Role of p38 map kinase in glycine-induced hepatocyte resistance to hypoxic injury.

BACKGROUND/AIMS: Glycine hepatoprotection is well known. However, the mechanisms involved are still poorly characterized. METHODS: Glycine protection was investigated in isolated rat hepatocytes pretreated with 2 mmol/L glycine 15 min before incubation under hypoxic conditions. RESULTS: Glycine significantly reduced Na+ overload and hepatocyte death caused by hypoxia. Glycine protection required the activation of a signal pathway involving Src, Pyk2 and p38 MAP kinases. Glycine treatment also induced a 11% increase of hepatocyte volume and transient ATP release. The prevention of cell swelling by hepatocyte incubation in a hypertonic medium as well as the degradation of extracellular ATP with apyrase or the block P2 purinergic receptors with suramin reverted glycine-induced cytoprotection and inhibited Src, Pyk2 and p38 MAPK activation. Glycine down-modulated Na+/H+ exchanger (NHE) activity, without affecting the development of intracellular acidosis during hypoxia. Such an effect was reverted by inhibiting p38 MAPK that also abolished glycine protection against Na+ overload caused by hypoxia. CONCLUSIONS: Glycine-induced ATP release in response to a moderate hepatocyte swelling led to the autocrine stimulation of P2 receptors and to the activation of Src, Pyk2 and p38 MAPK that increased hepatocyte resistance to hypoxia by preventing Na+ influx through NHE.

PI3K-dependent lysosome exocytosis in nitric oxide-preconditioned hepatocytes.

We investigated the signal mediators and the cellular events involved in the nitric oxide (NO)-induced hepatocyte resistance to oxygen deprivation in isolated hepatocytes treated with the NO donor (Z)-1-(N-methyl-N-[6-(N-methylammoniohexyl)amino])diazen-1-ium-1,2-diolate (NOC-9). NOC-9 greatly induced PI3K activation, as tested by phosphorylation of PKB/Akt. This effect was prevented by either 1H-(1,2,4)-oxadiazolo-(4,3)-quinoxalin-1-one, an inhibitor of the soluble guanylate cyclase (sGC), or KT5823, an inhibitor of cGMP-dependent kinase (cGK), as well as by farnesyl protein transferase inhibitor, which blocks the function of Ras GTPase. Bafilomycin A, an inhibitor of the lysosome-type vacuolar H+-ATPase, cytochalasin D, which disrupts the cytoskeleton-dependent organelle traffic, and wortmannin, which inhibits the PI3K-dependent traffic of lysosomes, all abolished the NOC-9-induced hepatocyte protection. The treatment with NOC-9 was associated with the PI3K-dependent peripheral translocation and fusion with the plasma membrane of lysosomes and the appearance at the cell surface of the vacuolar H+-ATPase. Inhibition of sGC, cGK, and Ras, as well as the inhibition of PI3K by wortmannin, prevented the exocytosis of lysosomes and concomitantly abolished the protective effect of NOC-9 on hypoxia-induced pHi and [Na+]i alterations and cell death. These data indicate that NO increases hepatocyte resistance to hypoxic injury by activating a pathway involving Ras, sGC, and cGK that determines PI3K-dependent exocytosis of lysosomes.

Purinergic P2Y2 receptors promote hepatocyte resistance to hypoxia.

BACKGROUND/AIMS: ATP stimulation of purinergic P2 receptors (P2YR and P2XR) regulates several hepatic functions. Here we report the involvement of ATP-mediated signals in enhancing hepatocyte tolerance to lethal stress. METHODS: The protection given by purinergic agonists was investigated in rat hepatocytes exposed to hypoxia. RESULTS: ATP released after hypotonic stress (200 mOsm/L) as well as P2YR agonists prevented hepatocyte killing by hypoxia with efficiency ranking UTP > ATPgammaS > ADPbetaS, whereas the P2XR agonist, methylene-adenosine-5'-triphosphate, was ineffective. Adenosine-5'-O-3-thiotriphosphate (ATPgammaS; 100 micromol/L) also prevented Na+ -overload in hypoxic cells by inhibiting the Na+/H+ exchanger, without interfering with hypoxic acidosis. ATPgammaS activated Src and promoted a Src-dependent stimulation of both ERK1/2 and p38MAPK. Blocking p38MAPK with SB203580 reverted the protection given by ATPgammaS on both cell viability and Na+ accumulation, whereas ERK1/2 inhibition with PD98058 was ineffective. An increased phosphorylation of ERK1/2 was also evident in untreated hypoxic hepatocytes. PD98058 ameliorated Na+ accumulation and cell death caused by hypoxia. Hepatocyte pre-treatment with ATPgammaS reverted ERK1/2 activation in hypoxic cells. SB203580 blocked the effects of ATPgammaS on both ERK1/2 and Na+/H+ exchanger. CONCLUSIONS: The activation of p38MAPK by P2Y2R increases hepatocyte resistance to hypoxia by down-modulating ERK1/2-mediated signals that promote Na+ influx through the Na+/H+ exchanger.

