Loss of orphan receptor small heterodimer partner sensitizes mice to liver injury from obstructive cholestasis

The orphan nuclear hormone receptor small heterodimer partner (SHP) regulates the expression of several genes involved in bile acid homeostasis in the liver. Because bile acid toxicity is a major source of liver injury in cholestatic disease, we explored the role of SHP in liver damage induced by common bile duct ligation (BDL). Shp(-/-) mice show increased sensitivity in this model of acute obstructive cholestasis, with greater numbers of bile infarcts and higher mortality than wild-type C57BL/6 mice. This increased sensitivity could not be accounted for by differences in expression of bile acid homeostatic genes 2 or 5 days after BDL. Instead, higher basal expression of such genes, including the key biosynthetic enzyme cholesterol 7alpha hydroxylase (Cyp7A1) and the bile salt export pump, is associated with both an increase in bile flow prior to BDL and an increase in acute liver damage at only 1.5 hours after BDL in Shp(-/-) mice, as shown by bile infarcts. At 3 hours, Cyp7A1 expression still remained elevated in Shp(-/-) with respect to wild-type mice, and the hepatic and serum bile acid levels and total hepatobiliary bile acid pool were significantly increased. The increased sensitivity of mice lacking SHP contrasts with the decreased sensitivity of mice lacking the farnesoid X receptor (FXR; nuclear receptor subfamily 1, group H, member 4) to BDL, which has been associated with decreased intraductal pressure and fewer bile infarcts. Conclusion: We propose that differences in acute responses to BDL, particularly the early formation of bile infarcts, are a primary determinant of the differences in longer term sensitivity of the Fxr(-/-) and Shp(-/-) mice to acute obstructive cholestasis.     

Serotonin protects mouse liver from cholestatic injury by decreasing bile salt pool after bile duct ligation

Obstructive cholestasis induces liver injury, postoperative complications, and mortality after surgery. Adaptive control of cholestasis, including bile salt homeostasis, is necessary for recovery and survival. Peripheral serotonin is a cytoprotective neurotransmitter also associated with liver regeneration. The effect of serotonin on cholestatic liver injury is not known. Therefore, we tested whether serotonin affects the severity of cholestatic liver injury. We induced cholestasis by ligation of the bile duct (BDL) in either wild-type (WT) mice or mice lacking peripheral serotonin (Tph1(-/-) and immune thrombocytopenic [ITP] mice). Liver injury was assessed by the levels of plasma aspartate aminotransferase (AST), alanine aminotransferase (ALT) and tissue necrosis. Bile salt-regulating genes were measured by quantitative polymerase chain reaction and confirmed by western blotting and immunohistochemistry. Tph1(-/-) mice displayed higher levels of plasma AST, ALT, bile salts, and hepatic necrosis after 3 days of BDL than WT mice. Likewise, liver injury was disproportional in ITP mice. Moreover, severe cholestatic complications and mortality after prolonged BDL were increased in Tph1(-/-) mice. Despite the elevation in toxic bile salts, expression of genes involved in bile salt homeostasis and detoxification were not affected in Tph1(-/-) livers. In contrast, the bile salt reabsorption transporters Ostα and Ostβ were up-regulated in the kidneys of Tph1(-/-) mice, along with a decrease in urinary bile salt excretion. Serotonin reloading of Tph1(-/-) mice reversed this phenotype, resulting in a reduction of circulating bile salts and liver injury. CONCLUSION: We propose a physiological function of serotonin is to ameliorate liver injury and stabilize the bile salt pool through adaptation of renal transporters in cholestasis.     

Nuclear receptors constitutive androstane receptor and pregnane X receptor ameliorate cholestatic liver injury

