Hormone-induced increase in free cytosolic calcium and glycogen phosphorylase activation in rat hepatocytes incubated in normal and low-calcium media

Intercellular calcium waves integrate hormonal control of glucose output in the intact liver

Key points

Sympathetic outflow and circulating glucogenic hormones both regulate liver function by increasing cytosolic calcium, although how these calcium signals are integrated at the tissue level is currently unknown.

We show that stimulation of hepatic nerve fibres or perfusing the liver with physiological concentrations of vasopressin only will evoke localized cytosolic calcium oscillations and modest increases in hepatic glucose production.

The combination of these stimuli acted synergistically to convert localized and asynchronous calcium responses into co‐ordinated intercellular calcium waves that spread throughout the liver lobule and elicited a synergistic increase in hepatic glucose production.

The results obtained in the present study demonstrate that subthreshold levels of one hormone can create an excitable medium across the liver lobule, which allows global propagation of calcium signals in response to local sympathetic innervation and integration of metabolic regulation by multiple hormones. This enables the liver lobules to respond as functional units to produce full‐strength metabolic output at physiological levels of hormone.

Abstract

Glucogenic hormones, including catecholamines and vasopressin, induce frequency‐modulated cytosolic Ca²⁺ oscillations in hepatocytes, and these propagate as intercellular Ca²⁺ waves via gap junctions in the intact liver. We investigated the role of co‐ordinated Ca²⁺ waves as a mechanism for integrating multiple endocrine and neuroendocrine inputs to control hepatic glucose production in perfused rat liver. Sympathetic nerve stimulation elicited localized Ca²⁺ increases that were restricted to hepatocytes in the periportal zone. During perfusion with subthreshold vasopressin, sympathetic stimulation converted asynchronous Ca²⁺ signals in a limited number of hepatocytes into co‐ordinated intercellular Ca²⁺ waves that propagated across entire lobules. A similar synergism was observed between physiological concentrations of glucagon and vasopressin, where glucagon also facilitated the recruitment of hepatocytes into a Ca²⁺ wave. Hepatic glucose production was significantly higher with intralobular Ca²⁺ waves. We propose that inositol 1,4,5‐trisphosphate (IP₃)‐dependent Ca²⁺ signalling gives rise to an excitable medium across the functional syncytium of the hepatic lobule, co‐ordinating and amplifying the metabolic responses to multiple hormonal inputs.

Sympathetic outflow and circulating glucogenic hormones both regulate liver function by increasing cytosolic calcium, although how these calcium signals are integrated at the tissue level is currently unknown.

We show that stimulation of hepatic nerve fibres or perfusing the liver with physiological concentrations of vasopressin only will evoke localized cytosolic calcium oscillations and modest increases in hepatic glucose production.

The combination of these stimuli acted synergistically to convert localized and asynchronous calcium responses into co‐ordinated intercellular calcium waves that spread throughout the liver lobule and elicited a synergistic increase in hepatic glucose production.

The results obtained in the present study demonstrate that subthreshold levels of one hormone can create an excitable medium across the liver lobule, which allows global propagation of calcium signals in response to local sympathetic innervation and integration of metabolic regulation by multiple hormones. This enables the liver lobules to respond as functional units to produce full‐strength metabolic output at physiological levels of hormone.

Taurolithocholate-induced Ca2+ release is inhibited by phorbol esters in isolated hepatocytes

The monohydroxy bile acid taurolithocholate (TLC) causes a rapid and transient increase in free cytosolic Ca2+ concentration ([Ca2+]i) in suspensions of rat hepatocytes similar to that elicited by the InsP3-dependent hormone vasopressin. The effect of the bile acid is due to a mobilization of Ca2+, independent of InsP3, from the endoplasmic reticulum (ER). Short-term preincubation of cells with the phorbol ester 4 beta-phorbol 12 beta-myristate 13 alpha-acetate (PMA), which activates protein kinase C (PKC), blocked the increase in [Ca2+]i induced by TLC, but did not alter that mediated by vasopressin. We obtained the following results, indicating that the effect of PMA is mediated by the activation of PKC. (1) Phorbol esters were effective over a concentration range where they activate PKC (IC50 = 0.5 nM); (2) phorbol esters that do not activate PKC did not inhibit the effects of TLC; (3) the permeant analogue oleoylacetylglycerol mimicked the inhibitory effect of PMA; (4) lastly, the inhibition of the TLC-induced Ca2+ mobilization by phorbol esters was partially prevented by preincubating the cells with the PKC inhibitors H7 and AMG-C16. Preincubating hepatocytes with PMA had no effect on the cell uptake of labelled TLC, indicating that the phorbol ester does not interfere with the transport system responsible for the accumulation of bile acids. In saponin-treated liver cells, PMA added before or after permeabilization failed to abolish TLC-induced Ca2+ release from the ER. The possibility is discussed that PMA, via PKC activation, may alter the intracellular binding or the transfer of bile acids in the liver.

Activation of glycogenolysis by methotrexate. Influence of calcium and inhibitors of hormone action

The influence of Ca2+ and the possible action of hormone blockers on the activation of glycogenolysis by methotrexate were investigated. Methotrexate was inactive on glycogenolysis and oxygen uptake when the liver, depleted of intracellular Ca2+, was perfused with Ca(2+)-free medium. The action of methotrexate in calcium-depleted hepatocytes could be restored by the addition of extracellular Ca2+. When Ca2+ was absent in the extracellular medium, but the intracellular stores were not depleted, methotrexate produced transient and progressively attenuated increases in glycogenolysis and oxygen uptake. Like many agonists, methotrexate produced transient increases in Ca2+ efflux. The action of methotrexate was not blocked by the antagonists of norepinephrine, phenylephrine, isoproterenol, vasopressin and angiotensin II. It was concluded that methotrexate acts through a Ca(2+)-dependent mechanism, which is similar to that of the Ca(2+)-dependent agonists. This action, however, seems not to be receptor mediated.

