Sinusoidal endothelial cells (SEC) constitute a permeable barrier between hepatocytes and blood. SEC are exposed to high concentrations of bile salts from the enterohepatic circulation. Whether SEC are responsive to bile salts is unknown. TGR5, a G-protein-coupled bile acid receptor, which triggers cAMP formation, has been discovered recently in macrophages. In this study, rat TGR5 was cloned and antibodies directed against the C-terminus of rat TGR5 were developed, which detected TGR5 as a glycoprotein in transfected HepG2-cells. B ile salts are required for cholesterol excretion and lipid absorption. 1 However, high concentrations of lipophilic bile salts have toxic effects. Bile salts alter membrane fluidity 2 and can act pro-or anti-apoptotic. [3][4][5][6] Many liver diseases are aggravated by the cholestatic potential of lipophilic bile salts. Therefore, several mechanisms exist to maintain bile salt homeostasis. These include the coordinated expression and action of bile salt transporters at the sinusoidal and canalicular membrane of liver parenchymal cells, 7 alternative pathways for bile salt synthesis and metabolism, 8,9 and the involvement of extrahepatic tissues (such as the gut and the kidneys) in bile salt excretion. [10][11][12] These mechanisms are closely regulated by nuclear receptors sensitive for bile salts, which control the expression of transporter proteins and enzymes. They comprise the farnesoid X receptor, 13-15 the pregnane X receptor, 16,17 and the vitamin D receptor. 18 Recently, a G-protein-coupled plasma membrane receptor responsive to bile salts has been discovered by highthroughput screening. This receptor, named TGR5, 19 M-BAR, or BG37, 20 stimulates adenylate cyclase on activation and increases the production of cyclic adenosine monophosphate (cAMP). Thereby, bile salts not only may be involved in the regulation of transcription but also may influence rapid, cAMP-dependent mechanisms in TGR5 expressing cells. So far, TGR5 expression has been demonstrated in enteroendocrine cells, 21 where bile salts stimulate the secretion of glucagon-like peptide-1 via TGR5 and in alveolar macrophages, 19 which secrete smaller amounts of cytokines in response to endotoxin, when bile salts are present. Recently, bile salts were shown to influence energy consumption in brown adipose tissue
The mechanisms underlying CD95 ligand (CD95L)- and hyperosmolarity-induced activation of the CD95 system [Reinehr, R., Graf, D., Fischer, R., Schliess, F., and Haussinger, D. (2002) Hepatology 36, 602-614] as initial steps of apoptosis were studied. Hyperosmotic exposure (405 mosmol/l) of rat hepatocytes induced within 1 min oxidative stress and antioxidant-sensitive activation of the epidermal growth factor receptor (EGFR) and c-Jun-N-terminal-kinase (JNK). After 30 min of hyperosmotic exposure EGFR associated with CD95 and CD95 became tyrosine phosphorylated. Inhibition of JNK or protein kinase C (PKC) had no effect on EGFR phosphorylation but abolished CD95/EGFR association, CD95-tyrosine phosphorylation, membrane targeting, and Fas-associated death domain/caspase 8 recruitment to CD95 [death-inducing signaling complex (DISC) formation]. Inhibition of EGFR tyrosine kinase activity prevented CD95 tyrosine phosphorylation and DISC formation but not hyperosmolarity-induced EGFR phosphorylation and EGFR association with CD95. Tyrosine-phosphorylated CD95 was enriched in the plasma membrane. All maneuvers preventing CD95 tyrosine phosphorylation inhibited CD95 membrane trafficking and DISC formation. Stimulation of EGFR by EGF induced EGFR phosphorylation but no association with CD95 or CD95 phosphorylation. Addition of CD95L also induced EGFR and JNK activation, EGFR/CD95 association, CD95 tyrosine phosphorylation, DISC formation, and CD95 membrane targeting with an inhibitor sensitivity profile similar to that of hyperosmotic CD95 activation, except that inhibition of PKC was ineffective. The data suggest that moderate hyperosmolarity or CD95L trigger oxidative stress and EGFR activation followed by a JNK-dependent EGFR/CD95association and CD95 tyrosine phosphorylation, probably through EGFR tyrosine kinase activity. This provides a signal for CD95 membrane trafficking and DISC formation.
