Iron overload promotes Cyclin D1 expression and alters cell cycle in mouse hepatocytes.

BACKGROUND/AIMS: Patients exhibiting hepatic iron overload frequently develop hepatocellular carcinoma. An impaired expression of hepatic genes could be involved in this phenomenon. Our aim was to identify, during iron overload, hepatic genes involved in cell cycle which are misregulated. RESULTS: Mouse iron overload was obtained by carbonyl-iron supplementation or iron-dextran injection. As expected, liver iron overload was associated to both hepatomegaly and hepatocyte polyploidisation. Hepatic gene expression was investigated using macroarray hybridizations. Cyclin D1 mRNA was the only gene whose expression increased in both models. Its overexpression was confirmed by real-time quantitative PCR. Immunobloting analysis demonstrated a strong increase of Cyclin D1 protein expression in iron-overloaded hepatocytes. This overexpression was correlated with early abnormalities in their cell cycle progression judged, in vitro, on DNA synthesis and mitotic index increase. CONCLUSIONS: Our data demonstrates that Cyclin D1, a protein involved in G1-phase of cell cycle, is overexpressed in the iron-overloaded liver. This iron-induced expression of Cyclin D1 may contribute to development of cell cycle abnormalities, suggesting a role of Cyclin D1 in iron-related hepatocarcinogenesis.

Arterial wall response to ex vivo exposure to oscillatory shear stress.

BACKGROUND: The aim of this study was to analyze the arterial wall response to plaque-prone hemodynamic environments, known to occur mainly in areas of arterial trees such as bifurcations and branching points. In these areas, the vasculature is exposed to cyclically reversing flow that induces an endothelial dysfunction predisposing thus arteries to local development of atherosclerotic plaques. METHODS: We used an ex vivo perfusion system that allows culturing arterial segments under different hemodynamic conditions. Porcine carotid arteries were exposed for 3 days to unidirectional high and low shear stress (6 +/- 3 and 0.3 +/- 0.1 dyn/cm(2)) as well as to oscillatory shear stress (0.3 +/- 3 dyn/cm(2)). This latter condition mimics the hemodynamics present at plaque-prone areas. At the end of the perfusion, the influence of different flow patterns on arterial metabolism was assessed in terms of matrix turnover as well as of smooth muscle cell function, differentiation and migration. RESULTS: Our results show that after 3 days of perfusion none of the applied conditions influence smooth muscle cell phenotype retaining their full contraction capacity. However, an increase in the expression level of matrix metalloproteinase-2 and -9, as well as a decrease in plasminogen activator inhibitor-1 expression were observed in arteries exposed to oscillatory shear stress when compared to arteries exposed to unidirectional shear stress. CONCLUSION: These observations suggest that plaque-prone hemodynamic environment triggers a vascular wall remodelling process and promotes changes in arterial wall metabolism, with important implication in atherogenesis.

Hepcidin in iron metabolism.

Hepcidin, which has been recently identified both by biochemical and genomic approaches, is a 25 amino acid polypeptide synthesized mainly by hepatocytes and secreted into the plasma. Besides its potential activity in antimicrobial defense, hepcidin plays a major role in iron metabolism. It controls two key steps of iron bioavailability, likely through a hormonal action: digestive iron absorption by enterocytes and iron recycling by macrophages. In humans, this could explain that low levels of hepcidin found during juvenile haemochromatosis and HFE-1 genetic haemochromatosis are associated with an iron overload phenotype. Conversely, an increase of hepcidin expression is suspected to play a major role in the development of anemia of chronic inflammatory diseases. However, the regulatory mechanisms of hepcidin expression are multiple, including iron-related parameters, anemia, hypoxia, inflammation and hepatocyte function. Therefore, many physiological and pathological situations may modulate hepcidin expression and subsequently iron metabolism. A better knowledge of the biological effects of hepcidin and of its expression regulatory mechanisms will clarify the place of hepcidin in the diagnosis and treatment of iron-related diseases.

