A 6-year survey of HFE gene test for hemochromatosis diagnosis.

PURPOSE: A 6-year survey of HFE gene test was conducted to evaluate its helpfulness for hereditary hemochromatosis diagnosis. METHODS: We analyzed C282Y, H63D, and S65C mutations on 3525 individuals. RESULTS: The test produced 89.7% and 30% of positive results for individuals clinically diagnosed hemochromatosis before HFE gene-test availability and those prospectively tested because of elevated serum iron parameter and/or family history, respectively; among them there were 90.4% and 48.7% of C282Y homozygotes. CONCLUSIONS: The HFE gene test confirmed a genetic defect that may lead to iron loading in individuals when iron parameter values, especially for the C282Y/C282Y, were still low as well as for genotypes usually associated with low expressivity and penetrance (C282Y/H63D, H63D/H63D). This gene-test should allow a biochemical follow-up of patients carrying a disease-related genotype.     

Nonexpressing homozygotes for C282Y hemochromatosis: minority or majority of cases?

Genetic testing for the C282Y mutation of the HFE gene has been a major advance in the diagnosis of hereditary hemochromatosis. In most studies, more than 90% of typical hemochromatosis patients are homozygous for the C282Y mutation. Large-scale population screening studies in predominantly Caucasian populations have demonstrated a high prevalence of C282Y homozygotes of approximately 1 in 300. Despite this high prevalence by genetic testing, the clinical diagnosis of hemochromatosis and mortality from the disease are much less common. One possibility is the presence of many undiagnosed cases with nonspecific symptoms, and deaths occurring that are attributed to liver disease, diabetes, and heart disease without the recognition of iron overload secondary to hemochromatosis. Another possibility is a high prevalence of nonexpressing homozygotes. In this review, the available data on nonexpressing C282Y homozygotes is collected including information on pathogenesis, environmental interactions, and implications for population screening using genetic testing.     

Recent advances in the pathophysiology, diagnosis and treatment of hereditary hemochromatosis and other iron overload syndromes

Recent years have witnessed tremendous advances in the fields of pathophysiology, diagnosis and management of hereditary hemochromatosis (HH) and other iron overload syndromes, the dreadful consequences of which are fully preventable by early diagnosis and treatment. Missense mutations in HFE, a newly discovered gene encoding for a major histocompatibility class-I like molecule, have been found to be strictly associated with most cases of HH. The mechanisms by which a dysfunctional HFE molecule determines increased absorption of iron in HH are on the way to be fully clarified, due to the availability of a knockout mouse model. Epidemiologic studies have shown that HH is one of the most common human hereditary disorders. The possibility to identify HFE heterozygotes by means of a simple genetic test have prompted studies on the association between HFE mutations and iron overload syndromes different from HH. In the era of the historic completion of the human genome projects, genetic testing for HH may soon qualify for being adopted in universal population screening policies. In the present paper, the recent advances in the fields of genetics and pathophysiology of HH and other iron overload syndromes will be summarized. Furthermore, its clinical features, pathology and treatment will be reviewed, and the emerging issues of cost-effective diagnosis and of possible population screening strategies will be succintly discussed.     

HFE gene mutation, C282Y causing hereditary hemochromatosis in Caucasian is extremely rare in Korean population

Hereditary hemochromatosis (HFE), which affects 1 in 400 and has an estimated carrier frequency of 1 in 10 individuals in Western population, results in multiple organ damage caused by iron deposition, and is treatable if detected early. C282Y mutation in HFE gene has been known to be responsible for the most hereditary hemochromatosis cases and 5-10% of white subjects are heterozygous for this mutation. However, the prevalence of hemochromatosis in the Asian population was reported to be very low and ethnic heterogeneity has been suspected. The aim of our study was to determine the prevalence of heterozygosity and homozygosity for the C282Y HFE gene mutations in 502 unrelated Koreans. Results revealed that none of them had the mutant gene, suggesting a significant ethnic difference when compared with Caucasians. Our study excluded underlying possibility of hereditary hemochromatosis in Korean which could mimic the findings of alcoholic liver disease with iron overload or liver cirrhosis with chronic hepatitis C.     