Cholestasis is associated with accumulation of bile acids and lipids, and liver injury. The constitutive androstane receptor (CAR) and pregnane X receptor (PXR) are xenobiotic nuclear receptors that coordinate protective hepatic responses to potentially toxic stimuli, including bile acids. We investigated the role of these receptors in the regulation of bile acid and lipid metabolism in a bile duct ligation (BDL) model of cholestasis applied to receptor knockout mice. Hepatic damage from bile acid accumulation was increased in both CAR knockout (CARKO) and PXR knockout mice, but bile acid concentrations were lower in CARKO mice. High-density lipoprotein (HDL) cholesterol was elevated in CARKO mice, and serum total cholesterol increased less in CARKO or PXR knockout mice than WT mice after BDL. Gene expression analysis of the BDL knockout animals demonstrated that, in response to cholestasis, PXR and CAR both repressed and induced the specific hepatic membrane transporters Oatp-c (organic anion transporting polypeptide C) and Oatp2 (Na⁺-dependent organic anion transporter 2), respectively. Induction of the xenobiotic transporter multidrug resistance protein 1 in cholestasis was independent of either PXR or CAR, in contrast to the known pattern of induction of multidrug resistance protein 1 by xenobiotics. These results demonstrate that CAR and PXR influence cholesterol metabolism and bile acid synthesis, as well as multiple detoxification pathways, and suggest their potential role as therapeutic targets for the treatment of cholestasis and lipid disorders.     

Cholestatic interleukin-6-deficient mice succumb to endotoxin-induced liver injury and pulmonary inflammation

Circulating and hepatic interleukin (IL)-6 levels are strongly increased during clinical and experimental cholestasis. Cholestatic liver injury is associated with increased susceptibility to endotoxin-induced toxicity. To determine the role of IL-6 herein, extrahepatic cholestasis was induced by bile duct ligation (BDL) in IL-6-gene deficient (IL-6(-/-)) and normal (IL-6(+/+)) mice. BDL elicited increased levels of hepatic IL-6 mRNA and protein in normal mice. Hepatocellular injury 2 weeks after BDL was similar in IL-6(-/-) and IL-6(+/+) mice as demonstrated by clinical chemistry and histopathology. Administration of endotoxin to cholestatic mice 2 weeks after BDL was associated with enhanced cytokine release, severe liver damage, and death when compared with sham-operated mice. Effects of endotoxin were largely similar in sham-operated IL-6(-/-) and IL-6(+/+) mice, but cholestatic IL-6(-/-) mice were more susceptible to the toxic effects of endotoxin, as reflected by increased cytokine release, more profound liver injury and lung inflammation, and higher mortality. Although endogenous IL-6 is not important in the development of liver injury after experimentally induced obstructive jaundice, this cytokine plays an important role in decreasing hypersensitivity to endotoxin in cholestatic mice.     

Increased expression of multidrug resistance-associated protein 1 (mrp1) in hepatocyte basolateral membrane and renal tubular epithelia after bile duct ligation in rats

Components of the multidrug resistance-associated protein (mrp) family mediate the adenosine triphosphate (ATP)-dependent transport of conjugated organic anions in the liver. Of these, mrp1 and mrp2 have been shown to have similar substrate specificity and nucleotide sequence. The intracellular localization and distribution of mrp1 under normal condition and cholestasis have not been as yet completely elucidated. To clarify this point, in the present study we evaluated the intracellular localization of mrp1 in rat liver and kidney after bile duct ligation (BDL). Bile duct was ligated in Wistar rats. Sequential staining of mrp1 by immunofluorescence was carried out in rat liver and kidneys 1, 3, and 5 days after bile duct ligation using confocal laser scanning microscopy. Weak granular staining of mrp1 was observed in cytoplasm of control rat hepatocytes. In addition to increased cytoplasm staining of mrp1, belt-and granule-like staining of mrp1 in basolateral membrane of hepatocytes was also shown after BDL. Furthermore, mrp1 immunofluorescence increased over time after BDL. No specific immunoflurescence of mrp1 was detected in control rat kidney. However, mrp1-positive staining was observed in epithelia of some renal tubules after BDL. This study showed that mrp1 immunofluorescence increased in hepatocyte basolateral membrane and cytoplasm and epithelia of some renal tubules after BDL. This increased mrp1 expression may be an adaptive response to impairment of hepato-biliary organic anion transport during obstructive cholestasis.     

Hepatocyte apoptosis after bile duct ligation in the mouse involves Fas.

