocytes (in vitro), it does control two later stages of prereplicative (G1) development. It must be one of the very many regulatory and permissive factors affecting early prereplicative development, because severe calcium deprivation reversibly arrests some types of cell early in the G1 phase of their growth-division cycle in vitro. However, calcium more specifically and much more often regulates a later (mid or late G1) stage of prereplicative development. Thus, regardless of its severity or the type of cell, calcium deprivation in vitro or in vivo reversibly stops proliferative development at that part of the G1 phase in which the cellular cyclic AMP content transiently rises and the synthesis of the four deoxyribonucleotides begins. The evidence points to calcium and the cyclic AMP surge being co-generators of the signal committing the cell to DNA synthesis. The evidence is best explained so far by the cyclic AMP surge causing a surge of calcium ions which combine with molecules of the multi-purpose, calcium-dependent, regulator protein calmodulin (CDR) somewhere between the cell surface and the cytosol. The resulting Ca-calmodulin complexes then stimulate many different (and possibly membrane-associated) enzymes such as protein kinases, one of which produces the DNA-synthetic initiator. Calcium has little or no influence on the proliferation of tumor cells. Some possible explanations of this very important loss of control are considered.     

The isolation of lymphocyte mitochondria and their regulation of extramitochondrial free Ca2+ concentration.

1. A method for the isolation of functionally intact mitochondria from lymphocytes is described. It involves digitonin breakage of the plasma membrane, followed by differential centrifugation. The yield was 36 mg of mitochondrial protein/200 g of pig mesenteric lymph node (6 mg of mitochondrial protein/10(9) lymphocytes). The mitochondrial had a respiratory-control ratio of 2--3.5 with succinate as substrate. 2. Ca2+ transport by these mitochondria was investigated. They were able to regulate the extramitochondrial free [Ca2+] very precisely, by buffering any displacements from the steady-state. The exact extramitochondrial free [Ca2+] of this steady-state depended on the conditions of incubation. In a medium designed to resemble the cytoplasmic environment, with added Ca2+, lymphocyte mitochondria maintained a steady-state free [Ca2+] of 0.63 microM (pCa of 6.2). The rates of Ca2+ uptake and efflux under these conditions, with both lymphocyte and liver mitochondria, were very much lower than those in a less complex medium. 3. Lymphocyte mitochondria were shown to possess an Na+-independent Ruthenium Red-insensitive efflux pathway similar to that of liver mitochondria. Ruthenium Red totally inhibited the electrophoretic uniporter. Although Na+ had no effect on the steady-state maintained by lymphocyte mitochondria, they were shown to possess an Na+/H+ antiporter.     

The network of calcium regulation in muscle

In this review the molecular characteristics and reaction mechanisms of different Ca(2+) transport systems associated with various membranes in muscle cells will be summarized. The following topics will be discussed in detail: a brief history of early observations concerning maintenance and regulation of cellular Ca(2+) homeostasis, characterization of the Ca(2+) pumps residing in plasma membranes and sarco(endo)plasmic reticulum, mitochondrial Ca(2+) transport, Ca(2+)-binding proteins, coordinated expression of Ca(2+) transport systems, a general background of muscle excitation-contraction coupling with emphasis to the calcium release channels of plasma membrane and sarcoplasmic reticulum, the structure and function of dihydropyridine and ryanodine receptors of skeletal and cardiac muscles, and finally their disposition in various types of muscles.     

The inhibition by fluorocitrate of rat liver mitochondrial and extramitochondrial aconitate hydratase

1. The effects of synthetic fluorocitrate were studied on: (a) the oxidation of citrate and cis-aconitate by rat liver mitochondria; (b) the activity of the aconitate hydratase found in the liver cell sap; (c) the activity of the aconitate hydratase solubilized from liver mitochondria. 2. Fluorocitrate was found to be a potent inhibitor of oxidation of citrate but only a weak inhibitor of oxidation of cis-aconitate: 6.7mum-fluorocitrate (containing 4% of the inhibitory isomer) caused 94% inhibition of the oxidation of citrate (2mm) whereas 1.0mm-fluorocitrate was necessary to provoke the same inhibition when cis-aconitate (2mm) was the substrate. The degree of inhibition varied in relation to the respiratory state of mitochondria when fluorocitrate was added. The inhibition could be partially reversed by cis-aconitate. 3. The aconitate hydratase extracted from the mitochondria was much less inhibited by fluorocitrate than was the mitochondria-bound enzyme, and the aconitate hydratase found in the cell sap was even less sensitive. 0.3mm-Fluorocitrate was required to cause 50% inhibition of the reaction citrate-->cis-aconitate, catalysed by the aconitate hydratase extracted from the mitochondria, and 1.2m-fluorocitrate for the extramitochondrial enzyme. For both enzymes the reaction citrate-->cis-aconitate was 2-3 times more sensitive to fluorocitrate than was the reaction isocitrate-->cis-aconitate. The inhibition was of the competitive type for both reactions.     

