Synergistic stimulation of Ca2+ uptake by glucagon and Ca2+-mobilizing hormones in the perfused rat liver. A role for mitochondria in long-term Ca2+ homoeostasis.

A perfused liver system incorporating a Ca2+-sensitive electrode was used to study the long-term effects of glucagon and cyclic AMP on the mobilization of Ca2+ induced by phenylephrine, vasopressin and angiotensin. At 1.3 mM extracellular Ca2+ the co-administration of glucagon (10 nM) or cyclic AMP (0.2 mM) and a Ca2+-mobilizing hormone led to a synergistic potentiation of Ca2+ uptake by the liver, to a degree which was dependent on the order of hormone administration. A maximum net amount of Ca2+ influx, corresponding to approx. 3800 nmol/g of liver (the maximum rate of influx was 400 nmol/min per g of liver), was induced when cyclic AMP or glucagon was administered about 4 min before vasopressin and angiotensin. These changes are over an order of magnitude greater than those induced by Ca2+-mobilizing hormones alone [Altin & Bygrave (1985) Biochem. J. 232, 911-917]. For a maximal response the influx of Ca2+ was transient and was essentially complete after about 20 min. Removal of the hormones was followed by a gradual efflux of Ca2+ from the liver over a period of 30-50 min; thereafter, a similar response could be obtained by a second administration of hormones. Dose-response measurements indicate that the potentiation of Ca2+ influx by glucagon occurs even at low (physiological) concentrations of the hormone. By comparison with phenylephrine, the stimulation of Ca2+ influx by vasopressin and angiotensin is more sensitive to low concentrations of glucagon and cyclic AMP, and can be correlated with a 20-50-fold increase in the calcium content of mitochondria. The reversible uptake of such large quantities of Ca2+ implicates the mitochondria in long-term cellular Ca2+ regulation.     

Phosphatidic acid and arachidonic acid each interact synergistically with glucagon to stimulate Ca2+ influx in the perfused rat liver.

The administration of phosphatidic acid to rat livers perfused with media containing either 1.3 mM- or 10 microM-Ca2+ was followed by a stimulation of Ca2+ efflux, O2 uptake and glucose output. The responses elicited by 100 microM-phosphatidic acid were similar to those induced by the alpha-adrenergic agonist phenylephrine. Contrary to suggestions that phosphatidic acid acts like a Ca2+-ionophore, no net influx of Ca2+ was detected until the phosphatidic acid was removed. Sequential infusions of phenylephrine and phosphatidic acid indicate that the two agents release Ca2+ from the same intracellular source. The co-administration of glucagon (or cyclic AMP) and phosphatidic acid, and also of glucagon and arachidonic acid, led to a synergistic stimulation of Ca2+ uptake of the liver, a feature similar to that observed after the co-administration of glucagon and other Ca2+-mobilizing hormones [Altin & Bygrave (1986) Biochem. J. 238, 653-661]. A notable difference, however, is that the synergistic stimulation of Ca2+ uptake induced by the co-administration of glucagon and arachidonic acid was inhibited by indomethacin, whereas that induced by glucagon and phosphatidic acid, or glucagon and other Ca2+-mobilizing agents, was not. The results suggest that the synergistic action of glucagon and arachidonic acid in stimulating Ca2+ influx is mediated by prostanoids, but that of glucagon and phosphatidic acid is evoked by a mechanism similar to that of Ca2+-mobilizing agents.     

The Ca2+-mobilizing actions of vasopressin and angiotensin differ from those of the alpha-adrenergic agonist phenylephrine in the perfused rat liver.

