Down-regulation of hepcidin in porphyria cutanea tarda.

Hepatic siderosis is common in patients with porphyria cutanea tarda (PCT). Mutations in the hereditary hemochromatosis (hh) gene (HFE) explain the siderosis in approximately 20% patients, suggesting that the remaining occurrences result from additional genetic and environmental factors. Two genes known to modify iron loading in hh are hepcidin (HAMP) and hemojuvelin (HJV). To determine if mutations in or expression of these genes influenced iron overload in PCT, we compared sequences of HAMP and HJV in 96 patients with PCT and 88 HFE C282Y homozygotes with marked hepatic iron overload. We also compared hepatic expression of these and other iron-related genes in a group of patients with PCT and hh. Two intronic polymorphisms in HJV were associated with elevated serum ferritin in HFE C282Y homozygotes. No exonic polymorphisms were identified. Sequencing of HAMP revealed exonic polymorphisms in 2 patients with PCT: heterozygosity for a G-->A transition (G71D substitution) in one and heterozygosity for an A-->G transition (K83R substitution) in the other. Hepatic HAMP expression in patients with PCT was significantly reduced, regardless of HFE genotype, when compared with patients with hh but without PCT with comparable iron overload. These data indicate that the hepatic siderosis associated with PCT likely results from dysregulated HAMP.

The hepcidin-binding site on ferroportin is evolutionarily conserved.

Mammalian iron homeostasis is regulated by the interaction of the liver-produced peptide hepcidin and its receptor, the iron transporter ferroportin. Hepcidin binds to ferroportin resulting in degradation of ferroportin and decreased cellular iron export. We identify the hepcidin-binding domain (HBD) on ferroportin and show that a synthetic 19 amino acid peptide corresponding to the HBD recapitulates the characteristics and specificity of hepcidin binding to cell-surface ferroportin. The binding of mammalian hepcidin to ferroportin or the HBD shows an unusual temperature dependency with an increased rate of dissociation at temperatures below 15 degrees C. The increased rate of dissociation is due to temperature- dependent changes in hepcidin structure. In contrast, hepcidin from poikilothermic vertebrates, such as fish or frogs, binds the HBD in a temperature-independent fashion. The affinity of hepcidin for the HBD permits a rapid, sensitive assay of hepcidin from all species and yields insights into the evolution of hepcidin.

Mapping genes responsible for strain-specific iron phenotypes in murine chromosome substitution strains.

The highly variable clinical phenotype observed in patients homozygous for the C282Y mutation of the hereditary hemochromatosis gene (HFE) is likely due to the influence of non-HFE modifier genes. The primary functional abnormality causing iron overload in hemochromatosis is hyper-absorption of dietary iron. We found that iron absorption in inbred mice varies in a strain-specific manner, as does the pattern of iron distribution to the liver and spleen. A/J mice absorbed approximately twice the amount of 59Fe delivered by gavage compared to the C57BL/6 strain. Genetic comparisons between A/J and C57BL/6 were facilitated by the availability of consomic chromosome substitution strains (CSS). Each CSS has an individual chromosome pair from A/J on an otherwise C57BL/6J background. We found that iron absorption and iron content in liver and in spleen were continuous variables suggesting that each trait is under multigenic control. No trait co-segregated among the CSS. Chromosome 5 from A/J, however, imparted the highest iron absorption phenotype and multiple CSS had absorption levels equivalent to A/J. Chromosomes 9 and X were associated with high spleen iron content. These data suggest that multiple genes contribute to the regulation of iron absorption and that individual organ iron phenotypes are independently regulated.

Biosynthesis of heme in mammals.

Most iron in mammalian systems is routed to mitochondria to serve as a substrate for ferrochelatase. Ferrochelatase inserts iron into protoporphyrin IX to form heme which is incorporated into hemoglobin and cytochromes, the dominant hemoproteins in mammals. Tissue-specific regulatory features characterize the heme biosynthetic pathway. In erythroid cells, regulation is mediated by erythroid-specific transcription factors and the availability of iron as Fe/S clusters. In non-erythroid cells the pathway is regulated by heme-mediated feedback inhibition. All of the enzymes in the heme biosynthetic pathway have been crystallized and the crystal structures have permitted detailed analyses of enzyme mechanisms. All of the genes encoding the heme biosynthetic enzymes have been cloned and mutations of these genes are responsible for a group of human disorders designated the porphyrias and for X-linked sideroblastic anemia. The biochemistry, structural biology and the mechanisms of tissue-specific regulation are presented in this review along with the key features of the porphyric disorders.

Oxidative stress, beta-cell apoptosis, and decreased insulin secretory capacity in mouse models of hemochromatosis.