Plasma membrane calcium pump regulation by metabolic stress

The plasma membrane Ca(2+)-ATPase (PMCA) is an ATP-driven pump that is critical for the maintenance of low resting [Ca(2+)](i) in all eukaryotic cells. Metabolic stress, either due to inhibition of mitochondrial or glycolytic metabolism, has the capacity to cause ATP depletion and thus inhibit PMCA activity. This has potentially fatal consequences, particularly for non-excitable cells in which the PMCA is the major Ca(2+) efflux pathway. This is because inhibition of the PMCA inevitably leads to cytosolic Ca(2+) overload and the consequent cell death. However, the relationship between metabolic stress, ATP depletion and inhibition of the PMCA is not as simple as one would have originally predicted. There is increasing evidence that metabolic stress can lead to the inhibition of PMCA activity independent of ATP or prior to substantial ATP depletion. In particular, there is evidence that the PMCA has its own glycolytic ATP supply that can fuel the PMCA in the face of impaired mitochondrial function. Moreover, membrane phospholipids, mitochondrial membrane potential, caspase/calpain cleavage and oxidative stress have all been implicated in metabolic stress-induced inhibition of the PMCA. The major focus of this review is to challenge the conventional view of ATP-dependent regulation of the PMCA and bring together some of the alternative or additional mechanisms by which metabolic stress impairs PMCA activity resulting in cytosolic Ca(2+) overload and cytotoxicity.     

Homologous regulation of voltage-dependent calcium channels by 1,4-dihydropyridines

Chronic treatment of PC 12 cells with the 1,4-dihydropyridine Ca2+ channel antagonist nifedipine [5 x 10-8M/5 days] and the activator S Bay K 8644 [5 x 10-7 M/5 days] resulted in up- and down-regulation of 1,4-dihydropyridine binding site density by 29 and 24%, respectively, without change in affinity. These changes in binding site density represent functional changes as indicated by the corresponding changes in K+ depolarization-induced 45Ca2+ uptake and in whole cell currents carried by Ba2+ ions. This homologous regulation of voltage-dependent Ca2+ channels [VDCC] by potent and specific ligands parallels that observed for other classes of membrane receptors.     

The structural basis for the regulation of tissue transglutaminase by calcium ions.

The role of calcium ions in the regulation of tissue transglutaminase is investigated by experimental approaches and computer modeling. A three-dimensional model of the transglutaminase is computed by homology building on crystallized human factor XIII and is used to interpret structural and functional results. The molecule is a prolate ellipsoid (6.2 x 4.2 x 11 nm) and comprises four domains, assembled pairwise into N-terminal and C-terminal regions. The active site is hidden in a cleft between these regions and is inaccessible to macromolecular substrates in the calcium-free form. Protein dynamics simulation indicates that these regions move apart upon addition of calcium ions, revealing the active site for catalysis. The protein dimensions are consistent with results obtained with small-angle neutron and X-ray scattering. The gyration radius of the protein (3 nm) increases in the presence of calcium ions (3.9 nm), but it is virtually unaffected in the presence of GTP, suggesting that only calcium ions can promote major structural changes in the native protein. Proteolysis of an exposed loop connecting the N-terminal and C-terminal regions is linearly correlated with enzyme inactivation and prevents the calcium-induced conformational changes.     

