Abstract
The molecular basis of haemochromatosis has proved more complex than expected. After the 1996 identification of the main causative gene HFE and confirmation that most patients were homozygous for the founder C282Y mutation, it became clear that some families were linked to rarer conditions, first named ‘non-HFE haemochromatosis’. The genetics of these less common forms was intensively studied between 2000 and 2004, leading to the recognition of haemojuvelin (HJV), hepcidin (HAMP), transferrin receptor 2 (TFR2) and ferroportin-related haemochromatosis, and opening the way for novel hypotheses such as those related to digenic modes of inheritance or the involvement of modifier genes. Molecular studies of rare haemochromatosis disorders have contributed to our understanding of iron homeostasis. In turn, recent findings from studies of knockout mice and functional studies have confirmed that HAMP plays a central role in mobilization of iron, shown that HFE, TFR2 and HJV modulate HAMP production according to the body's iron status, and demonstrated that HAMP negatively regulates cellular iron efflux by affecting the ferroportin cell surface availability. These data shed new light on the pathophysiology of all types of haemochromatosis, and offer novel opportunities to comment on phenotypic differences and distinguish mutations.
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Introduction – historical brief
The term haemochromatosis was coined by Von Recklinghausen1 in 1889 to describe the association of an abnormal iron deposition in tissues with the clinical syndrome of cirrhosis, diabetes mellitus and bronze skin pigmentation reported by Trousseau 24 years earlier.2 A familial origin of haemochromatosis was first posited by Sheldon3 in 1935 who, after conducting a comprehensive literature review, classed the disease as an inborn error of metabolism. After this elementary step, and despite the fact that the idiopathic (not acquired) origin of the disease remained a matter of debate for 40 more years,4 haemochromatosis was successively shown to be inherited by autosomal recessive transmission,5 mapped to the short arm of chromosome 6 close to the HLA-A locus6, 7 and associated with mutations of the HFE gene.8, 9 For much of the 20th century, and especially between 1976 and 1996 when positional cloning studies gained momentum and the presence of an ancestral haplotype of about 6 Mb in size was reported in most patients of European descent,10 haemochromatosis was basically considered as a monogenic disorder. This restrictive perception of the disease was reinforced by HFE gene identification since the vast majority of haemochromatosis cases were found to be homozygous for a founder mutation linked to the ancestral haplotype and leading to the substitution of a tyrosine residue for cysteine at position 282 (C282Y).11 By analogy with the MHC class I family of molecules, including HLA-A2 with which the HFE protein shares 37% sequence identity, it was immediately proposed that the predominant mutation in haemochromatosis probands prevents the formation of a crucial disulphide bridge and, as a consequence, has an important effect on HFE protein structure.8 Its functional impact was demonstrated in iron overload mice carrying an artificially introduced C282Y mutation.12
The discovery of the HFE gene and the development of simple tests for C282Y mutation genotyping were important steps in the diagnosis of haemochromatosis and the identification of related individuals at risk of developing iron overload. Once completed by the search for the change in amino acid 63 from histidine to aspartic acid (H63D), a more prevalent substitution albeit associated with a weak structural impact,13 and the subsequent scanning of the whole HFE coding region, the cloning of the HFE gene also paved the way for the identification of non-HFE-related forms of haemochromatosis. From 2000 to 2004, these rare conditions, which are of either adult or juvenile onset, were successively related to mutations in the genes that encode transferrin receptor 2 (TFR2),14 ferroportin 1 (SLC40A1),15 hepcidin (HAMP)16 and haemojuvelin (HJV).17 The description of a digenic mode of inheritance has recently completed our knowledge of the molecular basis of haemochromatosis18, 19 and, thus, definitively altered the monogenic perception of this old disease (Table 1).
This review will focus on the genetics of haemochromatosis, highlighting recent advances and hypotheses in our understanding of key regulatory mechanisms of iron homeostasis.
Classification of haemochromatosis
As stated in the Introduction, the term haemochromatosis (synonymous with hereditary or primary haemochromatosis) first referred to the HFE-related historical and most common condition, now called haemochromatosis type 1, which is characterized by increased duodenal iron absorption and rapid iron release from macrophages. This physiologically abnormal situation leads to the accumulation of iron in the blood compartment (manifested by a rise in serum transferrin saturation) and favours the progressive iron loading of parenchymal cells (witnessed by an increase in concentrations of serum ferritin). Iron tends to be selectively deposited in hepatocytes, but organs like the heart and pancreas are also targeted. More males than females are affected and onset is usually in the fourth decade for men and the fifth for women. At its fully developed stage, iron loading impairs the function of target organs and damages their structure. The clinical consequences of iron overload can be prevented by early diagnosis and treatment with repeated phlebotomies.20
Disregarding the onset and incidence of some clinical manifestations, haemochromatosis types 2 and 3 display similar histological and clinical features. Haemochromatosis types 2A and 2B refer to juvenile autosomal recessive conditions, respectively, associated with mutations in the HJV gene and the HAMP gene. These juvenile conditions are distinguished by greatly accelerated iron accumulation, which affects both sexes and causes clinical symptoms before the age of 30 years. Clinical manifestations are marked by an increased incidence of hypogonadism and cardiomyopathy.21, 22 Haemochromatosis type 3 refers to another autosomal recessive condition, which is due to mutations in the TFR2 gene and which could be classified as intermediate between the classical adult-type and the two juvenile types.23
Finally, haemochromatosis type 4 is related to an adult autosomal dominant iron overload syndrome caused by mutations in the ferroportin 1 gene. As this syndrome displays distinct biochemical, histological and clinical features, it is called ‘ferroportin disease’ by many authors,24, 25, 26 a situation that highlights the need for a less confused classification. As suggested by Roetto and Camaschella,25 the new respective terms for the disorders could be HFE-related haemochromatosis, TFR2-related haemochromatosis, HAMP- or HJV-related haemochromatosis and ferroportin disease.