Prevalence of the C282Y and H63D polymorphisms in a multi-ethnic control population.

Recently a candidate gene for hereditary hemo-chromatosis, HFE, was identified. The finding raises the possibility for genetic testing to provide earlier detection and more complete genotypic evaluation of hemochromatosis affected individuals. We determined the frequency of the HFE polymorphisms, C282Y and H63D, in a randomly selected multi-ethnic control population for establishment of a hemochromatosis genetic testing program. Prevalence was determined by PCR amplification and restriction enzyme digestion of HFE in 100 Caucasians, 100 Hispanics, and 56 African Americans. Heterozygosity for C282Y was detected in 8% of Caucasians, 3% of Hispanics, and 2% of African Americans. Homozygosity for C282Y was detected in 1% of Caucasians. Heterozygosity for H63D was detected in 24% of Caucasians, 15% Hispanics, and 3.5% of African Americans. Homozygosity for H63D was present in 4% of Caucasians and 1% of Hispanics. One Hispanic case was double heterozygous for C282Y and H63D. These results indicate the highest prevalence of C282Y and H63D in the Caucasian population. Additionally, we demonstrate C282Y and H63D polymorphisms in our Hispanic and African American populations, groups in which prevalence rates remain less defined. Our results support the need for thorough interpretation of genetic results for hereditary hemochromatosis in various ethnic populations.     

Screening for hereditary haemochromatosis

Hereditary haemochromatosis (HH) is a common autosomal recessive disorder of iron overload in Caucasian populations. Clinical manifestations usually occur in individuals homozygous for the C282Y mutation in the HFE gene product and who have developed significant iron loading. Current screening methods can detect affected individuals either prior to or early during disease evolution, enabling early introduction of phlebotomy treatment that can normalise life expectancy. Evaluation of possible iron overload, via measurement of serum transferrin saturation and ferritin level, is the most appropriate initial test for those subjects presenting clinically for evaluation. HFE genotyping, when combined with serum biochemical measurements, defines the presence of likely iron overload and the underlying genetic disorder and is the preferred initial screening modality for families of an affected individual. Definitive proof of iron overload requires measurement of hepatic iron concentration or total iron burden via therapeutic phlebotomy; elevated serum ferritin level alone is not adequate. We now recognise that the natural history of HH is not as discrete as previously believed, because genetic and environmental modifiers of disease penetrance are increasingly identified as influencing the clinical expression of HH. In fact, a minority of C282Y homozygotes develop classical 'iron overload disease', although it has recently emerged that the disorder may predispose to breast and colorectal cancer. Uncertainties as to the true clinical impact of the condition at a population level lead to current recommendations of cascade screening of families of affected patients, case-finding in high-risk groups, such as patients with clinical manifestations consistent with the diagnosis, and a high level of clinical awareness in the community to facilitate early diagnosis. Generalised population screening is not presently recommended.     

Implementation of HaemScreen, a workplace-based genetic screening program for hemochromatosis

There is debate as to whether community genetic screening for the mutation(s) causing hereditary hemochromatosis (HH) should be implemented, due to issues including disease penetrance, health economic outcomes, and concerns about community acceptance. Hemochromatosis is a common preventable iron overload disease, due in over 90% of cases to C282Y homozygosity in the HFE gene. We are, therefore, piloting C282Y screening to assess understanding of genetic information and screening acceptability in the workplace setting. In this program, HaemScreen, education was by oral or video presentation in a group setting. C282Y status was assessed by polymerase chain reaction (PCR) and melt-curve analysis on DNA obtained by cheek-brush sampling. Of eligible participants, 5.8% (1.5-15.8%) attended information and screening sessions, of whom 97.7% (5571 individuals) chose to be tested. Twenty-two C282Y (1 : 253) homozygotes were identified and offered clinical follow-up. There were 638 heterozygotes (1 : 8.7). The determinants for participation have been analyzed in terms of the principles outlined in the Health Belief Model. Widespread screening for HH is readily accepted in a workplace setting, and a one-to-many education program is effective. The level of participation varies greatly and the advertizing and session logistics should be adapted to the specific features of each workplace.     