Volume regulation by human lymphocytes. Role of calcium

Human peripheral blood lymphocytes regulate their volumes in hypotonic solutions. In hypotonic media in which Na+ is the predominant cation, an initial swelling phase is followed by a regulatory volume decrease (RVD) associated with a net loss of cellular K+. In media in which K+ is the predominant cation, the rapid initial swelling is followed by a slower second swelling phase. 86Rb+ fluxes increased during RVD and returned to normal when the original volume was approximately regained. Effects similar to those induced by hypotonic stress could also be produced by raising the intracellular Ca++ level. In isotonic, Ca++- containing media cells were found to shrink upon addition of the Ca++ ionophore A23187 in K+-free media, but to swell in K+-rich media. Exposure to Ca++ plus A23187 also increased 86Rb+ fluxes. Quinine (75 microM), an inhibitor of the Ca++-activated K+ pathway in other systems blocked RVD, the associated K+ loss, and the increase in 86Rb+ efflux. Quinine also inhibited the volume changes and the increased 86Rb fluxes induced by Ca++ plus ionophore. The calmodulin inhibitors trifluoperazine, pimozide and chlorpromazine blocked RVD as well as Ca++ plus A23187-induced volume changes. Trifluoperazine also prevented the increase in 86Rb+ fluxes and K+ loss induced by hypotonicity. Chlorpromazine sulfoxide, a relatively ineffective calmodulin antagonist, was considerably less potent as an inhibitor of RVD than chlorpromazine. It is suggested than an elevation in cytoplasmic [Ca++], triggered by cell swelling, increases the plasma membrane permeability to K+, the ensuing increased efflux of K+, associated anions, and osmotically obliged water, leading to cell shrinking (RVD).     

pH regulation of calcium efflux by turtle liver mitochondria

1. Turtle liver mitochondria are capable of taking up calcium in a pattern similar to that described from rat liver mitochondria. 2. Turtle liver mitochondria also possess a system for calcium efflux which is extremely sensitive to changes in extramitochondrial pH. A decrease in extramitochondrial pH by addition of HCl or by gassing with CO2 caused a rapid release of calcium. 3. The profound changes in pH and pCO2 during deep diving likely affects Ca efflux from mitochondria in the turtle liver.     

The role of phospholamban in the regulation of calcium transport by cardiac sarcoplasmic reticulum

The calcium transport mechanism of cardiac sarcoplasmic reticulum (SR) is regulated by a phosphoregulatory mechanism involving the phosphorylation-dephosphorylation of an integral membrane component, termed phospholamban. Phospholamban, a 27,000 Da proteolipid, contains phosphorylation sites for three independent protein kinases: 1) cAMP-dependent, 2) Ca²⁺-calmodulin-dependent, and 3) Ca²⁺-phospholipid-dependent. Phosphorylation of phospholamban by any one of these kinases is associated with stimulation of the calcium transport rates in isolated SR vesicles. Dephosphorylation of phosphorylated phospholamban results in the reversal of the stimulatory effects produced by the protein kinases. Studies conducted on perfused hearts have shown that during exposure to beta-adrenergic agents, a good correlation exists between the in situ phosphorylation of phospholamban and the relaxation of the left ventricle. Phosphorylation of phospholamban in situ is also associated with stimulation of calcium transport rates by cardiac SR, similar to in vitro findings. Removal of beta-adrenergic agents results in the reversal of the inotropic response and this is associated with dephosphorylation of phospholamban. These findings indicate that a phospho-regulatory mechanism involving phospholamban may provide at least one of the controls for regulation of the contractile properties of the myocardium.     

Reciprocal regulation of calcium dependent and calcium independent cyclic AMP hydrolysis by protein phosphorylation

The hydrolysis of cyclic nucleotide second messengers takes place through multiple cyclic nucleotide phosphodiesterases (PDEs). The significance of this diversification is not fully understood. Here we report the differential regulation of low K(m) Ca2+-activated (PDE1C) and Ca2+-independent, rolipram-sensitive (PDE4) PDEs by protein phosphorylation in the neuroendocrine cell line AtT20. Incubation of cells with 8-(4-chlorophenylthio)-cyclic AMP (CPT-cAMP) enhanced PDE4 and reduced PDE1C activity. These effects were blocked by H89 indicating mediation by cAMP-dependent protein kinase (PKA), furthermore in broken cell preparations PKA produced the same reciprocal changes of PDE activities. Calyculin A, an inhibitor of protein phosphatases 1 and 2 A, stimulated PDE4 and enhanced the inhibitory effect of CPT-cAMP on PDE1C. The reduction of PDE1C activity was characterized by a marked attenuation of the activation by Ca2+/calmodulin. Stimulation of PDE4 activity by CPT-cAMP or calyculin A was attributable to PDE4D3 and these effects could also be reproduced in human embryonic kidney cells expressing epitope-tagged PDE4D3. Together, these data show reciprocal regulation of PDE1C and PDE4D by PKA, which represents a novel scheme for plasticity in intracellular signalling.     