Haemochromatosis type 1 – HFE related
Predominance of the C282Y homozygous and C282Y/H63D compound heterozygous genotypes in the haemochromatosis patients
The positional cloning strategy that led to HFE identification was focused on the search for a founder mutation carried by an ancestral haplotype. The founder effect was previously suggested by the increased frequency of the HLA-A3, B7 and HLA-A3, B14 allelic associations in haemochromatosis patients,7 and subsequent linkage-disequilibrium studies demonstrated that a large DNA segment was identical-by-descent in the vast majority of the affected chromosomes.10 From a cohort of 178 patients, Feder et al8 identified the HFE 845 G>A transition (C282Y) on the ancestral haplotype and showed that this predominant mutation was found in the homozygous state in 83% of patients. They further found that most of the nonancestral haplotypes carried the 187 C>G transversion (H63D) and indicated that this second mutation was over-represented on the chromosomes not affected by the C282Y mutation. Subsequent genotype/phenotype correlation studies confirmed the strong relationship between the C282Y homozygous genotype, found in 64–100% of patients, and typical haemochromatosis phenotypes. They also revealed that the C282Y/H63D compound heterozygous genotype accounted for 74–100% of the non-C282Y homozygous patients and was associated with milder iron overload phenotypes.27
Despite an estimated frequency of 2% in European countries, the H63D homozygous genotype is rarely associated with an iron-loading condition.11, 28 Moreover, the H63D amino-acid change has little effect on HFE protein structure and is not expected to produce a significant loss-of-function.13 These observations support the idea that to be causative the frequent H63D variant requires the presence of an additional risk factor, such as a trans-C282Y mutation or excessive alcohol intake.29
282Y and 63D allele frequencies and related theories
The prevalence of the C282Y heterozygous genotype in European populations is about 1 in 11 (9.2%), but is not homogeneous and decreases from the north-west to the south-east, which is consistent with the disease distribution.30 The highest frequencies have thus been reported in Ireland (28.4),31 Brittany (17.4; unpublished result obtained from a sample of 796 subjects) and Wales (16.6),32 whereas the lowest frequencies have been observed in Italy (3.2) and Greece (2.6).11 These observations have often been related to the existence of a founder Celtic effect,27, 33 but a link with the Viking conquests and migrations has also been suggested.33 Much later, successive migrations from the western parts of Europe have introduced the C282Y mutation in white populations of North America, New Zealand and Australia.4, 27 On the other hand, the fact that the ancestral haplotype is about 6 Mb in size suggests that the C282Y mutation arose in the past 2000 years.34 If so, its current frequency is due to positive selection. A pressure mode is not easy to define as it can be single or multiple and may or may not still be effective. However, in case of the HFE gene, two hypotheses have been proposed. The first is particularly disputed,35 and is based on resistance to iron deficiency and a subsequent positive effect on the reproduction of young C282Y heterozygous women in ancient times, when dietary iron was scarcer.36 The second hypothesis adduces a protective effect against some pathological agent. It could be related either to the use of the HFE protein as a cell surface receptor by some infectious agent34 or to the relative iron deficiency that occurs with the C282Y mutation, and posits a possible protection against a number of virulent species of bacteria that multiply mainly in rich-iron macrophages.37
By contrast, the H63D variant is older than C282Y and is carried on a greater diversity of haplotypes. Its allele frequency is more than 5% in the Celtic population as well as in other Caucasian, Asian, Indian and African populations, and is particularly high in Southern-European regions like Spain (up to 32.3%).11 H63D may have arisen spontaneously in several parts of the world and its transmittance may have also been favoured through selective advantage. According to this assumption, Rochette et al34 noted that the H63D amino-acid change occurs in the HFE α2-domain, an extra-membrane region that might be implicated in interactions with infectious agents.
Other HFE genotypes related to iron overload phenotypes
Depending on the population studied, between 4 and 35% of cases presenting with haemochromatosis phenotypes are C282Y or H63D heterozygotes, or lack both C282Y and H63D.38 The HFE coding region from some of these patients has been studied, and 19 non-neutral novel variations have now been identified. With few exceptions, these variations occur in tandem with trans-C282Y mutations and are private (Figure 1).
Schematic representation of mutations in the HFE gene.
