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Commentary Free access | 10.1172/JCI25642
Institut Cochin, INSERM 567, CNRS 8104, Université Paris 5, Paris, France.
Address correspondence to: Sophie Vaulont, Institut Cochin, INSERM 567, CNRS 8104, Université Paris 5, Paris 75014, France. Phone: 33-144-41-24-08; Fax: 33-144-41-24-21; E-mail: vaulont@cochin.inserm.fr.
Find articles by Vaulont, S. in: JCI | PubMed | Google Scholar
Institut Cochin, INSERM 567, CNRS 8104, Université Paris 5, Paris, France.
Address correspondence to: Sophie Vaulont, Institut Cochin, INSERM 567, CNRS 8104, Université Paris 5, Paris 75014, France. Phone: 33-144-41-24-08; Fax: 33-144-41-24-21; E-mail: vaulont@cochin.inserm.fr.
Find articles by Lou, D. in: JCI | PubMed | Google Scholar
Institut Cochin, INSERM 567, CNRS 8104, Université Paris 5, Paris, France.
Address correspondence to: Sophie Vaulont, Institut Cochin, INSERM 567, CNRS 8104, Université Paris 5, Paris 75014, France. Phone: 33-144-41-24-08; Fax: 33-144-41-24-21; E-mail: vaulont@cochin.inserm.fr.
Find articles by Viatte, L. in: JCI | PubMed | Google Scholar
Institut Cochin, INSERM 567, CNRS 8104, Université Paris 5, Paris, France.
Address correspondence to: Sophie Vaulont, Institut Cochin, INSERM 567, CNRS 8104, Université Paris 5, Paris 75014, France. Phone: 33-144-41-24-08; Fax: 33-144-41-24-21; E-mail: vaulont@cochin.inserm.fr.
Find articles by Kahn, A. in: JCI | PubMed | Google Scholar
Published August 1, 2005 - More info
Recently, mutations causing juvenile hemochromatosis have been identified in a novel gene, hemojuvelin (HJV), located on chromosome 1. Mouse models of this disease have now been developed by 2 groups, Huang et al. and Niederkofler et al., through targeted disruption of the Hjv gene (see the related articles beginning on pages 2180 and 2187). These mutant mice will allow further investigation into the role of HJV in the regulation of iron homeostasis, a role that to date remains elusive.
The following scenario is classic with respect to genetic disorders: the disease is clinically recognized, the related gene is identified, and a couple of years later, a mouse model of the genetic disease is established. The genes involved in iron metabolism have not been an exception to this rule (in particular those related to hereditary hemochromatosis, a prevalent heterogeneous iron-overload disorder), and the development of mouse models have greatly facilitated our understanding of the pathogenesis of iron overload. The hemojuvelin gene (HJV, also known as HFE2 and RGMc), which is mutated in a form of juvenile hemochromatosis linked to chromosome 1, was identified in 2003 (1). Researchers in the field have therefore been waiting for the development of a relevant mouse model of this disease. This feat has now been accomplished by Huang et al. and Niederkofler et al., who in this issue of the JCI describe the phenotype of their mutant mice (2, 3). Their findings add further support to the emerging attractive hypothesis that hepcidin, a recently described iron-regulatory peptide, and ferroportin, its target, are common pathogenic denominators in all forms of iron overload.
In mammals, iron homeostasis is complex and depends on regulated dietary iron absorption by mature enterocytes of the duodenum and iron recycling by macrophages, which supply most of the serum iron through recovery of the metal from senescent erythrocytes (4). These 2 fundamental processes are deregulated in hereditary hemochromatosis; over time, this deregulation leads to iron deposition in parenchymal cells and transferrin saturation (5). As the disease progresses, patients develop iron-induced tissue damage, which results in serious illnesses including cirrhosis, hepatomas, diabetes, cardiomyopathy, arthritis, and endocrinopathies. Unless recognized and treated, this disease is fatal.
While hereditary hemochromatosis has been clinically recognized since 1889, it is only over the 10 past years that the genetic basis for the disease has been elucidated. Hereditary hemochromatosis is now recognized to be genetically heterogeneous and its nomenclature is under debate. Depending on distinct clinical and genetic entities, hereditary hemochromatosis can be divided into 3 classes: classical hemochromatosis, juvenile hemochromatosis, and ferroportin disease.