The pathogenesis of diabetes associated with hemochromatosis is not known. We therefore examined glucose homeostasis and beta-cell function in mouse models of hemochromatosis. Mice with targeted deletion of the hemochromatosis gene (Hfe(-/-)) on the 129/Sv genetic background exhibited a 72% increase in iron content in the islets of Langerhans compared with wild-type controls. Insulin content was decreased in Hfe(-/-) mice by 35%/pancreas and 25%/islet. Comparable decreases were seen in the mRNA levels of beta-cell-specific markers, ins1, ins2, and glucose transporter 2. By 6-8 months, islets from Hfe(-/-) mice were 45% smaller, associated with increased staining for activated caspase 3 and terminal deoxynucleotidyl transferase-mediated deoxy-UTP nick end labeling. Islets from Hfe(-/-) mice were also desensitized to glucose, with half-maximal stimulation of insulin secretion seen at 16.7 +/- 0.9 mm glucose in perifused islets from Hfe(-/-) mice compared with 13.1 +/- 0.6 mm glucose in wild-type animals. Carbonyl protein modification, a marker for oxidative stress, was increased by 58% in Hfe(-/-) islets. Despite decreased islet size, Hfe(-/-) mice exhibited enhanced glucose tolerance. Fasting serum insulin levels were comparable between Hfe(-/-) and Hfe(+/+) mice, but were 48% lower in the Hfe(-/-) mice 30 min after challenge. Similar results were seen in mice carrying an Hfe mutation analogous to the common human mutation (C282Y) and in mice fed excess dietary iron. Hfe(-/-)mice on the C57BL6 background exhibited decreased glucose tolerance at 10-12 months due to an inability to increase insulin levels as they aged. We conclude that iron excess results in beta-cell oxidant stress and decreased insulin secretory capacity secondary to beta-cell apoptosis and desensitization of glucose-induced insulin secretion. This abnormality alone, however, is insufficient to cause diabetes.

A method for detecting recent selection in the human genome from allele age estimates.

Mutations that have recently increased in frequency by positive natural selection are an important component of naturally occurring variation that affects fitness. To identify such variants, we developed a method to test for recent selection by estimating the age of an allele from the extent of haplotype sharing at linked sites. Neutral coalescent simulations are then used to determine the likelihood of this age given the allele's observed frequency. We applied this method to a common disease allele, the hemochromatosis-associated HFE C282Y mutation. Our results allow us to reject neutral models incorporating plausible human demographic histories for HFE C282Y and one other young but common allele, indicating positive selection at HFE or a linked locus. This method will be useful for scanning the human genome for alleles under selection using the haplotype map now being constructed.

Hereditary hemochromatosis.

Hereditary hemochromatosis (hh, type 1 hemochromatosis) is an autosomal recessive trait characterized by hyperabsorption of dietary iron. The disease trait occurs in approximately five per thousand Caucasians of northern European descent. The causative gene, designated HFE, was isolated and characterized in 1996; most individuals with hh are homozygous for a mutation resulting in a change from cysteine to tyrosine at residue 282 of the HFE protein (C282Y). Wild-type HFE protein binds to the transferrin receptor, and by an undefined mechanism the enterocyte is "programmed" to absorb an amount of dietary iron precisely matched to the body's needs. The C282Y mutant protein is not expressed on the cell surface and does not bind to the transferrin receptor; the result is an enterocyte programmed to absorb slightly more iron than required. Most individuals with hh display a common laboratory phenotype, an elevated transferrin saturation. Iron stores in excess of normal eventually occur in most men and some women. The prevalence of organ damage due to iron overload, however, remains a controversial issue. Published estimates range from less than 1% to "nearly all." The main reason for this discrepancy has been ascertainment bias. Retrospective studies have been biased in favor of individuals with morbid complications of hh, whereas screening studies of groups such as blood donors generally include only healthy subjects. We focus here on a review of studies that have attempted to avoid ascertainment bias. If biopsy-proven hepatic fibrosis and/or cirrhosis is employed as the single criterion for disease-related morbidity, clinical penetrance of hh occurs in 4% to 25% of homozygotes. This range, although narrower than in biased studies, is still wide and requires clarification. A large-scale population-based study has been sponsored by the National Institutes of Health to address this issue. Until results become available, the pragmatic approach is to continue to screen for hemochromatosis in the primary care setting and to maintain serum ferritin values at approximately 100 micro g/L or lower with phlebotomy therapy.

Regulation of iron absorption in Hfe mutant mice.

Hereditary hemochromatosis is most commonly caused by homozygosity for a point mutation (C282Y) in the human hemochromatosis gene (HFE). The mechanism by which HFE regulates iron absorption is not known, but the C282Y mutation results in loss of cell surface expression of the human hemachromatosis protein (HFE) and hyperabsorption of iron by the duodenal enterocyte. Mice homozygous for a deletion in the mouse hemochromatosis gene (Hfe) or a mutation equivalent to that seen in human hereditary hemochromatosis (C282Y) were compared with wild-type animals for their ability to regulate iron absorption. Both mutant strains hyperabsorbed (59)Fe administered by gavage. Feeding a diet supplemented with carbonyl iron resulted in a more than 5-fold reduction of (59)Fe absorption in both wild-type and mutant mouse strains. Similarly, the iron loading associated with age in Hfe mutant mice resulted in nearly a 4-fold reduction in iron absorption. When mice were stimulated to absorb iron either by depleting iron stores or by inducing erythropoiesis, wild type and Hfe mutant strains increased absorption to similar levels, approximately 5-fold over control values. Our data indicate that Hfe mutant mice retain the ability to regulate iron absorption. Mouse hemachromatosis protein (Hfe) plays a minor role in down-regulation but does not influence the up-regulation of iron absorption.