S65C missense mutation
The 193 A>T transversion, which leads to the serine 65 to cysteine substitution (S65C), displays a frequency ranging from 1.6 to 5.5% on Caucasian chromosomes.39 This mutation produces no evident effect on the HFE protein structure, but we and others have found that it is significantly enriched on affected chromosomes that carry neither the C282Y nor the H63D mutation. Moreover, it is associated with mild iron overload phenotypes when inherited with the predominant C282Y mutation in the compound heterozygous state.40, 41, 42, 43, 44 As with the H63D mutation, the S65C mutation should be considered as a risk factor rather than as a causative mutation, and either included in routine screening tests or genotyped when the systematic search for the two main haemochromatosis mutations is found to be insufficient.
E168X and W169X nonsense mutations
The case of the E168X and W169X variations can also be highlighted since they have been found in the compound heterozygous state with C282Y in haemochromatosis patients from two northern regions of Italy more frequently than the H63D mutation (respectively, in 25 and 8.4% of patients).45 This situation is representative of founder populations, in which the molecular testing strategy must be adapted.
HFE private mutations
The other 16 uncommon HFE mutations are private and have mostly been described in single patients or families. As genotype/phenotype correlation studies from unrelated subjects are unfeasible, the implication of some of the reported variations in iron overload phenotypes is not evident. A practical approach to overcoming this problem is to consider the nature of the variations and their expected functional consequences. According to this strategy, two groups of mutations can be distinguished. The first is composed of one nonsense (R71X), four frameshift (148–169del, 203delT, 277delC, 478delC) and two splice-site mutations (IVS3+1 G>T, IVS5+1 G>A). These mutations produce abnormal HFE mRNAs and/or highly modified or truncated HFE proteins. Even if they have been detected just once, these mutations may be useful for the molecular diagnosis of haemochromatosis patients and the identification of related individuals at risk of developing iron overload. The second group of private HFE variations is composed of nine missense mutations. The C282S variation, as the main hereditary haemochromatosis mutation, should be considered a causative allele.46 We successively demonstrated that the Q283P amino-acid change, which introduces a proline in a central β-strand position and is adjacent to cysteine 282, significantly damages the 3D structure of the HFE α-3 domain47 and leads to functional consequences similar to those described for the C282Y mutation.48 The R66S mutation might also be considered for haemochromatosis diagnosis, since the change of arginine 66 to glutamic acid (R66E) has been found to have a functional incidence: it reduces the capacity of HFE to inhibit iron release from reticuloendothelial cells.49 In the absence of functional characterization, implication of the other six rare HFE missense mutations found in mild to severe haemochromatosis phenotypes must be considered with caution.
Prevalence and penetrance of the C282Y homozygous genotype in the perception of haemochromatosis
A concise historical perspective helps to explain why haemochromatosis was deemed rare, then considered as the most common autosomal recessive disorder in populations of Northern European descent, and now again viewed as rare. When haemochromatosis was classed as an inborn error of metabolism by Sheldon in 1935, the disease was expected to be rare.3 In a review published in 1955, Finch and Finch50 reported that haemochromatosis was responsible for only one per 7000 hospital deaths and one per 20 000 hospitalizations in the United States. In the 1980s, the use of biochemical measurements, especially of transferrin saturation, which was presented as a valuable phenotypic marker in detection of subjects homozygous for the ancestral haemochromatosis mutation (not yet identified as the C282Y substitution),51 challenged clinically based evaluations and led to estimation of a novel prevalence between three and eight per 1000 individuals of Northern European origin.52, 53, 54 The biochemical prevalence of haemochromatosis was commonly cited in the literature until the identification of the HFE gene and the description of the C282Y homozygous genotype in five of 1000 individuals from identical populations.11, 27, 34 Therefore, a relationship was revealed between genetic and biochemical prevalence, albeit mainly when considering transferrin saturation rather than ferritin concentrations. By contrast, the estimated frequency of C282Y homozygous individuals in Northern European populations has shown that affected individuals remain clinically untroubled by haemochromatosis. This situation was not apparent from initial genotype/phenotype correlation studies since they were biased by a strong selection of patients, mostly recruited because of clinical features.
In the past few years, several large population studies have addressed the question of the penetrance of the C282Y homozygous genotype (ie the proportion of the C282Y homozygous individuals who exhibit an iron overload phenotype). This question calls for a uniform approach (regarding the recruitment of individuals and the selection of biochemical, treatment-based, histological or clinical criteria), but the idea is emerging that a majority of C282Y homozygous subjects will present abnormal iron parameters,55 whereas only a small number will manifest clinical features.56, 57, 58 The influence of environmental components, such as excessive alcohol consumption,56, 59, 60 surely explains one part of this phenotypical heterogeneity. The influence of epigenetic mechanisms or of modifier genes is an attractive additional explanation, and has been the subject of much recent discussion in the literature.18, 19, 61, 62, 63, 64 From a cohort of 392 C282Y homozygotes, we found one male and four female carriers of an additional HAMP mutation in the heterozygous state. We found that iron indices of these five patients were among the most elevated of the cohort and, using a comparative study with C282Y females of similar age range, that the transferrin saturation levels of the four females were also significantly increased. Combined with a previous report by Merryweather-Clark et al,19 along with the concomitant demonstration by Nicolas et al62 of an increased hepatic iron loading in HFE−/− mice with an additional HAMP-deficient allele, these data allowed us to propose that, even though they are not frequent, HAMP mutations could explain one part of the C282Y homozygous-related phenotypic heterogeneity by accentuating the iron burden. In the same cohort of C282Y homozygous patients, we more recently identified nine patients (six males and three females) heterozygous for an additional mutation in the second juvenile haemochromatosis-related gene, namely HJV. As reported in the case of the HAMP gene, the iron indices of eight patients appeared to be more severe than those observed in C282Y homozygous patients of identical sex and similar age ranges. The mean serum ferritin concentration of the six males with a HJV mutation was significantly higher than that of C282Y homozygous males without an additional mutation. These observations implicate another haemochromatosis gene as a possible modifier of HFE C282Y homozygous expression.
