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Allele frequencies of hemojuvelin gene (HJV) I222N and G320V missense mutations in white and African American subjects from the general Alabama population
BMC Medical Geneticsvolume 5, Article number: 29 (2004)
Homozygosity or compound heterozygosity for coding region mutations of the hemojuvelin gene (HJV) in whites is a cause of early age-of-onset iron overload (juvenile hemochromatosis), and of hemochromatosis phenotypes in some young or middle-aged adults. HJV coding region mutations have also been identified recently in African American primary iron overload and control subjects. Primary iron overload unexplained by typical hemochromatosis-associated HFE genotypes is common in white and black adults in Alabama, and HJV I222N and G320V were detected in a white Alabama juvenile hemochromatosis index patient. Thus, we estimated the frequency of the HJV missense mutations I222N and G320V in adult whites and African Americans from Alabama general population convenience samples.
We evaluated the genomic DNA of 241 Alabama white and 124 African American adults who reported no history of hemochromatosis or iron overload to detect HJV missense mutations I222N and G320V using polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) technique. Analysis for HJV I222N was performed in 240 whites and 124 African Americans. Analysis for HJV G320V was performed in 241 whites and 118 African Americans.
One of 240 white control subjects was heterozygous for HJV I222N; she was also heterozygous for HFE C282Y, but had normal serum iron measures and bone marrow iron stores. HJV I222N was not detected in 124 African American subjects. HJV G320V was not detected in 241 white or 118 African American subjects.
HJV I222N and G320V are probably uncommon causes or modifiers of primary iron overload in adult whites and African Americans in Alabama. Double heterozygosity for HJV I222N and HFE C282Y may not promote increased iron absorption.
Homozygosity or compound heterozygosity for coding region mutations of the hemojuvelin gene (HJV) in whites is a cause of early age-of-onset iron overload (juvenile hemochromatosis), and of hemochromatosis phenotypes in some young or middle-aged adults [1–4]. HJV coding region mutations have also been identified recently in African American primary iron overload and control subjects . We estimated the frequency of the HJV missense mutations I222N and G320V in Alabama white and African American adults who reported no history of hemochromatosis or iron overload, because primary iron overload unexplained by typical hemochromatosis-associated HFE genotypes is common in whites and blacks in Alabama [6–8], and HJV I222N and G320V were detected in an Alabama juvenile hemochromatosis index patient . In addition, HJV I222N and G320V have been described in white adults with hemochromatosis phenotypes in other geographic areas [1, 2, 9].
General criteria for selection of study subjects
Performance of this study was approved by the Institutional Review Boards of the University of Alabama at Birmingham and Brookwood Medical Center. Unrelated white subjects were spouses of patients who attended a hematology and medical oncology outpatient clinic; hospital employees; and controls who participated in a sleep study. Unrelated control black subjects were spouses of patients who attended a hematology and medical oncology outpatient clinic; hospital employees; controls who participated in a sleep study; and controls who participated in a study of gestational diabetes mellitus. All subjects were adults (≥ 18 years old). No subject reported a previous diagnosis of hemochromatosis or iron overload. Serum transferrin saturation, serum ferritin concentration, or other indicators of iron metabolism were not measured in most study subjects.
Polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) analyses
Genomic DNA was isolated from blood buffy coat as described previously . HJV I222N and G320V were genotyped by standard PCR-RFLP and agarose electrophoresis techniques. Exon 4 of the HJV locus was amplified using the primers HJEx4AF and HJEx4BR previously described ; this allowed for the amplification of the region containing both the I222N and G320V mutations of the HJV locus. Reaction conditions were as follows: 10 mM KCl, 10 mM (NH4)2SO4, 20 mM Tris-HCl (pH 8.8), 0.1% Triton X-100, 3.2 mM MgSO4, 200 μM dATP, 200 μM dCTP, 200 μM dGTP, 200 μM dTTP, 1 μM of each primer, 0.2 U/μL of Taq Polymerase. Amplification conditions on a Biometra UNO II thermocycler (LabRepCo/LabRepNet, Horsham, PA) consisted of an initial denaturing at 94°C for five minutes followed by thirty cycles of 94°C for 30 seconds, 60°C for 30 seconds and 72°C for 30 seconds.