A novel mechanism for Ca(2+)-dependent regulation of hepatic gluconeogenesis: stimulation of mitochondrial phosphoenolpyruvate synthesis by Ca2+

1. Isolated guinea pig liver mitochondria were used to assess a possible effect of Ca2+ on the rate of phosphoenolpyruvate (PEP) synthesis. 2. PEP synthesis from 2-oxoglutarate (2-OG), but not from malate, was stimulated by [Ca2+] between 200 and 1200 nM. The effect was more pronounced at low [2-OG] (i.e. 0.1 and 0.3 mM) and it reached 58 and 22%, respectively, at 1200 nM as compared to 200 nM [Ca2+]. 3. Ruthenium red (1.8 microM) totally suppressed the stimulatory effect of Ca2+. 4. Malonate (5 mM) abolished PEP formation with 2-OG alone but inhibited only slightly the process with 2-OG + malate. 5. The results suggest that the stimulation by Ca2+ of 2-OG dehydrogenase and, therefore, of GTP synthesis, provides a mechanism for an enhanced PEP synthesis and for regulation of hepatic gluconeogenesis by Ca(2+)-mobilizing hormones.

Effect of 2-acetylaminofluorene on intracellular free Ca2+ in isolated rat hepatocytes

The effect of 2-acetylaminofluorene (2-AAF) on the intracellular free Ca2+ ([Ca2+]i) and viability of isolated rat hepatocytes has been investigated using the fluorescent probes quin 2 and propidium iodide respectively. At the highest concentration tested (224 microM), 2-AAF produces an elevation of [Ca2+]i which shows a biphasic profile. A small initial increase is observed during the first 5 min; this is followed by a considerable rise which reaches up to 2.5 times the control value at 15 min. These changes in intracellular calcium are not accompanied by detectable alterations in cell viability. In order to determine the mechanisms by which this effect of 2-AAF takes place, three calcium antagonists, namely verapamil, TMB-8 (8-(diethylamino)-octyl-3,4,5-trimethoxybenzoate) and ruthenium red (RuR), have been used. The results suggest that the first phase is dependent upon internal Ca2+ store mobilization, while the second phase seems to be related to Ca2+ entry from the extracellular space. The data obtained with RuR further indicate that mitochondria may be involved in the perturbation of calcium homeostasis caused by 2-AAF. In addition, in the experiments involving antagonists, no consistent pattern emerges that suggests a close relationship between intracellular Ca2+ levels and cell viability. The present study provides further information on the mechanisms by which these well-known hepatotoxin 2-AAF may interact with liver cells. It also shows that when these cells are exposed to a toxin, short-term changes in [Ca2+]i may not be accompanied by loss of cell viability, and conversely, that changes in cell viability may occur without alterations in [Ca2+]i.

Possible involvement of arachidonic acid metabolites of cytochrome P450 monooxygenase pathway in vasopressin-stimulated glycogenolysis in isolated rat hepatocytes

Arachidonic acid (AA) is reported to be metabolized by three major pathways, i.e., cyclooxygenase (CO), lipoxygenase (LO), and NADPH-dependent cytochrome P450 monooxygenase (MO) pathways. Monooxygenase metabolites of AA have been proposed to play an important role in hormone action in various cells. Recently it was reported that the MO pathway may exist in rat liver. The present study was carried out to investigate the role of MO metabolites in vasopressin-induced glycogenolysis in isolated rat hepatocytes. The pretreatment of isolated rat hepatocytes with eicosatetraynoic acid (ETYA), an inhibitor of CO, LO, and MO pathways, and ketoconazole and SKF 525A, inhibitors of the MO pathway, dose-dependently reduced vasopressin-induced phosphorylase activation, while the pretreatment with indomethacin, an inhibitor of the CO pathway, had no effect. The increment of cytosolic calcium concentration in vasopressin-stimulated hepatocytes was also dose-dependently decreased by ETYA, ketoconazole, and SKF 525A. In vitro addition of epoxyeicosatrienoic acid (EET) dose-dependently increased both phosphorylase a activity and cytosolic calcium concentration. 14,15-EET was the most potent among four regioisomeric EETs. These results suggest that MO metabolites of AA, most likely EETs, may be involved in vasopressin-induced glycogenolysis probably via the activation of phosphorylase by increasing the cytosolic calcium concentration.

Bile acids mobilise internal Ca2+ independently of external Ca2+ in rat hepatocytes

In the present study, we investigated the possible role of external Ca2+ in the rise of the cytosolic Ca+ concentration induced by the monohydroxy bile acid taurolithocholate in isolated rat liver cells. The results showed that: (a) the bile acid promotes the same dose-dependent increase in the cytosolic Ca+ concentration (half-maximal effect at 23 microM) in hepatocytes incubated in the presence of 1.2 mM Ca2+ or 6 microM Ca2+; (b) taurolithocholate is able to activate the Ca2(+)-dependent glycogen phosphorylase a by 6.3-fold and 6.0-fold in high and low Ca2+ media, respectively; (c) [14C]taurolithocholate influx is not affected by external Ca2+, and 45Ca2+ influx is not altered by taurolithocholate. These results establish that the effects of taurolithocholate on cell Ca2+ do not require extracellular Ca2+ and are consistent with the view that monohydroxy bile acids primarily release Ca2+ from the endoplasmic reticulum in the liver.