The search for other modifier genes is crucial as it could enable us to distinguish more precisely those C282Y homozygous patients at increased risk of developing severe iron overload and, consequently, clinical complications. In addition to our two candidate gene approaches, others have been used. They have led to negative conclusions except for those highlighting a possible association between increased iron loading and either the haptoglobin type 2–2 or the 16189 T>C mitochondrial DNA polymorphisms.35, 56, 65 An alternative to the candidate gene approach is the use of knockout mouse models of haemochromatosis. Bensaid et al63 have recently produced mice from an F2 intercross between two HFE-deficient strains that greatly differ in their propensity to develop hepatic iron loading. Through a linkage analysis study, they identified four loci that independently co-segregated with severity of the iron loading and were found to contain several iron metabolism genes. Analysis of these genes will probably support the identification of novel modifiers. As emphasized by the authors, further positive results may also come from the study of the syntenic chromosomal regions in humans.
Haemochromatosis types 2A and 2B – HJV- and HAMP-related
Juvenile haemochromatosis differs from typical HFE-related haemochromatosis in that it affects both sexes equally, is linked to a faster iron deposition in parenchymal cells (with an iron distribution similar to that observed in the case of HFE), causes clinical symptoms in the second and third decades of life and, although liver dysfunction is also part of the syndrome, is associated with a more frequent presentation of hypogonadism and cardiomyopathies. In the absence of treatment, juvenile haemochromatosis patients may succumb to heart failure before the age of 30 years.21, 22
Molecular basis
Juvenile haemochromatosis is genetically heterogeneous, as it can be associated with mutations in two genes. The main locus was mapped to 1q21 by Roetto et al66 in 1999. Subsequent cloning of the causative gene proved difficult because of several gaps in the genome assembly of the pericentromeric 1q region and the combined exclusion of candidates implicated in iron metabolism. In all, 5 years passed before Papanikolaou et al17 identified the HJV gene (originally called HFE2), through the linkage analysis of 12 unrelated families predominantly of Greek origin, but also of Canadian or French descent. The authors identified six different mutations with one, the G320V substitution, observed in the homozygous or compound heterozygous state in 80% (15/19) of the patients. This predominant mutation was reported in some of six additional studies, based on a total of 43 novel families from Southeast USA, Italy, Saguenay-Lac-Saint Jean (Canada – Quebec), England, Albania, Australia, France, Germany, Slovakia, Croatia, Romania and China. It was found to be particularly prevalent in Saguenay-Lac-Saint Jean, where 18 homozygous patients were detected, while patients of different genetic backgrounds have permitted the identification of 23 novel mutations, thus highlighting marked allele heterogeneity67, 68, 69, 70, 71, 72 (Figure 2).
Schematic representation of mutations in the HJV gene. The first six reported mutations, including the predominant G320V amino-acid change, are marked with asterisks.
As soon as the main gene responsible for juvenile haemochromatosis was mapped to 1q21, it became clear that some families were linked to a rarer morbid locus. Roetto et al16 took advantage of the identification of HAMP as a key regulator of iron haemostasis and identified two mutations (93delG and R56X) in its coding gene, HAMP (19q13). This positive result, exclusively based on a gene candidate approach and the study of only two pedigrees from Italy and Greece, was confirmed by the report of three novel mutations in four other unrelated families: the C70R and C78T substitutions, which disrupt one of four disulphide bridges that are critical for the 3D hairpin structure of the HAMP peptide,73, 74, 75 and the 5′-UTR+14 G>A transition, which creates a new AUG codon. This premature start codon induces a shift of the reading frame and is further believed to prevent the synthesis of normal HAMP (Figure 3).76
Schematic representation of mutations in the HAMP gene. Mutations related to HFE/HAMP digenic inheritances are marked with an asterisk. The 84-amino-acid sequence of pro-HAMP is also presented. The mature peptide is divided from the penta-arginine basic domain (---); the eight cysteines are linked with their bonds. Positions of the four reported missense mutations are indicated.
Connection with our current knowledge of iron homeostasis
The discovery of HAMP has shown that the liver plays a central role in determining the amounts of iron that must be mobilized from macrophages (where most of the iron available in the body is recycling from senescent blood cells), enterocytes (where iron is absorbed from the diet to compensate daily losses or more pronounced iron deficiencies) and hepatocytes (where iron is stored and can be released at times of increased demand) to meet the body's needs.
