The Forkhead Box (Fox) proteins are an extensive family of transcription factors that shares homology in the winged helix DNAbinding domain and whose members play essential roles in cellular proliferation, differentiation, transformation, longevity, and metabolic homeostasis. Liver regeneration studies with transgenic mice demonstrated that FoxM1B regulates the onset of hepatocyte DNA replication and mitosis by stimulating expression of cell cycle genes. Here, we demonstrate that albumin-promoter-driven Cre recombinase-mediated hepatocyte-specific deletion of the Foxm1b Floxed (fl) targeted allele resulted in significant reduction in hepatocyte DNA replication and inhibition of mitosis after partial hepatectomy. Reduced DNA replication in regenerating Foxm1b ؊/؊ hepatocytes was associated with sustained increase in nuclear staining of the cyclin-dependent kinase (Cdk) inhibitor p21 Cip1 (p21) protein between 24 and 40 h after partial hepatectomy. Furthermore, increased nuclear p21 levels and reduced expression of Cdc25A phosphatase coincided with decreases in Cdk2 activation and hepatocyte progression into S-phase. Moreover, the significant reduction in hepatocyte mitosis was associated with diminished mRNA levels and nuclear expression of Cdc25B phosphatase and delayed accumulation of cyclin B1 protein, which is required for Cdk1 activation and entry into mitosis. Cotransfection studies demonstrate that FoxM1B protein directly activated transcription of the Cdc25B promoter region. Our present study shows that the mammalian Foxm1b transcription factor regulates expression of cell cycle proteins essential for hepatocyte entry into DNA replication and mitosis.knock-out mouse ͉ Cdc25A ͉ Cdc25B ͉ cyclin-dependent kinase inhibitor p21 Cip1
Conditional deletion of the mouse Forkhead Box (Fox) m1b targeted allele in adult hepatocytes (Foxm1, previously called HFH-11B, Trident, Win, or MPP2) demonstrated that the Foxm1b transcription factor is essential for hepatocyte mitosis during liver regeneration. To determine the role of Foxm1b in liver development, we have generated Foxm1b -/- mice that deleted the Foxm1b exons encoding the winged helix DNA binding and transcriptional activation domains. Here, we show that all of the Foxm1b -/- embryos died in utero by 18.5 days postcoitum (dpc). Embryonic Foxm1b -/- livers displayed a 75% reduction in the number of hepatoblasts, resulting from diminished DNA replication and a failure to enter mitosis causing a polyploid phenotype. Reduced hepatoblast mitosis was associated with decreased protein levels of the Polo-like kinase 1 and Aurora B kinase, which phosphorylate regulatory proteins essential for orchestrating mitosis and cytokinesis. Diminished proliferation of Foxm1b -/- hepatoblasts contributed to abnormal liver development with significant reduction in the number of large hepatic veins compared to embryonic wild-type (WT) liver. Furthermore, embryonic Foxm1b -/- livers did not develop intrahepatic bile ducts, and these presumptive biliary hepatoblasts failed to express either biliary cytokeratins or nuclear levels of hepatocyte nuclear factor 1beta. These results suggest that Foxm1b is critical for hepatoblast precursor cells to differentiate toward biliary epithelial cell lineage. Finally, we used a hepatoblast-specific Cre recombinase transgene to mediate deletion of the Foxm1b fl/fl allele in the developing liver, and these embryos died in utero and exhibited diminished hepatoblast proliferation with similar abnormalities in liver morphogenesis, suggesting that the defect in liver development contributed to embryonic lethality.
Recent liver regeneration studies indicate that maintaining hepatic Forkhead Box M1B (FoxM1B) expression in 12-month-old (old-aged) Transthyretin-FoxM1B transgenic mice increases hepatocyte proliferation and expression of cell cycle regulatory genes. Because these transgenic CD-1 mice maintain FoxM1B levels during the aging process, we conducted the current study to determine whether adenovirus delivery of the FoxM1B gene (AdFoxM1B) is sufficient to stimulate liver regeneration in old-aged Balb/c mice. Here we show that AdFoxM1B infection of old-aged mice caused a significant increase in FoxM1B expression, hepatocyte DNA replication, and mitosis following partial hepatectomy. This stimulation in hepatocyte S-phase progression was associated with diminished protein expression and perinuclear localization of cyclin-dependent kinase (Cdk) inhibitor p27Kip1 (p27) protein following partial hepatectomy. In contrast, old-aged mice infected with control virus displayed high hepatocyte levels of p27 protein, which had been localized to the nucleus prior to S-phase. Furthermore, we found that restoring FoxM1B expression did not influence p27 mRNA levels, and this new finding implicates FoxM1B in regulation of p27 protein levels. Likewise, AdFoxM1B-infected regenerating livers displayed elevated S-phase levels of Cdk2 kinase activity compared with old-aged mice infected with control virus. Furthermore, restoring FoxM1B expression in old-aged mice caused elevated levels of Cyclin B1, Cyclin B2, Cdc25B, Cdk1, and p55CDC mRNA as well as stimulating Cdc25B nuclear localization during liver regeneration, all of which are required for mitosis. These studies indicated that an acute delivery of the FoxM1B gene in old-aged mice is sufficient to re-establish proliferation of regenerating hepatocytes, suggesting that FoxM1B can be used for therapeutic intervention to alleviate the reduction in cellular proliferation observed in the elderly.
