Elizabeth C. Jazwinska

Expression of HLA-linked hemochromatosis in subjects homozygous or heterozygous for the C282Y mutation

BACKGROUND & AIMS In the absence of a genetic test, diagnostic criteria for hereditary hemochromatosis have been imprecise. The identification of the HFE gene and the C282Y mutation allow definition of expression of this disease and reassessment of diagnostic criteria. The aim of this study was to analyze the concordance between the genetic diagnosis and the previous clinical diagnosis in families with hemochromatosis. METHODS Three hundred subjects were tested for the C282Y mutation and were grouped as homozygous, heterozygous, or homozygous normal. RESULTS All adults previously diagnosed as homozygous or heterozygous for HLA-linked hereditary hemochromatosis carried at least one C282Y mutation. Two adolescents, previously thought to be homozygous, had no C282Y mutation. Of 127 subjects homozygous for the mutation, 105 met criteria for diagnosis. Iron overload was not expressed in 6.7% of homozygous men and 32.7% of homozygous women. The iron indices in 8 of 171 subjects heterozygous for the C282Y mutation were within the range previously regarded as indicative of homozygosity. Seven of these 8 carried the H63D mutation. CONCLUSIONS In Australia, 17.3% of subjects homozygous for the C282Y mutation do not express iron overload to meet current diagnostic criteria of hemochromatosis. In subjects heterozygous for the mutation, 4.8% have iron overload in the range previously diagnosed as homozygous. Nonexpression is common, particularly in women.

Effects of HFE C282Y and H63D Polymorphisms and Polygenic Background on Iron Stores in a Large Community Sample of Twins

The aim of this study was to assess and to compare the role of HFE polymorphisms and other genetic factors in variation in iron stores. Blood samples were obtained from 3,375 adult male and female twins (age range 29-82 years) recruited from the Australian Twin Registry. There were 1,233 complete pairs (562 monozygotic and 571 dizygotic twins). Serum iron, transferrin, transferrin saturation with iron, and ferritin were measured, and the HFE C282Y and H63D genotypes were determined. The frequency of the C282Y allele was.072, and that of the H63D allele was.141. Significant sources of variation in the indices of iron status included age, sex, age-sex interaction, body-mass index, and both the C282Y and H63D genotypes. The iron, transferrin, and saturation values of CC and CY subjects differed significantly, but the ferritin values did not. After correction for age and body-mass index, 23% and 31% of the variance in iron, 66% and 49% of the variance in transferrin, 33% and 47% of the variance in transferrin saturation, and 47% and 47% of the variance in ferritin could be explained by additive genetic factors, for men and women, respectively. HFE C282Y and H63D variation accounted for <5% of the corrected phenotypic variance, except for saturation (12% in women and 5% in men). We conclude that HFE CY and HD heterozygotes differ in iron status from the CC and HH homozygotes and that serum transferrin saturation is more affected than is serum ferritin. There are highly significant effects of other as-yet-unidentified genes on iron stores, in addition to HFE genotype.

Distribution of transferrin saturation in an Australian population: relevance to the early diagnosis of hemochromatosis.

BACKGROUND & AIMS An elevated transferrin saturation is the earliest phenotypic abnormality in hereditary hemochromatosis. Determination of transferrin saturation remains the most useful noninvasive screening test for affected individuals, but there is debate as to the appropriate screening level. The aims of this study were to estimate the mean transferrin saturation in hemochromatosis heterozygotes and normal individuals and to evaluate potential transferrin saturation screening levels. METHODS Statistical mixture modeling was applied to data from a survey of asymptomatic Australians to estimate the mean transferrin saturation in hemochromatosis heterozygotes and normal individuals. To evaluate potential transferrin saturation screening levels, modeling results were compared with data from identified hemochromatosis heterozygotes and homozygotes. RESULTS After removal of hemochromatosis homozygotes, two populations of transferrin saturation were identified in asymptomatic Australians (P < 0.01). In men, 88.2% of the truncated sample had a lower mean transferrin saturation of 24.1%, whereas 11.8% had an increased mean transferrin saturation of 37.3%. Similar results were found in women. A transferrin saturation threshold of 45% identified 98% of homozygotes without misidentifying any normal individuals. CONCLUSIONS The results confirm that hemochromatosis heterozygotes form a distinct transferrin saturation subpopulation and support the use of transferrin saturation as an inexpensive screening test for hemochromatosis. In practice, a fasting transferrin saturation of > or = 45% identifies virtually all affected homozygous subjects without necessitating further investigation of unaffected normal individuals.

The Hemochromatosis 845 G→A and 187 C→G Mutations: Prevalence in Non-Caucasian Populations

Hemochromatosis, the inherited disorder of iron metabolism, leads, if untreated, to progressive iron overload and premature death. The hemochromatosis gene, HFE, recently has been identified, and characterization of this gene has shown that it contains two mutations that result in amino acid substitutions-cDNA nucleotides 845 G-->A (C282Y) and 187 C-->G (H63D). Although hemochromatosis is common in Caucasians, affecting >=1/300 individuals of northern European origin, it has not been recognized in other populations. The present study used PCR and restriction-enzyme digestion to analyze the frequency of the 845 G-->A and 187 C-->G mutations in HLA-typed samples from non-Caucasian populations, comprising Australian Aboriginal, Chinese, and Pacific Islanders. Results showed that the 845 G-->A mutation was present in these populations (allele frequency 0.32%), and, furthermore, it was always seen in conjunction with HLA haplotypes common in Caucasians, suggesting that 845 G-->A may have been introduced into these populations by Caucasian admixture. 187 C-->G was present at an allele frequency of 2.68% in the two populations analyzed (Australian Aboriginal and Chinese). In the Australian Aboriginal samples, 187 C-->G was found to be associated with HLA haplotypes common in Caucasians, suggesting that it was introduced by recent admixture. In the Chinese samples analyzed, 187 C-->G was present in association with a wide variety of HLA haplotypes, showing this mutation to be widespread and likely to predate the more genetically restricted 845 G-->A mutation.

