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Linkage Analysis of Candidate Genes in Autoimmune Thyroid Disease. III. Detailed Analysis of Chromosome 14 Localizes Graves’ Disease-1 (GD-1) Close to Multinodular Goiter-1 (MNG-1)¹

Division of Endocrinology and Metabolism, Departments of Medicine and Psychiatry (D.A.G.), Mount Sinai School of Medicine, New York, New York 10029

Address all correspondence and requests for reprints to: Yaron Tomer, M.D., Division of Endocrinology and Metabolism, Box 1055, Mount Sinai Medical Center, One Gustave L. Levy Place, New York, New York 10029. E-mail: ytomer{at}smtplink.mssm.edu

	Abstract

Top Abstract Introduction Subjects and Methods Results Discussion References

 
The autoimmune thyroid diseases [Graves’ and Hashimoto’s diseases (GD and HT)] develop in genetically susceptible individuals, but the genes responsible for this susceptibility remain unknown. To identify such genes, we have been testing candidate genes and chromosomal regions using highly polymorphic microsatellite markers. We recently reported evidence for the first locus linked to GD (GD-1) on chromosome 14q31 in a small group of families. We have now extended these studies and analyzed 53 multiplex families with GD and/or HT (323 individuals). Chromosome 14 was screened using 16 microsatellite markers spanning the entire chromosome. Three additional markers located inside candidate genes on chromosome 14 were also studied. Microsatellite markers were amplified using fluorescent-labeled primers and separated on an ABI-310 genetic analyzer. The data were analyzed using LIPED software for two-point logarithm of odds (LOD) score analysis and GeneHunter software for multipoint linkage analysis. No linkage of any marker was found to HT or autoimmune thyroid diseases (GD+HT). The previously identified GD-1 locus on 14q31 continued to show evidence of linkage to GD in this much larger set of families. The maximum LOD score was 2.1 obtained for marker D14S81 ( = 0.01), assuming a recessive mode of inheritance and a penetrance of 0.3. Multipoint analysis yielded a maximum LOD score of 2.5 between markers D14S81 and D14S1054. There was no evidence for heterogeneity in our sample. These data again suggest the presence of a major Graves’ disease susceptibility gene (GD-1) on chromosome 14q31. This locus is close to the recently identified multinodular goiter-1 locus.

	Introduction

Top Abstract Introduction Subjects and Methods Results Discussion References

 
GRAVES’ disease (GD) and Hashimoto’s thyroiditis (HT) are autoimmune thyroid diseases (AITD). In GD, T lymphocytes are present that are specific for thyroid antigens. Consequently, the thyroid is infiltrated by immune effector cells, and B lymphocytes are activated to produce antibodies that stimulate the TSH receptor (TSHR), causing excess production and secretion of thyroid hormones (1). As a result, patients with Graves’ disease develop hyperthyroidism and a diffuse goiter (1). Similarly, HT is also associated with T lymphocytes sensitized to thyroid antigens. However, the end result in the patients is destruction of the thyroid gland by the immune effector cells manifested clinically by hypothyroidism (2). The etiology of the AITDs is believed to involve a complex interaction between susceptibility genes (3, 4) and environmental insults [e.g. infection (5)].

Although the genetic susceptibility to AITD has been studied extensively, the genes causing AITD have not been identified. Several candidate genes have been examined in the past. These have included the human leukocyte antigen (HLA) genes, Ig heavy chain genes (IgH), T cell receptor genes, the CTLA-4 gene, the thyroid peroxidase gene, and the TSHR gene (reviewed in Refs. 3, 4). Of these, only the HLA (6, 7) and CTLA-4 (8, 9) genes have shown positive associations with AITD. In particular, the HLA associations with AITD have received much attention. GD has been reported to be associated with HLA-DR3 (7) and HLA-DQA1¹0501 (10, 11) in Caucasians, and HT has been associated with HLA-DR5 (12, 13), HLA-DR3 (14), and HLA-DQw7 (DQB1¹0301) (15). Similarly, associations have been reported between AITD (GD and HT) and the 106 allele of a microsatellite inside the CTLA-4 gene, giving a relative risk of 2.0–2.8 (8, 9, 16). However, we have found that both the HLA and the CTLA-4 loci were not linked with either GD or HT (17, 18, 19, 20). Thus, the HLA and CTLA-4 genes confer a modulating effect on the development of AITD, but as neither is linked, they must be of minor significance in the overall genetic susceptibility to AITD. The major necessary genes (21) contributing to the development of AITD remain to be identified.

