Tumour suppressor p53 down-regulates the expression of the human hepatocyte nuclear factor 4alpha (HNF4alpha) gene

The liver is exposed to a wide variety of toxic agents, many of which damage DNA and result in increased levels of the tumour suppressor protein p53. We have previously shown that p53 inhibits the transactivation function of HNF (hepatocyte nuclear factor) 4alpha1, a nuclear receptor known to be critical for early development and liver differentiation. In the present study we demonstrate that p53 also down-regulates expression of the human HNF4alpha gene via the proximal P1 promoter. Overexpression of wild-type p53 down-regulated endogenous levels of both HNF4alpha protein and mRNA in Hep3B cells. This decrease was also observed when HepG2 cells were exposed to UV irradiation or doxorubicin, both of which increased endogenous p53 protein levels. Ectopically expressed p53, but not a mutant p53 defective in DNA binding (R249S), down-regulated HNF4alpha P1 promoter activity. Chromatin immunoprecipitation also showed that endogenous p53 bound the HNF4alpha P1 promoter in vivo after doxorubicin treatment. The mechanism by which p53 down-regulates the P1 promoter appears to be multifaceted. The down-regulation was partially recovered by inhibition of HDAC activity and appears to involve the positive regulator HNF6alpha. p53 bound HNF6alpha in vivo and in vitro and prevented HNF6alpha from binding DNA in vitro. p53 also repressed stimulation of the P1 promoter by HNF6alpha in vivo. However, since the R249S p53 mutant also bound HNF6alpha, binding HNF6alpha is apparently not sufficient for the repression. Implications of the p53-mediated repression of HNF4alpha expression in response to cellular stress are discussed.     

Transcriptional control of the human aldehyde dehydrogenase 2 promoter by hepatocyte nuclear factor 4: inhibition by cyclic AMP and COUP transcription factors.

An important regulatory element (designated FP330-3') of the ALDH2 promoter mediates activation by hepatocyte nuclear factor 4 (HNF4). This activation of promoter constructs containing this element by HNF4 was reduced by nearly half by 8-Br-cAMP in H4IIEC3 cells, an effect that was blocked by inhibitors of protein kinase A (PKA). Cotransfection assays showed that COUP-TF I, ARP-1, or PPARdelta suppressed the ability of HNF4 to activate the reporter. The repression was potentiated by 8-Br-cAMP. Electrophoretic mobility shift assays revealed that treatment of hepatoma cells or cultured rat hepatocytes with 1 mM 8-Br-cAMP or glucagon reduced binding of FP330-3' by HNF4 by half. In vitro phosphorylation of HNF4 by PKA decreased binding to FP330-3'. Fasting reduced the ALDH2 protein level in liver and kidney, two tissues expressing HNF4, but not heart. These data suggest that ALDH2 expression can be suppressed by cAMP, most likely through phosphorylation of HNF4 by PKA, and this may account for the reduction in enzyme protein during fasting.     

Hepatocyte nuclear factor 4α regulates the expression of the murine pyruvate carboxylase gene through the HNF4-specific binding motif in its proximal promoter

Pyruvate carboxylase (PC) is the first regulatory enzyme of gluconeogenesis. Here we report that the proximal promoter of the murine PC gene contains three binding sites for hepatocyte nuclear factor 4α (HNF4α). These sites include the classical direct repeat 1 (DR1) (− 386/− 374), non-perfect DR1 (− 118/− 106) and HNF4α-specific binding motif (H4-SBM) (− 26/− 14). Under basal conditions, mutation of the non-perfect DR1 decreased promoter activity by 50%, whereas mutation of neither the DR1 nor the H4-SBM had any effect. In marked contrast, only mutation of the H4-SBM decreased HNF4α-transactivation of the promoter activity by 65%. EMSA revealed that HNF4α binds to the DR1site and H4-SBM with similar affinity while it binds poorly to the non-perfect DR1. Interestingly, this non-perfect DR1 also coincides with two E-boxes. Mutation of the non-perfect DR1 together with the nearby E-box reduced USF1- but not USF2-transactivation of promoter activity, suggesting that USF1 partly contributes to the basal activity of the promoter. Substitution of the H4-SBM with the DR1 marginally reduced the basal promoter activity but did not eliminate HNF4α-transactivation, suggesting that HNF4α can exert its effect via DR1 within this promoter context. ChIP-assay confirmed that HNF4α is associated with the H4-SBM. Suppression of HNF4α expression in AML12 cells down-regulated PC mRNA and PC protein by 60% and 50%, respectively, confirming that PC is a target of HNF4α. We also propose a model for differential regulation of P1 promoter of PC gene in adipose tissue and liver.