Involvement of polyamines in iron(III) transport in human intestinal Caco-2 cell lines.

Natural polyamines such as putrescine (Put), spermidine (Spd), and spermine (Spm), which are present in the human diet in large amounts, associated with their active transporter, are assumed to play a role in non-heme iron uptake and iron bioavailability from nutrients. Enterocytes and hepatocytes play pivotal roles in the regulation of body iron homeostasis. In this study, we report the effects of natural polyamines on iron transport in the Caco-2 cell line. In enterocyte-like Caco-2 cells, polyamines did not significantly modulate the transepithelial iron flux across the cell monolayer cultured on permeable membranes. In contrast, Spd, Spm, and to a lesser extent, Put were shown to activate Caco-2 cell iron uptake and to induce an increase in the ferritin level. This iron co-transport in enterocytes, which involved an interaction between iron and polyamine then cell uptake of the polyamine-iron complexes by the polyamine transport system, was more pronounced in proliferating than in differentiated Caco-2 cells. Moreover, it was observed at physiological concentrations of both polyamines and iron. It could thus play a role in the rapid renewal of enterocytes. These data suggest the involvement of polyamines as components of the pool of transferrin-independent iron-chelating vectors. Further investigations are needed to demonstrate their biological relevance in physiological situations.

Ethanol effect on cell proliferation in the human hepatoma HepaRG cell line: relationship with iron metabolism.

BACKGROUND: Alcoholism increases the risk of cirrhosis and/or hepatocellular carcinoma development. Iron, like ethanol, modulates the cell growth. However, the relationship between alcohol and iron toward hepatocyte proliferation has not been clearly elucidated. The purpose of this study was to evaluate, in the human HepaRG cell line model, the impact of ethanol on hepatocyte proliferation in relation to modulations of iron metabolism and the protective effect of iron metabolism manipulation by chelators in alcohol liver diseases. METHODS: The human hepatoma HepaRG cell line model was used. Cell viability was determined by measuring succinate dehydrogenase activity, total protein level by the Bradford method. DNA synthesis was evaluated by [(3)H]-methyl thymidine incorporation. Cytotoxicity was studied by release of lactate dehydrogenase (LDH), aspartate aminotransferase (AST), alanine aminotransferase (ALT) in culture medium and apoptosis by measuring caspase 3/7 activity. Gene expression was analyzed by RT-qPCR. Total iron, soluble transferrin receptor, and ferritin levels were, respectively, measured by colorimetrical, immuno-nephelometrical, and immuno-turbidimetrical methods. Intracellular iron uptake and accumulation was examined by radionuclide (55)Fe (III) measurement and Perls staining. RESULTS: Results showed that ethanol decreased all the parameters associated with HepaRG cell proliferation (cell viability, total protein levels, and DNA synthesis) in a dose- and time-dependent manner. This effect was accompanied by cytotoxicity and apoptosis as evaluated by a significant increase in extracellular enzymes (LDH, AST, ALT) and caspase 3/7 activity, respectively. Ethanol exposure was accompanied by an increased cellular iron uptake, together with increased expression of genes involved in iron transport and storage such as l-ferritin, Divalent Metal transporter 1, transferrin, transferrin receptor 1, and ceruloplasmin. Ethanol impact was intensified by iron-citrate and decreased by iron chelators when added to the culture medium. CONCLUSIONS: The results indicated that (i) ethanol-induced iron metabolism dysfunction could be one of the underlying mechanisms of ethanol antiproliferative effect and (ii) exogenous iron may accentuate ethanol hepatoxicity. These data suggest that iron metabolism manipulation by chelators may be a useful therapeutic approach in alcohol-related liver diseases.

Antiproliferative effect on HepaRG cell cultures of new calix[4]arenes. Part II.