To map the major necessary genes (21) for the development of AITD we have recently screened several candidate genes and candidate genetic regions for linkage with AITD. Our strategy was to test genes involved in immunoregulatory pathways and genes encoding for the major thyroid autoantigens. In addition, genes linked to sex hormone functions were also tested, as the AITDs are 5–10 times more common in females (22). We have rejected linkage of AITD to several immunoregulatory genes in addition to the HLA region (23) and the CTLA-4 gene (20, 23), including the IgH gene and T cell receptor and ß genes (20). No linkage was found between AITD and several other candidate genes tested, including the thyroglobulin gene, the thyroid peroxidase gene (23), the estrogen receptor and ß genes, and the aromatase gene (24). However, in a preliminary screen of the TSHR region on chromosome 14q31 using 19 AITD families (8 with GD) we found evidence for linkage between a locus in the region (GD-1) and GD (23). This locus was not linked with HT or AITD as a whole (i.e. GD+HT) (23). We now report a full screening of chromosome 14 and fine mapping of the GD-1 locus using densely spaced microsatellite markers and a larger dataset of 53 families. Our results support our previous preliminary data, and we have mapped the GD-1 locus to the same region as the recently reported multinodular goiter-1 (MNG-1) locus (25). The presence of thyroid follicular hyperplasia in both GD and MNG (1) raises the possibility that GD-1 and MNG-1 may constitute a thyroid disease gene grouping.

	Subjects and Methods

Top Abstract Introduction Subjects and Methods Results Discussion References

 
Family recruitment

GD was diagnosed using the following criteria: 1) documented clinical and biochemical hyperthyroidism requiring treatment, 2) a diffuse goiter, and 3) the presence of TSHR antibodies and/or diffuse uptake on ¹³¹I thyroid scan. HT was diagnosed by 1) documented clinical and biochemical hypothyroidism requiring thyroid hormone replacement, and 2) the presence of autoantibodies to thyroid peroxidase and thyroglobulin. Fifty-three families (323 individuals) were used in the current study (32 families with GD). All families were multiplex (>1 affected subject) and multigenerational. Families were ascertained through an index case with AITD who confirmed having at least 1 other first degree relative with AITD. Although as many relatives as possible were recruited from each family, the minimum requirement for participation in the study (nuclear family) was a family consisting of 4 first degree relatives (including the index case) from 2 generations. On the average, our families had 6.1 members. Each participant was interviewed, examined, and signed a consent, and all the pertinent clinical and laboratory data were recorded and stored in our database. At the same time blood was collected for DNA purification as well as for thyroid function and antibody testing. DNA was purified using the PureGene kit (Gentra Systems, Minneapolis, MN) according to the manufacturer’s instructions (26).

Microsatellite screening of chromosome 14

For the chromosome 14 screen, microsatellites were selected using the Genethon linkage maps (27) and were analyzed according to the method of Weber (28). Oligonucleotides for amplification of the microsatellites were designed according to published sequences in the Genome Database (http://gdbwww.gdb.org/). Fluorescent-labeled primers were purchased from PE Applied Biosystems (Foster City, CA). PCRs were performed as previously described (20). Two microliters of the pooled PCR products were mixed with 0.5 µL internal size standard and 10 µL deionized formamide, denatured, and separated using an ABI 310 genetic analyzer (PE Applied Biosystems). Allele calling was performed using the Genotyper 2.0 software (PE Applied Biosystems). The results were then automatically exported to our database (Ingres database) for linkage analysis. This eliminated possible errors in copying results by inputting them manually.