HAMP was first identified as an antimicrobial peptide, secreted in urine and synthesized in the liver.77, 78 The first link between HAMP and iron metabolism arose from the study of Pigeon et al,79 who showed that the amount of HAMP mRNA increases dose-dependently in the liver of experimentally or spontaneously iron-overloaded mice. Then, Nicolas et al80, 81 showed that HAMP-deficient mice develop a human-like haemochromatosis phenotype (with iron deposition in the liver and pancreas, while iron deficiency is apparent in the spleen macrophages), whereas mice overexpressing HAMP under the control of a liver-specific promoter are severely anaemic and die shortly after birth unless supplemented by parenteral but not enteral iron. These early observations in transgenic mice led to the conclusion that HAMP was a key negative regulator of dietary iron absorption, iron transport across the placenta and iron release from macrophages.
Several in vitro studies have confirmed the relationship between the level of HAMP synthesis in hepatocytes and the need either to increase or decrease iron availability regarding syndromes such as iron loading, anaemia (related to inflammation syndromes) and hypoxia. They have also deepened our understanding of iron homeostasis, while uncovering novel cellular mechanisms.82, 83, 84, 85 There is no doubt that one of the most important of these mechanisms is associated with HAMP's capacity to bind ferroportin and cause its degradation, since ferroportin is the only known transporter that mediates release of iron from macrophages, enterocytes and hepatocytes.86 In the enterocytes, this novel discovery allows the suggestion that HAMP targets ferroportin on the basolateral membrane, blocking the unique pathway for egress of iron from the diet and, thus, causing an intracellular iron excess. In turn, this intracellular iron excess will be responsive to the known downregulation of genes such as DMT1 (which encodes a duodenal iron transporter) and DcytB (which encodes a duodenal ferric reductase), thus reducing apical iron uptake from the diet, but also such as SLC40A1 itself, thus increasing the negative effect on the basolateral membrane.82, 85
Concordant studies have also shown that the haemochromatosis gene products HFE, TFR2 and HJV are required for HAMP production that correlates with the body's iron status. In fact, expression of HAMP mRNA in the liver and/or assay of HAMP in the urine have been found to be inadequate (low or very low) regarding iron overload phenotypes of either genetic mice models or patients homozygous for mutations in HFE, TFR2 and HJV.17, 87, 88, 89, 90 Further studies are needed to clarify these observations but, taking into account the common expression of the three proteins in hepatocytes, it is tempting to propose that HFE, TFR2 and HJV act as modulators of HAMP transcription in response to iron and, thus, that the four haemochromatosis-related proteins are implicated in a common pathway. This suggestion does not exclude the existence of more independent functions for each of the proteins considered, but it establishes a physiological basis underpinning the existence of the digenic mode of inheritance in haemochromatosis, hitherto related to either the HFE/TFR2 or HFE/HAMP pair, as well as the modifier effects produced by the presence of a heterozygous mutation in one of the two juvenile haemochromatosis genes in patients already homozygous for the HFE C282Y mutation.18, 62, 64
Haemochromatosis type 3 – TFR2-related
Molecular basis
With the identification of the TFR2 gene as causative in 2000, haemochromatosis type 3 was the first non-HFE-related form for which a molecular diagnosis was possible. The first paper was published by Camaschella et al,14 who identified the homozygous Y250X nonsense mutation in six patients from two unrelated Sicilian families. The causality of this mutation was confirmed by the description of an iron overload phenotype, with features comparable to those of the human disease, in mice with a targeted (on the corresponding Y245 amino acid) and identical mutagenesis (Y245X).91
So far eight novel mutations have been identified in the TFR2 gene (Figure 4). These mutations have been detected in south European pedigrees, with an Italian specificity, but also in patients of French and Japanese extraction.23, 92, 93, 94, 95, 96, 97 Identification of the AVAQ 594–597del (three siblings), L490R (one case) and V561X (one case) mutations in Japanese patients is notable since, in contrast to Caucasian populations, haemochromatosis is a rare genetic disease in Asian populations.92, 97
Schematic structure of the TFR2 gene transcripts. Compared with the TFR2-α transcript, which contains 18 exons (grey box), the TFR2-β transcript lacks exons 1–3 and conserves the last 142 noncoding bases of intron 3 (white box). Positions of the 10 reported mutations are indicated.
Is TFR2-related haemochromatosis intermediate between the adult-HFE and the two juvenile forms?
As first shown by Girelli et al94 (in 13 patients homozygous for a TFR2 mutation), despite the observation of young patients, the iron overloads attributable to haemochromatosis type 3 are variable and distinct from those of juvenile haemochromatosis. Based on the review of the 23 cases reported in the literature until 2004, we have, however, suggested that haemochromatosis type 3 is a syndrome intermediate between typical adult-onset HFE-related haemochromatosis and the two juvenile forms.23
This suggestion leads to the view that the biochemical and clinical courses of iron overload in patients homozygous for TFR2 are more rapid than that usually reported in HFE-related patients. Consistent with this idea, we showed that the age at diagnosis was significantly lower in the 23 TFR2-related homozygous patients than among two cohorts of 421 C282Y homozygous patients (P=0.0002) and 96 C282Y/H63D compound heterozygous patients (P=0.0001), and further observed that evidence of biochemical iron overload was detected in four TFR2-related females and five TFR2-related males before the age of 30 years. Clinical features, including arthralgia (two of four), hypogonadism (two of four), skin pigmentation (one of four) and cirrhosis (one of four), were noted in four of the nine.