BACKGROUNS & AIMS: Cholestatic liver injury results from the intrahepatic accumulation of toxic bile salts. Toxic bile salt-induced hepatocyte apoptosis in vitro is Fas dependent. The aim of this study was to ascertain if hepatocyte apoptosis in vivo during cholestasis is Fas dependent. METHODS: Studies were performed in bile duct-ligated (BDL) Fas-deficient lpr (lymphoproliferation) and wild-type mice. RESULTS: Hepatocyte apoptosis was the predominant mechanism of cell death as determined by terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate nick-end labeling and trypan blue assays to quantitate apoptosis and necrosis. The mechanisms of hepatocyte apoptosis were dependent on the presence or absence of the Fas receptor and the duration of BDL. After BDL of 3 days' duration, increased hepatocyte apoptosis occurred only in wild-type but not lpr mice, indicating the apoptosis was Fas dependent. In contrast, after BDL of >/=7 days, hepatocyte apoptosis also occurred in lpr animals consistent with a Fas-independent mechanism of apoptosis. Hepatocyte apoptosis in BDL lpr mice was associated with an increase in Bax expression and Bax association with mitochondria. CONCLUSIONS: During extrahepatic cholestasis, hepatocyte apoptosis is mediated by Fas. However, in the absence of the Fas receptor, additional mechanisms of hepatocyte apoptosis occur. Inhibition of multiple apoptotic pathways is necessary to attenuate chronic cholestatic liver injury.     

Hyperstimulation with interleukin 6 inhibits cell cycle progression after hepatectomy in mice

Interleukin 6 (IL-6) is an important mediator of hepatocyte proliferation after hepatectomy. However, elevated IL-6 levels are found in patients with chronic liver disease. Therefore, it is unclear if hyperstimulation with IL-6 may have an influence on liver regeneration. We investigated whether a strong activation of IL-6-dependent pathways may change the course of hepatocyte proliferation after hepatectomy. Transgenic mice overexpressing the human soluble IL-6 receptor/gp80 (hsgp80) in hepatocytes were stimulated with or without hepatectomy with human IL-6 (hIL-6). Nuclear extracts were prepared and activation of gp130-dependent pathways was studied by Western blot and gel shift experiments. Cell cycle progression of hepatocytes after hepatectomy was investigated by monitoring cell cycle-specific factors. hIL-6 strongly activates Stat3 for more than 48 hours in human soluble hsgp80 transgenic mice. In contrast, no major differences were evident in the regulation of the Ras/MAP kinase pathway compared with wild-type (wt) mice. Also when hsgp80 mice were stimulated with hIL-6 3 hours before hepatectomy Stat3 is activated for more than 72 hours, whereas in unstimulated mice this event is restricted to the early hours. Strong activation of Stat3 resulted in a delay and inhibition of hepatocyte proliferation as measured by 5-bromo-2'-deoxyuridine (BrdU) staining and Cyclin A and E expression. This observation directly correlates with the induction of the cell cycle inhibitor p21. In summary, strong IL-6-dependent activation of Stat3 before hepatectomy results in delay and inhibition of cell cycle progression after hepatectomy. Therefore our results suggest that hyperstimulation with IL-6 can inhibit liver regeneration.     

Endogenous interferon gamma protects against cholestatic liver injury in mice

Cholestatic patients suffer from high perioperative morbidity and mortality, but the pathophysiology is still unknown. Interferon gamma (IFN-gamma) may play a role during cholestasis. Therefore, bile duct ligation (BDL) was induced in IFN-gamma alpha-chain receptor-deficient (IFN-gammaR(1)-/-) and wild-type (IFN-gammaR(1)+/+) mice. BDL elicited increased IFN-gamma messenger RNA and protein levels in the liver. One week after BDL, IFN-gammaR(1)+/+ mice showed less severe jaundice and liver injury than IFN-gammaR(1)-/- mice, as reflected by lower bilirubin and liver enzyme levels. In accordance, livers of IFN-gammaR(1)+/+ mice displayed smaller areas of necrosis by two-thirds than IFN-gammaR(1)-/- mice on histopathologic examination (P <.05), whereas mitotic activity and proliferating cell nuclear antigen (PCNA) labeling index was more than twice as high in IFN-gammaR(1)+/+ mice (P <.05). Livers of IFN-gammaR(1)+/+ mice displayed higher rates of apoptosis as indicated by DNA fragmentation rate, the number of apoptotic bodies, and poly ADP-ribose polymerase (PARP) immunostaining. BDL was not associated with lethality in IFN-gammaR(1)+/+ mice; IFN-gammaR(1)-/- mice, however, died from 10 days onward and survival after 2 weeks was 62% (10 of 16). In conclusion, these data suggest that IFN-gamma protects against liver injury during extrahepatic cholestasis by stimulation of apoptosis and subsequent proliferation of hepatocytes, leading to elegant removal of damaged hepatocytes, thus preventing necrosis and concomitant inflammatory responses.     