Analysis of candidate genes on chromosome 14

Chromosome 14 contains at least six candidate genes for thyroid autoimmunity: 1) TSHR gene, 2) IgH gene, 3) T cell receptor gene, 4) MNG-1 gene, 5) insulin-dependent diabetes mellitus-11 (IDDM-11) gene, and 6) estrogen receptor ß (ESRß) gene. Three of these candidate genes (IgH, T cell receptor , and ESRß) have been previously analyzed and have not been found to be linked with GD, HT, or AITD (GD+HT) (20, 24). The TSHR gene MNG-1 and IDDM-11 loci were studied individually. Microsatellite markers were selected inside these genes/loci, and they were amplified and analyzed as described above.

Linkage analysis

This was performed using parametric methods of likelihood-maximization [classical logarithm of odds (LOD) score analysis]. Two-point LOD scores for the different markers studied were computed using LIPED software (29), and multipoint LOD scores were calculated using the GeneHunter program (30). Two-point LOD scores were computed for dominant and recessive models and for a range of penetrances (0.2–0.9). For the 16 markers used to screen chromosome 14, linkage analysis was performed for recombination fractions of 0.01 and 0.05 (as the average distance between the markers was <10 cM). For the 3 candidate genes tested by markers inside these genes, linkage was analyzed at a recombination fraction of 0.01. In the largest epidemiological survey of thyroid diseases, the prevalence of AITD was estimated to be 1% (31, 32). We, therefore, assumed that the disease prevalence was 0.01, and adjusted the gene frequency according to the model (dominant or recessive) and penetrance used, assuming Hardy-Weinberg equilibrium. Multipoint LOD scores were computed for the whole chromosome 14 using 19 markers (including the 3 candidate genes markers; see Results). For the multipoint analysis we assumed recessive inheritance and 0.3 penetrance based on the model giving the maximum LOD score in the 2-point LOD score analysis (see Results).

Models

The AITDs include GD and HT. At present it is not clear whether these are two distinct disorders with different etiologies, or whether common etiological factors are involved in the pathogenesis of these disorders. Indeed, both disorders can occur in the same family, and in our dataset 34% of the families included first degree relatives with GD and HT. Therefore, we have analyzed the data using three models: 1) all AITD patients were considered as affected; 2) only GD patients were considered as affected (under this model, HT patients were considered unaffected even if they had relatives with GD); and 3) only HT patients were considered as affected (under this model, GD patients were considered unaffected even if they had relatives with HT). Family members with thyroid autoantibodies alone were classified as unaffected. In addition, we tested the dataset for heterogeneity. Heterogeneity testing was also performed using the GeneHunter program (30), as were extended haplotypes for recombinant mapping. Each extended haplotype generated by GeneHunter was verified manually.

	Results

Top Abstract Introduction Subjects and Methods Results Discussion References

 
Characteristics of the study sample

Table 1 shows some of the clinical characteristics of the 53 families studied: 14 (26%) had GD affected members only, 21 (40%) had HT affected members only, and 18 (34%) were mixed with GD and HT affected first degree relatives. Of the 138 affected individuals, 121 (87.7%) were females, and the affected female/male (F:M) ratio (7.1:1) was comparable to that reported previously (33). Of the clinically and biochemically unaffected family members, 35% had thyroid antibodies similar to the incidence reported in previous studies (34, 35). Interestingly, the F:M ratio in the thyroid antibody-positive unaffected individuals was 1:1, i.e. much lower than the F:M ratio in the affected family members, suggesting different pathogenic mechanisms for the development of the AITDs and the propensity to secrete thyroid autoantibodies.

Simulation studies were performed to assess the power of our 53 families to detect linkage and to assess the maximum attainable LOD scores for our dataset. We assumed a penetrance of 30% for our simulations based on the reported 30% concordance rate in monozygotic twins (36). The simulation software used for the power calculations (37) generated 53 families that were homologous to the families in our study. The simulations demonstrated that using a dataset of 53 families we had the statistical power to reject linkage (i.e. LOD score <-2) out to 10 cM ( = 0.1) at a penetrance of 0.3. Thus, our families were sufficient to reject linkage for the tested markers. Simulations also showed that we had the power to detect linkage at a penetrance of 0.3 using the 53 families. The maximum LOD scores were more than 4.0 for data generated with a marker at 0.01 recombination fraction from the disease gene and more than 2.8 for a marker at 0.05 recombination fraction from the disease gene. The theoretical maximum attainable LOD score in our dataset assuming the recessive model and a recombination fraction of 0.01 was 6.7.