A Ca2+-sensitive electrode was used to study net Ca2+-flux changes induced by the administration of phenylephrine, vasopressin and angiotensin to the perfused rat liver. The studies reveal that, although the Ca2+ responses induced by vasopressin and angiotensin are similar, they are quite different from the Ca2+ fluxes induced by phenylephrine. The administration of phenylephrine is accompanied by a stimulation of a net amount of Ca2+ efflux (140 nmol/g of liver). A re-uptake of a similar amount of Ca2+ occurs only after the hormone is removed. In contrast, the administration of vasopressin or angiotensin to livers perfused with 1.3 mM-Ca2+ induces the release of a relatively small amount of Ca2+ (approx. 40 nmol/g of liver) during the first 60 s. This is followed by a much larger amount of Ca2+ uptake (70-140 nmol/g of liver) after 1-2.5 min of hormone administration, and a slow efflux or loss of a similar amount of Ca2+ over a period of 6-8 min. At lower concentrations of perfusate Ca2+ (less than 600 microM) these hormones induce only a net efflux of the ion. These results suggest that at physiological concentrations of extracellular Ca2+ the mechanism by which alpha-adrenergic agonists mobilize cellular Ca2+ is different from that involving vasopressin and angiotensin. It seems that the hormones may have quite diverse effects on Ca2+ transport across the plasma membrane and perhaps organellar membranes in liver.     

Discrete intracellular Ca2+ pools coupled to two distinct Ca2+ influx pathways in human platelets

Ca(2+) influx is an important event associated with platelet activation and regulated by the content of intracellular Ca(2+). Previous studies have suggested two different Ca(2+) pools and two Ca(2+) influx pathways exist in platelets. In the present study, we have investigated the regulation of thrombin- and thapsigargin-induced Ca(2+) entry into human platelets, using fluorescent indicators to monitor Ca(2+) mobilization and membrane potential. It was found that depletion of thapsigargin-sensitive Ca(2+) stores was coupled to Ca(2+) influx through a Ca(2+)-selective pathway. Additional release of Ca(2+) from the thapsigargin-insensitive pool by thrombin caused the opening of a nonselective cation channel.     

Synergistic stimulation of the Ca2+ influx in rat hepatocytes by glucagon and the Ca2+-linked hormones vasopressin and angiotensin II

Glucagon was added to isolated rat hepatocytes, either alone or together with vasopressin or angiotensin II, and the effects on the initial 45Ca2+ uptake rate were investigated. Addition of glucagon alone which increased cyclic AMP content of the cells slightly increased the initial 45Ca2+ uptake rate. When glucagon was added together with vasopressin or angiotensin II--both of which when added separately increase the initial 45Ca2+ uptake rate but did not affect the cellular content of cyclic AMP--the measured initial 45Ca2+ uptake rate was larger than the sum of that seen with each hormone alone. This indicates that glucagon and Ca2+-linked hormones synergistically enhanced the Ca2+ influx in rat hepatocytes. These effects of glucagon can be mimicked by dibutyryl cyclic AMP or forskolin, suggesting that cyclic AMP augments both the resting Ca2+ and the vasopressin- or angiotensin II-stimulated influx. Measurement of the initial 45Ca2+ uptake rate as a function of the extracellular Ca2+ concentration indicated that the increase in the Ca2+ influx resulting from single or combined glucagon and vasopressin administration occurred through a homogeneous population of Ca2+ gates. These hormones were found to raise both the apparent Km for external Ca2+ and the apparent Vmax of the Ca2+ influx. The maximal increase in these two parameters was observed when the two hormones were added together. This suggests that glucagon and vasopressin synergistically stimulate the same Ca2+ gating mechanism. The dose-response curves for the action of glucagon or vasopressin applied in the presence of increasing concentrations of vasopressin or glucagon, respectively, showed that each hormone increases the maximal response to the other without affecting its ED50. It is proposed that glucagon and the Ca2+-linked hormones control the cellular concentration of two intermediates which are both necessary to allow Ca2+ entry into the cells.     