Calcium compartmentation and exchange rates in primary hepatocyte culture

We utilized a technique, previously used to study myocardial cells (G. A. Langer, J. S. Frank, and L. M. Nudd, 1979, Amer. J. Physiol. 237, H239-H246), to study 45Ca2+ isotope exchange kinetics in hepatocyte monolayers, cultured on scintillation disks, and perfused in a flow-through chamber. Isolated rat hepatocytes were plated directly on Primaria-coated disks impregnated with scintillation fluors which made up the walls of the perfusion chamber. Following the labeling of the cells with radioactive calcium (45Ca2+), to apparent asymptote, the washout of 45Ca2+ from the cells was measured. A large very fast turnover compartment, as well as small fast and slow turnover compartments, were identified in each experiment. Surface calcium (Ca2+) was determined by its displacement with 1 mM La3+ after asymptote had been reached during 45Ca2+ labeling (1.59 mmol Ca2+/kg dry wt). The rate constant for this compartment was faster than the washout of the chamber (greater than 3.4 min-1 with a t1/2 less than 12 s). The rate constants for the fast and slow exchangeable compartments were 0.11 min-1 (t1/2 = 6.5 min) and 0.013 min-1 (t1/2 = 56 min), respectively. The fast compartment contained 0.40 mmol Ca2+/kg dry wt and the slow compartment contained 0.27 mmol Ca2+/kg dry wt. Neither the fast nor the slow compartment was lanthanum displaceable. Release of 45Ca2+ in response to 100 microM phenylephrine, 10 nM angiotensin II, and 100-microM 2,5-ditert-butyl hydroquinone was measured during the washout phase. Ca2+ released by these compounds was determined to be 0.50 mmol 0.44, and 0.43 mmol Ca2+/kg dry cell wt, respectively. These agents had an effect only during the washout of the fast compartment. In conclusion, this novel technique of on-line measurement of 45Ca2+ exchange in hepatocyte monolayers identified three exchangeable compartments: (1) a very rapidly exchangeable surface compartment, (2) a fast "microsomal" hormone-releasable compartment, and (3) a slow, non-hormone-releasable compartment.

The measurement of Ca2+ inflow across the liver cell plasma membrane by using quin2 and studies of the roles of Na+ and extracellular Ca2+ in the mechanism of Ca2+ inflow

1. Rates of Ca2+ inflow across the hepatocyte plasma membrane in the presence of vasopressin were estimated by using quin2. 2. Plots of the rate of Ca2+ inflow as a function of the intracellular quin2 concentration reached a plateau at about 1.7 mM intracellular quin2. Ca2+ inflow was inhibited by 60% in the presence of 400 microM-verapamil. 3. A plot of the rate of Ca2+ inflow as a function of the concentration of extracellular Ca2+ ([Ca2+]o) was biphasic. The second (slower) phase showed no sign of saturation at values of [Ca2+]o up to 5 mM. It is concluded that, in the presence of vasopressin, Ca2+ flows into the liver cell by two different processes, one of which is not readily saturated by Ca2+o. 4. The effect of the replacement of extracellular NaCl by choline or tetramethylammonium chloride on cellular Ca2+ movement was found to depend on the presence or absence of intracellular quin2. 5. In cells loaded with quin2 and incubated in the presence of choline or tetramethylammonium chloride, a small decrease in the basal intracellular free Ca2+ concentration ([Ca2+]i) was observed, and the increase in [Ca2+]i caused by the addition of vasopressin was considerably diminished when compared with cells incubated in the presence of NaCl. In cells loaded with quin2, replacement of NaCl by choline chloride caused a decrease in Ca2+ inflow in the presence of vasopressin, as measured by using quin2 or 45Ca2+ exchange, whereas no change in Ca2+ inflow was observed in the absence of vasopressin. 6. In cells not loaded with quin2, replacement of NaCl by choline chloride did not alter Ca2+ inflow either in the presence or in the absence of vasopressin. 7. It is concluded that (i) Ca2+ inflow through the basal and receptor-activated Ca2+ inflow systems does not involve the inward movement of Ca2+ in exchange for Na+ or the induction of Ca2+ inflow by intracellular Na+, and (ii) the presence of both intracellular quin2 and extracellular choline or tetramethylammonium chloride (in place of NaCl) inhibits Ca2+ inflow through the receptor-activated Ca2+ inflow system but not through the basal Ca2+ inflow system, and inhibits the release of Ca2+ from intracellular stores.

Inhibition of the liver cell receptor-activated Ca2+ inflow system by metal ion inhibitors of voltage-operated Ca2+ channels but not by other inhibitors of Ca2+ inflow

