Linda M. Griffen

Prevalence of Hemochromatosis among 11,065 Presumably Healthy Blood Donors

There is evidence that iron loading and organ damage can be prevented in patients with hemochromatosis if prophylactic phlebotomy is employed early in the disease--findings emphasizing the importance of early detection before clinical signs occur. This study was designed to determine the efficacy of transferrin saturation as a screening tool for hemochromatosis and to assess the frequency of homozygosity for the HLA-linked hemochromatosis gene in a healthy population. We screened 11,065 presumably healthy blood donors (5840 men and 5225 women). Donors with transferrin saturations of 62 percent or more after an overnight fast were considered potential homozygotes and were asked to undergo liver biopsy and pedigree analysis. The frequency of values for transferrin saturation of 62 or higher in men was 0.008 and in women 0.003. Thirty-eight persons with values higher than 62 were studied in detail; 35 underwent liver biopsy. Liver iron stores ranged from normal to markedly increased. Twelve siblings with an identical HLA match to a proband underwent liver biopsy, and 11 had increased liver iron stores. According to likelihood analysis of the pedigrees, 26 of the 38 probands were homozygotes, and 12 were heterozygotes. The estimated frequency of homozygosity was based on the data in men, because the threshold value of 62 for the transferrin saturation identified only half as many female homozygotes as expected. The frequency of homozygosity was 0.0045, corresponding to a gene frequency of 0.067. The value of population screening is demonstrated in these studies by the detection of homozygotes before clinical manifestations of hemochromatosis occur.

Clinical and Biochemical Abnormalities in People Heterozygous for Hemochromatosis

BACKGROUND Ten percent of whites are heterozygous for the HLA-linked hemochromatosis mutation. We performed a cross-sectional analysis of 1058 genotyped heterozygotes to define the effects of age and sex on the phenotype. METHODS The heterozygous genotype was assigned to 505 male and 553 female members of 202 pedigrees, each with an HLA-typed homozygous proband. We measured serum iron, transferrin saturation, and ferritin in all heterozygotes and in 321 genetically normal subjects (unaffected family members or spouses of family members). Liver biopsies were performed in a subgroup of heterozygotes. RESULTS The mean serum iron concentrations and transferrin-saturation values were higher in heterozygotes than in normal subjects and did not increase with age. Initial transferrin-saturation levels exceeding the threshold associated with the homozygous genotype were found in 4 percent of male and 8 percent of female heterozygotes. The geometric mean serum ferritin concentration was higher in heterozygotes than in normal subjects and increased with age. Higher-than-normal values were found in 20 percent of male and 8 percent of female heterozygotes. The clinical and biochemical expression of hemochromatosis was more marked in heterozygotes with paternally transmitted mutations than in those with maternally transmitted mutations. Liver-biopsy abnormalities were generally associated with alcohol abuse, hepatitis, or porphyria cutanea tarda. CONCLUSIONS The phenotype of persons heterozygous for hemochromatosis differs from that of normal subjects, but complications due to iron overload alone in these heterozygotes are extremely rare.

Disease-Related Conditions in Relatives of Patients with Hemochromatosis

BACKGROUND Hemochromatosis occurs in approximately 5 white people per 1000 and is usually due to homozygosity for mutations in the HLA-linked HFE gene. Although screening has been proposed, the proportion of homozygotes with conditions related to hemochromatosis is uncertain. METHODS We studied the prevalence of disease-related conditions among relatives of probands with hemochromatosis. We identified probands who presented to a clinic with signs or symptoms of hemochromatosis or who had elevated transferrin-saturation values. We identified homozygous relatives, mainly siblings, on the basis of HLA identity with the proband and by HFE genotyping. Disease-related conditions were cirrhosis, hepatic fibrosis, elevated amino-transferase values, and hemochromatotic arthropathy. RESULTS We identified 214 homozygous relatives of 291 homozygous probands. Of the 113 men in this group (mean age, 41 years), 96 (85 percent) had iron overload, and 43 (38 percent) had at least one disease-related condition. Of the 52 men over 40 years of age, 27 (52 percent) had at least one disease-related condition. Of the 101 female homozygous relatives (mean age, 44 years), 69 (68 percent) had iron overload, and 10 (10 percent) had at least one disease-related condition. Of the 43 women over 50 years of age, 7 (16 percent) had at least one disease-related condition. If the proband had a disease-related condition, relatives who were men were more likely to have morbidity than if the proband had no disease-related condition. CONCLUSIONS A substantial number of homozygous relatives of patients with hemochromatosis--more commonly men than women--have conditions related to hemochromatosis that have yet to be detected clinically.