Accumulation of Ca2+ induced by cytotoxic levels of menadione in the isolated, perfused rat liver

Previous studies have indicated that the presence of cytotoxic levels of menadione (2-methyl-1,4-naphthoquinone) causes rapid changes in intracellular thiol and Ca2+ homeostasis in isolated rat hepatocytes. The present investigation was undertaken to examine these effects in the intact liver. Rat livers were therefore perfused with Krebs-Henseleit buffer containing 1.3 mM Ca2+ using a single-pass mode, and the perfusate Ca2+ level was monitored with an on-line Ca2+-selective electrode. Infusion of menadione elicited an increased O2 uptake by the liver, followed by a dose-dependent decrease in the perfusate level of Ca2+. Hepatic accumulation of Ca2+ was accompanied by stimulation of cytosolic phosphorylase a activity. Cessation of menadione infusion resulted in gradual recovery of perfusate Ca2+ to base levels. Ca2+ uptake was not accompanied by decreases in reduced pyridine nucleotide or ATP levels in the liver as evidenced by measurements either during maximal Ca2+ uptake or after recovery. However, Ca2+ uptake was correlated with decreased glutathione and increased glutathione disulfide levels in the liver, both of which reversed during recovery from Ca2+ uptake. Moreover, depletion of hepatic glutathione by pretreatment with diethylmaleate resulted in increased Ca2+ uptake during menadione infusion. The amount of protein-bound mixed disulfides showed a particularly striking relationship to Ca2+ uptake, reaching a maximal level during Ca2+ uptake and reversing toward normal value during recovery from Ca2+ accumulation. The present findings suggest that menadione-induced Ca2+ uptake is due to plasma membrane dysfunction as a result of loss of protein thiol groups critical for maintaining the plasma membrane Ca2+ extrusion mechanism. Our model offers a particularly useful opportunity to study mechanisms underlying toxic disturbances in Ca2+ homeostasis in the intact liver, since Ca2+ fluxes can be monitored under conditions in which cellular control mechanisms are not obliterated by excessive toxicity.     

Stimulation of prostaglandin release by Ca2+-mobilizing agents from the perfused rat liver. A comparative study on the action of ATP, UTP, phenylephrine, vasopressin and nerve stimulation

Several Ca2+-mobilizing agents were tested for their potential to elicit the net release of prostaglandins from the isolated perfused rat liver. Among these ATP and UTP only led to an efficient stimulation of PGD2 and PGE2 synthesis. 20 microM ATP or 20 microM UTP increased the release of PGD2 8-fold and that of PGE2 2 to 3-fold. In total, at least 40 times more PGD2 than PGE2 left the liver after stimulation. The time course of prostaglandin release was similar for both nucleotides. Vasopressin had almost no effect on the release of both prostaglandins and on portal vein pressure. But phenylephrine and nerve stimulation while raising the PGD2 efflux only slightly caused an elevation of PGE2 outflow and portal pressure.     

Inositol hexakisphosphate stimulates 45Ca2+ influx in purified mitochondria from rat liver.

Inositol hexakisphosphate (InsP6) stimulates 45Ca2+ influx in purified mitochondria from rat liver. The action of InsP6 is concentration-dependent, with an apparent EC50 value of 50 microM. Stimulation of 45Ca2+ influx may follow the interaction between InsP6 and specific membrane receptors. Accordingly, [3H]InsP6 binds to specific and saturable recognition sites in purified mitochondria. These results support the view that InsP6 acts as a signal molecule to regulate the intracellular homeostasis of Ca2+.     

Roles for Ca2+ stores release and two Ca2+ influx pathways in the Fc epsilon R1-activated Ca2+ responses of RBL-2H3 mast cells.