Screening chromosome 14

Analysis of microsatellite markers on chromosome 14 showed no linkage with either HT or AITD as a whole (data not shown). However, when considering GD as affected, positive LOD scores were obtained on chromosome 14q31 (Fig. 1A). The maximum two-point LOD score was 2.1 for marker D14S81, obtained for the recessive model, at a penetrance of 30% and a recombination fraction of 0.01 (Fig. 1B). Moreover, the LOD scores of other markers in the local region of D14S81 were positive in a geographically logical sequence (Fig. 1A).

View larger version (28K): [in this window] [in a new window]   Figure 1. A, Maximum two-point LOD score results for markers on chromosome 14 assuming GD as affected. Nineteen markers were used to scan chromosome 14, which has an estimated length of 129 cM. The highest LOD score was obtained for marker D14S81 (MLS = 2.1), and the LOD scores of other markers in the region were positive in a geographically logical sequence. B, LOD scores for marker D14S81 using the recessive model at five penetrances (0.2, 0.3, 0.5, 0.8, and 0.9) and different recombination fractions. The maximum LOD score was 2.1, obtained at a recombination fraction () of 0.01 and a penetrance of 0.3.

For the multipoint analysis, we generated a genetic map for chromosome 14, with sex-averaged distances between markers (in recombination fraction units) as follows: D14S261 - 0.07 - D14S283-0.12-D14S80-0.13 - D14S70 - 0.06 - D14S288 - 0.08 - D14S276-0.12-D14S63-0.07-D14S258 - 0.11 - D14S74 - 0.05 - TSHR - 0.04 - D14S68 - 0.005 - D14S67 (IDDM-11) - 0.095 - D14S280 - 0.03 - D14S973 - 0.01 - D14S81 - 0.05 - D14S1054 (MNG-1) - 0.04 - D14S65 - 0.08 - D14S78 - 0.09 - D14S292. These order and recombination fractions were obtained from the Genethon maps (27) and were verified on our dataset. Multipoint linkage analysis localized the GD-1 susceptibility locus on chromosome 14 to within an approximate interval of 3 cM between markers D14S81 and D14S1054 (MNG-1). The multipoint LOD scores throughout this interval were more than 2.2, with a maximum multipoint LOD score of 2.5 obtained 2 cM telomeric to D14S81 (Fig. 2). This represents significant evidence for linkage (38, 39). Further testing showed a lack of heterogeneity in the linked region ( = 0.99; maximum heterogeneity LOD score = 2.5). The GeneHunter nonparametric LOD score at the linked region was 1.9, further supporting the evidence for linkage in this region. Examination of individual families showed that only 3 of 32 GD families had negative LOD scores for marker D14S81, contributing a LOD score of -0.61 to the total LOD score. These results also indicated that significant heterogeneity was very unlikely at this marker locus.

View larger version (24K): [in this window] [in a new window]   Figure 2. Multipoint LOD score analysis for the region 14q31. The multipoint linkage analysis localized the GD-1 locus to within an approximate interval of 3 cM between markers D14S81 and D14S1054. The multipoint LOD scores throughout this interval were more than 2.2, with a maximum multipoint LOD score of 2.5.

Our Graves’ families consisted of some with GD only and some with both GD and HT phenotypes (mixed families). To examine whether the genetic influence of GD-1 was different in the group of Graves’ families in which some family members had HT, we tested them separately. In this analysis the HT individuals in the mixed families were classified as unaffected. Subgrouping the GD families into those in which HT did and did not appear demonstrated that the LOD scores for marker D14S81, which gave the highest two-point LOD score, were positive in both subsets of families, contributing approximately equally to the total LOD score (Table 2). This suggested that the contribution of GD-1 to the susceptibility to GD was similar in all families with GD that we examined, whether they included only GD-affected members or GD- and HT-affected members. Subgrouping of our Hashimoto’s families into HT-only families and families with both GD and HT (mixed families) did not change the negative linkage results obtained for HT (in this analysis the GD patients in the mixed families were classified as unaffected). In both groups of families the LOD scores were negative for all markers on chromosome 14 (data not shown).