To tell or not to tell – what to do about p.C282Y heterozygotes identified by HFE screening

Hereditary hemochromatosis (HH) is a common preventable disorder of iron overload that can result in liver cirrhosis and reduced lifespan. Most HH is due to homozygosity for the HFE p.C282Y substitution. We conducted a study of screening for p.C282Y in high schools where p.C282Y heterozygotes (CY) individuals were informed of their genotype by letter. We studied whether these individuals understood the implications of their genotype, whether this resulted in anxiety or reduced health perception and whether cascade testing was higher in families of CY than wild‐type homozygous (CC) individuals. We found 586 of 5757 (1 in 10) screened individuals were CY. One month after receiving their result, 83% correctly answered that they have one copy of p.C282Y. There was no adverse change in anxiety or health perception from prior to screening to 1 month after receiving results. Significantly more family members of CY individuals than CC individuals were informed about HH and had testing for HH. In conclusion, we found that informing CY individuals of their genotype does not increase anxiety and the implications are generally well understood. This leads to cascade testing in a minority of families. CY individuals should be informed of their genetic status when identified by population screening.     

HFE genotyping using multiplex allele-specific polymerase chain reaction and capillary electrophoresis

CONTEXT: Hereditary hemochromatosis is recognized as one of the most common autosomal recessive disorders, with a prevalence of 1 in 200 to 400 in the white population. Early detection and treatment are completely effective in preventing pathology. It is anticipated that testing for hereditary hemochromatosis will increase, as will the need for a technology that can handle the demand. OBJECTIVE: To describe a high-throughput, single-tube, allele-specific multiplex polymerase chain reaction assay for identifying the 2 mutations in the HFE gene associated with hereditary hemochromatosis. DESIGN: Fluorescence-labeled polymerase chain reaction products from a multiplex polymerase chain reaction are analyzed by automated capillary electrophoresis. DATA ANALYSIS: The assay was validated by analysis of 25 blinded samples, and results were concordant with an established laboratory assay. CONCLUSION: The assay described offers a significant improvement over manual laboratory assays in throughput, reduced technologist time, and cost.     

Categorizing genetic tests to identify their ethical, legal, and social implications.

Practice standards in medical genetics provide an implicit guide to the ethical, legal, and social implications (ELSI) of genetic tests. The common use of nondirective counseling reflects the principle that many testing decisions should be determined by personal values. Yet geneticists make test recommendations in some circumstances, e.g., RET mutation testing for MEN2 and newborn screening for phenylketonuria (PKU). Conversely, many geneticists recommend against testing for Apolipoprotein E (ApoE) alleles to predict Alzheimer disease (AD) risk. Taken together, these examples suggest that genetic tests can be categorized by a joint consideration of clinical validity and availability of effective treatment for persons who test positive. For genetic tests with high clinical validity/no treatment (e.g., presymptomatic testing for Huntington disease), the predominant concern is adequate nondirective counseling to ensure an informed, autonomous decision. By contrast, the predominant concern for tests with high clinical validity/effective treatment (e.g., PKU) is assuring access to care for eligible persons. For tests with limited clinical validity/no treatment (e.g., ApoE), recommending against test use can be justified on the principle of avoiding harm. For a fourth category, tests with limited clinical validity/effective treatment (e.g., HFE mutation testing for hereditary hemochromatosis), net benefit is the issue: the balance between potential benefits of treatment and potential harms of genetic labeling must be weighed. Where uncertainty exists concerning both clinical validity and effectiveness of treatment, as in the case of BRCA 1/2 mutation testing, the value of testing may vary according to different testing contexts. This approach to test categorization allows a rapid determination of the predominant ELSI concerns for different kinds of genetic tests and identifies the data most urgently needed for test evaluation.     