Cross-linking the high affinity IgE receptor, Fc epsilon R1, with multivalent antigen induces inositol 1,4,5-trisphosphate [Ins(1,4,5)P3]-dependent release of intracellular Ca2+ stores, Ca2+ influx, and secretion of inflammatory mediators from RBL-2H3 mast cells. Here, fluorescence ratio imaging microscopy was used to characterize the antigen-induced Ca2+ responses of single fura-2-loaded RBL-2H3 cells in the presence and absence of extracellular Ca2+ (Ca2+o). As antigen concentration increases toward the optimum for secretion, more cells show a Ca2+ spike or an abrupt increase in [Ca2+]i and the lag time to onset of the response decreases both in the presence and the absence of Ca2+o. When Ca2+o is absent, fewer cells respond to low antigen and the lag times to response are longer than those measured in the presence of Ca2+o, indicating that Ca2+o contributes to Ca2+ stores release. Ins(1,4,5)P3 production is not impaired by the removal of Ca2+o, suggesting that extracellular Ca2+ influences Ca2+ stores release via an effect on the Ins(1,4,5)P3 receptor. Stimulation with low concentrations of antigen can lead, only in the presence of Ca2+o, to a small, gradual increase in [Ca2+]i before the abrupt spike response that indicates store release. We propose that this small, initial [Ca2+]i increase is due to receptor-activated Ca2+ influx that precedes and may facilitate Ca2+ stores release. A mechanism for capacitative Ca2+ entry also exists in RBL-2H3 cells. Our data suggest that a previously undescribed response to Fc epsilon R1 cross-linking, inhibition of Ca2+ stores refilling, may be involved in activating capacitative Ca2+ entry in antigen-stimulated RBL-2H3 cells, thus providing the elevated [Ca2+]i required for optimal secretion. The existence of both capacitative entry and Ca2+ influx that can precede Ca2+ release from intracellular stores suggests that at least two mechanisms of stimulated Ca2+ influx are present in RBL-2H3 cells.     

Noradrenaline, vasopressin and angiotensin increase Ca2+ influx by opening a common pool of Ca2+ channels in isolated rat liver cells.

The effects of the Ca2+-mobilizing hormones noradrenaline, vasopressin and angiotensin on the unidirectional influx of Ca2+ were investigated in isolated rat liver cells by measuring the initial rate of 45Ca2+ uptake. The three hormones increased Ca2+ influx, with EC50 values (concentrations giving half-maximal effect) of 0.15 microM, 0.44 nM and 0.8 nM for noradrenaline, vasopressin and angiotensin respectively. The actions of noradrenaline and angiotensin were evident within seconds after their addition to the cells, whereas the increase in Ca2+ influx initiated by vasopressin was slightly delayed (by 5-15s). The activation of Ca2+ influx was maintained as long as the receptor was occupied by the hormone. The measurement of the resting and hormone-stimulated Ca2+ influxes at different external Ca2+ concentrations revealed Michaelis-Menten-type kinetics compatible with a saturable channel model. Noradrenaline, vasopressin and angiotensin increased both Km and Vmax. of Ca2+ influx. It is proposed that the hormones increase the rate of translocation of Ca2+ through a common pool of Ca2+ channels without changing the number of available channels or their affinity for Ca2+.     

Ca2+-dependent activation of the malate-aspartate shuttle by norepinephrine and vasopressin in perfused rat liver

The role of Ca2+ in stimulation of the malate-aspartate shuttle by norepinephrine and vasopressin was studied in perfused rat liver. Shuttle capacity was indexed by measuring the changes in both the rate of production of glucose from sorbitol and the ratio of lactate to pyruvate during the oxidation of ethanol. (T. Sugano et al. (1986) Amer. J. Physiol. 251, E385-E392). Asparagine (0.5 mM), but not alanine (0.5 mM) decreased the ethanol-induced responses. Norepinephrine and vasopressin had no effect on the ethanol-induced responses when the liver was perfused with sorbitol or glycerol. In the presence of 0.25 mM alanine, norepinephrine, vasopressin, and A23187 decreased the ethanol-induced responses that occurred with the increase of flux of Ca2+. In liver perfused with Ca2+-free medium, asparagine also decreased the ethanol-induced responses, but norepinephrine and vasopressin had no effect. Aminooxyacetate inhibited the effects of norepinephrine, A23187, and asparagine. Regardless of the presence or absence of perfusate Ca2+, the combination of glucagon and alanine had no effect on the ethanol-induced responses. Norepinephrine caused a decrease in levels of alpha-ketoglutarate, aspartate, and glutamate in hepatocytes incubated with Ca2+. The present data suggest that the redistribution of cellular Ca2+ may activate the efflux of aspartate from mitochondria in rat liver, resulting in an increase in the capacity of the malate-aspartate shuttle.     