Cell cycle progression is dependent on the intracellular iron level and chelators can lead to iron depletion and decrease cell proliferation. This antiproliferative effect can be inhibited by exogenous iron. In this work, we present the synthesis of some new synthetic calix[4]arene podands bearing diamino-tetraesters, diamino-tetraalcohols, diamino-tetraacid and tetraaryloxypentoxy groups at the lower rim, designed as potential iron chelators. We report their effect on cell proliferation, in comparison with the new oral chelator ICL670A (4-[3,5-bis-(2-hydroxyphenyl)-1,2,4-triazol-1-yl]-benzoic acid). The antiproliferative effect of these new compounds was studied in the human hepatocarcinoma HepaRG cell cultures using cell nuclei counting after staining with the DNA intercalating fluorescence dye, Hoechst 33342. Their cytotoxicity was evaluated by the extracellular LDH activity. Preliminary results indicated that their antiproliferative effect was mainly due to their cytotoxicity. The efficiency of these compounds, being comparable to that of ICL670, was independent of iron depletion. This effect remains to be further explored. Moreover, it also shows that the new substituted calix[4]arenes could open the way to valuable new approaches for medicinal chemistry scaffolding.

Synthesis and biological properties of iron chelators based on a bis-2-(2-hydroxy-phenyl)-thiazole-4-carboxamide or -thiocarboxamide (BHPTC) scaffold.

Bis-2-(2-hydroxy-phenyl)-thiazole-4-carboxamides and -thiocarboxamides (BHPTCs) form a family of gemini hexacoordinated bis-tridentate chelating scaffolds. Four molecules were synthesized and shown to chelate iron(III) efficiently with a 1:1 stoichiometry. A dithioamide BHPTC displayed promising antiproliferative activity in several cancerous cell lines, making this molecule an interesting lead compound for the design of new iron-chelating anticancer drugs. Conversely, diamide BHPTCs had significant cytoprotective activity against iron overload in HepaRG cells in vitro, and were as efficient as and less toxic than deferoxamine B (DFO).

Effects of deferasirox and deferiprone on cellular iron load in the human hepatoma cell line HepaRG.

Two oral chelators, CP20 (deferiprone) and ICL670 (deferasirox), have been synthesized for the purpose of treating iron overload diseases, especially thalassemias. Given their antiproliferative effects resulting from the essential role played by iron in cell processes, such compounds might also be useful as anticancer agents. In the present study, we tested the impact of these two iron chelators on iron metabolism, in the HepaRG cell line which allowed us to study proliferating and differentiated hepatocytes. ICL670 uptake was greater than the CP20 uptake. The iron depletion induced by ICL670 in differentiated cells increased soluble transferrin receptor expression, decreased intracellular ferritin expression, inhibited (55)Fe (III) uptake, and reduced the hepatocyte concentration of the labile iron pool. In contrast, CP20 induced an unexpected slight increase in intracellular ferritin, which was amplified by iron-treated chelator exposure. CP20 also promoted Fe(III) uptake in differentiated HepaRG cells, thus leading to an increase of both the labile pool and storage forms of iron evaluated by calcein fluorescence and Perls staining, respectively. In acellular conditions, compared to CP20, iron removing ability from the calcein-Fe(III) complex was 40 times higher for ICL670. On the whole, biological responses of HepaRG cells to ICL670 treatment were characteristic of expected iron depletion. In contrast, the effects of CP20 suggest the potential involvement of this compound in the iron uptake from the external medium into the hepatocytes from the HepaRG cell line, therefore acting like a siderophore in this cell model.

Antiproliferative effect on HepaRG cell cultures of new calix[4]arenes.

Cell cycle progression is dependent on the intracellular iron level, and chelators lead to iron depletion and decrease cell proliferation. This antiproliferative effect can be inhibited by exogenous iron. In this work, we present the synthesis of new synthetic calix[4]arene podands bearing alkyl acid and alkyl ester groups at the lower rim, designed as potential iron chelators. We report their effect on cell proliferation, in comparison with the new oral chelator ICL670 (4-[3,5-bis-(2-hydroxyphenyl)-1,2,4-triazol-1-yl]-benzoic acid). The antiproliferative effect of these new compounds was studied in human hepatocarcinoma HepaRG cell cultures using the MTT assay. Their cytotoxicity was evaluated by extracellular LDH activity. Preliminary results indicate that their antiproliferative effect is due to their cytotoxicity. The efficiency of these compounds, comparable to that of ICL670, was independent of iron depletion. This effect remains to be further explored. Moreover, it also shows that novel substituted calix[4]arenes could open the way to new valuable medicinal chemistry scaffolding.

