Stimulation of lipid peroxidation increases the intracellular calcium content of isolated hepatocytes.

Lipid peroxidation induced in isolated rat hepatocytes by FeCl3 (0.1 mM) was associated with an increase in the cytosolic free Ca2+ and in the ionophore-mobilizable Ca2+ content of both mitochondrial and extramitochondrial (endoplasmic reticular) pools. Ca2+ accumulation was completely prevented by the antioxidants promethazine and vitamin E succinate and was not linked to the inhibition of plasma membrane (Ca2+ + Mg2+)-ATPase and Ca2+ transport or to the depletion of intracellular ATP content. Moreover, preincubation of the hepatocytes with the Ca2+ channel blockers verapamil and nifedipine inhibited the elevation of cytosolic Ca2+, as well as the ion accumulation without interfering with the stimulation of lipid peroxidation by iron. These results suggest that peroxidative alterations of the hepatocyte plasma membranes might perturb the functions of verapamil- and nifedipine-sensitive Ca2+ channels resulting in a net influx of Ca2+, which is subsequently sequestrated in the intracellular compartments.

Ethanol potentiates hypoxic liver injury: role of hepatocyte Na(+) overload.

Centrilobular hypoxia has been suggested to contribute to hepatic damage caused by alcohol intoxication. However, the mechanisms involved are still poorly understood. We have investigated whether alterations of Na(+) homeostasis might account for ethanol-mediated increase in hepatocyte sensitivity to hypoxia. Addition of ethanol (100 mmol/l) to isolated rat hepatocytes incubated under nitrogen atmosphere greatly stimulated cell death. An increase in intracellular Na(+) levels preceded cell killing and Na(+) levels in hepatocytes exposed to the combination of ethanol and hypoxia were almost twice those in hypoxic cells without ethanol. Na(+) increase was also observed in hepatocytes incubated with ethanol in oxygenated buffer. Ethanol addition significantly lowered hepatocyte pH. Inhibiting ethanol and acetaldehyde oxidation with, respectively, 4-methylpyrazole and cyanamide prevented this effect. 4-methylpyrazole, cyanamide as well as hepatocyte incubation in a HCO(3)(-)-free buffer or in the presence of Na(+)/H(+) exchanger blocker 5-(N,N-dimethyl)-amiloride also reduced Na(+) influx in ethanol-treated hepatocytes. 4-methylpyrazole and cyanamide similarly prevented ethanol-stimulated Na(+) accumulation and hepatocyte killing during hypoxia. Moreover, ethanol-induced Na(+) influx caused cytotoxicity in hepatocytes pre-treated with Na(+), K(+)-ATPase inhibitor ouabain. Also in this condition 4-methylpyrazole and 5-(N,N-dimethyl)-amiloride decreased cell killing. These results indicate that ethanol can promotes cytotoxicity in hypoxic hepatocytes by enhancing Na(+) accumulation.

Alterations of Na(+) homeostasis in hepatocyte reoxygenation injury.

Reperfusion injury represents an important cause of primary graft non-function during liver transplantation. However, the mechanism responsible for cellular damage during reoxygenation has not yet been completely understood. We have investigated whether changes in intracellular Na(+) distribution might contribute to cause hepatocyte damage during reoxygenation buffer after 24 h of cold storage. Hepatocyte reoxygenation resulted in a rapid increase in cellular Na(+) content that was associated with cytotoxicity. Na(+) accumulation and hepatocyte death were prevented by the omission of Na(+) from the incubation medium, but not by the addition of antioxidants. Blocking Na(+)/H(+) exchanger and Na(+)/HCO(3)(-) co-transporter by, respectively, 5-(N,N-dimethyl)-amiloride or omitting HCO(3)(-) from the reoxygenation medium significantly decreased Na(+) overload and cytotoxicity. Stimulation of ATP re-synthesis by the addition of fructose also lowered Na(+) accumulation and cell death during reoxygenation. A significant protection against Na(+)-mediated reoxygenation injury was evident in hepatocytes maintained in an acidic buffer (pH 6.5) or in the presence of glycine. The cytoprotective action of glycine or of the acidic buffer was reverted by promoting Na(+) influx with the Na(+)/H(+) ionophore monensin. Altogether, these results suggest that Na(+) accumulation during the early phases of reoxygenation might contribute to liver graft reperfusion injury.

Stimulation of p38 MAP kinase reduces acidosis and Na(+) overload in preconditioned hepatocytes.

