Cholestasis and the role of basolateral efflux pumps

ATP-dependent transport of biliary constituents, such as bile acids, reduced glutathione, and bilirubin glucuronosides across the hepatocyte canalicular membrane into bile represents the decisive driving force for the formation of biliary fluid. Functional characterization, cloning, and localization of hepatocellular transporter proteins has provided a molecular understanding of the mechanisms underlying bile flow and intrahepatic cholestasis. Genetic variants in humans and genetic knockout in rodents, or transporter inhibition have indicated that both the conjugate export pump MRP2 (multidrug resistance protein 2; ABCC2) and the bile salt export pump BSEP (ABCB11) are major contributors to bile acid-independent and bile acid-dependent bile flow, respectively. In humans, genetic variants of BSEP, leading to an impaired transport activity or localization of the protein in the canalicular membrane, are associated with severe intrahepatic cholestasis. Efflux pumps of the basolateral hepatocyte membrane, particularly MRP3 (multidrug resistance protein 3; ABCC3) and MRP4 (multidrug resistance protein 4; ABCC4) pump substances from hepatocytes into sinusoidal blood. These efflux pumps have been recognized in recent years to play an important compensatory role in cholestasis and to contribute to the balance between uptake and efflux of substances during the vectorial transport from sinusoidal blood into bile. This sinusoidal efflux not only enables subsequent renal elimination, but also re-uptake of substances into neighboring and more centrally located hepatocytes in the sinusoid.     

Combined mutations of canalicular transporter proteins cause severe intrahepatic cholestasis of pregnancy

Intrahepatic cholestasis of pregnancy (ICP) is a cholestatic disorder that usually develops in the third trimester of pregnancy and persists until delivery. The cause of ICP remains elusive, but there is evidence that mutations in the canalicular ABC transporter phospholipid flippase (MDR3) and in the bile salt export pump (BSEP) can predispose for the development of ICP. MDR3 and BSEP were investigated by gene sequencing and immunofluorescence microscopy in a patient with severe ICP of early onset. ICP was diagnosed in a patient in the first trimester of pregnancy with severe pruritus, elevated levels of bile salts, and 48-fold elevation of transaminase levels. A liver biopsy specimen showed diminished canalicular expression of the bile salt export pump BSEP, while the expression and localization of the phospholipid flippase MDR3 was normal. Gene sequencing revealed a homozygous MDR3 gene mutation (S320F). The patient was also homozygous for the common BSEP polymorphism V444A. Treatment with ursodeoxycholate normalized transaminase levels but could not prevent further elevation of bile salt levels and preterm delivery. The combined homozygous alterations of the canalicular transporters may explain the early onset and severity of ICP in this patient. The common BSEP polymorphism V444A accounts for the reduced canalicular BSEP expression. Reduced bile salt secretion through BSEP may explain the persistence of elevated bile salt levels and incomplete efficacy of ursodeoxycholate treatment.     

Hepatocanalicular bile salt export pump deficiency in patients with progressive familial intrahepatic cholestasis

BACKGROUND & AIMS: Progressive familial intrahepatic cholestasis (PFIC), an inherited liver disease of childhood, is characterized by cholestasis and either normal or increased serum gamma-glutamyltransferase activity. Patients with normal gamma-glutamyltransferase activity have mutations of the FIC1 locus on chromosome 18q21 or mutations of the BSEP gene on chromosome 2q24. Also, patients with bile acid synthesis defects have low gamma-glutamyltransferase activity. We investigated expression of the bile salt export pump (BSEP) in liver samples from patients with a PFIC phenotype and correlated this with BSEP gene mutations. METHODS: BSEP and multidrug resistance protein 2 (MRP2) expressions were studied by immunohistochemistry in liver specimens of 28 patients and BSEP gene mutation analysis in 19 patients. Bile salt kinetics were studied in 1 patient. RESULTS: Sixteen of 28 liver samples showed no canalicular BSEP staining. Staining for MRP2 showed a normal canalicular pattern in all but 1 of these samples. Ten of 19 patients showed BSEP gene mutations; BSEP protein expression was lacking in all 10 patients. No mutations were found in 9 of 19 patients, and in all except 1, BSEP protein expression was normal. Bile salt concentration in bile of BSEP-negative/MRP2-positive PFIC patients was 0.2 +/- 0.2 mmol/L (n = 9; <1% of normal) and in BSEP-positive PFIC patients 18.1 +/- 9.9 mmol/L (n = 3; 40% of normal). The kinetic study confirmed the dramatic decrease of bile salt secretion in BSEP-negative patients. CONCLUSIONS: The findings show a close correlation between BSEP gene mutations and canalicular BSEP expression. Biliary secretion of bile salts is greatly reduced in BSEP-negative patients.     

