Obstructive cholestasis induces TNF-alpha- and IL-1 -mediated periportal downregulation of Bsep and zonal regulation of Ntcp, Oatp1a4, and Oatp1b2

Inverse acinar regulation of Mrp2 and 3 represents an adaptive response to hepatocellular cholestatic injury. We studied whether obstructive cholestasis (bile duct ligation) and LPS treatment affect the zonal expression of Bsep (Abcb11), Mrp4 (Abcc4), Ntcp (Slc10a1), and Oatp isoforms (Slco1a1, Slco1a4, and slco1b2) in rat liver, as analyzed by semiquantitative immunofluorescence. Contribution of TNF-alpha and IL-1beta to transporter zonation in obstructive cholestasis was studied by cytokine inactivation. In normal liver Bsep, Mrp4, Ntcp, and Oatp1a1 were homogeneously distributed in the acinus, whereas Oatp1a4 and Oatp1b2 expression increased from zone 1 to 3. Glutamine synthetase-positive pericentral hepatocytes exhibited markedly lower Oatp1a4 expression than the remaining zone 3 hepatocytes. In cholestatic liver Bsep and Ntcp immunofluorescence in periportal hepatocytes significantly decreased to 66 +/- 4% (P < 0.01) and 67 +/- 7% (P < 0.05), whereas it was not altered in pericentral hepatocytes. Oatp1a4 was significantly induced in hepatocytes with a primarily low expression, i.e., in periportal hepatocytes and in glutamine synthetase-positive pericentral hepatocytes. Likewise, Oatp1b2 was upregulated in periportal hepatocytes. Mrp4 zonal induction was homogeneous. Inactivation of TNF-alpha and IL-1beta prevented periportal downregulation of Bsep. Recruitment of neutrophils and polymorphonuclear cells mainly occurred in the periportal zone. Likewise, IL-1beta induction was largely found periportally. No significant transporter zonation was seen following LPS treatment. In conclusion, zonal downregulation of Bsep in obstructive cholestasis is associated with portal inflammation and is mediated by TNF-alpha and IL-1beta. Periportal downregulation of Ntcp and induction of Oatp1a4 and Oatp1b2 may represent adaptive mechanisms to reduce cholestatic injury in hepatocytes with profound downregulation of Bsep and Mrp2.     

Regulation of MRP2/ABCC2 and BSEP/ABCB11 Expression in Sandwich Cultured Human and Rat Hepatocytes Exposed to Inflammatory Cytokines TNF-α, IL-6, and IL-1β

In the present study MRP2/ABCC2 and BSEP/ABCB11 expression were investigated in sandwich cultured (SC) human and rat hepatocytes exposed to the proinflammatory cytokines. The investigation was also done in lipopolysaccharide (LPS)-treated rats. In SC human hepatocytes, both absolute protein and mRNA levels of MRP2/ABCC2 were significantly down-regulated by TNF-α, IL-6, or IL-1β. In contrast to mRNA decrease, which was observed for BSEP/ABCB11, the protein amount was significantly increased by IL-6 or IL-1β. A discrepancy between the change in BSEP/ABCB11 mRNA and protein levels was encountered in SC human hepatocytes treated with proinflammatory cytokines. In SC rat hepatocytes, Mrp2/Abcc2 mRNA was down-regulated by TNF-α and IL-6, whereas the protein level was decreased by all three cytokines. Down-regulations of both Bsep/Abcb11 mRNA and protein levels were found in SC rat hepatocytes exposed to TNF-α or IL-1β. Administration of LPS triggered the release of the proinflammatory cytokines and caused the decrease of Mrp2/Abcc2 and Bsep/Abcb11 protein in liver at 24 h post-treatment; however, the Mrp2 and Bsep protein levels rebounded at 48 h post-LPS treatment. In total, our results indicate that proinflammatory cytokines regulate the expression of MRP2/Mrp2 and BSEP/Bsep and for the first time demonstrate the differential effects on BSEP/Bsep expression between SC human and rat hepatocytes. Furthermore, the agreement between transporter regulation in vitro in SC rat hepatocytes and in vivo in LPS-treated rats during the acute response phase demonstrates the utility of in vitro SC hepatocyte models for predicting in vivo effects.     