The new orally active iron chelator ICL670A exhibits a higher antiproliferative effect in human hepatocyte cultures than O-trensox.

By comparing the antiproliferative effect of the iron chelators ICL670A and O-trensox in the human hepatoma cell line HUH7 and human hepatocyte cultures, we have shown that ICL670A decreased cell viability, inhibited DNA replication and induced DNA fragmentation more efficiently than O-trensox. O-trensox and ICL670A induced a cell cycle blockade in G0-G1 and S phases respectively. In parallel, ICL670A inhibited polyamine biosynthesis by decreasing ornithine decarboxylase and spermidine/spermine N(1)-acetyltransferase activities. O-trensox increased polyamine biosynthesis and particularly putrescine level by stimulating spermidine-spermine N(1)-acetyltransferase activity which could activate the polyamine retro-conversion pathway. Moreover, the two chelators exhibit some cytotoxic effect in the two culture models; ICL670A was more cytotoxic than O-trensox and higher concentrations of the two chelators were necessary to induce a cytotoxicity in primary cultures versus hepatoma cells. These results suggested that ICL670A has the most efficient antitumoral effect, blocks cell proliferation by a pathway different of O-trensox and may constitute a potential drug for anticancer therapy.

[Normal iron metabolism]. / Métabolisme du fer chez le sujet normal.

Normal iron metabolism is highly regulated and takes a crucial role in the maintenance of cell functions. The plasmatic iron bioavailability control is a key step of this metabolism which involves numerous proteins implicated at various levels, including the digestive iron absorption by enterocytes, and iron release from macrophages. These two phenomenons are modulated in a coordonated fashion by the plasmatic level of hepcidin, a peptide mainly synthetized by the liver, secreted in plasma and modulating the expression of ferroportin, the cellular exporter of iron, and thus the iron egress. Numerous factors are able to modulate the hepcidin expression, including iron status, erythropoietic activity, inflammation and hepatic status which are already identified. Abnormalities occurring in the regulation of hepcidin expression may favour the development of iron metabolism disturbance, including systemic iron overload or relative iron deficiency. The use of hepcidin for diagnostic purpose or as a therapeutic target remains to be determined.

[Genetic iron overload diseases: a deeply changing world]. / Les surcharges génétiques en fer: un monde en pleine mutation.

Iron overload diseases are a quickly and deeply changing world, due to major advances in genetics and molecular biology. Five main entities are concerned: a frequent one, namely HFE-related or type1 haemochromatosis, and four rare or exceptional diseases which are types 2, 3 and 4 haemochromatosis and aceruloplasminemia. Increased duodenal iron absorption and enhanced macrophagic iron recycling, both due to hypo-hepcidinemia, account for the development of cellular excess in types 1, 2, 3 haemochromatosis whereas decreased cellular iron egress is the main explanation for type 4 haemochromatosis and aceruloplasminemia. Non-transferrin bound iron plays an important role in cellular iron excess and damage. Phlebotomies remain an essential therapeutic tool but the improved understanding of the intimate mechanisms underlying these diseases open the road for innovative therapeutic approaches.

Polyamine modulation of iron uptake in CHO cells.

Polyamines are ubiquitous molecules, which, like iron, are essential for cell growth. All eukaryotic cells are equipped with a specific polyamine transport system (PTS). Polyamines have primary and secondary amino groups which chelate bivalent metal cations such as Fe and Cu. In the present study, we investigated the potential contribution of naturally occurring polyamines and their active transport system to iron uptake. In presence of subtoxic Fe(III) (10microM), treatment of CHO cells with spermine, and to a lesser extent with spermidine (10-100microM), resulted in a marked cytotoxic effect. This cytotoxicity was prevented by the addition of an iron-chelator, deferioxamine, and was not observed in CHO-MG cells, a mutant cell line devoid of polyamine transport activity. Experiments using 14C-polyamines and 55Fe(III) revealed that these toxic effects were related to polyamine-modulation of iron uptake, and were dependent on the presence of the active PTS. These results demonstrated active uptake of polyamine-iron complexes via the PTS. The number of amino groups affected the efficacy of the studied natural polyamines to transport iron via the PTS. Spermine, a tetramine, was more efficient than the triamine spermidine. Co-transport of iron by the diamine putrescine was not observed. These results demonstrate that the cell polyamine transport system is a potential cell entry pathway for iron. The studied polyamines, spermine and spermidine, may be components of the pool of transferrin-independent iron-chelating vectors, which have recently attracted the attention of many investigators.

