Morphogenetic competence of HNF4 alpha-deficient mouse hepatic cells.

BACKGROUND/AIMS: To specify roles of HNF 4 alpha in mouse liver development, we have analyzed the ex vivo morphogenetic potential of HNF4 alpha-null embryonic hepatic cells. METHODS: Using mice with floxed or deficiency alleles of HNF4 alpha, hepatic cells lacking this transcription factor were explanted into primary culture and derived into cell lines. RESULTS: Contrary to behavior in vivo where HNF4 alpha-null liver cells fail to show normal polarity and epithelialization, e18.5 hepatic cells in primary culture from mutant embryos show restoration of apical expression of tight junction protein-1 and of transcripts for E-cadherin. Clones of control and HNF4 alpha-null cell lines were indistinguishable, even when differentiation of bile canalicular formation was induced. HNF4 alpha-null and control cell lines showed similar potential to colonize livers of the murine ALB-uPA/SCID model of liver regeneration, but null cells formed only bile ducts and not clusters of hepatocytes. Finally, analysis of mutant embryonic livers revealed a transcriptional signature consistent with a stress response, which could underlie the morphogenetic defects observed in vivo. CONCLUSIONS: We conclude that the lack of epithelialization characteristic of the HNF4 alpha-null embryonic liver is due, at least in part, to non-cell autonomous defects, and that null cells do not suffer intrinsic defects in polarization.

Threshold levels of hepatocyte nuclear factor 6 (HNF-6) acting in synergy with HNF-4 and PGC-1alpha are required for time-specific gene expression during liver development.

During liver development, hepatocytes undergo a maturation process that leads to the fully differentiated state. This relies at least in part on the coordinated action of liver-enriched transcription factors (LETFs), but little is known about the dynamics of this coordination. In this context we investigate here the role of the LETF hepatocyte nuclear factor 6 (HNF-6; also called Onecut-1) during hepatocyte differentiation. We show that HNF-6 knockout mouse fetuses have delayed expression of glucose-6-phosphatase (g6pc), which catalyzes the final step of gluconeogenesis and is a late marker of hepatocyte maturation. Using a combination of in vivo and in vitro gain- and loss-of-function approaches, we demonstrate that HNF-6 stimulates endogenous g6pc gene expression directly via a synergistic and interdependent action with HNF-4 and that it involves coordinate recruitment of the coactivator PGC-1alpha. The expression of HNF-6, HNF-4, and PGC-1alpha rises steadily during liver development and precedes that of g6pc. We provide evidence that threshold levels of HNF-6 are required to allow synergism between HNF-6, HNF-4, and PGC-1alpha to induce time-specific expression of g6pc. Our observations on the regulation of g6pc by HNF-6 provide a model whereby synergism, interdependency, and threshold concentrations of LETFs and coactivators determine time-specific expression of genes during liver development.

Identification of a liver-specific uridine phosphorylase that is regulated by multiple lipid-sensing nuclear receptors.

In this work, we report the characterization of a novel liver-specific gene (L-UrdPase), whose expression is regulated by a number of hepatic nuclear receptors (including liver X receptors, peroxisome proliferator-activated receptor alpha, farnesoid X receptor, and hepatic nuclear factor-4alpha), which have been shown to be involved in lipid metabolism. L-UrdPase encodes a previously uncharacterized protein with similarity to an intestine-specific uridine phosphorylase. Enzymatic assays confirmed that L-UrdPase has uridine phosphorylase activity. However, L-UrdPase has a highly restricted, nonoverlapping pattern of expression with its intestinal counterpart and is regulated in a distinct manner by several different nuclear receptors. The identification of the liver uridine phosphorylase and its characterization as a target of lipid-sensing nuclear receptors implies the existence of a previously unknown nuclear receptor signaling pathway that links lipid and uridine metabolism.

Mouse liver CYP2C39 is a novel retinoic acid 4-hydroxylase. Its down-regulation offers a molecular basis for liver retinoid accumulation and fibrosis in aryl hydrocarbon receptor-null mice.

Livers of aryl hydrocarbon receptor (AHR)-null mice have high levels of retinoic acid (RA), retinol, and retinyl palmitate. Hepatic accumulation of RA in these mice may be responsible in part for the hepatic phenotype characterized by small liver size and fibrosis. The increased levels of hepatic RA may be due to decreased metabolism of RA to 4-hydroxyretinoic acid. To identify the P450 isoform(s) involved in RA metabolism, liver microsomes from AHR-null and wild-type mice were subjected to Western blotting and probed with antibodies to rat P450s that cross-react with murine forms. Signal intensity in Western blots probed with anti-rat CYP2C6 antibodies correlated with levels of RA 4-hydroxylation. Furthermore, this anti-rat CYP2C6 antibody inhibited RA 4-hydroxylase activity of wild-type mouse liver microsomes to the levels of AHR-null mouse liver. When used to screen a mouse liver cDNA expression library, this antibody exclusively recognized the murine P450 CYP2C39. Catalytic assays of five recombinant mouse CYP2Cs expressed in Escherichia coli revealed that only CYP2C39 was competent for RA 4-hydroxylation (K(m) = 812.3 nm and V(max) 47.85 (fmol/min/pmol P450)). Real time reverse transcriptase-PCR used to assess the Cyp2C39 mRNA expression showed decreased levels (30%) of this transcript in AHR-null compared with wild-type liver, consistent with decreased protein levels observed by Western blot analysis using an antibody to a CYP2C39-specific peptide. These data show that CYP2C39 catalyzes RA catabolism and thus possibly controls RA levels in mouse liver. Down-regulation of Cyp2C39 is hypothesized to be responsible for the liver phenotype in the AHR-null mouse.

Defective ureagenesis in mice carrying a liver-specific disruption of hepatocyte nuclear factor 4alpha (HNF4alpha ). HNF4alpha regulates ornithine transcarbamylase in vivo.

Hepatocyte nuclear factor 4alpha (HNF4alpha) regulates the expression of many genes preferentially expressed in liver. HNF4alpha-null mice die during embryogenesis precluding the analysis of its function in the adult. To circumvent this problem, liver-specific HNF4alpha-null mice were produced. Mice lacking hepatic HNF4alpha expression exhibited increased serum ammonia and reduced serum urea. This disruption in ureagenesis may be explained by a marked decrease in expression and activity of hepatic ornithine transcarbamylase (OTC). To determine the molecular mechanisms involved in transcriptional regulation of the mouse OTC gene, the OTC promoter region was analyzed. Sequence analysis revealed the presence of two putative HNF4alpha-binding sites in the mouse OTC promoter region. By using transient transfection analysis, it was established that high levels of promoter activity were dependent on both HNF4alpha-binding sites and the expression of HNF4alpha. Furthermore, the proximal HNF4alpha-binding site was found to be more important than the distal one for transactivating OTC promoter. These data demonstrate that HNF4alpha is critical for urea homeostasis by direct regulation of the OTC gene in vivo.