Connexin 43 hemichannels mediate the Ca2+ influx induced by extracellular alkalinization

Although alkaline pH is known to trigger Ca(2+) influx in diverse cells, no pH-sensitive Ca(2+) channel has been identified. Here, we report that extracellular alkalinization induces opening of connexin 43 hemichannels (Cx43 HCs). Increasing extracellular pH from 7.4 to 8.5, in the presence of physiological Ca(2+)/Mg(2+) concentrations, rapidly increased the ethidium uptake rate and open probability of HCs in Cx43 and Cx43EGFP HeLa transfectants (HeLa-Cx3 and HeLa-Cx43EGFP, respectively) but not in parental HeLa cells (HeLa-parental) lacking Cx43 HCs. The increase in ethidium uptake induced by pH 8.5 was not affected by raising the extracellular Ca(2+) concentration from 1.8 to 10 mM but was inhibited by a connexin HC inhibitor (La(3+)). Probenecid, a pannexin HC blocker, had no effect. Extracellular alkalinization increased the intracellular Ca(2+) levels only in cells expressing HCs. The above changes induced by extracellular alkalinization did not change the cellular distribution of Cx43, suggesting that HC activation occurs through a gating mechanism. Experiments on cells expressing a COOH-terminal truncated Cx43 mutant indicated that the effects of alkalinization on intracellular Ca(2+) and ethidium uptake did not depend on the Cx43 C terminus. Moreover, purified dephosphorylated Cx43 HCs reconstituted in liposomes were Ca(2+) permeable, suggesting that Ca(2+) influx through Cx43 HCs could account for the elevation in intracellular Ca(2+) elicited by extracellular alkalinization. These studies identify a membrane pathway for Ca(2+) influx and provide a potential explanation for the activation of cellular events induced by extracellular alkalinization.     

Desensitization of the Ca2+-mobilizing system to serum growth factors by Ha-ras and v-mos.

An elevation of the intracellular pH and a rise in the cytoplasmic Ca2+ concentration are considered important mitogenic signals which are observed after stimulation by various growth factors. In a preceding report it was demonstrated that the expression of Ha-ras or v-mos in cells transfected with Ha-ras or v-mos, respectively, leads to an activation of the Na+/H+ antiporter and a concomitant rise in intracellular pH (W. Doppler, R. Jaggi, and B. Groner, Gene 54:145-151, 1987). This report describes the effect of the Ha-ras and v-mos oncogenes on intracellular Ca2+ release. The expression of Ha-ras in NIH 3T3 cells carrying a glucocorticoid-inducible transforming Ha-ras gene caused a desensitization of the Ca2+-mobilizing system to serum growth factors. The induction of p21ras in cells carrying the corresponding glucocorticoid-inducible proto-oncogene did not affect the Ca2+ response to growth factors. Conditions leading to the expression of the transforming Ha-ras gene but not those causing the induction of the normal Ha-ras gene yielded an increase in phosphatidylinositol turnover and a concomitant rise in inositol phosphates. Results similar to those obtained with the transforming Ha-ras gene were seen after the expression of v-mos. The data are consistent with a mechanism in which expression of the transforming Ha-ras gene leads to a release of Ca2+ from intracellular stores via elevated levels of inositol trisphosphate.     

Phosphate and calcium uptake by mitochondria and by perfused rat liver induced by the synergistic action of glucagon and vasopressin.

Co-administration of glucagon and vasopressin to rat liver perfused with buffer containing 1.3 mM-Ca2+ induces a 4-fold increase in Pi in the subsequently isolated mitochondria (from approx. 9 to approx. 40 nmol/mg of mitochondrial protein). This increase is not attributable to PPi hydrolysis, and is not observed if the perfusate Ca2+ is lowered from 1.3 mM to 50 microM. The increase in mitochondrial Pi closely parallels that of mitochondrial Ca2+; when the increase in Pi and Ca2+ accumulation is maximal, the molar ratio is close to that in Ca3(PO4)2. Measurement of changes in the perfusate Pi revealed that, whereas administration of glucagon or vasopressin alone brought about a rapid decline in perfusate Pi, the largest decrease (reflecting net retention of Pi by the liver) was observed when the hormone was co-administered in the presence of 1.3 mM-Ca2+. The synergistic action of glucagon plus vasopressin was nullified by lowering the perfusate Ca2+ to 50 microM. The data provide evidence that, whereas glucagon may be able to alter Pi fluxes directly in intact liver, any alterations induced by vasopressin are indirect and result only from its action of mobilizing Ca2+.     