Hereditary hemochromatosis: impact of molecular and iron-based testing on the diagnosis, treatment, and prevention of a common, chronic disease.

OBJECTIVE: To review the current state-of-the-art regarding the role of iron- and DNA-based testing on the detection, treatment, and prevention of hereditary hemochromatosis (HH), the most common single-gene disorder in white people. SOURCES: Review of the medical literature, with particular emphasis on recent reports of the impact of DNA-based testing on the detection of symptomatic and presymptomatic patients with HH. CONCLUSIONS: Hereditary hemochromatosis, a common autosomal recessive iron overload disorder (with a population prevalence of 0.3%-0.8%), is a common cause of preventable liver, heart, joint, and endocrine disease. Since the associated clinical signs and symptoms are nonspecific, an accurate HH diagnosis demands both a high index of suspicion and the direct laboratory demonstration of elevated iron parameters. The substantial public health burden of HH as a common, deadly, detectable, and treatable chronic disease has led the College of American Pathologists to recommend that "systematic screening for hemochromatosis is warranted for all persons over the age of 20 years." The recent discovery that most HH cases are the result of a single well-conserved homozygous missense mutation (C282Y) within a novel transferrin-receptor binding protein (HFE) has given rise to diagnostic clinical tests for the DNA-based detection of this pathologic mutation. This direct HFE mutation test can now be used not only to confirm the diagnosis of HH in those with symptomatic disease, but also, perhaps more importantly, to detect those with presymptomatic iron overload in whom future disease manifestations may be prevented (with phlebotomy therapy).     

Les hémochromatoses héréditaires : partie III. Les autres hémochromatoses héréditaires

Hereditary hemochromatosis is a genetic disorder of iron metabolism. In addition to the C282Y mutation in the HFE gene responsible for the main form of the disease, others mutations have been described in genes implicated in iron homeostasis. Heterozygosity for mutations in the gene encoding ferroportin 1 (FPN1) is the second most common genetic cause of hemochromatosis (HFE4). Moreover, homozygous or double heterozygous mutations in the transferrin receptor 2 (TfR2) gene have also been reported in this disease. Mutations in two other genes encoding hemojuvelin (HJV) and hepcidin (HAMP) cause juvenile hemochromatosis (respectively HFE2a and HFE2b). Digenic forms have also been described. These recent data demonstrate that hereditary hemochromatosis may be considered as a polygenic and multifactorial disease. This article will describe these non-HFE rare forms of hemochromatosis and how to integrate these new data in clinical decision and laboratory tests interpretation.     

A retrospective anonymous pilot study in screening newborns for HFE mutations in Scandinavian populations

We have retrospectively analyzed 837 random anonymized dried blood spot (DBS) samples from neonatal screening programs in Scandinavia for mutations in HFE, the candidate gene for hemochromatosis. We have found C282Y allele frequencies of 2.3% (+2.0%) (-1.3%) in Greenland, 4.5%+/-1.9% in Iceland, 5.1%+/-2.3% in the Faeroe Islands, and 8.2%+/-2.7% in Denmark. The high prevalence of HFE mutations in Denmark suggests that population screening for the C282Y mutation could be highly advantageous in terms of preventive health care. Long-term follow-up evaluation of C282Y homozygotes and H63D/C282Y compound heterozygotes will give an indication of the penetrance of the mutations.     

The hereditary hemochromatosis gene (HFE)

The iron overload disorder, hereditary hemochromatosis, is one of the most common genetic diseases of individuals of Northern European descent. The disorder is characterized by the progressive accumulation of dietary iron in the major organs of the body, which if not diagnosed, leads to numerous medical maladies and eventually death. The locus for this disorder was mapped by genetic linkage to the short arm of chromosome over twenty years ago, but it was not until 1996 that the gene for this disorder was cloned by an identity-by-descent positional cloning approach. The gene, called HFE, encodes a major histocompatibility complex (MHC) class I like protein that is mutated in approx 85% of all individuals known to have hereditary hemochromatosis (HH). Since the cloning of the HFE gene, considerable work has been carried out which has furthered our understanding of the genetics of this prevalent disorder. In addition, with the identification of the transferrin receptor as a protein capable of interacting with HFE we are now beginning to understand how a protein with the structural characteristics of an MHC class I molecule can influence cellular iron homeostasis.     