The properties of the receptor-activated Ca2+ inflow system in the liver cell plasma membrane were compared with those of voltage-operated Ca2+ channels and receptor-operated Ca2+ channels present in other cell types by testing the susceptibility of the Ca2+ inflow system to inhibition by other metal ions and known inhibitors of Ca2+ movement across membranes. Co2+ inhibited Ca2+ inflow through the receptor-activated Ca2+ inflow system, as assessed by measurement of (a) the activation by extracellular Ca2+ (Cao2+) of glycogen phosphorylase in the presence of vasopressin and (b) 45Ca2+ exchange in the presence of the hormone. The concentration of Co2+ which gave half-maximal inhibition was 280 microM. The inhibition by Co2+ was reversed by high Cao2+. Co2+ did not inhibit basal Ca2+ inflow as measured by 45Ca2+ exchange in the absence of vasopressin. Zn2+, Cd2+, Ni2+ and Mn2+ each inhibited Ca2+ inflow through the receptor-activated Ca2+ inflow system. The concentrations of these ions which gave half-maximal inhibition were 10, 50, 220 and 400 microM, respectively. Little inhibition of receptor-activated Ca2+ inflow was observed in the presence of Sr2+ or Ba2+. However, substantial amounts of 90Sr2+ were taken up by hepatocytes. Rates of 90Sr2+ uptake increased from 0.5-8 nmol per min per mg wet wt. when the extracellular concentration of Sr2+ was varied from 0.25 to 2.5 mM. Sr2+ uptake was inhibited 50% by Cao2+ with half-maximal inhibition at 100 microM Cao2+, but was not inhibited by verapamil and was not stimulated by vasopressin. The movement of Ca2+ through the receptor-activated Ca2+ inflow system was not inhibited by high concentrations of each of a number of inhibitors of voltage-operated and receptor-operated Ca2+ channels and intracellular Ca2+ movement. It is concluded that while the susceptibility to inhibition by metal ions of the receptor-activated Ca2+ inflow system in the liver cell plasma membrane is similar to that of voltage-operated Ca2+ channels, there are significant differences between the liver cell receptor-activated Ca2+ inflow system and both voltage-operated Ca2+ channels and some other receptor-operated Ca2+ channels with respect to inhibition by organic compounds.

The regulation of the matrix volume of mammalian mitochondria in vivo and in vitro and its role in the control of mitochondrial metabolism

The purpose of this article is to describe briefly the methods by which the intra-mitochondrial volume may be measured both in vitro and in situ, to summarise the mechanisms thought to regulate the mitochondrial volume and then to review in more detail the evidence that changes in the intra-mitochondrial volume play an important part in the regulation of liver mitochondrial metabolism by glucogenic hormones such as glucagon, adrenaline and vasopressin. It will be shown that these hormones cause an increase in matrix volume sufficient to produce significant activation of fatty acid oxidation, respiration and ATP production, pyruvate carboxylation, citrulline synthesis and glutamine hydrolysis. These are all processes activated by such hormones in vivo. I will go on to demonstrate that the increase in matrix volume is brought about by an increase in mitochondrial [PPi]. This is able to stimulate K+ entry into the matrix, perhaps through an interaction with the adenine nucleotide translocase. The rise in matrix [PPi] is a consequence of an increase in cytosolic and hence mitochondrial [Ca2+] which inhibits mitochondrial pyrophosphatase. In the final section of the review I provide evidence that changes in mitochondrial volume may be important in the responses of a variety of tissues to hormones and other stimuli. I write as a metabolist with a working knowledge of bioenergetics rather than the converse, and this will certainly be reflected in the approach taken. If I cause offence to any dedicated experts in the field of bioenergetic by my ignorance or lack of understanding of their studies I can only offer my apologies and ask to be corrected.

Recovery of hepatocytes from attack by the pore former amphotericin B

Sublytic amounts of the pore former Amphotericin B (AmB) induced transient movements of Na and K ions across the hepatocyte plasma membranes without altering the intracellular free Ca ion concentration. The presence of 1-5 microM-AmB induced leakage of up to 80% of the intracellular K+ within 3 min, followed by Na+ entry without loss of cell viability. A repair process occurred after 3-10 min, which restored the initial cationic concentrations. Progressive binding of AmB to the cells could be observed by following the disappearance of the intense excitonic dichroic doublet of free AmB. It was shown that the amount of AmB binding, responsible for the Na+ and K+ movements, was low (approx. 16% of total AmB). The recovery process occurred when higher amounts of AmB bound to the cells, and was mediated by Na+/K+-ATPase. The c.d. spectrum of AmB bound to isolated hepatocyte plasma membranes, indicated that during this step AmB formed a complex with cholesterol, similar to that formed by the binary mixture in water.

Calcium compartmentation in isolated renal tubules in suspension

Substantial increases of total cell Ca2+ have been observed in suspensions of isolated rabbit proximal tubules subjected to hypoxic injury or treated with exogenous ATP followed by apparent recovery with reoxygenation of the hypoxic tubules or continued incubation of ATP-treated tubules. Ca2+ compartmentation studies using digitonin and metabolic inhibitors were done to clarify the basis for these changes. Digitonin, 40-90 micrograms/mg tubule protein, rapidly permeabilized the tubule cells and did not impair mitochondrial Ca2+ sequestration. Most of the increases of tubule cell Ca2+ produced by hypoxia and ATP were accounted for by pools which could be rapidly removed by exposure of tubules to EGTA and the uncoupler carbonyl cyanide m-chlorophenyl hydrazone without concomitant use of digitonin, suggesting that the changes of Ca2+ predominantly reflect sequestration by mitochondria in severely damaged cells or mitochondria already released to the medium from them. The time course of uptake followed by spontaneous release of mitochondrial Ca2+ from tubule cells deliberately permeabilized with digitonin, then incubated for prolonged periods, indicated that the decreases of tubule cell Ca2+ during reoxygenation of hypoxic suspensions and prolonged incubation of ATP-treated tubules were likely to be attributable to loss of Ca2+ from free mitochondria and those in damaged cells rather than to extrusion by intact cells.