Oxidative stress is a triggering factor for LPS-induced Mrp2 internalization in the cryopreserved rat and human liver slices

Cholestasis develops during inflammation and is characterized as occurring under oxidative stress. We have described the internalization of multidrug resistance-associated protein 2 (Mrp2), a biliary transporter involved in bile-salt-independent bile flow, under ethacrynic acid or lipopolysaccharide (LPS)-induced acute oxidative stress in rat liver. However, it remains unclear whether canalicular Mrp2 internalization is observed in human liver under conditions of acute oxidative stress. In this study, we examined the effect of dimerumic acid (DMA), an antioxidant and found in traditional Chinese medicine, on endotoxin-induced Mrp2 internalization in rat and human liver slices. At 1.5 h following LPS treatment (100 μg/mL), canalicular Mrp2 localization was disrupted without changing the expression of Mrp2 protein or the integrity of filamentous actin in the rat and human liver slices. Pretreatment with DMA (10 μM) counteracted LPS-induced subcellular distribution of Mrp2. Our data clearly indicated that LPS-induced short-term rapid retrieval of Mrp2 from the canalicular surface resulted from LPS-induced oxidative stress in rat and human liver slices.     

Hepatic Mrp4 induction following acetaminophen exposure is dependent on Kupffer cell function

During acetaminophen (APAP) hepatotoxicity, increased expression of multidrug resistance-associated proteins 2, 3, and 4 (Mrp2-4) occurs. Mrp4 is the most significantly upregulated transporter in mouse liver following APAP treatment. Although the expression profiles of liver transporters following APAP hepatotoxicity are well characterized, the regulatory mechanisms contributing to these changes remain unknown. We hypothesized that Kupffer cell-derived mediators participate in the regulation of hepatic transporters during APAP toxicity. To investigate this, C57BL/6J mice were pretreated with clodronate liposomes (0.1 ml iv) to deplete Kupffer cells and then challenged with APAP (500 mg/kg ip). Liver injury was assessed by plasma alanine aminotransferase and hepatic transporter protein expression was determined by Western blot and immunohistochemistry. Depletion of Kupffer cells by liposomal clodronate increased susceptibility to APAP hepatotoxicity. Although increased expression of several efflux transporters was observed after APAP exposure, only Mrp4 was found to be differentially regulated following Kupffer cell depletion. At 48 and 72 h after APAP dosing, Mrp4 levels were increased by 10- and 33-fold, respectively, in mice receiving empty liposomes. Immunohistochemistry revealed Mrp4 staining confined to centrilobular hepatocytes. Remarkably, Kupffer cell depletion completely prevented Mrp4 induction by APAP. Elevated plasma levels of TNF-alpha and IL-1beta were also prevented by Kupffer cell depletion. These findings show that Kupffer cells protect the liver from APAP toxicity and that Kupffer cell mediators released in response to APAP are likely responsible for the induction of Mrp4.     

Interleukin-6 regulates hepatic transporters during acute-phase response

Cholestasis develops during inflammatory conditions characterized by the release of cytokines like interleukin-6 (IL-6), which is the major player in the hepatic acute-phase response. However, the exact contribution of IL-6 to transporter down-regulation is unclear. Therefore, we compared wild-type and IL-6-deficient mice after IL-6-injection and induction of an aseptic (turpentine-injection) or septic (LPS-injection) acute-phase response. Down-regulation of basolateral (Ntcp, Oatp1, and Mrp3) and canalicular (Mrp2, Bsep) transporter mRNA occurred after treatment with IL-6, turpentine, and LPS. In IL-6-deficient mice, turpentine failed to decrease mRNA-levels of basolateral and canalicular transporters, whereas LPS-mediated down-regulation of Ntcp, Mrp3, and Mrp2 was abolished at later time points (24 h). In conclusion, induction of an aseptic and septic acute-phase response leads to the down-regulation of basolateral and canalicular organic anion transporters. IL-6 is required for transporter down-regulation during aseptic inflammation. Furthermore, IL-6 also contributes to transporter regulation during LPS-induced cholestasis at more delayed time points.     