Role of phosphatidylinositol 3-kinase in the development of hepatocyte preconditioning.

BACKGROUND & AIMS: Ischemic preconditioning has been proved effective in reducing ischemia/reperfusion injury during liver surgery. However, the mechanisms involved are still poorly understood. Here, we have investigated the role of phosphatidylinositol 3-kinase (PI3K) in the signal pathway leading to hepatic preconditioning. METHODS: PI3K activation was evaluated in isolated rat hepatocytes preconditioned by 10-minute hypoxia followed by 10-minute reoxygenation. RESULTS: Hypoxic preconditioning stimulated phosphatidylinositol-3,4,5-triphosphate production and the phosphorylation of PKB/Akt, a downstream target of PI3K. Conversely, PI3K inhibition by wortmannin or LY294002 abolished hepatocyte tolerance against hypoxic damage induced by preconditioning. PI3K activation in preconditioned hepatocytes required the stimulation of adenosine A 2A receptors and was mimicked by adenosine A 2A receptors agonist CGS21680. In the cells treated with CGS21680, PI3K activation was prevented either by inhibiting adenylate cyclase and PKA with, respectively, 2,5-dideoxyadenosine and H89 or by blocking Galphai-protein and Src tyrosine kinase with, respectively, pertussis toxin and PP2. H89 also abolished the phosphorylation of adenosine A 2A receptors. However, the direct PKA activation by forskolin failed to stimulate PI3K. This suggested that PKA-phosphorylated adenosine A 2A receptors may activate PI3K by coupling it with Galphai-protein through Src. We also observed that, by impairing PI3K-mediated activation of phospholypase Cgamma (PLCgamma), wortmannin and LY294002 blocked the downstream transduction of preconditioning signals via protein kinase C (PKC) delta/ isozymes. CONCLUSIONS: PI3K is activated following hepatocyte hypoxic preconditioning by the combined stimulation of adenosine A 2A receptors, PKA, Galphai protein, and Src. By regulating PKC-/delta-dependent signals, PI3K can play a key role in the development of hepatic tolerance to hypoxia/reperfusion.

Preconditioning-induced cytoprotection in hepatocytes requires Ca(2+)-dependent exocytosis of lysosomes.

A short period of hypoxia reduces the cytotoxicity produced by a subsequent prolonged hypoxia in isolated hepatocytes. This phenomenon, termed hypoxic preconditioning, is mediated by the activation of adenosine A2A-receptor and is associated with the attenuation of cellular acidosis and Na+ overload normally occurring during hypoxia. Bafilomycin, an inhibitor of the vacuolar H+/ATPase, reverts the latter effects and abrogates the preconditioning-induced cytoprotection. Here we provide evidence that the acquisition of preconditioning-induced cytoprotection requires the fusion with plasma membrane and exocytosis of endosomal-lysosomal organelles. Poisons of the vesicular traffic, such as wortmannin and 3-methyladenine, which inhibit phosphatydilinositol 3-kinase, or cytochalasin D, which disassembles the actin cytoskeleton, prevented lysosome exocytosis and also abolished the preconditioning-associated protection from acidosis and necrosis provoked by hypoxia. Preconditioning was associated with the phosphatydilinositol 3-kinase-dependent increase of cytosolic [Ca2+]. Chelation of free cytosolic Ca2+ in preconditioned cells prevented lysosome exocytosis and the acquisition of cytoprotection. We conclude that lysosome-plasma membrane fusion is the mechanism through which hypoxic preconditioning allows hepatocytes to preserve the intracellular pH and survive hypoxic stress. This process is under the control of phosphatydilinositol 3-kinase and requires the integrity of the cytoskeleton and the rise of intracellular free calcium ions.

Signal pathway responsible for hepatocyte preconditioning by nitric oxide.