Developmental expression of canalicular transporter genes in human liver

BACKGROUND/AIMS: BSEP, MRP2, and MDR3 are major hepatic canalicular transporters mediating bile secretion. Their expression in human liver during development has not been reported. METHODS: Human liver samples from fetus at gestational age 14-20 weeks, adult livers and liver samples of infants with biliary atresia were tested for mRNA expression of BSEP, MDR3, MRP2, NTCP, FIC1, and FXR genes by using real-time RT-PCR. Immunohistochemical staining of BSEP, MDR3, and MRP2 were performed on fetal and adult livers. RESULTS: All the genes tested were expressed at mid-gestational age. MDR3 and NTCP showed significant lower levels in fetal livers compared to adults. In patients with biliary atresia, all the genes tested showed higher mean expression levels than adults except for NTCP, but not statistically significant. The immunohistochemical staining of MRP2 in fetal liver was canalicular, BSEP showed both intracellular and canalicular staining, and MDR3 staining was faint, only occasional canalicular pattern could be seen. CONCLUSIONS: The major canalicular transporter genes are expressed at mid-gestational stage during human fetal development, but are different in expression level and targeting pattern, indicating differential regulation and maturation.     

Critical illness evokes elevated circulating bile acids related to altered hepatic transporter and nuclear receptor expression

Hyperbilirubinemia is common during critical illness and is associated with adverse outcome. Whether hyperbilirubinemia reflects intensive care unit (ICU) cholestasis is unclear. Therefore, the aim of this study was to analyze hyperbilirubinemia in conjunction with serum bile acids (BAs) and the key steps in BA synthesis, transport, and regulation by nuclear receptors (NRs). Serum BA and bilirubin levels were determined in 130 ICU and 20 control patients. In liver biopsies messenger RNA (mRNA) expression of BA synthesis enzymes, BA transporters, and NRs was assessed. In a subset (40 ICU / 10 controls) immunohistochemical staining of the transporters and receptors together with a histological evaluation of cholestasis was performed. BA levels were much more elevated than bilirubin in ICU patients. Conjugated cholic acid (CA) and chenodeoxycholic acid (CDCA) were elevated, with an increased CA/CDCA ratio. Unconjugated BA did not differ between controls and patients. Despite elevated serum BA levels, CYP7A1 protein, the rate-limiting enzyme in BA synthesis, was not lowered in ICU patients. Also, protein expression of the apical bile salt export pump (BSEP) was decreased, whereas multidrug resistance-associated protein (MRP) 3 was strongly increased at the basolateral side. This reversal of BA transport toward the sinusoidal blood compartment is in line with the increased serum conjugated BA levels. Immunostaining showed marked down-regulation of nuclear farnesoid X receptor, retinoid X receptor alpha, constitutive androstane receptor, and pregnane X receptor nuclear protein levels. CONCLUSION: Failure to inhibit BA synthesis, up-regulate canalicular BA export, and localize pivotal NR in the hepatocytic nuclei may indicate dysfunctional feedback regulation by increased BA levels. Alternatively, critical illness may result in maintained BA synthesis (CYP7A1), reversal of normal BA transport (BSEP/MRP3), and inhibition of the BA sensor (FXR/RXRα) to increase serum BA levels.     