The GD families were also subgrouped by their country of origin. The LOD scores obtained for marker D14S81 after subgrouping the GD families demonstrated that both the North American families and the European families contributed approximately equally to the total LOD score (Table 2). This suggested that the contribution of GD-1 to the susceptibility to GD was similar in the North American and European families with GD that we examined and provided further evidence for a lack of heterogeneity in our population.

Recombinant mapping of GD-1

An interval of 22 cM surrounding the GD-1 locus was analyzed by recombinant mapping in all families. Critical meiotic recombination events between markers D14S81 and D14S1054 were detected in two individuals (31-203, 31-304) in one large informative family (Fig. 3). These data provided support for the localization of the GD-1 locus telomeric to D14S81 and centromeric to D14S1054, as suggested by the multipoint analysis. Interestingly, the D14S1054 marker was linked to MNG according to a recent study in one large family (MNG-1) (25).

View larger version (25K): [in this window] [in a new window]   Figure 3. Pedigree of family 31 over four generations. Filled circles and filled squares represent GD affected females and males, respectively. The question marks denote individuals not available for testing. The extended haplotype of each individual is shown below each individual. The haplotype that cosegregated with GD is shown inside the solid-line boxes, and recombinants are shown inside the broken-line boxes. The order of the markers is indicated in the inset at the lower right corner. Critical meiotic recombinations occurred between D14S81 and D14S1054 in individuals 31-203 and 31-304.

The three candidate genes on chromosome 14 (TSHR, MNG-1, and IDDM-11) were analyzed using specific markers located inside these loci. For all of these candidate genes we were able to reject linkage to HT and AITD (GD+HT; Table 3). When considering GD as affected, linkage could not be strictly rejected, but there was no evidence for linkage for any of the candidate genes except for MNG-1. The maximum two-point LOD score for the MNG-1 locus, when considering GD as affected, was 1.65 at a recombination fraction of 0.01. Indeed, the multipoint analysis of chromosome 14 localized GD-1 to within 2 cM centromeric of the MNG-1 locus (Fig. 2). This raised the possibility that MNG-1 and GD-1 constituted the same locus.

	Discussion

Top Abstract Introduction Subjects and Methods Results Discussion References

In our previous analysis of 8 GD families, a 2-point LOD score of 2.1 was obtained using a dominant model at 80% penetrance, whereas the recessive model gave a low positive LOD score of 0.4 (23). With our larger dataset, which included 32 GD families, the maximum LOD score of 2.1 was obtained for the recessive model at 30% penetrance, whereas the dominant model gave a maximum LOD score of 0.73. This suggested that the recessive model better approximated the true genetic inheritance of GD-1 (37). Our preliminary analysis probably reflected the effects of a small sample size.

There are several factors that may reduce LOD scores when true linkage exists. These include heterogeneity in the dataset, too small a sample size, and the presence of other contributing genes or epistatic genes. Our analysis of the individual families as well as a computer analysis (using the GeneHunter algorithm for heterogeneity testing) showed that heterogeneity, if it existed in our dataset, was minimal. The power calculations demonstrated that our dataset was large enough to detect linkage with a LOD score of more than 2.8 if only one gene contributed to disease susceptibility. Therefore, other epistatic genes must exist, and the effect of GD-1 alone on the genetic susceptibility to GD is only moderate. Indeed, the reduced penetrance (30%) suggests that several genes of varying effects are involved in the pathogenesis of GD. When more loci for Graves’ disease are identified, this hypothesis could be tested by performing a linkage analysis for several loci together. However, because complex multifactorial diseases appear to be caused by more than one gene of varying effects (i.e. oligogenic diseases), the identification of susceptibility genes for these diseases has been difficult (42). For example, in IDDM at least four loci have been confirmed for linkage with the disease (41, 43), but only two of them (HLA and insulin-variable number tandem repeat genes) have been identified (44, 45).