Ischemic preconditioning has been shown to improve liver resistance to hypoxia/reperfusion damage. A signal pathway involving A(2A)-adenosine receptor, G(i)-proteins, protein kinase C and p38 MAP kinase is responsible for the development of hypoxic preconditioning in hepatocytes. However, the coupling of this signal pathway with the mechanisms responsible for cytoprotection is still unknown. We have observed that stimulation of A(2A)-adenosine receptors or of p38 MAPK by CGS21680 or anisomycin, respectively, appreciably reduced intracellular acidosis and Na(+) accumulation developing during hypoxia. These effects were reverted by p38 MAPK inhibitor SB203580 as well as by blocking vacuolar proton ATPase with bafilomycin A(1). SB203580 and bafilomycin A(1) also abolished the cytoprotective action exerted by both CGS21680 and anisomycin. We propose that the stimulation of p38 MAPK by preconditioning might increase hepatocyte resistance to hypoxia by activating proton extrusion through vacuolar proton ATPase, thus limiting Na(+) overload promoted by Na(+)-dependent acid buffering systems.

Mechanisms responsible for carbon tetrachloride-induced perturbation of mitochondrial calcium homeostasis.

Incubation of isolated hepatocytes with CCl4 results in early reduction of the intracellular calcium content, mostly due to loss from the mitochondrial compartment. CCl4 treatment directly affects mitochondrial functions as indicated by the inhibition of Ca2+ uptake in cells permeabilized to the ion by digitonin exposure and by the reduction of intracellular ATP content in hepatocytes incubated in a glucose-free medium. Such mitochondrial damage is not caused by CCl4-induced stimulation of lipid peroxidation since it is not prevented by alpha-tocopherol, used at a concentration able to inhibit completely peroxidative reactions without interfering with CCl4 activation. All data together are in favour of a direct action of CCl4-reactive metabolites on liver cell calcium homeostasis.

Activation of human immunodeficiency virus long terminal repeat by arachidonic acid.

Arachidonic acid is the precursor of highly reactive mediators, including prostaglandins and leukotrienes, and the most abundant n-6 polyunsaturated fatty acid in mammalian cell membranes. It is released from phospholipids upon many inflammatory stimuli. In this study, a chloramphenicol acyltransferase reporter gene, under control of the human immunodeficiency virus-1 long terminal repeat, was strongly induced upon treating human promonocytes with arachidonic acid. The n-3 fatty acid eicosapentenoic, found in abundance in fish oil, had no effect. HIV-1 long terminal repeat activation by arachidonic acid was suppressed by inhibitors of both lipoxygenase and cyclooxygenase pathways, suggesting that metabolites, rather than arachidonic acid itself, mediated the stimulatory effect. This is the first report linking HIV-1 expression to the metabolism of arachidonic acid.

Intracellular Na+ accumulation and hepatocyte injury during cold storage.

BACKGROUND: The mechanisms responsible for liver damage during cold storage are still not completely understood. We have investigated the role played by alterations of Na+ homeostasis in cell injury during cold hypoxia. METHODS: The changes in Na+ distribution were investigated in isolated rat hepatocytes stored at 4 degrees C under hypoxic conditions. RESULTS: Hepatocyte cold stored up to 72 hr in Krebs-Henseleit-Hepes buffer showed a progressive increase in intracellular Na+ content that preceded the loss of cell viability. Na+ accumulation and cell death were prevented using Na+-free, acidic (pH 6.5) or glycine-supplemented storage media. The Na+ ionophore monensin reverted the cytoprotection exerted by glycine and by the acidic medium, but not that given by Na+-free Krebs-Henseleit-Hepes. A low Na+ content was also important for the cytoprotection observed using University of Wisconsin solution. CONCLUSIONS: Na+ overload might contribute to liver graft injury occurring during cold storage.

Lipid peroxidation and irreversible damage in the rat hepatocyte model. Protection by the silybin-phospholipid complex IdB 1016.

IdB 1016 is a new silybin-phospholipid complex which is more bioavailable than the flavonoid silybin itself and displays free radical scavenging and antioxidant properties in liver microsomes. We report here that the addition of increasing concentrations of IdB 1016 to isolated rat hepatocytes caused a dose-dependent inhibition of lipid peroxidation induced by ADP-Fe3+ or cumene hydroperoxide. Moreover, IdB 1016 at the concentration which completely prevented MDA formation also protected isolated hepatocytes against the toxicity of pro-oxidant agents such as allyl alcohol, cumene hydroperoxide and bromotrichloromethane, without interfering with the activation mechanism of these xenobiotics. Similar protection was also obtained in hepatocytes prepared from animals pretreated in vivo with IdB 1016 while rat supplementation with pure silybin was totally inefficient. These results indicate IdB 1016 as being a potentially useful protective agent against free radical-mediated toxic liver injury.