Hemochromatosis (HFE) gene splice site mutation IVS5+1 G/A in North American Vietnamese with and without phenotypic evidence of iron overload

Homozygosity for a novel hemochromatosis (HFE) gene splice site mutation (IVS5+1 G/A) was previously reported in a 48-year-old Vietnamese man residing in Germany who had an elevated serum ferritin (SF) and transferrin saturation (TS) and severe iron overload on liver biopsy. This mutation was not found in 222 controls of central European origin but has been found in Southeast Asians living in Vietnam without evidence of iron overload. Hemochromatosis and iron overload screening (HEIRS) Study is an ongoing, multiethnic, primary care-based study of 101,168 North American adults, including 12,772 Asians, a group that the HEIRS Study found has a significantly higher than expected prevalence of elevated serum TS and SF but very low prevalence of the common C282Y and H63D HFE alleles usually associated with hereditary hemochromatosis. It was hypothesized that the IVS5+1 G/A splice site mutation might explain some elevated biochemical iron measures in North American Asians. Overall, 200 Vietnamese subjects from the Los Angeles Field Center who had TS and SF values greater than the 75th percentile of all HEIRS Study participants after adjusting for covariates and 149 controls randomly selected to represent this Vietnamese population were genotyped. Among cases, 1 homozygous mutant and 7 heterozygotes were found; among controls, 1 homozygous mutant and 4 heterozygotes were found yielding an allele frequency of 2.32% for cases and 2.04% for controls (P>0.5). This finding suggests that the HFE IVS5+1 G/A splice site mutation is not the major explanation for unexpectedly high prevalence of TS and SF in North American Asians.     

The hereditary hemochromatosis gene (HFE): a MHC class I-like gene that functions in the regulation of iron homeostasis

The iron overload disorder, hereditary hemochromatosis, is one of the most common genetic diseases of individuals of Northern European descent. The disorder is characterized by the progressive accumulation of dietary iron in the major organs of the body, which if not diagnosed, leads to numerous medical maladies and eventually death. The locus for this disorder was mapped by genetic linkage to the short arm of chromosome over twenty years ago, but it was not until 1996 that the gene for this disorder was cloned by an identity-by-descent positional cloning approach. The gene, called HFE, encodes a major histocompatibility complex (MHC) class I-like protein that is mutated in approx 85% of all individuals known to have hereditary hemochromatosis (HH). Since the cloning of the HFE gene, considerable work has been carried out which has furthered our understanding of the genetics of this prevalent disorder. In addition, with the identification of the transferrin receptor as a protein capable of interacting with HFE we are now beginning to understand how a protein with the structural characteristics of an MHC class I molecule can influence cellular iron homeostasis.     

Molecular diagnosis of HFE mutations in routine laboratories. Results of a survey from reference laboratories in France

HFE-related hemochromatosis (HFE hemochromatosis) or type 1 hemochromatosis is an autosomal recessive disease characterized by progressive iron overload usually expressed in adulthood. The HFE gene, located on the short arm of chromosome 6 (6p21.3), encodes a protein that plays a crucial role in iron metabolism by modulating hepcidin synthesis in the liver. Homozygosity for the p.Cys282Tyr mutation accounts for nearly 80% of cases of hemochromatosis in France. Genetic testing is the key investigation to confirm the diagnosis of HFE hemochromatosis. A survey on routine practices was carried out among the eight reference laboratories of the French national network on genetic iron disorders. The main findings from this survey are as follows: 1) the p.Cys282Tyr mutation must be searched for as an initial step to establish the diagnosis of HFE hemochromatosis. This is in agreement with the recommendations of the French Health Authority (HAS) published in 2005. In these recommendations, homozygosity for the p.Cys282Tyr mutation with at least elevated transferrin saturation, is considered the only genotype that confirms of the diagnosis of HFE hemochromatosis; 2) in combination with the p.Cys282Tyr mutation (compound heterozygous genotypes), the p.Ser65Cys and the p.His63Asp variants may contribute to the occurrence of mild iron overload; 3) family screening is mandatory following the detection of homozygous individuals for the p.Cys282Tyr mutation.     