Haplotype Analysis of Hemochromatosis: Evaluation of Different Linkage-Disequilibrium Approaches and Evolution of Disease Chromosomes

We applied several types of linkage-disequilibrium calculations to analyze the hereditary hemochromatosis (hh) locus. Twenty-four polymorphic markers in the major histocompatibility complex (MHC) class I region were used to haplotype hh and normal chromosomes. A total of 169 hh and 161 normal chromosomes were analyzed. Disequilibrium values were found to be high over an unusually large region beginning 150 kb centromeric of HLA-A and extending nearly 5 Mb telomeric of it. Recombination in this region was approximately 28% of the expected value. This low level of recombination contributes to the unusually broad region of linkage disequilibrium found with hh. The strongest disequilibrium was found at locus HLA-H (delta = .84) and at locus D6S2239 (delta = .85), a marker approximately 10 kb telomeric to HLA-H. All disequilibrium methods employed in this study found peak disequilibrium at HLA-H or D6S2239. The cys282tyr mutation in HLA-H, a candidate gene for hh, was found in 85% of disease chromosomes. A haplotype phylogeny for hh chromosomes was constructed and suggests that the mutation associated with the most common haplotype occurred relatively recently. The age of the hh mutation was estimated to be approximately 60-70 generations. Disequilibrium was maintained over a greater distance for hh-carrying chromosomes, consistent with a recent mutation for hh. Our data provide a reasonable explanation for previous difficulties in localizing the hh locus and provide an evolutionary history for disease chromosomes.

HLA-linked hemochromatosis alleles in sporadic porphyria cutanea tarda

We tested the hypothesis that the hepatic siderosis that characterizes sporadic porphyria cutanea tarda is due to the presence of HLA-linked hemochromatosis alleles. We studied 21 probands with sporadic porphyria cutanea tarda and 135 of their relatives by determining HLA haplotypes and measuring transferrin saturation and serum ferritin concentration. Liver biopsies were performed in all probands and in relatives when appropriate. Seventeen pedigrees were available and were studied by both likelihood analysis and by a gene counting method. We estimated that 10 of the 17 probands with available living relatives possessed at least one hemochromatosis allele. Thirteen of the 21 probands (62%) possessed at least one HLA-A3 alloantigen. Eighteen of 69 relatives who shared an HLA haplotype with a proband (26%) had an elevation of transferrin saturation or serum ferritin concentration. Only one first-degree relative not sharing an HLA haplotype with a proband had an elevated transferrin saturation or serum ferritin concentration. These findings indicate that HLA-linked hemochromatosis alleles are far more common in patients with sporadic porphyria cutanea tarda than in individuals in the general population and may be responsible for the hepatic siderosis associated with most cases of sporadic porphyria cutanea tarda.

The Morbidity of Hemochromatosis among Clinically Unselected Homozygotes: Preliminary Report

Hemochromatosis is an autosomal recessive disorder that often results in accumulation of excessive amounts of storage iron in parenchymal organs. 1-14 The end-stage of the disease in individuals who are homozygous for the HLA-linked hemochromatosis allele is characterized by massive iron overload associated with organ damage. The frequency of homozygosity for hemochromatosis in some populations, including the U.S. Caucasian population, is estimated to be about 5 per 1000. 15 Massive iron overload, however, with multiple organ failure occurs less frequently. 15-21 The disparity between the frequency of the homozygous genotype and the observed frequency of massive iron over-load is due in part to physiologic iron loss in women, and may be due to variable penetrance of the clinical phenotype in homozygotes of both sexes. 15,20

Southern blood club symposium: an update on selected aspects of hemochromatosis.