Effect of pH and Ca2+ on the retention of Ca2+ by rat liver mitochondria.

A transient Ca²⁺ release from preloaded mitochondria can be induced by a sudden decrease in the pH of the outer medium from 8.0 or 7.4 to 6.8. In the presence of inorganic phosphate the released Ca²⁺ is not taken up again. Upon Ca²⁺ addition to respiring mitochondria the mitochondrial membrane potential (Δ♀) decreases to a new resting level. A further decrease in Δ♀ occurs after the decrease in pH from 7.4 to 6.8, concomitant with the reuptake phase of the Ca²⁺ release. Phosphate, EGTA, and ruthenium red restore Δ♀ to its initial level. If phosphate is present initially, only transient changes in Δ♀ occur upon addition of Ca²⁺ or H⁺ ions. Only a small transient change in Δ♀ upon H⁺ ion addition is seen in the absence of accumulated Ca²⁺. La³⁺, a competitive inhibitor of Ca²⁺ transport, prevents the H⁺ ion-induced Ca²⁺ efflux, whereas this is not the case in the presence of the noncompetitive inhibitor ruthenium red. Ruthenium red, however, prevents the reuptake phase. Mg²⁺, an inhibitor of the surface binding of Ca²⁺, has no or only a slight effect on the H⁺ ion-induced Ca²⁺ release. Mitochondria preloaded with Ca²⁺ release a small fraction of Ca²⁺ during the subsequent uptake of another pulse of Ca²⁺. The results indicate that at least one pool of mitochondrial Ca²⁺ exists in a mobile state. The possible existence of a $\text{H}{}^{\mathrm{+}}\text{Ca}{}^{\mathrm{2+}}$ exchanger in the mitochondrial membrane is discussed.     

Stimulation by alpha-adrenergic agonists of Ca2+ fluxes, mitochondrial oxidation and gluconeogenesis in perfused rat liver.

Glucose output from perfused livers of 48 h-starved rats was stimulated by phenylephrine (2 microM) when lactate, pyruvate, alanine, glycerol, sorbitol, dihydroxyacetone or fructose were used as gluconeogenic precursors. Phenylephrine-induced increases in glucose output were immediately preceded by a transient efflux of Ca2+ and a sustained increase in oxygen uptake. Phenylephrine decreased the perfusate [lactate]/[pyruvate] ratio when sorbitol or glycerol was present, but increased the ratio when alanine, dihydroxyacetone or fructose was present. Phenylephrine induced a rapid increase in the perfusate [beta-hydroxybutyrate]/[acetoacetate] ratio and increased total ketone-body output by 40-50% with all substrates. The oxidation of [1-14C]octanoate or 2-oxo[1-14C]glutarate to 14CO2 was increased by up to 200% by phenylephrine. All responses to phenylephrine infusion were diminished after depletion of the hepatic alpha-agonist-sensitive pool of Ca2+ and returned toward maximal responses after Ca2+ re-addition. Phenylephrine-induced increases in glucose output from lactate, sorbitol and glycerol were inhibited by the transaminase inhibitor amino-oxyacetate by 95%, 75% and 66% respectively. Data presented suggest that the mobilization of an intracellular pool of Ca2+ is involved in the activation of gluconeogenesis by alpha-adrenergic agonists in perfused rat liver. alpha-Adrenergic activation of gluconeogenesis is apparently accompanied by increases in fatty acid oxidation and tricarboxylic acid-cycle flux. An enhanced transfer of reducing equivalents from the cytoplasmic to the mitochondrial compartment may also be involved in the stimulation of glucose output from the relatively reduced substrates glycerol and sorbitol and may arise principally from an increased flux through the malate-aspartate shuttle.     

The ability of the mitochondrial Ca2+-binding glycoprotein to restore Ca2+ transport in glycoprotein-depleted rat liver mitochondria.

