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. Author manuscript; available in PMC: 2014 Jan 18.
Published in final edited form as: Mov Disord. 2011 Jan 24;26(3):516–519. doi: 10.1002/mds.23459

Family-Based and Population-Based Association Studies Validate PTPRD as a Risk Factor for Restless Legs Syndrome

Qinbo Yang 1,2,3, Lin Li 2,3, Rong Yang 1,2,3, Gong-Qing Shen 2,3, Qiuyun Chen 2,3, Nancy Foldvary-Schaefer 4,3, William G Ondo 5,*, Qing Kenneth Wang 1,2,3,4,*
PMCID: PMC3895410  NIHMSID: NIHMS537722  PMID: 21264940

Abstract

Objective

We previously mapped a genetic locus for restless legs syndrome (RLS) to chromosome 9p22–24 (RLS3) and a later genome-wide association study (GWAS) implicated the PTPRD gene at the RLS3 locus as a susceptibility gene for RLS. However, from the standpoint of genetics, the GWAS association needs to be validated by independent studies. In this study, we used both family-based and population-based association studies to assess the association between PTPRD and RLS in an American Caucasian population.

Methods

We genotyped two intronic SNPs rs1975197 and rs4626664 in PTPRD in 144 family members from 15 families and a case control cohort of 189 patients and 560 controls. Direct DNA sequence analysis was used to screen coding exons and exon-intron boundaries of PTPRD for rare mutations.

Results

A family-based sibling transmission disequilibrium test showed association of RLS with SNP rs1975197 (P = 0.015), but not with rs4626664 (P = 0.622). The association with rs1975197 was significantly replicated by a population-based case control association study (allelic P = 0.0004, odds ratio 5 1.68; genotypic P = 0.0013 and 0.0003 for an additive and dominant model, respectively). One rare p.E1639D variant was identified in exon 39 in kindred RLS40005. The rare D1639 allele did not co-segregate with RLS in the family, suggesting that p.E1639D variant is not a causative mutation.

Conclusions

This represents the first independent study to validate the association between PTPRD variants and RLS. Both family-based and population-based association studies suggest that PTPRD variant rs1975197 confers risk of RLS.

Keywords: PTPRD gene, sibling transmission/disequilibrium test, restless legs syndrome, family-based association study, case-control association study


Restless legs syndrome (RLS, MIM 102300) is a common neurological disorder characterized by an urge to move the limbs and is usually accompanied by uncomfortable sensations that worsen with rest, improve with movement, and are worse in the evening or night.1 It can impair sleep and adversely affects health and quality of life. Epidemiological studies of RLS revealed a prevalence rate of 5 to 12% in Caucasian populations, which is much higher than the rate in Asian and African populations (0.1–0.6%), suggesting a possible role for racial or ethnic factors in the occurrence of RLS.2 Furthermore, RLS is as much as twice more common in females than in males.3 RLS is associated with a positive family history in 45 to 65% of patients, and twin studies showed a high concordant rate in monozygotic twins.4 Our familial aggregation analysis showed a correlation rate of 0.17 between first degree relatives and heritability of 0.60.5 All these results suggest that genetic factors play an important role in the pathogenesis of RLS.

Genome-wide linkage studies have identified six genetic loci for RLS, including RLS1 on chromosome 12q12–q21,6 RLS2 on 14q13–21,7 RLS3 on 9p24-p22,5 RLS4 on 2q33,8 RLS5 on 20p13, and RLS6 on 16p12.1.9,10 Till date, no disease-causing mutations from these loci have been reported. A recent genome-wide association study (GWAS) in a Caucasian population showed that two single nucleotide polymorphisms (SNPs), including rs1975197 and rs4626664 located within introns of the PTPRD gene, were significantly associated with RLS.11 The PTPRD gene is located within the RLS3 locus reported by our group.5 In this study, we took advantage of the 15 large families used for identifying the RLS3 locus to independently assess whether SNPs in PTPRD (ENST00000381196) are associated with RLS using a family-based sibling transmission disequilibrium test (Sib-TDT). We also evaluated the association using a population- based association study in a cohort of 189 sporadic patients and 560 controls. To the best of knowledge, this is the first study to replicate the association between variants in PTPRD gene and RLS. Furthermore, we scanned the sequences of all coding exons and boundaries between exons and introns of PTPRD gene in the 15 probands from the 15 different families to identify potential disease-causing mutations.

Subjects and Methods

Subjects

This study was approved by local institutional review boards on human subject research and written consent was obtained from the participants. All study subjects are Caucasians in the U.S. The ascertainment strategy was described in detail in our previous report.5 The diagnosis of study subjects was made by two expert neurologists (W.G.O. and N.F.S.) and followed the diagnostic criteria for RLS described in the 1995 IRLSSG and 2003 NIH reports.1,1214 The 15 large and extended RLS families were initially used for identification of the RLS3 locus on chromosome 9p24-22, and their detailed characteristics were described previously.5 The case control cohort consisted of a total of 189 RLS patients and 560 Caucasian controls. The controls were general population study subjects who were not specifically screened for the presence or absence of RLS.