Delineation of c.665T→A of the HJV exon 4 nucleotide sequence defining I222N was made utilizing the restriction endonuclease Bcc I (New England Biolabs, Beverly, MA), which recognizes the nucleotide c.665T of I222 as a restriction site, and not the nucleotide c.665A of N222. Similarly, the nucleotide polymorphism site c.959G→T defining the G320V polymorphism of the HJV exon 4 locus was determined by using the restriction endonuclease Ban I (New England Biolabs, Beverly, MA). Ban I recognizes the nucleotide c.959G of G320 as part of the restriction site sequence, but not the nucleotide c.959T of V320. DNA specimens from the parents of a white juvenile hemochromatosis index case were used as positive controls for HJV I222N and G320V .
The data set consisted of observations on 241 Alabama white and 124 African American adults. Analysis for HJV I222N was performed in 240 whites and 124 African Americans. Analysis for HJV G320V was performed in 241 whites and 118 African Americans. Results are expressed as allele frequencies and 95% confidence intervals (CI). To estimate the CI for frequencies of HJV mutations that were not detected in the present subjects, we computed the allele frequency as the quotient of single minimal hypothetical value (= 0.01) and the number of chromosomes corresponding to the respective groups of subjects. Computations were performed with GB-STAT (v10.0; Dynamic Microsystems, Inc., Silver Spring, MD).
Allele frequencies of HJVI222N and G320V
These results are displayed in Table 1. One of 240 white subjects was heterozygous for HJV I222N, but this mutation was not detected in African American subjects. HJV G320V was not detected in either white or African American subjects.
Characteristics of a HJVI222N heterozygote
Medical records of the white subject heterozygous for HJV I222N were available for review. This 29 year-old woman was also heterozygous for HFE C282Y. She reported that she had had two normal pregnancies and one spontaneous abortion. She has always experienced heavy menstrual flow, but she reported no other significant blood loss. She reported no blood donation. She reported that she eats a variety of meats, vegetables, and other foods; there was no history of supplemental iron ingestion. Her hemoglobin level was 12.8 g/dL, platelets 113,000/mm3, transferrin saturation 21%, and serum ferritin 23 ng/mL; marrow examination performed to evaluate thrombocytopenia revealed normal cellular morphology and normal iron stores.
A variety of HJV coding region mutations occur in homozygous or compound heterozygous configuration in persons with juvenile or adult-onset hemochromatosis phenotypes [1–5, 9–11]. However, these types of HJV-associated hemochromatosis are collectively uncommon [1–3, 11, 12]. HJV mutations were also uncommon in control whites studied with dHPLC (denaturing high-performance liquid chromatography) . In 200 Greek volunteer blood donors, none carried the HJV G320V mutation detectable by PCR-RFLP analysis, suggesting that the frequency of the G320V allele in the Greek population is lower than 0.004 . In French control subjects, for example, only the HJV missense mutations L101P (two heterozygotes) and E302K (one heterozygote) were identified in 333 control subjects, representing an aggregate HJV mutation frequency of 0.0045 (95% CI: 0, 0.0096) . The present results in Alabama white control subjects are consistent with these previous reports. Taken together, these observations confirm and extend previous observations that the individual or aggregate frequency of HJV coding region mutations is low in general populations of whites .