Evidence that neomycin inhibits plasma membrane Ca2+ inflow in isolated hepatocytes

The effects of neomycin on Ca2+ fluxes and inositol polyphosphates in hepatocytes were investigated since it has been proposed that this antibiotic inhibits inositol 1,4,5-triphosphate formation in fibroblasts [D. H. Carney, D. L. Scott, E. A. Gordon and E. F. LaBelle, Cell 42, 479 (1985)]. In hepatocytes incubated at 1.3 mM extracellular Ca2+ (Ca2+o) neomycin (2 mM) inhibited 45Ca2+ exchange both in the presence or absence of vasopressin. At 1.3 mM Ca2+o, but not at higher concentrations of Ca2+o, the antibiotic (2 mM) inhibited the increase in glycogen phosphorylase a activity observed at late but not at early times after addition of vasopressin. The antibiotic also inhibited the increase in phosphorylase activity caused by the subsequent addition of 1.3 mM Ca2+o to cells previously incubated in the presence of vasopressin and in the absence of added Ca2+o. The concentration of the antibiotic (2 mM) which gave half-maximal inhibition of phosphorylase activation by vasopressin had no effect on the activation of phosphorylase by glucagon or the release of Ca2+ from intracellular stores induced by vasopressin. At a concentration of 10 mM, neomycin caused a 50% inhibition of the formation of [3H]inositol polyphosphates induced by vasopressin. It is concluded that neomycin, at concentrations which inhibit phosphoinositide-specific phospholipase C in other types of cells inhibits the inflow of Ca2+ across the plasma membrane but does not inhibit inositol trisphosphate formation in hepatocytes.

Heparin inhibits the inositol 1,4,5-trisphosphate-induced Ca2+ release from rat liver microsomes

Inositol 1,4,5-trisphosphate (Ins (1,4,5)P3)-stimulated Ca2+ release is inhibited by low concentrations of heparin (IC50 = 4.5 micrograms/ml). GTP-stimulated Ca2+ release is unaffected at a heparin concentration of 16 micrograms/ml. Addition of heparin after Ins (1,4,5)P3 causes the rapid re-uptake of Ins (1,4,5)P3-releasable Ca2+.

Comparison of the effects of [leucine]enkephalin and angiotensin on hepatic carbohydrate and cyclic nucleotide metabolism

The effects of [leucine]enkephalin and angiotensin on hepatic carbohydrate and cyclic nucleotide metabolism are compared. Both peptides stimulated glycogenolysis as a result of an increase in phosphorylase a activity and enhanced glucose synthesis from [2-14C]pyruvate, although neither had any significant effect on pyruvate kinase activity. Although the magnitudes of the effects of both peptides on glycogenolysis were comparable and unaffected by the presence of insulin. [Leu]enkephalin proved to be more efficacious in enhancing gluconeogenesis, the response being comparable with that to glucagon. Both effectors decreased the intracellular concentration of cyclic AMP in hepatocytes when incubated under control conditions and after addition of sub-optimal concentrations of glucagon. This was correlated with the ability of the two peptides to inhibit both basal and hormone-stimulated adenylate cyclase activity in purified liver plasma membranes.

Effect of the bile acid taurolithocholate on cell calcium in saponin-treated rat hepatocytes

Neomycin was used to assess the involvement of Ins (1,4,5)P3 in the Ca2+ release from the endoplasmic reticulum induced by the bile acid taurolithocholate. In saponin-permeabilized rat hepatocytes, neomycin via its ability to bind Ins (1,4,5)P3 abolished the release of Ca2+ induced by added Ins (1,4,5)P3. In contrast, it did not alter the Ca2+ release initiated by the bile acid. In intact cells, neomycin had no effect on the [Ca2+]i rises promoted by taurolithocholate and vasopressin. It is suggested that the effect of taurolithocholate in liver is not mediated by Ins (1,4,5)P3 but results from a primary action on endoplasmic reticulum.

Evidence that a pertussis-toxin-sensitive substrate is involved in the stimulation by epidermal growth factor and vasopressin of plasma-membrane Ca2+ inflow in hepatocytes

1. In hepatocytes, epidermal growth factor (EFG) (a) increased the rate of 45Ca2+ exchange in cells incubated at 1.3 mM extracellular Ca2+, (b) increased the activity of glycogen phosphorylase a and the intracellular free Ca2+ concentration (measured with quin2) in a process dependent on the concentration of extracellular Ca2+, and (c) enhanced the increase in glycogen phosphorylase activity which follows the addition of Ca2+ to cells previously incubated in the absence of Ca2+. It is concluded that EGF stimulates plasma-membrane Ca2+ inflow. 2. The effects of the combination of EGF and vasopressin on the rate of 45Ca2+ exchange and on the rate of increase in glycogen phosphorylase activity were the same as those of vasopressin alone. 3. The amount of 45Ca2+ released by EGF from internal stores was about 30% of that released by vasopressin. No detectable increase in [3H]inositol mono-, bis- or tris-phosphate was observed after the addition of EGF to cells labelled with myo-[3H]inositol. 4. In hepatocytes isolated from rats treated with pertussis toxin, the effects of EGF and vasopressin on phosphorylase activity (measured at 1.3 mM-Ca2+) and on the rate of Ca2+ inflow (measured with quin2) were markedly decreased compared with those in normal cells. 5. Treatment with pertussis toxin did not impair the ability of vasopressin to release Ca2+ from internal stores, but decreased vasopressin-stimulated [3H]inositol polyphosphate formation by 50%. 6. It is concluded that the mechanism(s) by which vasopressin and EGF stimulate plasma-membrane Ca2+-inflow transporters in hepatocytes involves a GTP-binding regulatory protein sensitive to pertussis toxin, and does not require an increase in the concentration of inositol trisphosphate comparable with that which induces the release of Ca2+ from the endoplasmic reticulum.