Educational outcomes of a workplace screening program for genetic susceptibility to hemochromatosis

Education is an essential component of a genetic screening program. Knowledge outcomes were measured after large-scale workplace education and screening for genetic susceptibility to hereditary hemochromatosis. The aim was to assess knowledge of concepts presented, impact of mode of delivery, and knowledge retention. Education in a group setting was delivered via oral or video presentation and knowledge assessed using self-administered questionnaires at baseline, 1 month, and 12 months. Over 60% of 11 679 participants correctly answered all questions at baseline, scoring higher with clinical concepts (disease etiology and treatment) than genetic concepts (penetrance and genetic heterogeneity). Revising the education program significantly increased correct responses for etiology (p < 0.002), whilst modifying the knowledge assessment tool significantly increased correct responses for etiology (p < 0.001) and gene penetrance (p < 0.001). For three of the four concepts assessed, use of video was as effective as oral presentation for knowledge outcomes. A significantly higher proportion of those at increased risk of disease (n = 44) responded correctly at 12 months than did controls (n = 82; p = 0.011 for etiology, p = 0.002 for treatment and p = 0.003 for penetrance). Hence, genetic screening can be successfully offered in a group workplace setting, with participants remembering clinical concepts better than genetic concepts up to 1 year later.     

HFE-associated hereditary hemochromatosis

In populations of northern European descent, the p.C282Y mutation in the HFE gene is highly prevalent, and HFE-associated hereditary hemochromatosis is the most common type of inherited iron overload disorder. Inappropriate low secretion of hepcidin, which negatively regulates iron absorption, is postulated to be the mechanism for iron overload in this condition. The characteristic biochemical abnormalities are elevated serum transferrin-iron saturation and serum ferritin. Typical clinical manifestations include cirrhosis, liver fibrosis, hepatocellular carcinoma, elevated serum aminotransferase levels, diabetes mellitus, restrictive cardiomyopathy and arthropathy of the second and third metacarpophalangeal joints. Most patients are now diagnosed before the development of these clinical features. Molecular genetic tests are currently available for genotypic diagnosis. In selected individuals, diagnosis might require liver biopsy or quantitative phlebotomy. Iron depletion by phlebotomy is the mainstay of treatment and is highly effective in preventing the complications of iron overload if instituted before the development of cirrhosis. Genetic testing is currently not recommended for population screening because of low yield as the majority of the healthy, asymptomatic p.C282Y homozygotes do not develop clinically significant iron overload. HFE gene testing remains an excellent tool for the screening of first-degree relatives of affected probands who are p.C282Y homozygotes.     

Les hémochromatoses héréditaires

Genetic hemochromatosis is a metabolic disease leading to iron toxic accumulation in parenchymal cells (mainly liver), a raised serum transferrin saturation and ferritin concentration. Since discovery of the first gene HFE involved in the disease in 1996, elucidation of the molecular pathways of iron transports through cells and its control has made an important breakthrough. Hereditary hemochromatosis, a common genetic defect in the Caucasian population, is classified in four types, HFE1 associated with mutations in the HFE gene, HFE2 (juvenile hemochromatosis) associated with mutations in the HAMP (hepcidin) or in the hemojuvelin genes, HFE3 associated with the TfR2 gene and HFE4 associated with the ferroportin gene. Except HFE4, which is autosomal dominant, the other types of hemochromatosis are autosomal recessive. Digenic forms have also been described. This new classification and a better understanding of the physiopathology of hemochromatosis have modified general strategy in the screening and diagnosis of the disease.