Abstract
Objective. To evaluate the genetic background of systemic sclerosis (SSc) in the Turkish population.
Methods. There were 354 cases and 718 unaffected controls from Turkey genotyped for the most relevant SSc genetic markers (IRF5-rs10488631, STAT4-rs3821236, CD247-rs2056626, DNASE1L3-rs35677470, IL12A-rs77583790, and ATG5-rs9373839). Association tests were conducted to identify possible associations.
Results. Except for ATG5, all the analyzed genes showed either significant associations (IRF5: p = 1.32E–05, OR 1.76; CD247: p = 2.20E–03, OR 0.75) or trends of association (STAT4: p = 0.066, OR 1.21; IL12A: p = 0.079, OR 4.07; DNASE1L3: p = 0.097, OR 1.41) with the overall disease or with specific phenotypes.
Conclusion. The genetic component of SSc seems to be similar between Turks and Europeans.
- SYSTEMIC SCLEROSIS
- GENETICS
- TURKEY
Large-scale genetic analyses have represented a substantial step forward toward the understanding of the etiology of autoimmune processes1. One of the autoimmune diseases that has benefitted the most from this type of study is systemic sclerosis (SSc), a complex polygenic condition characterized by extensive fibrosis of the skin and internal organs, vascular damage, and presence of autoantibodies against nuclear antigens2. To date, around 20 genetic loci are firmly associated with SSc susceptibility3. However, most genetic studies on this disease have been performed in European populations, and additional studies in other ancestries are required to continue unraveling its genetic component. A clear example of a population for which no solid data regarding SSc genetics are available is the Turkish population. Although Turks show a genetic relatedness with Europeans, Middle Easterners, and South/Central Asians, it has been reported that their genetic structure is unique4.
Considering the above, we decided to evaluate for the first time the population-specific relationship between the most relevant SSc risk genes outside the HLA region described in the 2 most powered large-scale studies [a genome-wide association study (GWAS) and an Immunochip study in Europeans]5,6 and disease predisposition in Turks. These include IRF5, STAT4 (both crucial in the Type I interferon pathway), CD247 (encoding the ζ chain of the T cell receptor), DNASE1L3 (involved in DNA fragmentation during apoptosis), IL12A (encoding a subunit of the interleukin 12 that regulates different T cell responses), and ATG5 (involved in autophagy processes)7.
MATERIALS AND METHODS
Study population
In total, 354 patients with clinically defined SSc, i.e., diagnosed as having limited cutaneous SSc (lcSSc) or diffuse cutaneous SSc (dcSSc) according to LeRoy, et al8, and 718 healthy individuals were included in our study. Both cases and controls were from Istanbul, Turkey. However, analysis of ancestry-informative markers was not performed, and therefore a population stratification could not be ruled out, which represents a limitation of our study. Informed written consent from all participants and approval from the responsible committee on human experimentation of all centers (Gaziantep Medical Faculty and Istanbul Bilim University) were obtained. All patients with SSc fulfilled the 2013 American College of Rheumatology/European League Against Rheumatism classification criteria for this disease9,10.
The case set was further subdivided according to the degree of skin involvement into lcSSc and dcSSc, as well as according to the presence/absence of other relevant clinical manifestations such as anticentromere antibodies (ACA), antitopoisomerase antibodies (ATA), interstitial lung disease (ILD), and digital ulcers (DU). ACA were determined by their characteristic distinctive pattern on human epithelial cell line 2 cells, and ATA were detected using a line immunoassay (EUROLINE ANA Profile 3, Euroimmun) according to the manufacturer’s protocol. ILD was diagnosed by high-resolution computed tomography (HRCT) and pulmonary function test (PFT) in all cases (forced vital capacity and/or diffusion capacity of the lung of < 75% of predicted was used as the cutoff value to define presence of ILD). Both methods were performed routinely in the first year, with a subsequent control by PFT and yearly chest radiograph (if abnormal PFT was detected during the followup, patients were then subjected to yearly HRCT). DU was defined as a loss of both epidermis and dermis in an area of at least 2 mm in diameter on the distal phalanx of the fingers. Table 1 shows the prevalence of each clinical feature in our study cohort.