The stimulation by sodium fluoride of plasma-membrane Ca2+ inflow in isolated hepatocytes. Evidence that a GTP-binding regulatory protein is involved in the hormonal stimulation of Ca2+ inflow

1. In isolated hepatocytes NaF increased the rate of 45Ca2+ exchange, the cytoplasmic free Ca2+ concentration ([Ca2+]i) (monitored by using quin2), and the activity of glycogen phosphorylase a in a Ca2+-dependent manner. 2. In cells previously incubated in the absence of extracellular Ca2+(Ca2+o), NaF caused a pronounced enhancement in the increases in the activity of glycogen phosphorylase and in [Ca2+]i observed when Ca2+ was subsequently added. The effect of NaF on glycogen phosphorylase activity was inhibited by verapamil and deferoxamine, and was potentiated by AlCl3. 3. The actions of NaF were associated with (a) increases in [3H]inositol polyphosphates, which were slower in onset and about half the magnitude of those induced by vasopressin, in hepatocytes labelled with [3H]inositol, and (b) enhanced rates of O2 utilization and decreased concentrations of ATP. The latter effects were not potentiated by AlCl3. 4. Preincubation of hepatocytes with vasopressin in the absence of added Ca2+o for times up to 30 min did not diminish the ability of a subsequent addition of extracellular Ca2+ to activate glycogen phosphorylase. 5. 12-O-Tetradecanoylphorbol 13-acetate had little effect on 45Ca2+ exchange and did not enhance the activation by Ca2+o of phosphorylase in hepatocytes incubated in the absence of Ca2+o. 6. On the basis of the observation that AlF4- activates GTP-binding regulatory proteins [Sternweiss & Gilman (1982) Proc. Natl. Acad. Sci. U.S.A. 79, 4888-4891], it is concluded that the present results provide evidence for the function of a GTP-binding regulatory protein in the mechanism by which hormones stimulate plasma-membrane Ca2+ inflow in the liver cell, and indicate that an increase in [Ca2+]i and the activation of protein kinase C are not part of this mechanism.

How far does phospholipase C activity depend on the cell calcium concentration? A study in intact cells

The dependence of phospholipase C activity on the cytosolic Ca2+ concentration ([Ca2+]i) was studied in intact liver cells treated with the Ca2+-mobilizing hormone vasopressin, or not so treated. Phospholipase C (PLC) activity was estimated from the formation of [3H]inositol trisphosphate (InsP3) and the degradation of [3H]phosphatidylinositol 4,5-bisphosphate (PtdInsP2). The [Ca2+]i of the cells was clamped from 29 to 1130 nM by quin2 loading. This wide concentration range was obtained by loading the hepatocytes with a high concentration of the Ca2+ indicator in low-Ca2+ medium or by using the Ca2+ ionophore ionomycin in medium containing Ca2+. In resting cells, in which [Ca2+]i was 193 nM, treatment with 0.1 microM-vasopressin which stimulates liver PLC maximally, tripled InsP3 content and raised [Ca2+]i to 2 microM within 15 s. Lowering [Ca2+]i partially decreased cell InsP3 content as well as the ability of vasopressin to stimulate InsP3 formation maximally. At 29 nM, the lowest Ca2+ concentration obtained in isolated liver cells, basal InsP3 content was 64% of that measured in control cells. Addition of vasopressin no longer affected [Ca2+]i, but significantly increased InsP3 by 200%, although less than in the controls (300%). The maintenance of the greater part of the PLC response at constant [Ca2+]i indicated that, in the liver, InsP3 formation does not result from an increase in [Ca2+]i. The effects of lowering [Ca2+]i were reversible. When low cell [Ca2+]i was restored to a normal value, resting InsP3 content and the ability of vasopressin to stimulate InsP3 formation maximally by 300% were also restored. Raising [Ca2+]i from 193 to 1130 nM had little effect on the InsP3 content or the vasopressin-mediated increase in InsP3. In agreement with the stimulation of PLC activity by vasopressin, cell [3H]PtdInsP2 and total PtdInsP2 were degraded by application of this hormone for 15 s. In contrast, when [Ca2+]i was lowered to 29 nM, basal [3H]PtdInsP2 and total PtdInsP2 were increased by about 30%, [3H]PtdInsP2 was further increased by vasopressin, but total PtdInsP2 was not changed. These results show that, in intact hepatocytes, PLC is little affected by [Ca2+]i concentrations above 193 nM, but is partially dependent on Ca2+ below that value. They suggest that, in addition to activating PLC activity, vasopressin might stimulate PtdInsP2 synthesis, presumably via phosphatidylinositol-phosphate kinase, and that this pathway might predominate in cells with low [Ca2+]i.

Blebbing, free Ca2+ and mitochondrial membrane potential preceding cell death in hepatocytes

Cell surface 'blebbing' is an early consequence of hypoxic and toxic injury to cells. A rise in cytosolic free Ca2+ has been suggested as the stimulus for bleb formation and the final common pathway to irreversible cell injury. Here, using digitized low-light video microscopy, we examine blebbing, cytosolic free Ca2+, mitochondrial membrane potential and loss of cell viability in individual cultured hepatocytes. Unexpectedly, we found that after 'chemical hypoxia' with cyanide and iodoacetate, cytosolic free Ca2+ does not change during bleb formation or before loss of cellular viability. Cell death was precipitated by a sudden breakdown of the plasma membrane permeability barrier, possibly caused by rupture of a cell surface bleb.