As in all complex and common diseases, the genetic susceptibility to AITD lacks a simple Mendelian pattern of inheritance and probably involves several genes with varying penetrances and interactions. This makes the identification of susceptibility genes for complex diseases very difficult. One possible solution is to test for linkage using different models. We tested our markers for linkage with AITD using two models, dominant and recessive. In addition, we decided a priori to subgroup the AITDs based on clinical criteria into HT and GD, and test each of these independently and as a whole. Although these multiple analyses enabled us to maximize the LOD score with respect to the model and phenotype of the disease, they may have weakened the evidence for linkage because of multiple testing. It was recently suggested that in cases when dominant and recessive models are used, the maximum LOD score obtained should be reduced by 0.3 (46). In our case this would result in a maximum LOD score of 2.2, still giving strong evidence in favor of linkage (38). Thus, analyzing for two genetic models did not significantly change the strength of our linkage results and enabled us to find the model that best approximated the inheritance of GD-1.

In addition to screening chromosome 14, we tested six specific candidate genes on this chromosome [three of them, IgH, TCR, and ESRß, were previously reported (20, 24)]. Candidate genes are genes of known sequence and location that could be involved in disease pathogenesis by virtue of their involvement in pathways associated with the pathological manifestations of the disease. Linkage tests using candidate genes offer a rapid way to test the hypothesis that these particular genes are major contributors to the disease. The candidate gene approach has already been used successfully in maturity-onset diabetes of the young (47, 48). Potential candidate genes for autoimmune thyroid diseases include 1) genes participating in immune regulatory pathways, 2) genes controlling the expression of the thyroid autoantigens, 3) genes involved in sex hormone function (in view of the female preponderance of AITD) (22), and 4) IDDM genes (in view of the association between IDDM and AITD) (49). The six chromosome 14 candidate genes tested in this and our previous studies belong to all of these categories. None of the candidate genes studied, except MNG-1, demonstrated evidence of linkage to GD, HT, or AITD as a whole (20, 24). Of note is the evidence against linkage of Graves’ disease with the TSHR gene. Previous work has shown a weak association between the TSHR gene and GD (50), but other studies could not confirm these results (51). Indeed, we and others were unable to demonstrate TSHR mutations in thyroid tissues from GD patients (52, 53). However, a gene close to the TSHR locus could theoretically confer susceptibility to GD by influencing the expression of the TSHR gene. Our results showing no evidence for linkage between GD and the TSHR gene made such a possibility highly unlikely and confirmed the results of a previous linkage study (54).

In conclusion, we confirmed evidence for a new GD susceptibility gene (GD-1) on chromosome 14q31. GD-1 was mapped to within 2 cM of the recently reported MNG-1 locus (25), which has been linked to MNG. In both GD and MNG, the thyroid gland may show follicular hyperplasia, and MNG is often associated with AITD (1). This raises the possibility that GD-1 and MNG-1 may represent a thyroid disease gene grouping. A newly isolated growth factor, SEL1L, was recently mapped to 14q31 (55), and this would be an interesting candidate to examine in both GD and MNG.

	Acknowledgments

 
We thank all the AITD families who graciously agreed to participate in the study.

	Footnotes

 
¹ This work was supported in part by NIDDK Grants DK-35764, DK-45011, and DK-52464 (to T.F.D.); NIDDK Grant DK-02498 (to Y.T.); Grants DK-31775, NS-27941, and MH-48858 (to D.A.G.); the David Owen Segal Endowment; and the Consorzio Pisa Ricerche, University of Pisa (to G.B.).

² Additional members of the International Consortium for the Genetics of Autoimmune Thyroid Disease include Drs. Meir Berezin (Tel-Hashomer, Israel), Rhoda Cobin (New York, NY), Luca Chiovato and Aldo Pinchera (Pisa, Italy), Sandra McLachlan (Los Angeles, CA), Bernard Rees Smith (Cardiff, UK), and Fred Clark and Eric Young (Newcastle upon Tyne, UK).

Received June 30, 1998.

Revised August 10, 1998.

Accepted August 18, 1998.

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