Very recently, Pietrangelo et al96 reported the case of a pair of Italian sibs (of opposite sexes) where juvenile haemochromatosis resulted from the synergic effect of mutations in TFR2 (Q317X homozygosity) and HFE (C282Y/H63D compound heterozygosity), rather than from homozygous or compound heterozygous mutations in the HJV or HAMP gene. The authors have proposed that the TFR2 and HFE genotypes, considered singly, would be expected to produce no more than the adult onset typically seen with the haemochromatosis type 1 and 3 forms, whereas their combination may be sufficient to produce a juvenile haemochromatosis phenotype. The concomitant observation of a younger brother homozygous for the nonsense TFR2 mutation, but presenting with a less severe iron overload phenotype, was used to support this assumption. Without disregarding the explanation advanced by Pietrangelo et al, and because the younger brother was found to have raised iron values (transferrin saturation of 100%; serum ferritin concentration of 955 μg/l) along with skin pigmentation and hepatic iron overload (hepatic iron index of 2.9) at 21 years of age, one may also consider this new report as another indication that TFR2-related haemochromatosis is intermediate between classical adult-onset HFE and the two juvenile forms. Recent identification of the L490R and V561X mutations in Japanese patients with haemochromatosis manifesting at middle age, respectively, at 41 and 58 years old, could serve to counterbalance the Italian observation. However, it should be noted that the V561X patient was diagnosed with the historical triad of cirrhosis, diabetes mellitus and skin pigmentation along with congestive heart failure, while cirrhotic liver histology and diabetes were noted in the younger L490R homozygous patients.97
The iron metabolism function of TFR2 has yet to be clearly defined, but there are cumulative arguments to suggest that this second receptor for transferrin acts as a liver sensor of circulating iron and thereby plays a significant role in HAMP expression.
The TFR2 gene encodes two transcripts: a 2.9 kb isoform, called TFR2-α, and a 2.5 kb isoform, called TFR2-β, which lacks exons 1–3 and conserves the last 142 noncoding bases of intron 3 (Figure 4). Whereas the TFR2-β transcript is weakly expressed in various tissues, TFR2-α is predominantly transcribed in hepatocytes,98, 99 where HAMP expression is limited.100 Moreover, the TFR2-α form encodes a type II membrane protein that shares 45% identity and 66% similarity in its extracellular domain with the transferrin receptor (TFR1).98 This new TfR-like receptor has a lower affinity for holotransferrin,101 but its translation is not downregulated when the cellular iron content is high99, 101 (in comparison with the TFR1 transcript, the 3′ untranslated region of the TFR2-α mRNA lacks iron responsive elements). In 2002, the latter findings allowed Fleming et al91 to suggest that the TFR2-α receptor mediates hepatocyte transferrin-bound iron uptake, which is dependent on plasma transferrin saturation levels. In turn, the hepatocyte iron content would correlate HAMP synthesis with the body's iron needs. More recent studies still argue for a TFR2-piloted sensory role in the liver,84, 89, 90 most notably those that have demonstrated that TFR2 is stabilized in vitro in the presence of diferric transferrin.102, 103
In future, data elucidating the mechanism(s) by which HFE, TFR2 and HJV influence HAMP liver expression would aid the classification of haemochromatosis according to age at onset.
Haemochromatosis type IV – ferroportin disease
Molecular basis
The existence of an adult, autosomal, dominant primary iron overload, soon regarded as an atypical form of haemochromatosis, was based on the description of Melanesian (Solomon Islands),104 Italian105 and Dutch15 pedigrees. Concomitant genome-wide screens and the search for iron metabolism genes in the identified morbid regions (on 2q32) resulted in successive reports of the SLC40A1 heterozygous 430 A>C (N144H) and 230 C>A (A77D) transversions, respectively, in Dutch15 and Italian patients.106 The study of the Melanesian pedigree is as yet incomplete, but the description of the 431 A>C transversion (N144T) in an iron overload patient of Melanesian-Solomon Island extraction suggests that it was also related to ferroportin disease.107
In all, 12 other mutations have been reported in the SLC40A1 gene (Figure 5). As the three mutations referenced above are at variance with the distribution of the C282Y HFE mutation, they have been identified in patients with distinct genetic backgrounds. A common mutation, the Val 162 deletion, has particularly been found in unrelated families from the United Kingdom, Australia, Italy and Greece.108, 109, 110, 111 The other SLC40A1 mutations are private, with the exception of the Q248H substitution, which has been detected at high frequency in some populations of African descent, but for which causality is a matter of debate.112, 113, 114, 115
Schematic representation of mutations in the SCL40A1 gene. Mutations that are expected to cluster in domains 1–4 are marked with asterisks.