鼠肝缺血再灌注后血浆胆红素升高的分子机制

目的探讨鼠肝缺血再灌注后血浆胆红素升高的分子机制。方法实验分为假手术组、70%的鼠肝缺血20 min再灌注组和缺血35 min再灌注组,研究时点为再灌注后的6h、1d、3d和5d。HE染色分析肝组织病理改变。常规生物化学方法检测血浆及缺血肝叶胆汁中胆红素含量的变化。RT-PCR检测肝组织多药耐药相关蛋白2（MRP2）的表达。免疫组织化学方法分析MRP2在肝细胞毛细胆管膜上的定位。结果缺血20 min组和35 min组再灌注模型炎症反应轻,无肝细胞坏死的发生。与假手术组比较,缺血20 min组血浆中胆红素含量的升高、胆汁中胆红素含量的下降发生于再灌注后的6h～1d;缺血35 min组却持续至再灌注后的3～5 d。RT-PCR发现,缺血20 min组和缺血35 min组MRP2 mRNA表达的明显下调仅发生于再灌注后的6 h。免疫组织化学法发现缺血35 min组MRP2在胞膜下呈“囊状”分布,在毛细胆管膜上的定位减少。结论MRP2在毛细胆管膜上的定位减少很可能是鼠肝缺血再灌注后血浆胆红素升高发生的分子机制。     

Changes in the expression and localization of hepatocellular transporters and radixin in primary biliary cirrhosis

BACKGROUND/AIMS: Expression and localization of human hepatocellular transporters and of radixin, cross-linking actin with some membrane transporters, may change in cholestatic liver diseases. METHODS: We investigated the uptake transporters OATP2 (SLC21A6), OATP8 (SLC21A8), and NTCP (SLC10A1), the export pumps MRP2 (ABCC2), MRP3 (ABCC3), MRP6 (ABCC6), and P-glycoproteins (ABCB1, ABCB4, ABCB11), and radixin, in non-icteric primary biliary cirrhosis (PBC stages I-III) and control human liver needle-biopsies using immunofluorescence microscopy and semi-quantitative RT-PCR. RESULTS: Expression and localization of all transporters were unchanged in PBC I-II. Immunostaining intensities of uptake transporters decreased in PBC III with a concomitant decrease in mRNA levels. Immunostaining intensities and mRNA levels of export pumps were similar in controls and PBC I-III, however, irregular MRP2 immunostaining suggested redistribution of MRP2 into intracellular structures in PBC III. Areas of irregular MRP2 immunostaining showed largely reduced radixin immunostaining, whereas normal hepatocytes had MRP2 and radixin confined to the canalicular membrane. Disrupted localization of radixin and MRP2 supports the concept that radixin contributes to the canalicular localization of MRP2. CONCLUSIONS: Down-regulation of uptake transporters may contribute to the impaired hepatobiliary elimination in advanced PBC, and partially altered localization of MRP2 may reflect the onset of changes leading to icteric PBC.     

Ursodeoxycholic acid in cholestatic liver disease: mechanisms of action and therapeutic use revisited

Ursodeoxycholic acid (UCDA) is increasingly used for the treatment of cholestatic liver diseases. Experimental evidence suggests three major mechanisms of action: (1) protection of cholangiocytes against cytotoxicity of hydrophobic bile acids, resulting from modulation of the composition of mixed phospholipid-rich micelles, reduction of bile acid cytotoxicity of bile and, possibly, decrease of the concentration of hydrophobic bile acids in the cholangiocytes; (2) stimulation of hepatobiliary secretion, putatively via Ca(2+)- and protein kinase C-alpha-dependent mechanisms and/or activation of p38(MAPK) and extracellular signal-regulated kinases (Erk) resulting in insertion of transporter molecules (e.g., bile salt export pump, BSEP, and conjugate export pump, MRP2) into the canalicular membrane of the hepatocyte and, possibly, activation of inserted carriers; (3) protection of hepatocytes against bile acid-induced apoptosis, involving inhibition of mitochondrial membrane permeability transition (MMPT), and possibly, stimulation of a survival pathway. In primary biliary cirrhosis, UDCA (13-15 mg/kg/d) improves serum liver chemistries, may delay disease progression to severe fibrosis or cirrhosis, and may prolong transplant-free survival. In primary sclerosing cholangitis, UDCA (13-20 mg/kg/d) improves serum liver chemistries and surrogate markers of prognosis, but effects on disease progression must be further evaluated. Anticholestatic effects of UDCA have also been reported in intrahepatic cholestasis of pregnancy, liver disease of cystic fibrosis, progressive familial intrahepatic cholestasis, and chronic graft-versus-host disease. Future efforts will focus on definition of additional clinical uses of UDCA, on optimized dosage regimens, as well as on further elucidation of mechanisms of action of UDCA at the molecular level.     