Rat liver mitochondria may be subfractionated in sediment and supernatant fractions by swelling in the presence of EDTA and oxaloacetate. The sediment is largely depleted of the Ca2+-binding glycoprotein and its Ca2+-transporting activity may be as low as 10--20% of the starting value. Both the rate of Ca2+ uptake and the capacity to maintain a high Ca2+ concentration gradient across the membrane are depressed. Addition of an osmotic supernatant to the assay mixture may partially restore the original Ca2+-transporting ability. The active component in the supernatant is the Ca2+-binding glycoprotein. This is shown by the following facts: (a) the effect is enhanced by the addition of the purified glycoprotein to the supernatant; (b) precipitation of the glycoprotein from the supernatant by affinity chromatography-purified antibodies abolishes the stimulatory effect, and (c) in the presence of 130 microM Mg2+, the glycoprotein alone may restore fully the Ca2+-transporting ability of the particles. The maximal velocity is already reached at 0.1 microgram glycoprotein/mg mitochondrial protein.     

Ca2+-mediated activation of phosphofructokinase in perfused rat heart.

Perfusion of the isolated rat heart with Ca2+ concentrations exceeding 3 mM activated phosphofructokinase and phosphorylase, and decreased the concentration of cyclic AMP. Half-maximal activation of phosphofructokinase occurred at 5 mM-CaCl2; significant activation of phosphorylase did not occur until the concentration of CaCl2 exceeded 12 mM. The time course for the activation of phosphofructokinase at 12 mM-CaCl2 indicated that maximal activation occurred within 2 min; when the perfusion-medium Ca2+ concentration was re-adjusted to 3 mM, the phosphofructokinase activity returned to pre-activation values within 30 s. The addition of Ca2+ to extracts of heart did not activate phosphofructokinase. The activation of phosphofructokinase by sub-maximal doses of adrenaline and Ca2+ were not additive. The activation of phosphofructokinase by 1 microM-adrenaline + 10 microM-propranolol and by 1 microM-isoprenaline was inhibited by high concentrations of K+ (22-56 mM). The activation of phosphofructokinase by 1 microM-adrenaline + 10 microM-propranolol, 12 mM-CaCl2 and by 1 microM-isoprenaline was blocked by the slow Ca2+-channel blocker nifedipine. These findings suggest that both the beta- and alpha-adrenergic mechanisms for the activation of rat heart phosphofructokinase involve an increase in the myoplasmic Ca2+ concentration. This increase may result from an inhibition of Ca2+ efflux or a stimulation of Ca2+ influx.     

Evidence of separate pathways for lactate uptake and release by the perfused rat heart

The simultaneous release and uptake of lactate by the heart has been observed both in vivo and ex vivo; however, the pathways underlying these observations have not been satisfactorily explained. Consequently, the purpose of this study was to test the hypothesis that hearts release lactate from glycolysis while simultaneously taking up exogenous lactate. Therefore, we determined the effects of fatty acids and diabetes on the regulation of lactate uptake and release. Hearts from control and 1-wk diabetic animals were perfused with 5 mM glucose, 0.5 mM [3-(13)C]lactate, and 0, 0.1, 0.32, or 1.0 mM palmitate. Parameters measured include perfusate lactate concentrations, fractional enrichment, and coronary flow rates, which enabled the simultaneous, but independent, measurements of the rates of 1) uptake of exogenous [(13)C]lactate and 2) efflux of unlabeled lactate from metabolism of glucose. Although the rates of lactate uptake and efflux were both similarly inhibited by the addition of palmitate, (i.e., the ratio of lactate uptake to efflux remained constant), the ratio of lactate uptake to efflux was significantly higher in the controls compared with the diabetic group (1.00 +/- 0.14 vs. 0.50 +/- 0.07, P < 0.002). These data, combined with heterogeneous (13)C enrichment of tissue lactate, pyruvate, and alanine, suggest that glycolytically derived lactate production and oxidation of exogenous lactate operate as functionally separate metabolic pathways. These results are consistent with the concept of an intracellular lactate shuttle.