Linkage disequilibrium analysis in Australian haemochromatosis patients indicates bipartite association with clinical expression

BACKGROUND/AIMS Hereditary haemochromatosis shows a wide variation in phenotypic expression, which is thought to be due, in part, to genetic factors. A single missense mutation in HFE, leading to an amino acid substitution (C282Y) has been shown to be the causative mutation, clearly responsible for clinical expression of the disorder. Since homozygosity for the C282Y mutation can give rise to a disorder which shows wide variation in clinical expression, we investigated the possibility that genetic modifiers of HFE may exist. METHODS Linkage disequilibrium analysis was performed on chromosome 6p21.3 in 74 patients homozygous for the C282Y mutation using microsatellite markers spanning the haemochromatosis gene region. Phenotypic expression was evaluated based on transferrin saturation, serum ferritin, hepatic iron concentration and index, and iron grade. RESULTS Linkage disequilibrium (LD) analysis showed a predominant ancestral haplotype from D6S265 to D6S2236 covering a region of approximately 5 Mb. The overall LD distribution in this region showed two peaks of highly significant association at D6S105 (2 Mb proximal to HFE) and at D6S2239 approximately 50 kb distal to HFE. Male patients homozygous for D6S105 allele 8, had significantly higher hepatic iron indices than patients heterozygous or nullizygous for D6S105-8 (p<0.038). CONCLUSION This analysis indicates that modifying gene(s) or another mutation affecting HHC clinical expression may be located in the region of D6S105.

A single amino acid deletion in the antigen binding site of BoLA-DRB3 is predicted to affect peptide binding.

Two bovine MHC class II alleles, BoLA-DRB3*0201 and BoLA-DRB3*3301, contain a three base pair deletion which results in the deletion of a lysine (K beta 65) in the antigen recognition site (ARS). Modelling of BoLA-DRB3*0201 with the conserved lysine K beta 65 and BoLA-DRB3*0201 without K beta 65 indicated that this deletion altered the peptide specificity of the ARS, and may impact on the immune response. To test this hypothesis, the presence of K beta 65 was analysed in a sample of cattle vaccinated with the commercial cattle tick vaccine (TickGARD). Homozygous deletion of K beta 65 was significantly associated with high response to TickGARD (P<0.05). Screening of the TickGARD antigen identified a potential T cell epitope that is recognised better by animals that are homozygous for the K beta 65 deletion. This study provides evidence that changes in the ARS of MHC class II molecules may be associated with the well recognised animal to animal variation in magnitude of vaccine response.

Hemochromatosis in Heterozygotes

Hemochromatosis, first described more than 100 years ago, is a common inherited disorder of iron metabolism in people of European descent.1 Nonetheless, it has been much underdiagnosed and misdiagn...

The spinal muscular atrophy gene region at 5q13.1 has a paralogous chromosomal region at 6p21.3

Paralogous regions are duplicated segments of chromosomal DNA that have been acquired during the evolution of the genome. Subsequent divergent evolution of the genes within paralogous regions can lead to the formation of gene families. Here, we report the identification of a region on Chromosome (Chr) 6 at 6p21.3 that is paralogous with the Spinal Muscular Atrophy (SMA) gene region on Chr 5 at 5q13.1. Partial characterization of this region identified nine sequences all of which are highly homologous to DNA sequences of the SMA gene region at 5ql3.1. These sequences include four β-glucuronidase sequences, two retrotransposon sequences, a novel cDNA, a Sequence Tagged Site (STS), and one that is homologous to exon 9 of the Neuronal Apoptosis Inhibitor Protein (NAIP) gene. The 6p21.3 paralogous SMA region may contain genes that are related to those in the SMA region at 5q13.1; however, a direct association of this region with SMA is unlikely given that no linkage of SMA with Chr 6 has been reported.

A region of primer binding variation at the D6S265 locus associated with HLA-A25 and HLA-A26 antigens

D6S265 is a polymorphic dinucleotide repeat, mapped within 70 kb centromeric of HLA-A, on chromosome 6p21.3. While genotyping families for genetic linkage analysis, allele non-amplification resulting in apparent non-Mendelian inheritance was observed at the D6S265 locus in 15 individuals, on chromosomes carrying the HLA-A25 and HLA-A26 antigens. The D6S265 locus was sequenced in a variant individual homozygous for allele non-amplification, and in a non-HLA-A25/-A26 individual, homozygous for D6S265 allele 1. Five base changes were identified in the reverse primer binding region of the variant individual, effectively preventing annealing of the 3′ primer to the template.

Isolation and Characterisation of Cosmids to Intervals Within a 4.5Mb Region at 6p21.3

The gene responsible for hereditary haemochromatosis (HH) has recently been identified. One mutation in this gene, termed HFE, has been found in all Australian HH patients. We previously identified a predominant HH ancestral haplotype covering 4.5Mb at 6p21.3, and showed that patients with two copies of this haplotype express a more severe form of the disorder. One key question to now be resolved is why haplotype related variation in phenotypic expression of HH is present if all patients tested have the same HFE mutation. A cosmid resource covering the 4.5Mb HH ancestral haplo type region was obtained. These cosmids provide the material for the completion of a transcript map of this region, and will assist the identification of candidate modifiers of HFE expression.