Interindividual variability of canalicular ATP-binding-cassette (ABC)-transporter expression in human liver

Interindividual variability in hepatic canalicular transporter expression might predispose to the development of hepatic disorders such as acquired forms of intrahepatic cholestasis. We therefore investigated expression patterns of bile salt export pump (BSEP, ABCB11), multidrug resistance protein 3 (MDR3, ABCB4), multidrug resistance associated protein 2 (MRP2, ABCC2) and multidrug resistance protein 1 (MDR1, ABCB1) in healthy liver tissue of a white population. Protein expression levels were correlated with specific single nucleotide polymorphisms (SNPs) in the corresponding transporter genes. Hepatic protein expression levels from 110 individuals undergoing liver resection were assessed by Western blot analysis of liver plasma membranes enriched in canalicular marker enzymes. Each individual was genotyped for the following synonymous (s) and nonsynonymous (ns) SNPs: ABCB11: (ns:1457T>C and 2155A>G), ABCB4: (ns:3826A>G) and ABCC2 (ns:1286G>A,3600T>A and 4581G>A) and ABCB1 (ns:2677G>T/A and s:3435C>T). Transporter expression followed unimodal distribution. However, of all tested individuals 30% exhibited a high expression and 32% a low or very low expression phenotype for at least one of the four investigated transport proteins. Transporter expression levels did not correlate with age, sex, underlying liver disease, or presurgery medication. However, low BSEP expression was associated with the 1457C-allele in ABCB11 (P = .167) and high MRP2 expression was significantly correlated with the 3600A and 4581A ABCC2 variants (P = .006). In conclusion, the results demonstrate a considerable interindividual variability of canalicular transporter expression in normal liver. Furthermore, data suggest a polymorphic transporter expression pattern, which might constitute a risk factor for the development of acquired forms of cholestatic liver diseases.     

Hepatobiliary transport of bile acids and organic anions

Recent studies have elucidated the mechanism and regulation of hepatic transport of bile acids and organic anions. Bile acids are taken up into hepatocytes by basolateral transporters, Na⁺‐dependently by Na⁺/taurocholate cotransporting polypeptide (NTCP) and Na⁺‐independently by organic anion transporting polypeptide (OATP) families. Organic anions are taken up into hepatocytes by OATP families. These compounds are then transported in hepatocytes bound to cytosolic binders, and subjected to transport by ATP binding cassette (ABC) transporters at the canalicular membrane. Amidated bile acids are excreted into bile by bile salt export pump (BSEP), and organic anions and bile acid sulfates and glucuronides are excreted by multidrug resistance protein 2 (MRP2). Hepatic transporters are downregulated under cholestasis in rats and humans, except for MRP3, a basolateral ABC transporter, which is upregulated and may have a role in removing bile acids and organic anions from hepatocytes to the blood under cholestatic conditions. Nuclear receptors, which bind bile acids, have been shown to regulate the expression of hepatic transporters. Farnesoid X receptor (FXR), which downregulates CYP7A1, the rate‐limiting enzyme of bile acid biosynthesis, upregulates BSEP and downregulates NTCP. MRP2 is upregulated by both FXR and pregnane X receptor (PXR), which upregulates CYP3A.     