Acute obstructive cholangiopathy in interleukin-6 deficient mice: compensation by leukemia inhibitory factor (LIF) suggests importance of gp-130 signaling in the ductular reaction

AIM: The hypothesis that interleukin-6-IL-6/gp130 signaling is involved in liver and biliary epithelial cell (BEC) biology and growth control was tested by subjecting homozygous IL-6 deficient mice (IL-6-/-) and wild type (IL-6+/+) littermate controls to bile duct ligation (BDL). MATERIALS AND METHODS: During the first week after BDL, the two groups were compared with respect to routine liver injury tests, liver histology, BEC and hepatocyte DNA synthesis, together with the expression of mRNA and protein of IL-6 as well as related growth factors, and their receptors. RESULTS: During the first week after BDL, there was marked upregulation of IL-6 mRNA and protein in the IL-6+/+ mice only in the vicinity of the biliary tree; whereas, biliary/peri-biliary IL-6R, HGF and met mRNA and protein increased in both groups. IL-6, HGF mRNA and protein localized to periductal inflammatory cells and stellate cells, while met and IL-6R protein were upregulated in the BEC and, to a lesser extent, in hepatocytes. This occurred during maximal proliferation of the BEC. Despite the absence of IL-6 in the IL-6-/- mice, there were only mildly phenotypic differences between the two groups, and no differences in mortality. Compared to IL-6+/+ controls, IL-6-/- mice showed slightly less BEC proliferation, a trend toward more liver injury, and significantly higher total serum bilirubin (TB) levels, suggestive of impaired biliary tree integrity. These changes were associated with slightly less HGF mRNA and protein expression in the IL-6-/- mice, but the differences were not significant. Leukemia inhibitory factor (LIF), another gp-130 ligand, also showed marked peri-biliary upregulation after BDL in both groups, and also induced BEC DNA synthesis, in vitro. CONCLUSIONS: The mild phenotypical differences between IL-6+/+ and IL-6-/- mice in the acute response to BDL is most likely attributable to the redundancy of the gp-130 signaling system. However, the long-term response to BDL results in a distinct phenotype in the IL-6-/- mice, marked by a relentless rise in serum total bilirubin and an inability to maintain compensatory increase in liver mass.     

Kupffer cells abrogate cholestatic liver injury in mice

BACKGROUND & AIMS: Biliary obstruction and cholestasis can cause hepatocellular apoptosis and necrosis. Ligation of the common bile duct in mice provides an excellent model in which to study the underlying mechanisms. Kupffer cells play a key role in modulating the inflammatory response observed in most animal models of liver injury. This study was performed to determine the role of Kupffer cells in the injury attending cholestasis. METHODS: Mice were not treated or were rendered Kupffer cell-depleted by intravenous inoculation of multilamellar liposome-encapsulated dichloromethylene diphosphonate, the common bile duct was ligated and divided; sham-operated animals served as controls. Similarly, interleukin-6 (IL-6)-deficient and tumor necrosis factor-receptor-deficient mice underwent bile duct ligation (BDL) or sham operations. RESULTS: Serum alanine transaminase levels were increased in all BDL mice at 3 days after surgery, but were significantly higher in IL-6-deficient mice or mice rendered Kupffer cell-depleted before ligation. Histologic examination of BDL livers showed portal inflammation, neutrophil infiltration, bile duct proliferation, and hepatocellular necrosis. Photoimage analyses confirmed more necrosis in the livers of Kupffer cell-depleted and IL-6-deficient animals. Purified Kupffer cells derived from BDL animals produced more IL-6 in culture. Similarly, Kupffer cells obtained by laser capture microdissection from the livers of BDL mice expressed increased levels of IL-6 messenger RNA. Recombinant mouse IL-6 administered 1 hour before BDL completely reversed the increased liver damage assessed otherwise in Kupffer cell-depleted mice. CONCLUSIONS: These findings indicate that Kupffer cells abrogate cholestatic liver injury by cytokine-dependent mechanisms that include the production of IL-6.     