Upregulation in the expression of multidrug resistance protein Mrp1 mRNA and protein by increased bilirubin production in rat

Earlier studies suggest that Mrp1 may mediate ATP-dependent cellular extrusion of unconjugated bilirubin (UCB). We studied the serial responses of expression of Mrp1 mRNA and protein in rats with increased bilirubin production due to hemolysis induced by phenylhydrazine (PHZ) treatment. Mrp1 mRNA was analyzed by quantitative PCR and protein by Western blot. Hepatic expression of Mrp1 mRNA and protein peaked at day 3 of PHZ treatment. Splenic expression of Mrp1 mRNA peaked within 24h and returned to baseline at day 5 whereas Mrp1 protein expression peaked at day 3. Pretreatment with heme-oxygenase inhibitor, tin mesoporphyrin, blunted the increase in serum UCB and erased the overexpression of Mrp1 both in liver and spleen. Thus, the upregulation of Mrp1 in hemolysis is mediated by UCB and/or other products of heme oxygenase, further supporting a role of Mrp1 in UCB transport and protection from its cellular toxicity.     

Mrp1 Multidrug Resistance-Associated Protein and P-Glycoprotein Expression in Rat Brain Microvessel Endothelial Cells

Abstract: Two membrane glycoproteins acting as energy-dependent efflux pumps, mdr -encoded P-glycoprotein (P-gp) and the more recently described multidrug resistance-associated protein (MRP), are known to confer cellular resistance to many cytotoxic hydrophobic drugs. In the brain, P-gp has been shown to be expressed specifically in the capillary endothelial cells forming the blood-brain barrier, but localization of MRP has not been well characterized yet. Using RT-PCR and immunoblot analysis, we have compared the expression of P-gp and Mrp1 in homogenates, isolated capillaries, primary cultured endothelial cells, and RBE4 immortalized endothelial cells from rat brain. Whereas the mdr1a P-gp-encoding mRNA was specifically detected in brain microvessels and mdr1b mRNA in brain parenchyma, mrp1 mRNA was present both in microvessels and in parenchyma. However, Mrp1 was weakly expressed in microvessels. Mrp1 expression was higher in brain parenchyma, as well as in primary cultured brain endothelial cells and in immortalized RBE4 cells. This Mrp1 overexpression in cultured brain endothelial cells was less pronounced when the cells were cocultured with astrocytes. A low Mrp activity could be demonstrated in the endothelial cell primary monocultures, because the intracellular [³H]vincristine accumulation was increased by several MRP modulators. No Mrp activity was found in the cocultures or in the RBE4 cells. We suggest that in rat brain, Mrp1, unlike P-gp, is not predominantly expressed in the blood-brain barrier endothelial cells and that Mrp1 and the mdr1b P-gp isoform may be present in other cerebral cells.     

Interaction of Mrp2 with radixin causes reversible canalicular Mrp2 localization induced by intracellular redox status

Oxidative stress is a feature of cholestatic syndrome and induces multidrug resistance-associated protein 2 (Mrp2) internalization from the canalicular membrane surface. We have previously shown that the activation of a novel protein kinase C (nPKC) by oxidative stress regulates Mrp2 internalization. The internalized Mrp2 was recycled to the canalicular surface in a protein kinase A (PKA)-dependent manner after intracellular glutathione (GSH) levels were replenished. However, the putative phosphorylation targets of these protein kinases involved in reversible Mrp2 trafficking remain unclear. In this study, we investigated the effect of changing the intrahepatic redox status on the C-terminal phosphorylation status of radixin (p-radixin), which links Mrp2 to F-actin, and the interaction of p-radixin with Mrp2 in rat hepatocytes. We detected a significant decrease in the amount of p-radixin that co-immunoprecipitated with Mrp2 after tertiary-butylhydroperoxide (t-BHP) treatment. After treatment with GSH-ethylester (GSH-EE), the phosphorylation level became the same as that of the control. A PKC and protein phosphatase (PP)-1/2A inhibitor, but not a PP-2A selective inhibitor, prevented the t-BHP-induced decrease of p-radixin and subsequent canalicular Mrp2 localization. In contrast, a PKA inhibitor affected the recovery process facilitated by GSH-EE treatment. In conclusion, the interaction of p-radixin with Mrp2 was decreased by the activation of PKC and PP-1 under oxidative stress conditions which subsequently led to Mrp2 internalization, whereas the interaction of p-radixin and Mrp2 was increased by the activation of PKA during recovery from oxidative stress.     