4-phenylbutyrate enhances the cell surface expression and the transport capacity of wild-type and mutated bile salt export pumps

Progressive familial intrahepatic cholestasis type 2 (PFIC2) is caused by a mutation in the bile salt export pump (BSEP/ABCB11) gene. We previously reported that E297G and D482G BSEP, which are frequently found mutations in European patients, result in impaired membrane trafficking, whereas both mutants retain their transport function. The dysfunctional localization is probably attributable to the retention of BSEP in endoplasmic reticulum (ER) followed by proteasomal degradation. Because sodium 4-phenylbutyrate (4PBA) has been shown to restore the reduced cell surface expression of mutated plasma membrane proteins, in the current study, we investigated the effect of 4PBA treatment on E297G and D482G BSEP. Transcellular transport and cell surface biotinylation studies using Madin-Darby canine kidney (MDCK) II cells demonstrated that 4PBA treatment increased functional cell surface expression of wild-type (WT), E297G, and D482G BSEP. The prolonged half-life of cell surface-resident BSEP with 4PBA treatment was responsible for this result. Moreover, treatment of Sprague-Dawley rats with 4PBA resulted in an increase in BSEP expression at the canalicular membrane, which was accompanied by an increase in the biliary excretion of [(3)H]taurocholic acid (TC). CONCLUSION: 4PBA treatment with a clinically achievable concentration enhances the cell surface expression and the transport capacity of WT, E297G, and D482G BSEP in MDCK II cells, and also induces functional BSEP expression at the canalicular membrane and bile acid transport via canalicular membrane in vivo. 4PBA is a potential pharmacological agent for treating not only PFIC2 patients with E297G and D482G mutations but also other cholestatic patients, in whom the BSEP expression at the canalicular membrane is reduced.     

BSEP and MDR3 haplotype structure in healthy Caucasians, primary biliary cirrhosis and primary sclerosing cholangitis

Primary biliary cirrhosis (PBC) and primary sclerosing cholangitis (PSC) are characterized by a cholestatic pattern of liver damage, also observed in hereditary or acquired dysfunction of the canalicular membrane transporters bile salt export pump (BSEP, ABCB11) and multidrug resistance protein type 3 (MDR3, ABCB4). Controversy exists whether a genetically determined dysfunction of BSEP and MDR3 plays a pathogenic role in PBC and PSC. Therefore, 149 healthy Caucasian control individuals (control group) were compared to 76 PBC and 46 PSC patients with respect to genetic variations in BSEP and MDR3. Sequencing spanned approximately 10,000 bp including promoter and coding regions as well as 50-350 bp of flanking intronic regions. In all, 46 and 45 variants were identified in BSEP and MDR3, respectively. No differences between the groups were detected either in the total number of variants (BSEP: control group: 37, PBC: 37, PSC: 31; and MDR3: control group: 35; PBC: 32, PSC: 30), or in the allele frequency of the common variable sites. Furthermore, there were no significant differences in haplotype distribution and linkage disequilibrium. In conclusion, this study provides an analysis of BSEP and MDR3 variant segregation and haplotype structure in a Caucasian population. Although an impact of rare variants on BSEP and MDR3 function cannot be ruled out, our data do not support a strong role of BSEP and MDR3 genetic variations in the pathogenesis of PBC and PSC.     

AP2 adaptor complex mediates bile salt export pump internalization and modulates its hepatocanalicular expression and transport function

The bile salt export pump (BSEP) mediates the biliary excretion of bile salts and its dysfunction induces intrahepatic cholestasis. Reduced canalicular expression of BSEP resulting from the promotion of its internalization is one of the causes of this disease state. However, the molecular mechanism underlying BSEP internalization from the canalicular membrane (CM) remains unknown. We have shown previously that 4-phenylbutyrate (4PBA), a drug used for ornithine transcarbamylase deficiency (OTCD), inhibited internalization and subsequent degradation of cell-surface-resident BSEP. The current study found that 4PBA treatment decreased significantly the expression of α- and μ2-adaptin, both of which are subunits of the AP2 adaptor complex (AP2) that mediates clathrin-dependent endocytosis, in liver specimens from rats and patients with OTCD, and that BSEP has potential AP2 recognition motifs in its cytosolic region. Based on this, the role of AP2 in BSEP internalization was explored further. In vitro analysis with 3×FLAG-human BSEP-expressing HeLa cells and human sandwich-culture hepatocytes indicates that the impairment of AP2 function by RNA interference targeting of α-adaptin inhibits BSEP internalization from the plasma membrane and increases its cell-surface expression and transport function. Studies using immunostaining, coimmunoprecipitation, glutathione S-transferase pulldown assay, and time-lapse imaging show that AP2 interacts with BSEP at the CM through a tyrosine motif at the carboxyl terminus of BSEP and mediates BSEP internalization from the CM of hepatocytes. CONCLUSION: AP2 mediates the internalization and subsequent degradation of CM-resident BSEP through direct interaction with BSEP and thereby modulates the canalicular expression and transport function of BSEP. This information should be useful for understanding the pathogenesis of severe liver diseases associated with intrahepatic cholestasis.     

