1 Department of Genetics and Microbiology, University of Geneva Medical School, Geneva, Switzerland
2 Juvenile Diabetes Research Foundation/Wellcome Trust Diabetes and Inflammation Laboratory, Cambridge Institute for Medical Research, University of Cambridge, Cambridge, U.K
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ABSTRACT |
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Type 1 diabetes is a multifactorial disease caused by the T-cell-mediated destruction of the insulin-producing ß-cells owing to a complex, and largely unknown, interaction with the environment (1). Although the major locus has been discovered, the HLA complex on chromosome 6p21, and other loci have been associated with disease susceptibility including the insulin gene and the T-cell inhibition gene CTLA4 (2), many other genes probably contribute to the familial clustering of the disease. The candidate gene approach remains a powerful method for susceptibility gene identification, especially if the candidacy is specific. Such a strong candidacy exists for the human endogenous retrovirus (HERV)-K18 locus on human chromosome 1.
Several lines of evidence suggest the involvement of HERV-K18 in the etiology of type 1 diabetes. HERV-K18 encodes T-cell superantigen (SAg), and T-cells with HERV-K18 SAg reactive T-cell receptor Vß7 chains were found to be enriched in the pancreas, in the spleen (3,4), and in circulation (5) at disease onset. HERV-K18 mRNA expression was also enhanced in inflammatory lesions of patients with recent-onset type 1 diabetes (6). HERV-K18 transcription and SAg function in cells capable of efficient presentation are induced by proinflammatory stimuli (7,8) with established immunopathological potential, namely viruses (9) and interferon- (10). HERV-K18 SAg may thus trigger progression of disease to insulitis, or from insulitis to overt diabetes, and allelic variation of the HERV or the DNA flanking it, the CD48 gene, could modulate genetic susceptibility (7).
HERV-K18 is 9,235 bp in length and located within intron 1 of CD48 on human chromosome 1q. We previously characterized the locus and determined its haplotype diversity in the European population (7). Three main haplotypes were identified that differed in amino acid sequence at five positions within the SAg coding region (7). Two of them have or could have biochemical consequences for SAg structure and function, namely a Y/C substitution in haplotypes 1 and 3 at position 97 and a premature stop codon in haplotype 1 at position 154. The latter variant produces a soluble COOH-terminally truncated SAg protein for haplotype 1 and full-length envelope proteins requiring intracellular cleavage for haplotypes 2 and 3. The Y/C substitution in haplotypes 1 and 3 could interfere with intra- and interchain disulfide bonding that is critical for the maturation of secreted and membrane proteins. Despite these differences, the three HERV-K18 alleles all encode SAgs with an indistinguishable capacity to stimulate mature T-cells and T-cell hybrids.
To evaluate the association of HERV-K18 polymorphisms with type 1 diabetes, we undertook a large family-based association study involving 14 single nucleotide polymorphisms (SNPs) and 754 families (see RESEARCH DESIGN AND METHODS), focusing on the main haplotypes of HERV-K18 and flanking them with CD48 SNPs to delimit linkage disequilibrium.
Table 1 shows results of allelic and genotypic association analyses. Hardy-Weinberg equilibriums were observed for all SNPs. Figure 1 shows the pattern of linkage disequilibrium of the CD48 locus with three regions of high linkage disequilibrium and breaks at rs3766367 and rs352683.
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In a small pilot study involving 74 Japanese case subjects and 54 control subjects (11), no significant association was shown between HERV-K18 SNPs at nucleotide positions 6836 and 7007, and borderline association (P = 0.03) was demonstrated only in subgroup analyses. That study, however, was underpowered. It nevertheless demonstrated significant differences in haplotype frequencies between the Japanese and Caucasian populations (7).
A number of explanations can be given for our observed associations between HERV-K18 SNPs and diabetes. Given that the three associated SNPs were highly correlated with each other, Hardy-Weinberg equilibrium was observed, and the misinheritance rate was very low, associations due to technical errors (12) seem unlikely. However, it is possible that our result is a statistical false-positive, even given the functional candidacy of HERV-K18. Replication studies with other large datasets are thus warranted. If the associations are true positives, the causative variant may lie anywhere between rs3766367 and rs352683, a 30-kb region from intron 1 to exon 3 of CD48. The high degree of correlation between SNPs would make isolating the disease variant difficult (2).
The association of HERV-K18 in the context of other genes involved in type 1 diabetes will warrant further examination. HERV-K18 SAgs are exquisitely major histocompatibility complex class II dependent (7,8), and therefore, genetic epistasis between the two loci is possible. However, given the moderate genetic effect we have reported, interactions analyses between HERV-K18 and HLA and with other loci firmly established in type 1 diabetes will require much larger sample sizes to ensure statistical power. This is provided that our current primary association can be confirmed. The involvement of HERV-K18 in other autoimmune diseases also remains to be tested (2). Our PCR assay and genotyping methods, and our determination of linkage disequilibrium structure in this genomic region, will facilitate those future investigations.
The HERV-K18 locus appears to be unique among the endogenous retrovirus HERV-K family with respect to gene regulatory features that could predispose it for autoimmunity, namely its transcriptional induction by proinflammatory stimuli with immunopathological potential and its constitutive expression in the thymus (B.C. and F. Meylan, unpublished data). Both of these characteristics are not shared by other known HERV-K proviruses, and our observation that cis regulatory elements residing outside the HERV-K18 provirus in the CD48 gene are required for these responses could constitute at least in part a basis for why disease susceptibility has yet to be detected with other HERV loci.
In conclusion, our current study supports the HERV-K18/CD48 locus in the genetic etiology of type 1 diabetes. This complex region, however, will require further genetic and functional analyses to firmly establish its role in the disease.
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RESEARCH DESIGN AND METHODS |
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SNP selection and genotyping.
Five SNPs within HERV-K18 and nine SNPs in the flanking CD48 locus were genotyped. Using HERV-K18 nucleotide positions as reference, genotyped HERV-K18 SNPs were at nt6836, nt7007, nt8146, nt8594, and nt8460 (7). Their correspondence with HERV-K18 haplotypes has been described previously (7). CD48 SNPs genotyped were dbSNP rs3795324, rs3766366, rs3766367, rs3796502, rs2295615, rs3766369, rs352683, rs352684, and rs352685. The first five were telomeric to HERV-K18, and the rest were centromeric.
Genotyping was performed using Taqman MGB chemistry (Applied Biosystems, Foster City, CA) (15) on either PCR products (7) for the five HERV-K18 SNPs or genomic DNA.
Statistical analysis.
Statistical analyses were performed in Stata using Genassoc routines (available from http://www.gene.cimr.cam.ac.uk/clayton/software/stata/). For the transmission disequilibrium test and tests of genotype distortion, the "robust cluster (pedigree)" option was used to provide valid tests of association when there were more than one affected member per family. Between-marker linkage disequilibrium analyses involved the use of only parents.
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ACKNOWLEDGMENTS |
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We thank the Human Biological Data Interchange and Diabetes U.K. for the family collections.
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FOOTNOTES |
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B.C. holds stock in NovImmune, a company that develops diabetes drugs.
Address correspondence and reprint requests to B. Conrad or John A. Todd, Department of Genetics & Microbiology, CMU, 1 rue Michel Servet, University of Geneva Medical School, 1211 Geneva 4, Switzerland. E-mail: b.conrad{at}medecine.unige.ch
Received for publication October 13, 2003 and accepted in revised form November 17, 2003
HERV, human endogenous retrovirus; SAg, T-cell superantigen; SNP, single nucleotide polymorphism
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REFERENCES |
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