Iron mobilization, cytoprotection, and inhibition of cell proliferation in normal and transformed rat hepatocyte cultures by the hydroxypyridinone CP411, compared to CP20: a biological and physicochemical study.

The present study analyzes the iron mobilization, the cytoprotective, and the antiproliferative effects of the lipophilic hydroxypyridinone CP411, in comparison with the hydrophilic chelator CP20 or deferiprone used in the treatment of iron overload. Primary rat hepatocyte cultures and the rat hepatoma cell line Fao were used. Chelator cell uptake was evaluated by mass spectrometry in the two models. This method was also used to investigate the stability of the chelators in an acellular system as well as their scavenging and chelating effects against the hydroxyl radical generated by the Fenton reaction. The iron mobilization and the cytoprotective effects of the chelators were evaluated in primary cultures by measuring respectively 55Fe and lactate dehydrogenase release in the culture medium. The antiproliferative effect of the chelators was studied using the Fao cell line and measuring DNA synthesis by thymidine incorporation and DNA content by flow cytometry. We observed that CP411 entered the hepatocytes and the Fao cells respectively 4 and 13 times more than CP20. CP411 was 2.5 times more effective than CP20 to mobilize iron from preloaded hepatocytes. Pretreatment of the hepatocytes with CP20 or CP411 decreased the toxic effect of iron and CP411 was 1.6 times more effective than CP20. A dose-dependent decrease of DNA synthesis, correlated to an accumulation of cells in S phase, was observed in the Fao cell line in the presence of CP411, while CP20 was without effect. CP411 effect was inhibited by addition of iron simultaneously with the chelator, the addition of Zn or Cu was without effect. The inhibitory effect of CP411 was reversible since, 24hr after removal of the chelator, DNA replication reached the control level. The results show that CP411 is more efficient to protect the hepatocyte from the toxic effect of iron load and to inhibit tumor cell proliferation. Its higher efficiency may result from its better cell uptake since equimolar solutions of the two chelators in an acellular system exhibit the same ability to inhibit the Fenton reaction.

Iron-mediated effect of alcohol on hepatocyte differentiation in HepaRG cells.

The development of alcoholic liver diseases depends on the ability of hepatocyte to proliferate and differentiate in the case of alcohol-induced injury. Our previous work showed an inhibitory effect of alcohol on hepatocyte proliferation. However, the effect of alcohol on hepatocyte differentiation has not yet been precisely characterized. In the present study, we evaluated the effect of alcohol on hepatocyte differentiation in relationship with changes of iron metabolism in HepaRG cells. This unique bipotent human cell line can differentiate into hepatocytes and biliary epithelial cells, paralleling liver development. Results showed that alcohol reduced cell viability, total protein level and enhanced hepatic enzymes leakage in differentiated HepaRG cells. Moreover, it caused cell enlargement, decreased number of hepatocyte and expression of C/EBPα as well as bile canaliculi F-actin. Alcohol increased expression of hepatic cell-specific markers and alcohol-metabolizing enzymes (ADH2, CYP2E1). This was associated with a lipid peroxidation and an iron excess expressed by an increase in total iron content, ferritin level, iron uptake as well as an overexpression of genes involved in iron transport and storage. Alcohol-induced hepatoxicity was amplified by exogenous iron via exceeding iron overload. Taken together, our data demonstrate that in differentiated hepatocytes, alcohol reduces proliferation while increasing expression of hepatic cell-specific markers. Moreover, iron overload could be one of the underlying mechanisms of effect of alcohol on the whole differentiation process of hepatocytes.