Comparative evaluation of the antioxidant activity of alpha-tocopherol, alpha-tocopherol polyethylene glycol 1000 succinate and alpha-tocopherol succinate in isolated hepatocytes and liver microsomal suspensions.

The antioxidant activity of alpha-tocopherol polyethylene glycol 1000 succinate (TPGS) and of alpha-tocopherol succinate (TS) has been examined in isolated hepatocytes and microsomal fractions from rat liver. Both TPGS and TS require esterase activity to yield free alpha-tocopherol and, hence, antioxidant activity. TPGS and TS consistently exerted a more effective antioxidant protection than an equivalent amount of directly-added free alpha-tocopherol. The low antioxidant efficiency of directly added free alpha-tocopherol in such water-based experimental systems as used here seems to be due to its extreme hydrophobicity. TPGS, on the other hand, is an extremely hydrophilic compound that is being examined as a useful source of alpha-tocopherol in certain clinical situations and is here shown to be a convenient and effective source for experimental studies into lipid peroxidation and antioxidant mechanisms.

Effect of spin traps in isolated rat hepatocytes and liver microsomes.

Spin traps are increasingly employed in the detection of free radicals in biological systems, including liver microsomes and isolated hepatocytes. Two spin traps phenyl-t-butyl nitrone (PBN) and 4-pyridyl-l-oxide-t-butyl nitrone (4-POBN) have been tested for their effects on hepatocyte viability and mixed-function oxidase activity. High concentration of PBN but not of 4-POBN proved to moderately affect liver cell integrity, without interfering with intracellular ATP or cytochrome P-450 content. PBN also decreased hepatocyte GSH content, probably as the result of its metabolism to benzaldehyde. The two spin traps were found to inhibit aminopyrine demethylase and ethoxycoumarin deethylase activity in hepatocytes and microsomes. At low concentrations (1-5 mM) PBN enhanced aniline hydroxylase while high concentrations of the spin trap inhibited this activity. The inhibition of the monooxygenase system was not caused by damage of microsomal enzymes, but rather by competition with other substrates for the binding to the haemoprotein. The effects of spin traps on mixed function oxidase systems should be taken into account when evaluating the results of spin trapping experiments.

Effects of carbon tetrachloride on calcium homeostasis. A critical reconsideration.

The incubation of isolated rat hepatocytes with 0.172 mM carbon tetrachloride caused a rapid decrease in the calcium content of both mitochondrial and extramitochondrial compartments. However, the release of Ca2+ from the intracellular stores was not associated with an increase in the cytosolic Ca2+ levels as measured by activation of phosphorylase alpha or by Quin-2 fluorescence. A rapid rise in hepatocyte free calcium was only observed with concentrations of CCl4 higher than 0.172 mM. The lack of activation of phosphorylase alpha was not due to the inhibition of the enzyme by CCl4, since in CCl4-treated hepatocytes the phosphorylase activity could be stimulated by glucagon, butyryl--cAMP or by the increase of cell calcium induced by the addition of A23187. Ca2+-dependent ATPase of plasma membranes was only slightly affected in the early phases of poisoning with CCl4 when both mitochondrial and extramitochondrial calcium pools were already lowered. This led to the conclusion that calcium released from intracellular organelles could be extruded from the cells in sufficient amounts to prevent the increase of the cytosolic levels. A rise in hepatocyte free calcium was observed during the second hour of incubation with CCl4, concomitantly with the appearance of both LDH leakage and plasma membrane blebbing. The addition of EGTA to the medium prevented both the increase in cytosolic Ca2+ and the blebbing suggesting that they were a consequence of an influx of calcium into the cells. However, neither EGTA nor the addition of inhibitors of calcium-dependent phospholipase A2 or non-lysosomal proteases were able to protect against cell death. These latter results suggested that the alterations of calcium distribution induced by CCl4 in isolated hepatocytes were not a primary cause of the toxic effects, although they did not exclude that a sustained rise in cytosolic Ca2+ could contribute in the progression of cell injury.

Alterations of hepatocyte Ca2+ homeostasis by triethylated lead (Et3Pb+): are they correlated with cytotoxicity?

