Hepcidin, a liver-derived hormone, is the central regulator of systemic iron homeostasis. Elevated hepcidin levels contribute to iron-refractory iron deficiency anemia (IRIDA) and anemia of inflammati Show more
Hepcidin, a liver-derived hormone, is the central regulator of systemic iron homeostasis. Elevated hepcidin levels contribute to iron-refractory iron deficiency anemia (IRIDA) and anemia of inflammation, both characterized by restricted iron availability. Current treatments, such as parenteral iron infusions, are often ineffective and pose risks of adverse reactions, underscoring the need for alternative therapeutic strategies targeting hepcidin. We previously identified a novel hepcidin regulatory pathway involving liver heparan sulfate (HS) proteoglycans (HSPGs), which modulate receptor-ligand interactions through their sulfated HS chains. Recently, we found that halofuginone impairs HS biosynthesis and considered whether it could be used as a hepcidin modulator. Here, we demonstrate that in human hepatoma (Hep3B) cells, halofuginone inhibits both basal and BMP6-induced hepcidin expression and p-SMAD1 signaling in a dose- and time-dependent manner. Consistently, Hep3B cells lacking HS (EXT1-/-) show no hepcidin suppression in response to halofuginone. In vivo administration of halofuginone reduces hepcidin expression in an iron-overload mouse model (8.3 g/kg carbonyl iron). This effect was absent in mice with impaired liver HS sulfation (Ndst1f/fAlbCre+), confirming that halofuginone suppresses hepcidin via HSPG-mediated mechanisms. Additionally, halofuginone decreased hepcidin expression in mice subjected to acute inflammation. These findings establish halofuginone as a potential therapeutic for mitigating hepcidin-driven iron restriction in anemic disorders. Show less
In Saccharomyces cerevisiae, the G1 cyclin/cyclin-dependent kinase (CDK) complexes Cln1,-2,-3/Cdk1 promote S phase entry during the mitotic cell cycle but do not function during meiosis. It has been p Show more
In Saccharomyces cerevisiae, the G1 cyclin/cyclin-dependent kinase (CDK) complexes Cln1,-2,-3/Cdk1 promote S phase entry during the mitotic cell cycle but do not function during meiosis. It has been proposed that the meiosis-specific protein kinase Ime2, which is required for normal timing of pre-meiotic DNA replication, is equivalent to Cln1,-2/Cdk1. These two CDK complexes directly catalyze phosphorylation of the B-type cyclin/CDK inhibitor Sic1 during the cell cycle to enable its destruction. As a result, Clb5,-6/Cdk1 become activated and facilitate initiation of DNA replication. While Ime2 is required for Sic1 destruction during meiosis, evidence now suggests that Ime2 does not directly catalyze Sic1 phosphorylation to target it for destabilization as Cln1,-2/Cdk1 do during the cell cycle. We demonstrated that Sic1 is eventually degraded in meiotic cells lacking the IME2 gene (ime2Δ), supporting an indirect role of Ime2 in Sic1 destruction. We further examined global RNA expression comparing wild type and ime2Δ cells. Analysis of these expression data has provided evidence that Ime2 is required early in meiosis for normal transcription of many genes that are also periodically expressed during late G1 of the cell cycle. Our results place Ime2 at a position in the early meiotic pathway that lies upstream of the position occupied by Cln1,-2/Cdk1 in the analogous cell cycle pathway. Thus, Ime2 may functionally resemble Cln3/Cdk1 in promoting S phase entry, or it could play a role even further upstream in the corresponding meiotic cascade. Show less