Cap G, a gelsolin family protein modulating protective effects of unidirectional shear stress.

Atherosclerosis is a progressive and complex pathophysiological process occurring in large arteries. Although it is of multifactorial origin, the disease develops at preferential sites along the vasculature in regions experiencing specific hemodynamic conditions that are predisposed to endothelial dysfunction. The exact mechanisms allowing endothelial cells to discriminate between plaque-free and plaque-prone flows remain to be explored. To investigate such mechanisms, we performed a proteomic analysis on endothelial cells exposed in vitro to these two-flow patterns. A few spots on the two-dimensional gel had an intensity that was differentially regulated by plaque-free versus plaque-prone flows. One of them was further investigated and identified as macrophage-capping protein (Cap G), a member of the gelsolin protein superfamily. A 2-fold increase of Cap G protein and a 5-fold increase of Cap G mRNA were observed in cells exposed to a plaque-free flow as compared with static cultures. This increase was not observed in cells exposed to plaque-prone flow. Plaque-free flow induced a corresponding increase in nuclear and cytoskeletal-associated Cap G. Finally, overexpression of Cap G in transfection assays increased the motility potential of endothelial cells. These observations together with the known functions of Cap G suggest that Cap G may contribute to the protective effect exerted by plaque-free flow on endothelial cells. On the contrary, in cells exposed to a plaque-prone flow, no induction of Cap G expression could be observed.

Comparative analysis of mouse hepcidin 1 and 2 genes: evidence for different patterns of expression and co-inducibility during iron overload.

In contrast to the human genome, the mouse genome contains two HEPC genes encoding hepcidin, a key regulator of iron homeostasis. Here we report a comparative analysis of sequence, genomic structure, expression and iron regulation of mouse HEPC genes. The predicted processed 25 amino acid hepcidin 2 peptide share 68% identity with hepcidin 1 with perfect conservation of eight cysteine residues. Both HEPC1 and HEPC2 genes have similar genomic organization and have probably arisen from a recent duplication of chromosome 7 region, including the HEPC ancestral gene and a part of the adjacent USF2 gene. Insertion of a retroviral intracisternal A-particle element was found upstream of the HEPC1 gene. Both genes are highly expressed in the liver and to a much lesser extent in the heart. In contrast to HEPC1, a high amount of HEPC2 transcripts was detected in the pancreas. Expression of both genes was increased in the liver during carbonyl-iron and iron-dextran overload. Overall our data suggest that both HEPC1 and HEPC2 genes are involved in iron metabolism regulation but could exhibit different activities and/or play distinct roles.

A new subfamily of structurally related human F-box proteins.

F-box proteins, a critical component of the evolutionary conserved ubiquitin-protein ligase complex SCF (Skp1/Cdc53-Cullin1/F-box), recruit substrates for ubiquitination and consequent degradation through their specific protein-protein interaction domains. Here, we report the identification of full-length cDNAs encoding three novel human F-box proteins named FBG3, FBG4 and FBG5 which display similarity with previously identified NFB42 (FBX2) and FBG2 (FBX6) proteins. All five proteins are characterized by an approximately 180-amino-acid (aa) conserved C-terminal domain and thus constitute a third subfamily of mammalian F-box proteins. Analysis of genomic organization of the five FBG genes revealed that all of them consist of six exons and five introns. FBG1, FBG2 and FBG3 genes are located in tandem on chromosome 1p36, and FBG4 and FBG5 are mapped to chromosome 19q13. FBG genes are expressed in a limited number of human tissues including kidney, liver, brain and muscle tissues. Expression of rat FBG2 gene was found related to differentiation/proliferation status of hepatocytes. Specifically, FBG2 mRNA was expressed in foetal liver, decreased after birth and re-accumulated in adult liver. Expression of FBG2 was strongly inhibited in hepatoma cells by okadaic acid.

C/EBPalpha regulates hepatic transcription of hepcidin, an antimicrobial peptide and regulator of iron metabolism. Cross-talk between C/EBP pathway and iron metabolism.