Isolated rat hepatocytes were used to investigate the biochemical mechanisms of toxicity of triethyllead (Et3Pb+), a highly neurotoxic degradation product of the antiknocking petrol additive tetraethyllead. As early as 5 min from the addition of 50 microM Et3Pb+ to hepatocyte suspensions a decrease of mitochondrial membrane potential and of the capacity of mitochondria and microsomes to retain Ca2+ occurred. A dose-dependent release of mitochondrial Ca2+ as well as an inhibition of microsomal Ca(2+)-ATPase activity were also evident when Et3Pb+ (from 2.5 microM up to 50 microM) was added to, respectively, isolated liver mitochondria and microsomes. Further experiments using hepatocytes loaded with the Ca2+ indicator Fura-2AM demonstrate that 1 min from addition of Et3Pb+ the cytosolic free Ca2+ levels increased by about 3-fold. High affinity plasma membrane Ca(2+)-ATPase activity was also significantly inhibited in hepatocytes treated with Et3Pb+, suggesting that an impairement of the mechanisms controlling the efflux of extracellular Ca2+ was concomitantly involved in the rise in cytosolic Ca2+ concentration. The increase in the cytosolic Ca2+ levels caused by Et3Pb+ was followed by a rapid decline of cell viability. However, the addition of EGTA or of the intracellular Ca2+ chelator BAPTA/AM did not affect either the time-course or the extent of cytotoxicity. Conversely, fructose, a glycolytic substrate that was able to support ATP production, prevented hepatocyte death. Thus, the depletion of cellular energy stores rather than the increase in cytosolic Ca2+ appears to be the mechanism by which Et3Pb+ causes irreversible injury in isolated hepatocytes.

Negative regulation of diacylglycerol kinase theta mediates adenosine-dependent hepatocyte preconditioning.

In liver ischemic preconditioning (IP), stimulation of adenosine A2a receptors (A2aR) prevents ischemia/reperfusion injury by promoting diacylglycerol-mediated activation of protein kinase C (PKC). By concerting diacylglycerol to phosphatidic acid, diacylglycerol kinases (DGKs) act as terminator of diacylglycerol signalling. This study investigates the role of DGK in the development of hepatocyte IP. DGK activity and cell viability were evaluated in isolated rat hepatocytes preconditioned by 10 min hypoxia followed by 10 min re-oxygenation or by the treatment with the A2aR agonist, CGS21680, and subsequently exposed to prolonged hypoxia. We observed that after IP or A2aR activation, a decrease in DGK activity was associated with the onset of hepatocyte tolerance to hypoxia. CGS21680-induced stimulation of A2aR specifically inhibited DGK isoform theta by activating RhoA-GTPase. Consistently, both siRNA-mediated downregulation of DGK theta and hepatocyte pretreatment with the DGK inhibitor R59949 induced cell tolerance to hypoxia. The pharmacological inhibition of DGK was associated with the diacylglycerol-dependent activation of PKC delta and epsilon and of their downstream target p38 MAPK. In conclusion, we unveil a novel signalling pathway contributing to the onset of hepatocyte preconditioning, which through RhoA-GTPase, couples A2aR to the downregulation of DGK. Such an inhibition is essential for the sustained accumulation of diacylglycerol required for triggering PKC-mediated survival signals.

Evidence for a sodium-dependent calcium influx in isolated rat hepatocytes undergoing ATP depletion.

ATP depletion caused by menadione and triethyllead in isolated hepatocytes is associated with intracellular acidosis and a sustained increase in intracellular Na+ and Ca2+ concentrations. Removal of Na+ from the incubation medium as well as the inclusion of EGTA largely prevented the increase in cytosolic Ca2+, thus indicating that Ca2+ was mobilized from the extracellular medium in response to Na+ load. To further validate these findings, hepatocytes were incubated with a combination of sodium propionate and ouabain in order to induce intracellular acidosis and inhibit Na+ extrusion. This treatment promoted a marked increase in intracellular Na+ and Ca2+ concentrations that was prevented by omission of Na+ from the incubation medium as well as by agents that inhibited cellular Na+ influx. These data indicate that following Na+ load, Ca2+ can be accumulated in hepatocytes via a Na+/Ca2+ antiporter operating on a reverse mode.

Mitochondrial damage and its role in causing hepatocyte injury during stimulation of lipid peroxidation by iron nitriloacetate.