Genetic epidemiology studies have indicated that hereditary hemochromatosis (HH) occurs in caucasians with a frequency of 3 to 13 per thousand. Clinical recognition however occurs far less frequently. The disparity is best resolved by defining HH as homozygosity for the HLA-linked hemochromatosis allele, regardless of the total body iron burden. Variability of clinical expression is explained in part by physiologic iron loss in women but variability in males may be due to environmental factors, gene-gene interactions or polymorphisms in mutated hemochromatosis alleles. Although clinical variability is great, the laboratory phenotype of HH is fairly constant and is marked by elevation of the transferrin saturation. The elevated transferrin saturation occurs early in life, before organ iron loading occurs and can be used as a screening tool to detect HH before organ damage occurs. Cloning and characterizing the HH gene, which is located within 1 centimorgan of the HLA-A locus should resolve some of the issues concerning clinical variability.

Comparison of Stainable Liver Iron Between Symptomatic and Asymptomatic Hemochromatosis Homozygotes and Their Homozygous Relatives

The authors compared the amount of hepatic parenchymal cell stainable iron in 159 hemochromatosis homozygotes. They were separated into four groups. Group 1: 59 symptomatic hemochromatosis probands with hemochromatosis (mean age 49 years) who were identified because of symptoms and signs of iron overload. Group 2: 38 asymptomatic probands with hemochromatosis (mean age 29 years) identified during population screening studies or during routine health maintenance evaluation. Group 3: 47 homozygous relatives (mean age 43 years) of Group 1 probands. Group 4: 15 homozygous relatives (mean age 30 years) of Group 2 probands. The symptomatic probands (Group 1) were 20 years older and had much more stainable hepatic iron (p less than 0.0001) than the asymptomatic probands (Group 2). The homozygous relatives (Group 3) of the symptomatic probands also were older and had much more stainable hepatic iron than the homozygous relatives (Group 4) of asymptomatic probands (p less than 0.0002). The results of this study suggest that population screening studies can result in early identification of individuals with hemochromatosis before massive hepatic iron overload occurs and before symptoms of iron overload develop.

Coincidental hemochromatosis and viral hepatitis.

A 35-year-old woman presented with liver failure, hepatic iron overload, and secondary amenorrhea due to hypogonadotropic hypogonadism. She had chronic inflammatory hepatitis which was considered to be due to post-transfusional viral hepatitis. Her hepatic iron overload was considered to be due to hemochromatosis. Her premature menopause was thought to be due to the severity of her liver disease, but her iron overload also could have contributed to gonadotrophin deficiency. She underwent liver transplantation and 5 months later, she experienced return of menstrual function. The distinction between hepatitis as a cause of iron loading, hemochromatosis as a cause of hepatic inflammation, the small influence of alcohol on increased iron stores, and other features of her history, physical examination, and laboratory evaluation are discussed.

Mapping recombinant events with molecular markers in hemochromatosis pedigrees

The gene responsible for hereditary hemochromatosis (HH) is tightly linked to the class I region of the human leukocyte antigen (HLA) complex. Initial studies designed to map the disease locus have relied on serological markers for the class I antigens. Molecular markers from this region can now be used in combination with HLA serotyping for mapping studies. We previously reported two pedigrees in which serological data indicated recombinant events within the class I region. These data suggested a location for the HH locus between HLA-A and HLA-B. Molecular mapping studies have allowed us to demonstrate that an apparent recombination in one pedigree did not occur. This approach has also produced a more precise centromeric boundary for the region containing the disease locus, telomeric of HLA-C. These results emphasize the importance of including both serological and molecular markers in pedigree studies aimed at fine mapping the HH locus.