Genotyping and DNA Sequencing Analyses

Genotyping of SNPs was carried out using the Taq-Man SNP genotyping assay as described by us previously.1518

All coding exons and exon-intron boundaries of the PTPRD gene were amplified from genomic DNA and sequenced as described previously.1921

Statistical Analysis

All SNP genotyping data were tested for Hardy-Weinberg equilibrium using a Chi-square test22 (http://www.oege.org/software/hwe-mr-calc.sht ml).

A sibling transmission and disequilibrium test (sib-TDT) was used to test the association between PTPRD SNPs and RLS in the 15 families.23,24 The sib-TDT was carried out for genotyping data of 15 multiplex families using the TDT/STDT program 1.1. The results from the sib-TDT were expressed as Z scores and P values that were determined by use of the two tailed normal distribution approximation.

Statistical analysis of the genotyping data from the case-control association study cohort was performed using a Pearson 2 × 2 or 2 × 3 contingency table Chi-square test for allelic association and genotypic association assuming three different inheritance models, additive, dominant or recessive, respectively (SAS version 9.0). Odds ratios (OR) and 95% confidence intervals (CI) were estimated using SAS version 9.0.

For all statistical analyses, a Bonferroni-corrected P value of 0.025 after adjustment for two SNPs (0.05/2) was considered to be significant.

Results

We designed a family-based study to test the previously reported association between SNPs rs1975197 and rs4626664 in the PTPRD gene and RLS by a population- based GWAS.11 The two SNPs were genotyped in 144 study subjects from the 15 families used for linkage analysis to identify the RLS3 locus, and a sib- TDT was used to test whether the risk allele of a SNP was preferentially transmitted to affected offspring. Our sib-TDT analysis showed that SNP rs1975197 was significantly associated with RLS (P = 0.015) (Table 1). However, SNP rs4626664 did not show association with RLS (P = 0.62) (Table 1). These results suggest that PTPRD SNP rs1975197 confers risk of RLS in a Caucasian population in the U.S.

TABLE 1.

Sib-TDT to assess association between two SNPs in PTPRD and RLS in 15 large and extended families

SNP Genomic location Gene Minor allele Z-score P
rs1975197 Chr9:8,836955 PTPRD T 2.437 0.015
rs4626664 Chr9:9,251737 PTPRD A 0.493 0.622

We also used a population-based case control cohort of 189 RLS patients (including the 15 probands from the 15 large families) and 560 general population controls to further test the association between SNP rs1975197 and RLS. Genotypic distribution of two SNPs rs1975197 and rs4626664 in cases and controls was in Hardy-Weinberg equilibrium (P = 0.308 and 0.396, respectively). Highly significant allelic association was identified between SNP rs1975197 and RLS with an odds ratio (OR) of 1.68 (P = 0.0004) (Table 2).

TABLE 2.

Analysis of allelic association of two SNPs in PTPRD with RLS in a case-control association study

MAF

SNP Minor allele OR (95% CI) Case Control P
rs1975197 T 1.68 (1.26–2.25) 0.234 0.154 0.0004
rs4626664 A 0.66 (0.46–0.95) 0.112 0.16 0.0227

OR, odds ratio; CI, confidence interval; MAF, minor allele frequency.

We analyzed genotypic association assuming an additive, dominant, or recessive inheritance model. SNP rs1975197 showed highly significant association with RLS in either an additive model (P = 0.0013) or dominant model (P = 0.0003), but not with a recessive model (P = 0.2143) (Table 3).

TABLE 3.

Analysis of genotypic association of two SNPs in PTPRD with RLS in a case-control association study

SNP Model P OR (95% CI)
rs1975197 Additive 0.0013
Recessive 0.2143 1.8247 (0.6968–4.7781)
Dominant 0.0003 1.8826 (1.3338–2.6571)
rs4626664 Additive 0.0774
Recessive 0.3263 0.5412 (0.1559–1.8785)
Dominant 0.026 0.6380 (0.4287–0.9496)

OR, odds ratio; CI, confidence interval.

The allelic association between SNP rs4626664 and RLS reached a significant level (P = 0.023), but genotypic association did not (P > 0.025 in all three different models); (Table 3).

Because SNP rs1975197 in PTPRD showed highly significant association with RLS, we hypothesized that rare disease-causing mutations may be found in RLS families, in particular in families that showed linkage to the RLS3 locus. The probands from the 15 families used for linkage analysis and family-based TDT were scanned for potential mutations in all coding exons and exon-intron boundaries of PTPRD (ENST00000381196) by direct DNA sequence analysis. We found 10 variants (Supporting Information Table 1). Five variants are located in exons and five in introns. Four of the 5 exonic variants and two of the 5 intronic variants were found in the Ensemble and Hap-Map databases. The other three intronic variants, including c.3056-111 C>G, c.3504+64delC, and c.3955-14 G>C, were not found in the HapMap database, but they were present in the general Caucasian population at a frequency of 6.1%, 13.1%, and 39.4% (minor allele, n = 312 chromosomes, Supporting Information Table 1), respectively, suggesting that the three new variants are not RLS-causing mutations.