Nitric oxide (NO) improves liver resistance to hypoxia/reperfusion injury acting as a mediator of hepatic preconditioning. However, the mechanisms involved are still poorly understood. In this study, we have investigated the mechanisms by which short-term exposure to the NO donor (Z)-1-(N-methyl-N-[6-(N-methylammoniohexyl)amino])-diazen-1-ium-1,2-diolate (NOC-9) increases hepatocyte tolerance to hypoxic injury. Isolated rat hepatocytes preincubated 15 min with NOC-9 (0.250 mM) became resistant to the killing caused by hypoxia. NOC-9 cytoprotection did not involve the activation of protein kinase C, but was instead blocked by inhibiting soluble guanylate cyclase with 1H-(1,2,4)-oxadiazolo-(4,3) quinoxalin-1-one (ODQ) (50 microM) or cGMP-dependent kinase (cGK) with KT 5823 (5 microM). Conversely, cGMP analogue, 8Br-cGMP (50 microM) mimicked the effect of NOC-9. Western blot analysis revealed that hepatocyte treatment with NOC-9 or 8Br-cGMP significantly increased dual phosphorylation of p38 MAPK. The activation of p38 MAPK was abolished by inhibiting guanylate cyclase or cGK. Pretreatment with NO significantly reduced intracellular Na(+) accumulation in hypoxic hepatocytes. This effect was reverted by KT 5823 as well as by the p38 MAPK inhibitor SB203580. SB203580 also reverted NOC-9 protection against hypoxic injury. Altogether, these results demonstrated that NO can induce hepatic preconditioning by activating p38 MAPK through a guanylate cyclase/cGK-mediated pathway.

Mechanisms of hepatocyte protection against hypoxic injury by atrial natriuretic peptide.

Atrial natriuretic peptide (ANP) reduces ischemia and/or reperfusion damage in several organs, but the mechanisms involved are largely unknown. We used freshly isolated rat hepatocytes to investigate the mechanisms by which ANP enhances hepatocyte resistance to hypoxia. The addition of ANP (1 micromol/L) reduced the killing of hypoxic hepatocytes by interfering with intracellular Na(+) accumulation without ameliorating adenosine triphosphate (ATP) depletion and pH decrease caused by hypoxia. The effects of ANP were mimicked by 8-bromo-guanosine 3', 5'-cyclic monophosphate (cGMP) and were associated with the activation of cGMP-dependent kinase (cGK), suggesting the involvement of guanylate cyclase-coupled natriuretic peptide receptor (NPR)-A/B ANP receptors. However, stimulating NPR-C receptor with des-(Gln(18), Ser(19),Gly(20),Leu(21),Gly(22))-ANP fragment 4-23 amide (C-ANP) also increased hepatocyte tolerance to hypoxia. C-ANP protection did not involve cGK activation but was instead linked to the stimulation of protein kinase C (PKC)-delta through G(i) protein- and phospholipase C-mediated signals. PKC-delta activation was also observed in hepatocytes receiving ANP. The inhibition of phospholipase C or PKC by U73122 and chelerythrine, respectively, significantly reduced ANP cytoprotection, indicating that ANP interaction with NPR-C receptors also contributed to cytoprotection. In ANP-treated hepatocytes, the stimulation of both cGK and PKC-delta was coupled with dual phosphorylation of p38 mitogen-activated protein kinase (MAPK). The p38 MAPK inhibitor SB203580 abolished ANP protection by reverting p38 MAPK-mediated regulation of Na(+) influx by the Na(+)/H(+) exchanger. In conclusion, ANP recruits 2 independent signal pathways, one mediated by cGMP and cGK and the other associated with G(i) proteins, phospholipase C, and PKC-delta. Both cGK and PKC-delta further transduce ANP signals to p38 MAPK that, by maintaining Na(+) homeostasis, are responsible for ANP protection against hypoxic injury.

Beta-alanine protection against hypoxic liver injury in the rat.

Liver hypoxia still represents an important cause of liver injury during shock and liver transplantation. We have investigated the protective effects of beta-alanine against hypoxic injury using isolated perfused rat livers and isolated rat hepatocyte suspensions. Perfusion with hypoxic Krebs-Henseleit buffer increased liver weight and caused a progressive release of lactate dehydrogenase (LDH) in the effluent perfusate. The addition of 5 mmol/l beta-alanine to the perfusion buffer completely prevented both weight increase and LDH leakage. These findings were confirmed by histological examinations showing that beta-alanine blocked the staining by trypan blue of either liver parenchymal and sinusoidal cells. Studies performed in isolated hepatocytes revealed that beta-alanine exerted its protective effects by interfering with Na+ accumulation induced by hypoxia. The addition of gamma-amino-butyric acid, which interfered with beta-alanine uptake by the hepatocytes or of Na+/H+ ionophore monensin, reverted beta-alanine protection in either hepatocyte suspensions or isolated perfused livers. We also observed that liver receiving beta-alanine were also protected against LDH leakage and weight increase caused by the perfusion with an hyposmotic (205 mosm) hypoxic buffer obtained by decreasing NaCl content from 118 to 60 mmol/l. This latter effect was not reverted by blocking K+ efflux from hepatocyte with BaCl(2) (1mmol/l). Altogether these results indicated that beta-alanine protected against hypoxic liver injury by preventing Na+ overload and by increasing liver resistance to osmotic stress consequent to the impairment of ion homeostasis during hypoxia.