Heterozygosity for a HJV missense mutation was associated with increased severity of iron overload in nine of 310 French patients with hemochromatosis and HFE C282Y homozygosity who were studied with dHPLC . In 48 white U.S. hemochromatosis patients with HFE C282Y homozygosity studied with dHPLC, no HJV coding region mutation was detected . Thus, aggregate HJV coding region mutation frequencies in C282Y homozygotes with a hemochromatosis phenotype in France and the U.S. are similar (0.0148 vs. 0, respectively; p = 0.2716, Fisher exact test). The aggregate frequency of HJV coding region mutations was similar in French hemochromatosis patients with HFE C282Y homozygosity and in French control subjects (0.0145 vs. 0.0045, respectively; p = 0.0564, Fisher exact test), although the hemochromatosis patients with HJV coding region mutations had more severe iron overload, on the average, than did hemochromatosis patients without HJV coding region mutations .
Double heterozygosity for HJV I222N and HFE C282Y was not associated with evidence of increased iron absorption in the present case. Some persons with JH have common HFE genotypes, including C282Y heterozygosity, H63D heterozygosity or homozygosity, and S65C heterozygosity [13–18]. However, these HFE genotypes are infrequently associated with a severe hemochromatosis phenotype [6, 7, 19–25]. Further, sequencing HFE introns and exons in English and French Canadian JH cases did not reveal novel HFE mutations that could likely explain the development of iron overload [14, 15]. In 310 C282Y homozygotes in France, HJV mutations were relatively common and were associated with greater severity of iron overload . In 48 C282Y homozygotes in the U.S. who had severe iron overload phenotypes, no HJV coding region mutation was detected . The frequency of H63D is significantly greater in persons with cardiomyopathy than in normal control subjects . The brother of a Spanish JH proband had evidence of iron overload associated with H63D homozygosity and heterozygosity for a putative JH-associated Ch1q haplotype . Although these reports are consistent with observations in another JH patient with cardiomyopathy who had HFE H63D [3, 12], other persons with JH and cardiomyopathy did not have H63D . Altogether, these reports indicate that further exploration of the potential role of variant HJV alleles in the clinical expression of iron overload with particular reference to HFE hemochromatosis is warranted , and that the frequency and biological significance of HJV alleles may vary among racial/ethnic groups.
Primary iron overload in African Americans is phenotypically and genetically heterogeneous . Some patients have common HFE mutations, a common allele of the ferroportin gene (FPN1 Q248H), or heritable types of anemia [8, 27, 28], but the genetic basis of most cases remains unknown. HJV I222N and G320V were not detected in the present African American subjects. However, HJV coding region mutations were recently identified in two of 51 African American subjects with iron overload: exon 3, nt 205–207 ins GGA (ins G69) (frequency 0.0098); and exon 4, nt 929 C→G (A310G) (allele frequency 0.0196) . The HJV alleles ins G69 and A310G were also identified in African American control subjects (allele frequencies 0.0038 and 0.0720, respectively) . Taken together, these observations suggest that HJV coding region mutations are uncommon in African Americans, but may account for some cases of primary iron overload .
HJV I222N and G320V are uncommon causes or modifiers of primary iron overload in adult whites and African Americans in Alabama. Double heterozygosity for HJV I222N and HFE C282Y may not promote increased iron absorption.
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The pre-publication history for this paper can be accessed here:http://www.biomedcentral.com/1471-2350/5/29/prepub
This work was supported in part by the Immunogenetics Program, U.S. Department of Education McNair Scholars Program grant P217A030260, National Institutes of Health/ National Heart, Lung, and Blood Institute Short-Term Training Grant for Students in Health Professional Schools T35 HL07473, and Southern Iron Disorders Center.
The author(s) declare that they have no competing interests.
JCB participated in conceiving the study, provided DNA specimens, performed statistical evaluation, and wrote part of the manuscript. CAR devised the PCR-RFLP assay, provided DNA specimens, participated in data collection, and wrote part of the manuscript. SN and SB performed testing on DNA specimens and participated in data collection. RTA participated in conceiving the study, provided DNA specimens, and wrote part of the manuscript. All authors approved the final version of the manuscript.
James C Barton, Charles A Rivers, Sandrine Niyongere, Sean B Bohannon and Ronald T Acton contributed equally to this work.