The Forkhead Box (Fox) proteins are an extensive family of transcription factors that shares homology in the winged helix DNA-binding domain and the members of which play essential roles in cellular proliferation, differentiation, and longevity. Reduced cellular proliferation during aging is associated with a progressive decline in both growth hormone (GH) secretion and Foxm1b expression. Liver regeneration studies with 12-month-old (old-aged) transgenic mice indicated that increased hepatocyte expression of Foxm1b alone is sufficient to restore hepatocyte proliferation to levels found in 2-month-old (young) regenerating liver. GH therapy in older people has been shown to cause an increase in cellular proliferation, but the transcription factors that mediated this stimulation in proliferation remain uncharacterized. In this study, we showed that human GH administration to old-aged Balb/c mice dramatically increased both expression of Foxm1b and regenerating hepatocyte proliferation. This increase in old-aged regenerating hepatocyte proliferation was associated with elevated protein expression of Cdc25A, Cdc25B, and cyclin B1, with reduced protein levels of cyclin-dependent kinase inhibitor p27(Kip1) (p27). GH treatment also was found to stimulate hepatocyte proliferation and expression of Foxm1b protein without partial hepatectomy (PHx). Furthermore, GH treatment of young Foxm1b -/- mice failed to restore regenerating hepatocyte DNA replication and mitosis caused by Foxm1b deficiency. These genetic studies provided strong evidence that the presence of Foxm1b is essential for GH to stimulate regenerating hepatocyte proliferation. In conclusion, our old-aged liver regeneration studies show that increased Foxm1b levels are essential for GH to stimulate hepatocyte proliferation, thus providing a mechanism for GH action in the elderly.
The Forkhead Box (Fox) proteins are an extensive family of transcription factors that shares homology in the winged helix DNA binding domain. Liver regeneration studies with the -3 kb transthyretin (TTR) promoter-driven FoxM1B transgenic (TG) mice demonstrated that premature hepatocyte nuclear localization of the FoxM1B transgene protein at 16 h following partial hepatectomy (PHx) caused an 8-h acceleration in the onset of hepatocyte DNA replication (S-phase) and mitosis by stimulating earlier expression of cell cycle genes. Whether the FoxM1B transgene protein participates in immediate early events during liver regeneration remains to be determined. Here, we found that the FoxM1B transgene protein translocated to hepatocyte nuclei immediately following PHx, that its nuclear staining persisted for the first 6 h after surgery, and that this translocation was associated with an increase in size of regenerating TG hepatocytes. However, regenerating TTR-FoxM1B liver did not exhibit altered expression of proteins that have been implicated in mediating increased cell size, including serum-and-gucocorticoid-inducible protein kinase (SGK), protein kinase-B/Akt, the tumor suppresser gene PTEN (negative regulator of the PI3K/Akt pathway), c-Myc, or peroxisome proliferation. Moreover, we demonstrated that hepatocyte nuclear translocation of the FoxM1B transgene protein was rapidly induced during the hepatic acute phase response, which occurs during the immediate early stages of liver regeneration. Analysis of cDNA expression arrays identified a number of genes such as immediate early transcription factors (ID-3, Stat3, Nur77), matrix metalloproteinase-9 (MMP-9), and several glutathione S-transferase (GST) isoforms and stress response genes, whose expression is elevated in regenerating TTR-FoxM1B TG livers compared with regenerating wild-type (WT) liver. These liver regeneration studies demonstrate that hepatocyte nuclear translocation of the FoxM1B transgene protein was sustained for the first 6 h after PHx, and was associated with transient hypertrophy of regenerating TG hepatocytes and increased expression of genes that may enhance hepatocyte proliferation.
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