Canalicular Mrp2 localization is reversibly regulated by the intracellular redox status

Oxidative stress is known to be a common feature of cholestatic syndrome. We have described the internalization of multidrug resistance-associated protein 2 (Mrp2), a biliary transporter involved in bile salt-independent bile flow, under acute oxidative stress, and a series of signaling pathways finally leading to the activation of novel protein kinase C were involved in this mechanism; however, it has been unclear whether the internalized Mrp2 localization was relocalized to the canalicular membrane when the intracellular redox status was recovered from oxidative stress. In this study, we demonstrated that decreased canalicular expression of Mrp2 induced by tertiary-butyl hydroperoxide (t-BHP) was recovered to the canalicular membrane by the replenishment of GSH by GSH-ethyl ester, a cell-permeable form of GSH. Moreover, pretreatment of isolated rat hepatocytes with colchicine and PKA inhibitor did not affect the t-BHP-induced Mrp2 internalization process but did prevent the Mrp2 recycling process induced by GSH replenishment. Moreover, intracellular cAMP concentration similarly changed with the change of intracellular GSH content. Taken together, our data clearly indicate that the redox-sensitive balance of PKA/PKC activation regulates the reversible Mrp2 localization in two different pathways, the microtubule-independent internalization pathway and -dependent recycling pathway of Mrp2.     

An in vivo role of Mrp2 in the rat hepatocytes by immunocytochemistry for amoxicillin using the transporter-deficient EHBR

An in vivo role of the multidrug resistant-associated protein (Mrp2) in rat hepatocytes was examined by immunocytochemistry (ICC) for amoxicillin (AMPC) by the use of the transporter-deficient Eisai hyperbilirubinemic rats (EHBR). The ICC revealed that in the liver of EHBR at 3-h post-administration, amoxicillin accumulated in the cytoplasmic pools and nuclei of the hepatocytes in a characteristic granular morphology on the bile capillaries. However, no amoxicillin was observed on the surface of the lumina ranging from the bile capillaries to the interlobular bile ducts. The drug persisted at least for 6-h after administration. In contrast, in the control rat liver at 3-h post-administration, AMPC-adsorption occurred on such luminal surface, while AMPC accumulated to a less level in both the cytoplasm and nuclei of the hepatocytes. The drug completely disappeared in the hepatocytes at 6-h post-administration. These results strongly suggest that AMPC taken up into the cytoplasm of the hepatocytes excretes via Mrp2 into the bile flow. Furthermore, electron microscopy demonstrated that the lower electron density areas in large sizes, corresponding to the cytoplasmic pools in ICC for AMPC, occurred in the cytoplasm peripheral to the nuclei of the hepatocytes in EHBR at 3-h post-administration, and then disappeared 24 h after administration.     

HIV-1 viral envelope glycoprotein gp120 produces oxidative stress and regulates the functional expression of multidrug resistance protein-1 (Mrp1) in glial cells

Brain human immunodeficiency virus type-1 (HIV-1) infection is associated with oxidative stress, which may lead to HIV-1 encephalitis, a chronic neurodegenerative condition. In vitro , oxidative stress can be induced in glial cells by exposure to HIV-1 envelope protein glycoprotein (gp120). Multidrug resistance proteins (Mrps) are known to efflux endogenous substrates (i.e. GSH and GSSG) involved in cellular defense against oxidative stress. Altered GSH/GSSG export may contribute to oxidative damage during HIV-1 encephalitis. At present, it is unknown if gp120 exposure can alter the functional expression of Mrp isoforms. Heat-shock protein 70, inducible nitric oxide synthase, intracellular GSSG, 2',7'-dichlorofluorescein fluorescence, and extracellular nitrite were increased in primary cultures of rat astrocytes triggered with gp120, suggesting an oxidative stress response. RT-PCR and immunoblot analysis demonstrated increased Mrp1 mRNA (2.3-fold) and protein (2.2-fold), respectively, in gp120 treated astrocytes while Mrp4 mRNA or protein expression was not changed. Cellular retention of 2',7'-bis-(2-carboxyethyl)-5-(and-6)-carboxyfluorescein, an established Mrp substrate, was reduced (twofold) in gp120-treated astrocytes, suggesting increased Mrp-mediated transport. In addition, GSH and GSSG export were enhanced in gp120-triggered cells. These data suggest that gp120 can up-regulate Mrp1, but not Mrp4, functional expression in cultured astrocytes. Our observation of increased GSH/GSSG efflux in response to gp120 treatment implies that Mrp isoforms may be involved in regulating the oxidative stress response in glial cells.     