Old proteins,developing roles: The regulation of calcium channels by synaptic proteins

Coupling of presynaptic voltage-gated calcium channels to synaptic release machinery is critical for neurotransmission. It was traditionally believed that anchoring calcium channels close to the calcium micro-domain dependent release machinery was the main reason for the physical interactions between channels and synaptic proteins, however in recent years, it is becoming clear that these proteins additionally regulate channel activity, and such processes as channel targeting and alternative splicing, to orchestrate a much broader regulatory role in controlling calcium channel function, calcium influx, and hence neurotransmission. Calcium signalling serves a multitude of cellular functions and therefore requires tight regulation. Specific, often calcium-dependent interactions between synaptic proteins and calcium channels appear to play a significant role in fine-tuning of the synaptic response over development. While it is clear that investigation of a few of the multitude of synaptic proteins will not provide a complete understanding of calcium channel regulation, consideration of the emerging mechanisms by which synaptic protein interactions might regulate calcium channel function is important in order to understand their possible contributions to synaptic transmission. Here, we review the current state of knowledge of the molecular mechanisms by which synaptic proteins regulate presynaptic calcium channel activity.     

Old proteins, developing roles: The regulation of calcium channels by synaptic proteins

Coupling of presynaptic voltage-gated calcium channels to the synaptic release machinery is critical for neurotransmission. It was traditionally believed that anchoring calcium channels close to the calcium microdomain dependent release machinery was the main reason for the physical interactions between channels and synaptic proteins, however in recent years, it is becoming clear that these proteins additionally regulate channel activity, and such processes as channel targeting and alternative splicing, to orchestrate a much broader regulatory role in controlling calcium channel function, calcium influx and hence neurotransmission. Calcium signalling serves a multitude of cellular functions and therefore requires tight regulation. Specific, often calcium-dependent interactions between synaptic proteins and calcium channels appear to play a significant role in fine-tuning of the synaptic response over development. While it is clear that investigation of a few of the multitude of synaptic proteins will not provide a complete understanding of calcium channel regulation, consideration of the emerging mechanisms by which synaptic protein interactions might regulate calcium channel function is important in order to understand their possible contributions to synaptic transmission. Here, we review the current state of knowledge of the molecular mechanisms by which synaptic proteins regulate presynaptic calcium channel activity.     

Sugar transport regulation in vitro by new calcium ionophores

The influence of calcium ionophores--tenoyltrifluoroacetate (TTFA) and divaleryldibenzo-18-crown-6(divaleryl) on the glucose consumption, D-xylose transport and glycogen content in rat diaphragm was studied. TTFA caused a clear dose-dependent inhibition of carbohydrate transport and glycogenolysis stimulation. Divaleryl, on the other hand, raised glucose consumption, D-xylose transport without influencing glycogen content. Exclusion of Ca++ from incubation medium increased the TTFA inhibiting effect on glucose consumption, decreased its glycogenolytic effect and removed divaleryl induced stimulation of glucose transport. Mechanisms of calcium ionophore action and a possible role of intracellular Ca2+ in carbohydrate transport are discussed.     

Intramitochondrial and extramitochondrial free calcium ion concentrations of suspensions of heart mitochondria with very low,plausibly physiological,contents of total calcium

The 2-oxoglutarate dehydrogenase of intact rat heart mitochondria is activated by Ca²⁺, with 50% activation at approximately 0.5 nmol of total Ca/mg of mitochondrial protein, in the presence of P_i and Mg²⁺. Mitochondrial Ca contents in excess of 2 nmol/mg of protein result in 100% activation of the enzyme. Investigation of Ca²⁺ release from the mitochondria using the metallochromic indicator Arsenazo III defines aS _0.5 of 5.4±0.4 nmol of Ca/mg of protein, when the endogenous Ca content of the mitochondria is progressively depleted with EGTA, prior to the initiation of the release process being studied. The subsequent determination of matrix free Ca²⁺ concentration by the null-point technique has allowed expression of these results in terms of free concentration rather than Ca content, with an activity coefficient of approximately 0.001 for matrix Ca²⁺. From the above, Ca²⁺ efflux from heart mitochondria is not saturated at the mitochondrial Ca contents or Ca²⁺ concentrations which give effective regulation of dehydrogenase activity. A consequence is that heart mitochondria do not buffer the pCa of the extramitochondrial medium at these Ca contents (<2 nmol/mg of protein), and this is shown in direct measurements of extramitochondrial pCa. This is taken to question the physiological significance of mitochondrial buffering of cytosolic free Ca²⁺ in normal heart.