Incubation of isolated rat hepatocytes with 0.1 mM iron nitrilotriacetic acid (FeNTA) caused a rapid rise in lipid peroxidation followed by a substantial increase in trypan blue staining and lactate dehydrogenase release, but did not affect the protein and non-protein thiol content of the cells. Hepatocyte death was preceded by the decline of mitochondrial membrane potential, as assayed by rhodamine 123 uptake, and by the depletion of cellular ATP. Chelation of extracellular Ca2+ by ethylene glycol bis(beta-aminoethyl ether) N,N'-tetraacetic acid or inhibition of Ca2+ cycling within the mitochondria by LaCl3 or cyclosporin A did not prevent the decline of rhodamine 123 uptake. On the other hand, a dramatic increase in the conjugated diene content was observed in mitochondria isolated from FeNTA-treated hepatocytes. Oxidative damage of mitochondria was accompanied by the leakage of matrix enzymes glutamic oxalacetic aminotransferase (GOT) and glutamate dehydrogenase (GLDH). The addition of the antioxidant N,N'-diphenylphenylene diamine (DPPD) completely prevented GOT and GLDH leakage, inhibition of rhodamine 123 uptake, and ATP depletion induced by FeNTA, indicating that Ca(2+)-independent alterations of mitochondrial membrane permeability consequent to lipid peroxidation were responsible for the loss of mitochondrial membrane potential. DPPD addition also protected against hepatocyte death. Similarly hepatocytes prepared from fed rats were found to be more resistant than those obtained from starved rats toward ATP depletion and cell death caused by FeNTA, in spite of undergoing a comparable mitochondrial injury. A similar protection was also observed following fructose supplementation of hepatocytes isolated from starved rats, indicating that the decline of ATP was critical for the development of FeNTA toxicity. From these results it was concluded that FeNTA-induced peroxidation of mitochondrial membranes impaired the electrochemical potential of these organelles and led to ATP depletion which was critical for the development of irreversible cell injury.

The operation of Na+/Ca2+ exchanger prevents intracellular Ca2+ overload and hepatocyte killing following iron-induced lipid peroxidation.

Stimulation of lipid peroxidation by incubating isolated rat hepatocytes with ADP/FeCl3 caused a time dependent increase in cytosolic free Ca2+ levels, without influencing cellular Na+ content. Omission of Na+ from the incubation medium greatly increased the accumulation of Ca2+, which was partially reverted upon transferring the cells in a Na+ containing medium. This suggested that a Na(+)-dependent Ca2+ transporter was activated upon the elevation of cytosolic Ca2+ and partially counteracted the influx of Ca2+ promoted by lipid peroxidation. In the presence of Na+ cell death was not associated with the increase of Ca2+ induced by peroxidative injury; however, decrease of mitochondrial membrane potential and loss of cell viability followed by massive accumulation of Ca2+ occurring in hepatocytes incubated with ADP/FeCl3 in a Na(+)-free medium. Both these effects were completely prevented by chelation of extracellular Ca2+ with EGTA. Thus, we conclude that Na(+)-dependent Ca2+ transporter is involved in controlling excessive accumulation of Ca2+ induced by stimulation of lipid peroxidation and can prevent hepatocyte death caused by Ca(2+)-dependent alterations of mitochondrial activity.

Alterations of cell volume regulation in the development of hepatocyte necrosis.

Intracellular Na+ accumulation has been shown to contribute to hepatocyte death caused by anoxia or oxidative stress. In this study we have investigated the mechanism by which Na+ overload can contribute to the development of cytotoxicity. ATP depletion in isolated hepatocytes exposed to menadione-induced oxidative stress or to KCN was followed by Na+ accumulation, loss of intracellular K+, and cell swelling. Hepatocyte swelling occurred in two phases: a small amplitude swelling (about 15% of the initial size) with preservation of plasma membrane integrity and a terminal large amplitude swelling associated with cell death. Inhibition of Na+ accumulation by the use of a Na+-free medium prevented K+ loss, cell swelling, and cytotoxicity. Conversely, blocking K+ efflux by the addition of BaCl2 did not influence Na+ increase and small amplitude swelling, but greatly stimulated large amplitude swelling and cytotoxicity. Menadione or KCN killing of hepatocytes was also enhanced by inducing cell swelling in an hypotonic medium. However, increasing the osmolarity of the incubation medium did not protect against large amplitude swelling and cytotoxicity, since stimulated Na+ accumulation and K+ efflux. Altogether these results indicate that the impairment of volume regulation in response to the osmotic load caused by Na+ accumulation is critical for the development of cell necrosis induced by mitochondrial inhibition or oxidative stress.