Classical hemochromatosis is associated with the historical and most prevalent form of hereditary hemochromatosis and is almost always caused by mutations in HFE, a gene which encodes a protein of the major histocompatibility complex class I (6). Rarely, another gene can be involved, namely transferrin receptor 2 (TFR2) (7), which encodes a homolog of TFR1 that mediates cellular uptake of transferrin-bound iron in most cells (reviewed in ref. 8). While the functional role of HFE remains a mystery [apart from regulating hepcidin antimicrobial peptide (HAMP) expression; see below], TFR2 was recently proposed to be involved in sensing serum diferric transferrin concentration at the level of the hepatocytes where its expression is directly regulated by holotransferrin (9, 10). Knockout mice lacking either Hfe (11–13) or Tfr2 (14) develop hepatic iron overload and increased transferrin saturation, as do human patients.
Juvenile hemochromatosis is a rare form of the disease characterized by the early and severe onset of symptoms, in particular cardiac and endocrine defects. Most juvenile hemochromatosis families have been reported to have mutations in the recently cloned HJV gene (reviewed in ref. 8). HJV is expressed in the muscle, liver, and heart, but the normal function of the protein is unknown (1). Several protein domains have been described, including a large repulsive guidance molecule (RGM) motif homologous to motifs of proteins involved in neuronal cell migration and a von Willebrand type D domain, but none of these domains have a known connection with iron metabolism (1). For a very small subset of patients, mutations have been identified in HAMP, which encodes hepcidin (reviewed in ref. 8). Hepcidin is a recently discovered secreted peptide synthesized mainly by the liver and excreted by the kidneys. It is a major regulator of iron metabolism and is positively regulated by iron and negatively regulated by iron deficiency, anemia, and hypoxia (reviewed in ref. 15). Hepcidin limits intestinal iron absorption as well as iron release by macrophages. Accordingly, hepcidin-deficient mice have been found to develop hemochromatosis with iron deposition in the liver and pancreas and, in contrast, decreased iron load in the macrophage-rich spleen (16). Conversely, transgenic mice overexpressing hepcidin present with severe iron-deficient anemia (17). The mechanism of hepcidin action has been recently determined (18, 19). To limit iron export, hepcidin binds to ferroportin, a transmembrane iron transporter necessary for iron transfer out of intestinal epithelial cells and macrophages (20), and induces its internalization and subsequent degradation (18). This action is expected to decrease dietary iron absorption in the enterocytes and iron recycling in the macrophages (Figure 1).
Regulation of systemic iron homeostasis. Increased diferric transferrin, Fe2-Tf, is detected by the liver via an as-yet unknown complex regulatory pathway involving HFE, TFR2, and HJV. Hepatocytes respond to this signal by inducing HAMP expression and hepcidin secretion. Circulating hepcidin acts in turn to diminish dietary iron absorption by the enterocytes and iron recycling by the macrophages through the internalization of ferroportin, which blocks iron export. As a consequence, serum iron decreases. As a feedback response, hepcidin synthesis is downregulated, which allows ferroportin molecules to be displayed on the surface of the target cells. In classical and juvenile hemochromatosis the mutations in HFE, TFR2, and HJV lead to abnormal hepcidin regulation, hypohepcidinemia, and ferroportin hyperactivity. The latter results in increased iron absorption and uncontrolled iron release from macrophages, 2 defects characteristic of hereditary hemochromatosis. DMT1, divalent metal transporter 1.
A breakthrough in the understanding of iron overload in hemochromatosis came first from the discovery that hepcidin production was deficient (as assessed by urinary hepcidin and/or liver mRNA levels) in mice and humans with classical hereditary hemochromatosis (21–27). Patients with juvenile hemochromatosis caused by mutations in HJV were subsequently shown to be devoid of any measurable hepcidin in their urine (1). Therefore the concept arose that a regulatory iron-sensing pathway is centered around the hepatocytes, with HFE, TFR2, and HJV serving as regulators of hepcidin production by as-yet unknown direct or indirect mechanisms (Figure 1). Consequently, hereditary hemochromatosis severity could depend mainly on the level of residual hepcidin. Partial hepcidin deficiency would result in classical hereditary hemochromatosis, while almost complete deficiency would lead to juvenile hemochromatosis. In full agreement with this hypothesis, constitutive hepcidin expression has been shown to be able to prevent increased iron deposition in Hfe knockout mice (24).