Originally identified as a gene up-regulated by iron overload in mouse liver, the HEPC gene encodes hepcidin, the first mammalian liver-specific antimicrobial peptide and potential key regulator of iron metabolism. Here we demonstrate that during rat liver development, amounts of HEPC transcripts were very low in fetal liver, strongly and transiently increased shortly after birth, and reappeared in adult liver. To gain insight into mechanisms that regulate hepatic expression of hepcidin, 5'-flanking regions of human and mouse HEPC genes were isolated and analyzed by functional and DNA binding assays. Human and mouse HEPC promoter-luciferase reporter vectors exhibited strong basal activity in hepatoma HuH-7 and mouse hepatocytes, respectively, but not in non-hepatic U-2OS cells. We found that CCAAT/enhancer-binding protein alpha (C/EBPalpha) and C/EBPbeta were respectively very potent and weak activators of both human and mouse promoters. In contrast, co-expression of hepatocyte nuclear factor 4alpha (HNF4alpha) failed to induce HEPC promoter activity. By electrophoretic mobility shift assay we demonstrated that one putative C/EBP element found in the human HEPC promoter (-250/-230) predominantly bound C/EBPalpha from rat liver nuclear extracts. Hepatic deletion of the C/EBPalpha gene resulted in reduced expression of HEPC transcripts in mouse liver. In contrast, amounts of HEPC transcripts increased in liver-specific HNF4alpha-null mice. Decrease of hepcidin mRNA in mice lacking hepatic C/EBPalpha was accompanied by iron accumulation in periportal hepatocytes. Finally, iron overload led to a significant increase of C/EBPalpha protein and HEPC transcripts in mouse liver. Taken together, these data demonstrate that C/EBPalpha is likely to be a key regulator of HEPC gene transcription and provide a novel mechanism for cross-talk between the C/EBP pathway and iron metabolism.

Aceruloplasminemia: new clinical, pathophysiological and therapeutic insights.

Aceruloplasminemia is an autosomal recessive disease of iron overload associated with mutation(s) in the ceruloplasmin gene. We report here a new case of aceruloplasminemia in a woman who is a compound heterozygote for two new mutations. Besides this novel genotypic profile, this observation provides new insights on: (i) iron metabolism with normal erythroid repartition, in the absence of serum non-transferrin-bound iron and with an increase of 59Fe plasma clearance; (ii) hepatic abnormalities associated with the presence of iron-free foci; (iii) the therapeutic management of the disease, chronic subcutaneous infusion of deferrioxamine being remarkably effective at reducing hepatic iron overload.

Differential effects of iron overload on GST isoform expression in mouse liver and kidney and correlation between GSTA4 induction and overproduction of free radicles.

We have investigated the effect of iron overload on the expression of mouse GSTA1, A4, M1, and P1 in liver, the main iron storage site during iron overload, and in kidney. In iron-overloaded animals, mRNA and protein levels of GSTA1, A4, and M1 were increased in liver. In kidney, GSTA4 protein level was also increased while, unexpectedly, GSTA1 and M1 expression was strongly decreased. We showed, by immunohistochemistry, that GSTA4 was more abundant in hepatocytes of periportal areas and in convoluted proximal tubular cells in normal liver and kidney, respectively. In iron-overloaded mice, GSTA4 staining was more intense in cells that preferentially accumulated iron, and conjugation of 4-hydroxynonenal, a specific substrate of GSTA4, was enhanced in both organs. Moreover an acute exposure of primary cultures of mouse hepatocytes to iron-citrate strongly induced oxidative stress and cellular injury and resulted in an increase in GSTA4 expression, while cotreatment with iron-citrate and either desferrioxamine or vitamin E prevented both toxicity and GSTA4 induction. These data demonstrate that GSTA1 and M1 are differentially regulated in liver and kidney while GSTA4 is induced in both organs during iron overload. Moreover, they support the view that iron-induction of GSTA4 is related to an overproduction of free radicals.