Proposal of two functional groups in the classification of ferroportin mutations
The 15 reported mutations span the entire primary sequence of ferroportin. However, considering consensus predicted structures with the presence of nine or more transmembrane domains, 12 mutations (from Y64N to D270V) cluster in domains 1–4, and nine of them localize to the external face of the protein.109, 116 Taking into account the cellular iron export activity of ferroportin and its strong expression in liver macrophages (Kupffer cells) and duodenal enterocytes,117, 118, 119 it was first hypothesized that ferroportin interacts with caeruloplasmin (on the membrane of macrophages) and hephaestin (on the basolateral membrane of enterocytes), or hephaestin alone (which has recently been found to be expressed on the membrane of both macrophages and enterocytes100), to generate ferroxidase activity and provide Fe3+ for circulating transferrin. Without disregarding this complementation model,120 and pending detailed analysis of the HAMP–ferroportin interaction, the demonstration by Nemeth et al86 that HAMP negatively regulates ferroportin transporters on the surface of cultured cells has opened the way to characterization of some ferroportin mutants and clearer pathophysiological explanations.
In fact, different phenotypic presentations have been noted in patients with SLC40A1 mutations, mainly distinguished by the absence or presence of increased transferrin saturation levels and the existence or otherwise of a predominant iron deposition in Kupffer cells. Further investigations may help to explain this phenotypic heterogeneity, in particular the search for modifier factors, but the very recent studies of Schimanski et al115 have supplied some very important information. These authors first showed that the 77D, V162del and 490D ferroportin protein displayed a greatly reduced capacity to reach the cell surface and permit iron export. In a second study, they found that the 64N, 144D, 144H and 326Y mutated proteins, which retain cell surface expression and export function, were resistant to inhibition by HAMP. The authors also reviewed the literature and confirmed that the clinical features of haemochromatosis patients carrying the 77D, V162del or 490D mutations are distinct from those carrying the Y64N, N144D, N144H and C326Y mutations, most notably in terms of higher transferrin saturation.121
The predominant iron loading of liver macrophages, in contrast to hepatocytes in the HFE haemochromatosis form, with the manifestation of high-serum ferritin concentrations contrasting with normal or slightly elevated transferrin saturation, is the characteristic phenotype of ferroportin disease.24 It has been reported for the main V162del mutation and to a lesser extent for the older A77D mutation, which has been associated with an age-dependent rise in transferrin saturation. These loss-of-function mutations do not impede the action of wild-type ferroportin in vitro115 and may cause the disease by haploinsufficiency, a model consistent with the autosomal dominant trait of the disease and first suggested by Montosi et al.106 The model is related to a more pronounced effect of the mutation considered on iron recycling from senescent erythrocytes by macrophages, which normally supply ∼20–30 mg of iron per day, than on absorption of dietary iron by enterocytes, which normally supply ∼1 mg of iron per day.122 In that case, iron retention by macrophages leads to accumulation of iron in the tissue, which explains the high-serum ferritin levels, and reduces the serum iron available for erythropoiesis, which explains the low transferrin saturation. This negative situation may be responsible for occasional anaemia (observed in patients with intolerance to phlebotomy) and is expected to induce a compensatory mechanism, ordered by the haematopoietic system and leading to upregulation of dietary iron uptake.106, 115 It should, however, be noted that this compensatory mechanism is at odds with the recent finding of dramatically increased urinary HAMP in two patients heterozygous for the main V162del mutation123 and, therefore, the loss-of-function model suggested for some ferroportin mutants needs to be completed.
On the other hand, mutations which resist HAMP regulation in vitro are associated with iron overload conditions less restricted to iron deposition in the Kupffer cells, and are usually marked by a transferrin saturation increase. Shimansky et al particularly focused on the Y64N mutant, reported in individuals displaying iron deposition in hepatocytes and Kupffer cells,124 the C326Y and the C326S mutant, which was associated with a predominant iron overload in hepatocytes,125 and those affecting asparagine 144 (N144H, D or T), for which iron deposition was either in hepatocytes or had a reticuloendothelial distribution.107, 126, 127 They found a strong correlation between mutations that completely abolish HAMP sensitivity (Y64N and C326S) and high transferrin saturation and, in contrast, between mutations that partially impede HAMP regulation (N144D and N144H) and the possibility of keeping transferrin saturation in the normal range. They concluded that HAMP-resistant ferroportin transporters may be associated with a greater flow of iron through the erythrocyte iron-recycling pathway, as well as with increased iron absorption. In that case, the existence of an iron overload in the blood compartment, as observed in typical forms of haemochromatosis, may be related to a better tolerance of phlebotomy. The N144H and N144D mutations, which are associated with less severe dysfunction and with more apparent intra-familial phenotypic heterogeneity,107, 127, 128 may be representative of the influence of additional modifying factors.