Toll-like receptors 2 and 4 are differentially involved in Fas dependent apoptosis in Peyer's patch and the liver at an early stage after bile duct ligation in mice

BACKGROUND AND AIMS: Surgical management of extrahepatic cholestasis is frequently complicated by bacterial translocation and severe liver injury. The aim of this study was to clarify the involvement of Toll-like receptors (TLRs) in the pathogenesis of bacterial translocation and liver injury in obstructive cholestasis. METHODS: TLR2 deficient (TLR2(-/-)), MyD88(-/-), Jalpha281(-/-), gld/gld, and lpr/lpr mice, all of which have a C57BL/6 background, and C3H/HeN and TLR4 mutated C3H/HeJ mice were subjected to bile duct ligation (BDL). Faecal IgA and serum alanine aminotransferase levels were determined after BDL. Apoptosis was examined by histological and flow cytometric analyses of cells from Peyer's patches and the liver. RESULTS: The size and number of B cells in Peyer's patches markedly decreased on day 3 after BDL. Increased apoptosis in Peyer's patch B cells was evident on day 1 after BDL in control mice but not in lpr/lpr, MyD88(-/-), or C3H/HeJ mice. On the other hand, TLR2 and Fas ligand expression on intrahepatic NK1.1(+) T cells increased on day 1 after BDL in C57BL/6 mice. Liver injury and apoptosis were evident on day 1 after BDL in control and C3H/HeJ mice but were significantly reduced in TLR2(-/-), Jalpha281(-/-), gld/gld, and lpr/lpr mice. CONCLUSIONS: TLR4 and TLR2 may play important roles in Fas dependent apoptosis in Peyer's patch B cells and hepatocytes, respectively, at an early stage after BDL in mice.     

Lack of gp130 expression in hepatocytes promotes liver injury

BACKGROUND & AIMS: Interleukin 6 (IL-6) contributes via its signal transducer gp130 to the acute phase response (APR) in hepatocytes. Recent studies indicated that IL-6 is involved in the regulation of different pathophysiologic conditions of the liver. To define the IL-6-dependent intracellular pathways more specifically, we generated a hepatocyte-specific gp130 knockout mouse. METHODS: Hepatocyte-specific gp130-deficient mice were generated using the Cre-loxP system. Expression of the Cre recombinase was under the control of a hepatocyte-specific control element. Adult mice were challenged with IL-6, oncostatin M (OSM), and LPS. RESULTS: Cre expression started at day 10.5 postconception, and a complete deletion of gp130 in hepatocytes was found at day 14 during liver development. The adult liver of these mice showed no abnormalities; however, after IL-6 and OSM stimulation, gp130-dependent pathways (STAT3, APR gene expression) were completely blocked in the liver of these animals. Additionally, challenging hepatocyte-specific gp130 knockout animals with lipopolysaccharides (LPS) lead to an onset of acute liver injury with an increase of hepatocyte apoptosis associated with elevated tumor necrosis factor alpha (TNF-alpha) serum levels and reduced nuclear factor kappaB (NF-kappaB) activation in hepatocytes. CONCLUSIONS: Our findings demonstrate that gp130 is of minor relevance for embryonal development of hepatocytes. However, the molecule has an essential role in controlling acute phase gene expression and provides hepatocellular protection after LPS challenge.     

Mutual changes of thioredoxin and nitrosothiols during biliary cirrhosis: results from humans and cholestatic rats

Cholestasis is associated with changes in NO metabolism and thiol oxidation. Thioredoxin contributes to regulate vascular tone and intracellular redox status by cleaving nitrosothiols and maintaining -SH groups. This study investigated the changes in circulating thioredoxin and nitrosothiols and the relationship with protein sulfhydryls (PSH), hepatic concentrations, hyaluronate, and histology in patients with primary biliary cirrhosis (PBC) and in rats with bile duct ligation (BDL). PSH in erythrocytes were significantly decreased in stage III and IV PBC and at day 10 after BDL. Compared with controls, erythrocyte thioredoxin levels were higher in stage I through III PBC and lower in stage IV patients. Serum thioredoxin levels were significantly higher in PBC stages I and II and lower in stages III and IV. Serum nitrosothiols were higher in all PBC patients and inversely related to thioredoxin and hyaluronate. In rats, serum, hepatic, and mitochondrial thioredoxin had initially increased after BDL (day 1-3) and then decreased. After day 7 BDL, nitrosothiols were 10-fold increased in serum and liver, and even higher in mitochondria. In the liver, thioredoxin was inversely related to both nitrosothiols and PSH. In rats, the difference in time average changes from baseline among serum, hepatic, and erythrocyte thioredoxin suggests that most of circulating thioredoxin originates from the liver. Conclusion: Our findings indicate that cholestasis is associated with significant mutual and interrelated changes between circulating and hepatic thioredoxin and nitrosothiols. The increase of hepatic, mitochondrial, and circulating nitrosothiols with ongoing cholestasis suggests an active participation of NO in both liver injury and extrahepatic changes.     