Oxidative stress and Mrp2 internalization

Oxidative stress in the liver is sometimes accompanied by cholestasis. We have described the internalization of multidrug resistance-associated protein 2/ATP-binding cassette transporter family 2 (Mrp2/Abcc2), a biliary transporter involved in bile-salt-independent bile flow, under ethacrynic acid (EA)-induced acute oxidative stress in rat liver. However, the signaling pathway and regulatory molecules have not been investigated. In the present study, we investigated the mechanism of EA-induced Mrp2 internalization using isolated rat hepatocyte couplets (IRCHs). The Mrp2 index, defined as the ratio of Mrp2-positive canalicular membrane staining in IRCHs per number of cell nuclei, was significantly reduced by treatment with EA. This reduction was abolished by a nonspecific protein kinase C (PKC) inhibitor Gö6850, a Ca²⁺ chelator, EGTA, but not by a protein kinase A (PKA)-selective inhibitor, a Ca²⁺-dependent conventional PKC (cPKC) inhibitor Gö6976, or a protein kinase G (PKG) inhibitor (1 μM). Moreover, an increase in the intracellular Ca²⁺ level and NO release into medium were observed shortly after the EA treatment. Both of these increases, as well as Mrp2 internalization, were completely blocked by EGTA. In conclusion, EA produced a reduction in GSH, Ca²⁺ elevation, NO production, and nPKC activation in a sequential manner, finally leading to Mrp2 internalization.     

Interactions between hepatic Mrp4 and Sult2a as revealed by the constitutive androstane receptor and Mrp4 knockout mice

The ABC transporter, Mrp4, transports the sulfated steroid DHEA-s, and sulfated bile acids interact with Mrp4 with high affinity. Hepatic Mrp4 levels are low, but increase under cholestatic conditions. We therefore inferred that up-regulation of Mrp4 during cholestasis is a compensatory mechanism to protect the liver from accumulation of hydrophobic bile acids. We determined that the nuclear receptor CAR is required to coordinately up-regulate hepatic expression of Mrp4 and an enzyme known to sulfate hydroxy-bile acids and steroids, Sult2a1. CAR activators increased Mrp4 and Sult2a1 expression in primary human hepatocytes and HepG2, a human liver cell line. Sult2a1 was down-regulated in Mrp4-null mice, further indicating an inter-relation between Mrp4 and Sult2a1 gene expression. Based on the hydrophilic nature of sulfated bile acids and the Mrp4 capability to transport sulfated steroids, our findings suggest that Mrp4 and Sult2a1 participate in an integrated pathway mediating elimination of sulfated steroid and bile acid metabolites from the liver.     

Anaphylatoxin C5a actions in rat liver: synergistic enhancement by C5a of lipopolysaccharide-dependent alpha(2)-macroglobulin gene expression in hepatocytes via IL-6 release from Kupffer cells

The effects of the anaphylatoxins C5a and C3a on the liver are only poorly characterized in contrast to their well known systemic actions. Recently, it has been demonstrated that the anaphylatoxin C5a enhanced glucose output from hepatocytes (HC) indirectly via prostanoid release from Kupffer cells (KC). In the present study, it is shown that recombinant rat C5a (rrC5a), together with LPS, activated the gene of the acute phase protein alpha(2)-macroglobulin (alpha(2)MG) in HC also indirectly via IL-6 release from KC. RrC5a alone increased neither IL-6 mRNA in nor IL-6 release from KC, whereas LPS alone did so. However, rrC5a synergistically enhanced the LPS-dependent increase in IL-6 mRNA and IL-6 release. Only rIL-6, but not TNF-alpha or IL-1beta, enhanced alpha(2)MG mRNA in HC. In line with the actions of rrC5a and LPS on KC, conditioned medium of KC stimulated only with rrC5a did not increase alpha(2)MG mRNA in HC. However, medium of KC stimulated with rrC5a plus LPS induced alpha(2)MG mRNA expression in HC more strongly than medium from cells stimulated only with LPS; thus, C5a acted synergistically with LPS. The stimulatory effects of KC-conditioned medium could partially be inhibited by a neutralizing anti-IL-6 Ab, indicating that KC-derived IL-6 was a major mediator in C5a- plus LPS-elicited alpha(2)MG gene expression. These results suggest that C5a, besides enhancing glucose output via prostanoids, is involved in the initiation of the acute phase response in HC via proinflammatory cytokines from KC. This provides evidence for another important function of C5a in the regulation of hepatocellular defense reactions.