Effects of vasopressin and La3+ on plasma-membrane Ca2+ inflow and Ca2+ disposition in isolated hepatocytes. Evidence that vasopressin inhibits Ca2+ disposition

Vasopressin caused a 40% inhibition of 45Ca uptake after the addition of 0.1 mM-45Ca2+ to Ca2+-deprived hepatocytes. At 1.3 mM-45Ca2+, vasopressin and ionophore A23187 each caused a 10% inhibition of 45Ca2+ uptake, whereas La3+ increased the rate of 45Ca2+ uptake by Ca2+-deprived cells. Under steady-state conditions at 1.3 mM extracellular Ca2+ (Ca2+o), vasopressin and La3+ each increased the rate of 45Ca2+ exchange. The concentrations of vasopressin that gave half-maximal stimulation of 45Ca2+ exchange and glycogen phosphorylase activity were similar. At 0.1 mM-Ca2+o, La3+ increased, but vasopressin did not alter, the rate of 45Ca2+ exchange. The results of experiments performed with EGTA or A23187 or by subcellular fractionation indicate that the Ca2+ taken up by hepatocytes in the presence of La3+ is located within the cell. The addition of 1.3 mM-Ca2+o to Ca2+-deprived cells caused increases of approx. 50% in the concentration of free Ca2+ in the cytoplasm [( Ca2+]i) and in glycogen phosphorylase activity. Much larger increases in these parameters were observed in the presence of vasopressin or ionophore A23187. In contrast with vasopressin, La3+ did not cause a detectable increase in glycogen phosphorylase activity or in [Ca2+]i. It is concluded that an increase in plasma membrane Ca2+ inflow does not by itself increase [Ca2+]i, and hence that the ability of vasopressin to maintain increased [Ca2+]i over a period of time is dependent on inhibition of the intracellular removal of Ca2+.

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.

4 beta-Phorbol 12-myristate 13-acetate attenuates the glucagon-induced increase in cytoplasmic free Ca2+ concentration in isolated rat hepatocytes

Hepatocytes were isolated from rats and then loaded with the fluorescent Ca2+ indicator quin2. Glucagon caused a sustained increase (at least 5 min) in the fluorescence of the quin2-loaded cells; the increase was much greater than that observed with control, non-quin2-loaded, cells. These observations indicate that glucagon caused an increase in cytoplasmic free Ca2+ concentration [( Ca2+]c). The effects of glucagon were mimicked if forskolin (to activate adenylate cyclase), dibutyryl cyclic AMP or bromo cyclic AMP were added directly to the cells. Thus an increase in cyclic AMP concentration may mediate the effect of glucagon on [Ca2+]c. If 4 beta-phorbol 12-myristate 13-acetate (PMA; an activator of protein kinase C) was added to the cells before glucagon, the magnitude of the increase in [Ca2+]c was greatly diminished. If PMA was added after glucagon it caused a lowering of [Ca2+]c. These effects of PMA on the glucagon-induced increase in [Ca2+]c could not be mimicked if [Ca2+]c was increased by the Ca2+-ionophore ionomycin. Thus an event involved in the mechanism by which glucagon increases [Ca2+]c appears to be required for the action of PMA. If [Ca2+]c was increased by forskolin, dibutyryl cyclic AMP or bromo cyclic AMP, the effect of PMA on [Ca2+]c was similar to that observed when glucagon was used to elevate [Ca2+]c. When [Ca2+]c was raised by dibutyryl cyclic AMP the presence of the phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine did not prevent the subsequent addition of PMA from causing [Ca2+]c to decrease. These observations suggest that PMA can inhibit the cyclic AMP-induced increase in [Ca2+]c independently of any changes in cyclic AMP concentration. Glucagon appears to increase [Ca2+]c by releasing intracellular stores of Ca2+ and stimulating net influx of Ca2+ into the cell; PMA greatly diminishes both of these effects.

Studies with verapamil and nifedipine provide evidence for the presence in the liver cell plasma membrane of two types of Ca2+ inflow transporter which are dissimilar to potential-operated Ca2+ channels

The addition of 500 microM verapamil or nifedipine to isolated hepatocytes incubated in the presence of 1.3 mM Ca2+ caused 20% inhibition of Ca2+ inflow as measured by the initial rate of 45Ca2+ exchange. No stimulation of 45Ca2+ exchange was observed in the presence of the Ca2+ agonist CGP 28392. An increase in the concentration of extracellular K+ from 6 to 60 mM (to depolarize the plasma membrane) increased the initial rate of 45Ca2+ exchange by 30%. In the presence of 60 mM K+, 400 microM verapamil inhibited the initiate rate of 45Ca2+ exchange by 50%. Verapamil and nifedipine completely inhibited vasopressin-induced Ca2+ inflow as determined by measurement of the initial rate of 45Ca2+ exchange and of glycogen phosphorylase a activity. This effect of verapamil was completely reversed by increasing the extracellular concentration of Ca2+. The concentrations of Ca2+ antagonist which gave 50% inhibition of vasopressin- or K+-stimulated Ca2+ inflow were in the range 50-100 microM, about 50-fold greater than the concentration which gave 50% inhibition of the beating of electrically-stimulated myocardial muscle cells. In the absence of vasopressin, verapamil caused a transient increase in glycogen phosphorylase a activity by a process which is largely independent of Ca2+. It is concluded that verapamil and nifedipine inhibit the transport of Ca2+ across the hepatocyte plasma membrane through a putative Ca2+ transporter which is activated by vasopressin and which differs in nature from potential-operated Ca2+ channels in excitable cells and from the Ca2+ transporter present in hepatocytes in the absence of hormone.