Acute obstructive cholangiopathy in interleukin‐6 deficient mice: compensation by leukemia inhibitory factor (LIF) suggests importance of gp‐130 signaling in the ductular reaction

Abstract: Aim: The hypothesis that interleukin‐6‐IL‐6/gp130 signaling is involved in liver and biliary epithelial cell (BEC) biology and growth control was tested by subjecting homozygous IL‐6 deficient mice (IL‐6^?/?) and wild type (IL‐6^+/+) littermate controls to bile duct ligation (BDL). Materials and methods: During the first week after BDL, the two groups were compared with respect to routine liver injury tests, liver histology, BEC and hepatocyte DNA synthesis, together with the expression of mRNA and protein of IL‐6 as well as related growth factors, and their receptors. Results: During the first week after BDL, there was marked upregulation of IL‐6 mRNA and protein in the IL‐6^+/+ mice only in the vicinity of the biliary tree; whereas, biliary/peri‐biliary IL‐6R, HGF and met mRNA and protein increased in both groups. IL‐6, HGF mRNA and protein localized to periductal inflammatory cells and stellate cells, while met and IL‐6R protein were upregulated in the BEC and, to a lesser extent, in hepatocytes. This occurred during maximal proliferation of the BEC. Despite the absence of IL‐6 in the IL‐6^?/? mice, there were only mildly phenotypic differences between the two groups, and no differences in mortality. Compared to IL‐6^+/+ controls, IL‐6^?/? mice showed slightly less BEC proliferation, a trend toward more liver injury, and significantly higher total serum bilirubin (TB) levels, suggestive of impaired biliary tree integrity. These changes were associated with slightly less HGF mRNA and protein expression in the IL‐6^?/? mice, but the differences were not significant. Leukemia inhibitory factor (LIF), another gp‐130 ligand, also showed marked peri‐biliary upregulation after BDL in both groups, and also induced BEC DNA synthesis, in vitro. Conclusions: The mild phenotypical differences between IL‐6^+/+ and IL‐6^?/? mice in the acute response to BDL is most likely attributable to the redundancy of the gp‐130 signaling system. However, the long‐term response to BDL results in a distinct phenotype in the IL‐6^?/? mice, marked by a relentless rise in serum total bilirubin and an inability to maintain compensatory increase in liver mass.     

Impaired ketogenesis is a major mechanism for disturbed hepatic fatty acid metabolism in rats with long-term cholestasis and after relief of biliary obstruction

BACKGROUND/AIMS: Rats with long-term cholestasis have reduced ketosis of unknown origin. METHODS: Fatty acid metabolism was studied in starved rats with biliary obstruction for 4 weeks (bile duct ligated rats = BDL rats), and 3, 7, 14, 28 and 84 days after reversal of biliary obstruction by Roux-en-Y anastomosis (RY rats), and in sham-operated control rats. RESULTS: BDL rats had reduced beta-hydroxybutyrate concentrations in plasma (0.25 +/- 0.10 vs. 0.75 +/- 0.20 mmol/l) and liver (2.57 +/- 0.20 vs. 4.63 +/- 0.61 micromol/g) which increased after restoring bile flow. Hepatic expression and activity of carnitine palmitoyltransferase I (CPT I) or CPT II were unaffected or decreased in BDL rats, respectively, and increased after restoring bile flow. Oxidative metabolism of different substrates by isolated liver mitochondria and activation of palmitate were reduced in BDL rats and recovered 7-14 days after restoring bile flow. Ketogenesis was decreased in mitochondria from BDL rats and recovered 3 months after restoring bile flow. Both mRNA and protein expression of hydroxymethylglutaryl-coenzyme A synthase (HMG-CoA synthase), the rate-limiting enzyme of ketogenesis, was reduced in livers of BDL rats and increased after reversing biliary obstruction. CONCLUSIONS: In BDL rats, impairment of hepatic fatty acid metabolism is multifactorial. After reversing biliary obstruction, reduced activity of HMG-CoA synthase is the major factor.