The ferroportin disease is the third class of hereditary hemochromatosis. It is an autosomal-dominant disease caused by pathogenic mutations in the gene encoding the iron exporter ferroportin (reviewed in ref. 28). Since ferroportin is a downstream target of hepcidin, hepcidin level is not expected to be decreased in this type of hemochromatosis (29).
In this issue of the JCI, Huang et al. (2) and Niederkofler et al. (3) report the establishment of murine models of HJV deficiency. Although the data presented do not provide any new information on the functional role of HJV, they effectively describe the increased iron deposition in the liver, heart, and pancreas and the decreased iron levels in tissue macrophages of the mutant mouse. The authors note that liver iron accumulation begins earlier and progresses more quickly in Hjv–/– mice than in Hfe–/– mice. The heterozygous Hjv+/– mice are indistinguishable from control mice (2). These results definitively confirm that loss-of-function mutations in the Hjv gene lead to severe hemochromatosis and are consistent with the fact that parents of juvenile hemochromatosis patients are unaffected. Interestingly, both groups report that HAMP mRNA is virtually undetectable in the livers of mutant mice, which suggests that HJV acts by depressing HAMP gene activity. It is likely that HJV, like HFE, is needed as a sensor or mediator of activating signals of HAMP expression, including iron. In fact, the hepcidin gene’s decreased sensitivity to iron has been reported in Hfe–/– mice (24). Niederkofler et al. show that the Hjv–/– mice fail to express HAMP in response to dietary or injected iron, which demonstrates that the transmission of the iron signal in the liver is completely blocked in the absence of HJV. However, the authors report that Hjv–/– mice retain their ability to upregulate HAMP expression in response to inflammation and emphasize that the 2 inducers of HAMP expression, iron and inflammation, act through different pathways, the latter one independent of HJV.
Having established the impairment of hepcidin synthesis in mutant mice, Huang et al. (2) further show that the ferroportin level is considerably enhanced in both intestinal epithelial cells and macrophages of Hjv–/– mice, most likely reflecting the profound hepcidin deficiency. Accordingly, ferroportin has been shown to be overexpressed in the intestine and macrophages of hepcidin-deficient mice (30). It should be noted that in addition to hepcidin deficiency–induced ferroportin hyperactivity, Drakesmith et al. recently reported that ferroportin mutations resulting in insensitivity to hepcidin could also lead to ferroportin hyperactivity and subsequent hemochromatosis (31). Together, these results confirm and extend the key role of the hepcidin/ferroportin axis in regulating iron absorption by the intestine and iron efflux from macrophages.
While HJV mouse models of juvenile hemochromatosis are elegantly described in these important studies (2, 3), some key questions are still awaiting answers: (a) What is the functional role of HJV, in particular its role — if any — in the skeletal and cardiac muscles that express Hjv at a high level? Will older knockout animals develop specific muscular damage in addition to iron overload?; (b) Does hepcidin gene expression in organs other than the liver (e.g., in the heart, pancreas, and kidney) play any role? Does HJV regulate HAMP expression in a similar manner in all tissues?; and (c) How do iron-sensing and inflammatory pathways converge on HAMP expression, and at what level is the HAMP/iron-activating signal disturbed in the absence of HJV? Could HAMP be activated in patients and mice suffering from this type of juvenile hemochromatosis by drugs that, for instance, mimic inflammatory cues but are devoid of their detrimental effects?
There is no doubt that the discoveries of the hormonal iron-regulating role of hepcidin (16, 17) followed by the elucidation of its mechanism of action — to regulate ferroportin degradation in the intestine, macrophages, and probably placenta (18) — herald exciting times in the field of iron metabolism and related disorders. The hepcidin/ferroportin axis occupies a central position in regulating iron homeostasis and explaining the physiopathology of iron-overload syndromes and likely — at the other end of the spectrum of iron disorders — anemia of inflammation (23, 32). Although considerable efforts are still required in order to solve remaining questions, the studies by Huang et al. and Niederkofler et al. have paved the way for rapid progress in the development of inducers or drugs capable of enhancing endogenous HAMP expression in spite of HFE or HJV deficiency. This should lead to breakthrough treatments for hereditary hemochromatosis, secondary hemosiderosis, and chronic inflammatory anemias (thanks to hepcidin antagonists or inhibitors of HAMP gene expression) — pathologies that affect millions of patients around the world.