CD95 ligand (CD95L) triggers a rapid formation of reactive oxygen species (ROS) as an upstream event of CD95 activation and apoptosis induction in rat hepatocytes. This ROS response was sensitive to inhibition by diphenyleneiodonium, apocynin, and neopterin, suggestive of an involvement of NADPH oxidases. In line with this, hepatocytes expressed mRNAs not only of the phagocyte gp91 phox (Nox 2), but also of the homologs Nox 1 and 4 and Duox 1 and 2, as well as the regulatory subunit p47 phox . gp91 phox (Nox 2) and p47 phox were also identified at the protein level in rat hepatocytes. CD95L induced within 1 min ceramide formation and serine phosphorylation of p47 phox , which was sensitive to inhibitors of sphingomyelinase and protein kinase C (PKC). These inhibitors and p47 phox protein knockdown inhibited the early CD95L-induced ROS response, suggesting that ceramide and PKC are upstream events of the CD95L-induced Nox/Duox activation. CD95L also induced rapid activation of the Src family kinase Yes, being followed by activation of c-Src, Fyn, and c-Jun-N-terminal kinases (JNK). Only Yes and JNK activation were sensitive to N-acetylcysteine, inhibitors of NADPH oxidase, PKC, or sphingomyelinase, indicating that the CD95L-induced ROS response is upstream of Yes and JNK but not of Fyn and c-Src activation. Activated Yes rapidly associated with the epidermal growth factor receptor (EGFR), which became phosphorylated at Tyr 845 and Tyr 1173 but not at Tyr 1045 . Activated EGFR then triggered an AG1478-sensitive CD95-tyrosine phosphorylation, which was a signal for membrane targeting of the EGFR/CD95 complex, subsequent recruitment of Fasassociated death domain and caspase 8, and apoptosis induction. All of these events were significantly blunted by inhibitors of sphingomyelinase, PKC, NADPH oxidases, Yes, or EGFR-tyrosine kinase activity and after protein knockdown of either p47 phox , Yes, or EGFR. The data suggest that CD95L-induced apoptosis involves a sphingomyelinase-and PKC-dependent activation of NADPH oxidase isoforms, which is required for Yes/EGFR/CD95 interactions as upstream events of CD95 activation.
The role of NADPH oxidase (NOX) and the regulatory subunit p47(phox) for hypoosmotic ROS generation was studied in cultured rat astrocytes and brain slices of wilde type and p47(phox) knock-out mice. Cultured rat astrocytes express mRNAs encoding for the regulatory subunit p47(phox), NOX1, 2, and 4, and the dual oxidases (DUOX)1 and 2, but not NOX3. Hypoosmotic (205 mosmol/L) swelling of cultured astrocytes induced a rapid generation of ROS that was accompanied by serine phosphorylation of p47(phox) and prevented by the NADPH oxidase inhibitor apocynin. Apocynin also impaired the hypoosmotic tyrosine phosphorylation of Src. Both, hypoosmotic ROS generation and p47(phox) serine phosphorylation were sensitive to the acidic sphingomyelinase inhibitors AY9944 and desipramine, the protein kinase C (PKC)zeta-inhibitory pseudosubstrate peptide, the NMDA receptor antagonist MK-801 and the intracellular Ca(2+) chelator BAPTA-AM. Also hypoosmotic exposure of wilde type mouse cortical brain slices increased ROS generation, which was allocated in part to the astrocytes and which was absent in presence of apocynin and in cortical brain slices from p47(phox) knock-out mice. Also ammonia induced a rapid ROS production in cultured astrocytes and brain slices, which was sensitive to apocynin. The data suggest that astrocyte swelling triggers a p47(phox)-dependent NADPH oxidase-catalyzed ROS production. The findings further support a close interrelation between osmotic and oxidative stress in astrocytes, which may be relevant to different brain pathologies including hepatic encephalopathy.
The effect of hyperosmolarity on CD95 membrane targeting and CD95 ligand (CD95L)-induced apoptosis was studied in rat hepatocytes. CD95 showed a predominant intracellular localization in normoosmotically exposed rat hepatocytes, whereas hyperosmotic exposure induced, within 1 hour, CD95 trafficking to the plasma membrane followed by activation of caspase-3 and -8. Hyperosmotic CD95 membrane targeting was sensitive to inhibition of c-Jun-N-terminal kinase (JNK), protein kinase C (PKC), and cyclic adenosine monophosphate, but not to inhibition of extracellular regulated kinases (Erks) or p38 mitogen activated protein kinase (p38 MAPK ). Hyperosmotic CD95 targeting to the plasma membrane was dose-dependently diminished by glutamine or taurine, probably caused by an augmentation of volume regulatory increase. Despite CD95 trafficking to the plasma membrane and caspase activation, hyperosmolarity per se did not induce apoptosis. Hyperosmolarity, however, sensitized hepatocytes toward CD95L-induced apoptosis, as assessed by annexin V staining and terminal deoxynucleotidyl transferase-mediated X-dUTP nick-end labeling (TUNEL) assay. This sensitization was abolished when hyperosmotic CD95 membrane trafficking was prevented by cyclic adenosine monophosphate, PKC, or JNK inhibition, whereas these effectors had no effect on CD95L-induced apoptosis in normoosmotically exposed hepatocytes. CD95L addition under normoosmotic conditions caused CD95 membrane trafficking, which was sensitive to JNK inhibition, but not to cyclic adenosine monophosphate or inhibition of PKC, Erks, and p38 MAPK . In conclusion, multiple signaling pathways are involved in CD95 membrane trafficking. Hyperosmotic hepatocyte shrinkage induces CD95 trafficking to the plasma membrane, which involves JNK-, PKA-, and PKC-dependent mechanisms and sensitizes hepatocytes toward CD95L-mediated apoptosis. (HEPATOLOGY 2002;36:602-614.)
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