HFE/HAMP digenic inheritance in haemochromatosis
At almost the same period, we and others proposed that in some cases a digenic model of inheritance may be responsible for iron overload phenotypes. Merryweather-Clarke et al19 first described the association between a juvenile-like haemochromatosis condition and the presence of the C282Y heterozygous mutation in HFE along with a novel frameshift heterozygous deletion in HAMP (148–151del ATGG, which removes methionine at position 50 and the first nucleotide of intron 2). In a second pedigree, they described the coinheritance of the HFE C282Y and HAMP G71D heterozygous missense mutations in a 65-year-old patient, identified by screening his son (found to be homozygous for the C282Y mutation and heterozygous for the HAMP G71D one), who presented with elevated serum ferritin. The G71D substitution, which was detected in control chromosomes with a 0.3% allele frequency, was not considered as a highly deleterious mutation. The authors, however, noted that this substitution leads to a change from a neutral amino acid to an acidic residue between two of eight structural cysteines, a modification expected to affect folding of the HAMP peptide and reduce its activity (Figure 3). We agreed with this assumption when presenting the cases of four unrelated iron overload patients, firstly identified as heterozygous for the C282Y, H63D or S65C HFE mutations and secondly found to be carriers of either the G71D (one H63D heterozygous patient) or the novel R59G missense mutation in HAMP (one C282Y and two S65C heterozygous patients). We correlated the R59G amino-acid change, which occurs at the critical position for activity of prohormone convertases in a penta-arginine basic domain (residue 55–59), with a preventive effect on production of the 25-amino-acid mature HAMP from the 84-amino-acid pro-HAMP.18
Although the digenic model of inheritance has been demonstrated in many other genetic disorders,129 it can be related to the involvement of the HFE and HAMP gene products in a common pathway18, 62, 84 and is also consistent with the synergic effect proposed by Pietrangelo et al96 to implicate HFE and TFR2 mutations in the genesis of a juvenile haemochromatosis phenotype, its applicability to haemochromatosis is still not commonly admitted. Criticisms are essentially focused on the very limited number of cases that have been reported to date and, taking into account this limitation, on a phenotypic variability that encompasses juvenile and adult haemochromatosis.25 The nature of each of the mutations considered and the subsequent HFE/HAMP combination of heterozygous mutations would explain one aspect of this phenotypical heterogeneity. This possibility makes particular sense when considering the G71D HAMP mutation and, on the other hand, the H63D and S65C mutations which are deemed to be risk factors rather than causative mutations in HFE-related haemochromatosis. In addition, one can consider that, as reported for the main HFE causative genotype (C282Y homozygous), and probably to differing degrees for all forms of haemochromatosis, the HFE/HAMP digenic mode of inheritance is influenced by environmental factors and modifier genes. Right now, however, nobody can contest that novel cases would help to define and classify the HFE/HAMP digenic mode of inheritance in the haemochromatosis group. Further advances will surely accrue from better comprehension of the roles of HFE in iron metabolism – first confined to a repressive effect on the transferrin–transferrin receptor iron uptake pathway, then focused on a sensory function in the duodenal crypts,130 and now clearly opened to regulatory mechanisms in the hepatocytes and macrophages.49, 82, 83, 84, 85, 131
Conclusion
We should keep in mind that the vast majority of haemochromatosis patients are homozygous for the ancestral HFE C282Y mutation, and that the combination of transferrin saturation measurement and genotyping of this predominant mutation has improved our ability to diagnose the disease and prevent morbid complications. We have recently shown that HFE C282Y mutation testing has modified the epidemiology of haemochromatosis, with the sex ratio reduced to close to 1.0 and a weaker clinical expression than observed previously.132 However, we should also be aware that the C282Y homozygous genotype is not fully penetrant and that its expression depends on the complex interplay of genetic and nongenetic factors. Several investigations are focusing on discovery of the genetic factors that enable us to identify more precisely those C282Y homozygous patients at increased risk of developing clinical features.
In non-C282Y homozygous patients, we now know that a haemochromatosis phenotype can be associated either with another HFE mutation, especially H63D and S65C if they are inherited in-trans with C282Y, or with mutations in the genes that encode HAMP, HJV, TFR2 or ferroportin. The standard biochemical marker for all types of haemochromatosis is transferrin saturation, with the exception of the ferroportin disease for which a high-serum ferritin concentration can contrast with normal or slightly increased transferrin saturation. The expected transmission pattern (autosomal recessive or autosomal dominant), the course of the disease (juvenile, young adult or adult onset), the observation of particular symptoms (hypogonadism or unexplained heart failure are indicative of a juvenile haemochromatosis syndrome), and the predominant localization of hepatic iron (hepatocytes, Kupffer cells or both) can help in the decision to perform second-line genetic testing (the first test should be for the HFE C282Y and H63D mutation).133 However, as the HJV G320V and SLC40A1 V162del are the only common mutations of the non-HFE types of haemochromatosis, a general mutation strategy is required and the use of rapid, accurate and cheap scanning methods such as D-HPLC is highly recommended.38, 58, 134
Whether or not the general population should be screened for haemochromatosis is a source of continuing debate.135 However, there is no doubt that, once a diagnosis of haemochromatosis has been established in a proband, screening of family members, namely cascade screening, is efficient and cost-effective. This cascade screening should be based on both biochemical testing and genetic testing, if one or more pathogenic mutations have been identified.136
In the last few years, genetic, in vitro and animal model studies have shown that HAMP plays a central role in iron homeostasis. Therapeutic spin-offs can be expected from growing understanding of the roles of HAMP and identification of the factors that help to modulate its hepatic expression.
Accession codes
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Acknowledgements
This work was supported by The Programme Hospitalier de Recherche Clinique ‘Mise en place d'un diagnostic exhaustif des surcharges en fer primaires’. The Conseil Scientifique de I'Etablissement Français du Sang (projects 2003.19 et 2002.36).
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Le Gac, G., Férec, C. The molecular genetics of haemochromatosis. Eur J Hum Genet 13, 1172–1185 (2005). https://doi.org/10.1038/sj.ejhg.5201490
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DOI: https://doi.org/10.1038/sj.ejhg.5201490
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