The exonic, non-synonymous c.4917G>C variant (p.E1639D) in exon 39 was identified in only one of the 15 probands, a proband from kindred RLS40005, but not in 156 controls. We then sequenced all available DNA samples from RLS40005 and found that only 2 of 6 patients in the family, individuals 4 and 5 at the second generation, carried the rare allele (Fig. 1). The results suggest that p.E1639D variant does not cause RLS in the family.

FIG. 1.

FIG. 1

Genotyping data of PTPRD variant p.E1639D in exon 39 in RLS family RLS40005. The affected individuals are shown as filled squares (males) or circles (females). Healthy individuals are shown with empty symbols, and deceased individuals are shown with “/.” The genotyping data for the PTPRD variant (p.E1639D) in exon 39 are shown below each symbol.

Discussion

A recent GWAS in Germany by Schormair et al. identified two SNPs in the PTPRD gene, rs1975197 and rs4626664, that showed significant association with RLS.11 In the same report, they sought to replicate the finding in a combined German, Austria, Czech, and Canadian population. Both SNPs showed significant association with RLS in the combined three populations, but only nominal significance in the Canadian population and a trend (not significant) for association in the Czech population. There has not been any independent replication study for this association from an external group. Here for the first time, we used the family-based association study to determine whether SNPs rs1975197 and rs4626664 are associated with RLS in 15 large and extended multiplex families. Because these 15 families are the original families used to identify the RLS3 locus within which the PTPRD gene is located, they are particularly useful for evaluating the association between PTPRD and RLS. The results from our study share some similarities as well as differences from the GWAS. Similarly, SNP rs1975197 showed significant association with RLS by sib-TDT analysis. These results provide family-based evidence to support the association between PTPRD and RLS. However, in contrast, SNP rs4626664 was not associated with RLS in our family-based association studies. In fact, the German study showed that the association of SNP rs4626664 with RLS was stronger than rs1975197 with a higher OR (1.44 vs. 1.33) and a more significant P value (5.91 × 10−10 vs. 5.81 × 10−9).11 Based on the HapMap genotyping data (http://hapmap.ncbi.nlm.nih.gov/), rs1975197 and rs4626664 are located in different linkage disequilibrium (LD) blocks, it is possible that recombination events occurred between rs1975197 and rs4626664 in 15 multiplex U.S. families, but not in the German population, which may explain the difference between our results and those of the German study. It was reported that this region of the genome was prone to recombination for 17 haplotype boundaries between them.25 Schormair et al. also reported that there was no significant interaction between two SNPs.11

To substantiate our results from a family-based association study, we performed a population-based case control study using a U.S. cohort of 189 Caucasian RLS patients and 560 Caucasian general population controls. Interestingly, a significant Bonferroni-corrected P value was obtained for allelic association between SNP rs1975197 and RLS, but not for SNP rs4626664 (Table 3). Our results from the population-based association study reached a similar conclusion as the family-based association study. Thus, we conclude that SNP rs1975197 in the PTPRD gene confers a significant risk of RLS in the U.S. population. Despite this significant association, we did not find any RLS-causing mutation in PTPRD, suggesting that a rare variant in PTPRD is unlikely to be a cause of RLS.

In summary, the results of our study provide the first independent genetic evidence that the PTPTD gene is a risk factor for RLS. In the study, we first replicated significant association between SNP rs1975197 and RLS in a family-based study. Furthermore, population-based association studies reached the identical conclusion as the family-based association studies. Therefore our study demonstrates that SNP rs1975197 in the PTPRD gene confers a significant risk of RLS in the U.S. population.

Supplementary Material

Supplementary Table 1

Acknowledgments

Dr. N. Foldvary receives research support from Glaxo Smith Kline, Inc., and Dr. W.G. Ondo is a speaker and consultant for Glaxo Smith Kline, Inc., Allergan, Ipsen, TEVA, Lundbeck, and Novartis.

This study was supported in part by grants from the NIH (P50 HL077107) and the China Scholarship Council, a Key Program of Hubei Natural Science Funds (2008CDA047), and a Wuhan City Academic Leadership award.

We greatly appreciate all study participants for their enthusiastic support of this study. We thank Stella Baccaray, R.N. at Cleveland Clinic for her help with ascertainment of study subjects.

Footnotes

Additional Supporting Information may be found in the online version of this article.

Relevant conflicts of interest/financial disclosures: Other authors report no disclosures.

Full financial disclosures and author roles may be found in the online version of this article.

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Supplementary Materials

Supplementary Table 1

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