Expression of bile acid synthesis and detoxification enzymes and the alternative bile acid efflux pump MRP4 in patients with primary biliary cirrhosis.

BACKGROUND: Bile acid synthesis, transport and metabolism are markedly altered in experimental cholestasis. Whether such coordinated regulation exists in human cholestatic diseases is unclear. We therefore investigated expression of genes for bile acid synthesis, detoxification and alternative basolateral export and regulatory nuclear factors in primary biliary cirrhosis (PBC). MATERIAL/METHODS: Hepatic CYP7A1, CYP27A1, CYP8B1 (bile acid synthesis), CYP3A4 (hydroxylation), SULT2A1 (sulphation), UGT2B4/2B7 (glucuronidation), MRP4 (basolateral export), farnesoid X receptor (FXR), retinoid X receptor (RXR), short heterodimer partner (SHP), hepatocyte nuclear factor 1alpha (HNF1alpha) and HNF4alpha expression was determined in 11 patients with late-stage PBC and this was compared with non-cholestatic controls. RESULTS: CYP7A1 mRNA was repressed in PBC to 10-20% of controls, while CYP27 and CYP8B1 mRNA remained unchanged. SULT2A1, UGT2B4/2B7 and CYP3A4 mRNA levels were unaltered or only mildly reduced in PBC. MRP4 protein levels were induced three-fold in PBC, whereas mRNA levels remained unchanged. Expression levels of FXR, RXR, SHP, PXR, CAR, HNF1alpha and HNF4alpha were moderately reduced in PBC without reaching statistical significance. SUMMARY/CONCLUSIONS: Repression of bile acid synthesis and induction of basolateral bile acid export may represent adaptive mechanisms to limit bile acid burden in chronic cholestasis. As these changes do not sufficiently counteract cholestatic liver damage, future therapeutic strategies should aim at stimulation of bile acid detoxification pathways.     

Hepatic secretion of conjugated drugs and endogenous substances

Conjugate export pumps of the multidrug resistance protein (MRP) family mediate the ATP-dependent secretion of anionic conjugates across the canalicular and the basolateral hepatocyte membrane into bile and sinusoidal blood, respectively. Xenobiotic and endogenous lipophilic substances may be conjugated with glutathione, glucuronate, sulfate, or other negatively charged groups and thus become substrates for export pumps of the MRP family. The apical isoform, MRP2 (gene symbol ABCC2), has been localized to the apical membrane of several polarized epithelia and particularly to the canalicular membrane of hepatocytes. Absence of functionally active MRP2 glycoprotein from this membrane domain prevents the secretion of many anionic conjugates into bile. Prototypic endogenous substrates of high affinity for recombinant human MRP2 include bisglucuronosyl bilirubin, monoglucuronosyl bilirubin, and the glutathione S-conjugate leukotriene C4. Several mutations in the human MRP2 gene have been identified that lead to the absence of MRP2 from the canalicular membrane and to the conjugated hyperbilirubinemia of Dubin-Johnson syndrome. MRP2-mediated conjugate export represents a decisive final step in the detoxification of drugs, toxins, and endogenous substances. The basolateral isoform, MRP3 (gene symbol ABCC3), is upregulated in MRP2 deficiency and in extrahepatic cholestasis. MRP3 mediates the ATP-dependent transport of anionic conjugates, particularly of glucuronides and sulfoconjugates, across the basolateral hepatocyte membrane into sinusoidal blood. The inverse regulation of MRP3 and MRP2 expression under many conditions is consistent with their distinct localization and with a compensatory role of MRP3 in the hepatic secretion of anionic conjugates during impaired transport into bile.