Antiproliferative and iron chelating efficiency of the new bis-8-hydroxyquinoline benzylamine chelator S1 in hepatocyte cultures.

If a new generation of iron chelators specifically devoted for cancer chemotherapy emerged these last years, any of them has not yet been approved at this time. Accordingly, there is a need to optimize new chelating molecules for iron chelation therapy and cancer treatment. So, the objective of the present investigation was to characterize the antiproliferative activity and the iron chelating capacity of the iron chelator S1 [bis-N-(8-hydroxyquinoline-5-ylmethyl)benzylamine]. Its effects were compared to O-trensox which binds ferric iron with a very high affinity (pFe(3+)=29.5). For this purpose, primary rat hepatocyte stimulated by EGF and human hepatoma HepaRG cell cultures were used. In these models, the anti-proliferative effect, the inhibition of DNA synthesis and the iron-chelating efficiency of increasing concentrations of S1 and O-trensox (0 up to 200 µM) were investigated. In the two cell culture models, we observed that S1 was about 100 times more efficient than O-trensox and the antiproliferative effect of S1 in HepaRG cells appeared at concentrations as low as 0.1 µM without cytotoxicity. Moreover, the stoichiometry of S1 for iron seemed to be in the range S1/Fe(3+)=1. Using the calcein fluorescence assay, we demonstrated that the affinity of S1 for iron was better than that of O-trensox since it was at least two times more effective to restore the fluorescence of calcein previously quenched by iron. So, the iron chelating efficiency of S1 could explain at least partially its higher anti-proliferative effect compared to O-trensox. Finally, these results suggest that molecules such as S1 may constitute a promising starting point to improve cancer treatment.

Modulation of cell proliferation and polyamine metabolism in rat liver cell cultures by the iron chelator O-trensox.

The antiproliferative effects of the iron chelator O-trensox and the ornithine-decarboxylase (ODC) inhibitor alpha-difluoromethylornithine (DFMO) were characterized in the rat hepatoma cell line FAO, the rat liver epithelial cell line (RLEC) and the primary rat hepatocyte cultures stimulated by EGF. We observed that O-trensox and DFMO decreased cell viabilty and DNA replication in the three culture models. The cytostatic effect of O-trensox was correlated to a cytotoxicity, higher than for DFMO, and to a cell cycle arrest in G0/G1 or S phases. Moreover, O-trensox and DFMO decreased the intracellular concentration of spermidine in the three models without changing significantly the spermine level. We concluded that iron, but also polyamine depletion, decrease cell growth. However, the drop in cell proliferation obtained with O-trensox was stronger compared to DFMO effect. Altogether, our data provide insights that, in the three rat liver cell culture models, the cytostatic effect of the iron chelator O-trensox may be the addition of two mechanisms: iron and polyamine depletion.

Modulation of cell proliferation in rat liver cell cultures by new calix[4]arenes.

Cell cycle progression is dependent on intracellular iron level and chelators lead to iron depletion and decrease cell proliferation. This antiproliferative effect can be inhibited by exogenous iron. In this work, we present the synthesis of new synthetic calix[4]arene podands bearing two aspartic/glutamic acid, ornithine groups or hydrazide function at the lower rim, designed as potential iron chelators. The synthesis only afforded calix[4]arenes in the cone conformation. We report their effect on cell proliferation, in comparison with the new oral chelator ICL670A (4-[3,5-bis-(2-hydroxyphenyl)-1,2,4-triazol-1-yl]-benzoic acid). The antiproliferative effect of these new compounds was studied in the rat hepatoma cell line Fao by measuring mitochondrial succinate dehydrogenase activity. Their cytotoxicity was evaluated by extracellular LDH activity. Preliminary results indicated that among all tested compounds, monohydrazidocalix[4]arene 2 which is not cytotoxic in Fao cells exhibits interesting antiproliferative activity. This effect, independent on iron depletion, remains to be further explored. Moreover, it also shows that new substituted calix[4]arenes could open the way to new valuable medicinal chemistry scaffolding.