Changes in free cytosolic calcium and accumulation of inositol phosphates in isolated hepatocytes by [Leu]enkephalin

Isolated hepatocytes from fed rats were used to study the effects of the opioid peptide [Leu]enkephalin on intracellular free cytosolic Ca2+ ([Ca2+]i) and inositol phosphate production. By measuring the fluorescence of the intracellular Ca2+-selective indicator quin-2, [Leu]enkephalin was found to increase [Ca2+]i rapidly from a resting value of 0.219 microM to 0.55 microM. The magnitude of this response was comparable with that produced by maximally stimulating concentrations of either vasopressin (100 nM) or phenylephrine (10 microM). The opioid-peptide-mediated increase in [Ca2+]i showed a dose-dependency comparable with the activation of phosphorylase, but it preceded the increase in phosphorylase alpha activity. Addition of [Leu]enkephalin to hepatocytes prelabelled with myo-[2-3H(n)]inositol resulted in a significant stimulation of inositol phosphate production. At 10 min after hormone addition, there were increases in the concentrations of inositol mono-, bis- and tris-phosphate fractions of 12-, 9- and 14-fold respectively. No effect was apparent on the glycerophosphoinositol fraction. The effect of 10 microM-[Leu]enkephalin on inositol phosphate production was significantly greater than that obtained with 10 microM-phenylephrine, but marginally smaller than that induced by 100 nM-vasopressin. However, at these concentrations all three agonists gave a comparable increase in [Ca2+]i and activation of phosphorylase a. These data provide evidence for [Leu]enkephalin acting via a mechanism involving a mobilization of Ca2+ as a result of increased phosphatidylinositol turnover.

Glucagon and vasopressin interactions on Ca2+ movements in isolated hepatocytes

The effects of glucagon and vasopressin, singly or together, on cytosolic free Ca2+ concentration [( Ca2+]i) and on the 45Ca2+ efflux were studied in isolated rat liver cells. In the presence of 1 mM external Ca2+, glucagon and vasopressin added singly induced sustained increases in [Ca2+]i. The rate of the initial fast phase of the [Ca2+]i increase and the magnitude of the final plateau were dependent on the concentrations (50 pm-0.1 microM) of glucagon and vasopressin. Preincubating the cells with a low concentration of glucagon (0.1 nM) for 2 min markedly accelerated the fast phase and elevated the plateau of the [Ca2+]i increase caused by vasopressin. In the absence of external free Ca2+, glucagon and vasopressin transiently increased [Ca2+]i and stimulated the 45Ca2+ efflux from the cells, indicating mobilization of Ca2+ from internal store(s). Preincubating the cells with 0.1 nM-glucagon accelerated the rate of the fast phase of the [Ca2+]i rise caused by the subsequent addition of vasopressin. However, unlike what was observed in the presence of 1 mM-Ca2+, glucagon no longer enhanced the maximal [Ca2+]i response to vasopressin. In the absence of external free Ca2+, higher concentrations (1 nM-0.1 microM) of glucagon, which initiated larger increases in [Ca2+]i, drastically decreased the subsequent Ca2+ response to vasopressin (10 nM). At these concentrations, glucagon also decreased the vasopressin-stimulated 45Ca2+ efflux from the cells. It is suggested that, in the liver, glucagon accelerates the fast phase and elevates the plateau of the vasopressin-mediated [Ca2+]i increase respectively by releasing Ca2+ from the same internal store as that permeabilized by vasopressin, probably the endoplasmic reticulum, and potentiating the influx of extracellular Ca2+ caused by this hormone.

Effect of cyclic AMP-dependent hormones and Ca2+-mobilizing hormones on the Ca2+ influx and polyphosphoinositide metabolism in isolated rat hepatocytes

The effect of the interaction between the Ca2+-mobilizing hormone adrenaline, used as alpha-adrenergic agonist, and cyclic AMP-dependent hormones, including beta-adrenergic agonists and glucagon, on the initial 45Ca2+ uptake rate and polyphosphoinositide metabolism were investigated in isolated rat hepatocytes. Each hormone alone increased the initial 45Ca2+ uptake rate. When adrenaline was added without inhibitor, it induced a rise in the initial 45Ca2+ uptake rate larger than the sum of the rises elicited by its alpha and beta components singly. Similarly, when adrenaline was used as an alpha-agonist and added together with glucagon, it enhanced the initial 45Ca2+ uptake rate synergistically. Kinetic analysis of the initial 45Ca2+ uptake rate measured at different Ca2+ concentrations suggested that the increased influx elicited by the combination of adrenaline as alpha-adrenergic agonist and glucagon reflects an activation of the rate of Ca2+ transport via a homogeneous population of Ca2+ channels or carriers. Dose-response curves for the alpha-adrenergic action of adrenaline or glucagon applied in the presence of increasing doses of glucagon or adrenaline showed that each hormone increases the maximal response to the other without affecting its ED50. Measurement of polyphosphoinositide hydrolysis and of the inositol phosphates formed in the presence of adrenaline or vasopressin and/or glucagon showed that Ca2+-mobilizing hormones and glucagon had no synergistic effects on inositol 1,4,5-trisphosphate production. It is therefore proposed that the synergistic action of glucagon and Ca2+-mobilizing hormones on Ca2+ influx occurs at a step that takes place close to the Ca2+ channels or carriers themselves. The Ca2+ gating involved might be mainly controlled by two products, one of them arising from the polyphosphoinositide metabolism, and the other from the increase in internal cyclic AMP.