Single-nucleotide polymorphism (SNP) selection criteria and genotype methods
We followed a candidate gene strategy by selecting the lead signals of the most associated non-HLA genes in Europeans described in both the GWAS by Radstake, et al5 (IRF5-rs10488631, STAT4-rs3821236, and CD247-rs2056626) and the Immunochip study by Mayes, et al6 (DNASE1L3-rs35677470, IL12A-rs77583790, and ATG5-rs9373839). The overall statistical power of our study for each analyzed marker is shown in Table 2.
DNA was extracted from peripheral white blood cells following standard procedures. The genotyping of the whole SSc sample set and part of the control group (219 samples) was performed using predesigned TaqMan assays in an ABI 7900HT (Applied Biosystems), whereas the remaining control data (499 samples) were obtained from a previously published Immunochip study11 to increase the statistical power of our analyses.
Statistical analyses
Data analysis was performed using PLINK, v 1.07 (pngu.mgh.harvard.edu/purcell/plink)12. Association tests were conducted by performing 2 × 2 contingency tables, chi-square, and/or Fisher’s exact tests when appropriate to obtain p values, OR, and 95% CI. The statistical threshold was set at 0.05. Benjamini and Hochberg step-up false discovery rate (FDR) control correction for multiple testing13 was applied to the p values in the case/control analyses.
RESULTS
No significant deviation from the Hardy-Weinberg equilibrium (p < 0.05) was observed for any of the analyzed SNP. In an initial approach, we compared the SSc group against controls to test for possible associations with the overall disease. Statistically significant differences between the allele frequencies of the global SSc group and the control set were observed for IRF5-rs10488631 (p = 1.32E–05, OR 1.76, 95% CI 1.36–2.28) and CD247-rs2056626 (p = 2.20E–03, OR 0.75, 95% CI 0.62–0.90). These association signals remained significant after adjusting for multiple testing (IRF5-rs10488631: pFDR = 7.90E–05; CD247-rs2056626: pFDR = 6.58E–03). Suggestive p values were also detected for STAT4-rs3821236 (p = 0.066, OR 1.21, 95% CI 0.99–1.48), DNASE1L3-rs35677470 (p = 0.097, OR 1.41, 95% CI 0.94–2.12), and IL12A-rs77583790 (p = 0.079, OR 4.07, 95% CI 0.74–22.30; Table 3).
When the different SSc case subsets were compared against the control population, statistical significance was reached in the analysis of most phenotypes for IRF5-rs10488631 and CD247-rs2056626 (Table 3). Additionally, evidence of association was observed for STAT4-rs3821236 (lcSSc vs controls: p = 0.041, OR 1.30, 95% CI 1.01–1.67; DU+ vs controls: p = 0.038, OR 1.30, 95% CI 1.01–1.68) and IL12A-rs77583790 (lcSSc vs controls: p = 0.032, OR 5.68, 95% CI 0.95–34.09; Table 3).
A case-case analysis between the SSc subjects with and without the different clinical features was then conducted to dissect those putative associations. Interestingly, phenotype-specific associations were either observed or suggested for some polymorphisms. That is, IRF5-rs10488631 was significantly associated with the presence of ATA (ATA+ SSc vs ATA− SSc: p = 0.031, OR 1.54, 95% CI 1.04–2.28), and CD247-rs2056626 showed evidence of association with the diffuse form of the disease (dcSSc vs lcSSc: p = 0.065, OR 0.75, 95% CI 0.55–1.02). On the other hand, STAT4-rs3821236 and IL12A-rs77583790 lost their suggestive associations with specific phenotypes in this analysis (data not shown).
DISCUSSION
To our knowledge, our study represents the first evaluation of established SSc risk polymorphisms in the Turkish population. Except for ATG5, we found evidence of association either with the overall disease or with a particular phenotype for all the investigated genes. The lower statistical significance observed in our Turkish cohort was most likely due to a considerably reduced statistical power in comparison with the studies performed in Europeans. Indeed, the allele frequencies and the effect sizes on disease susceptibility of the analyzed SNP were consistent with those described for the European population in all analyzed variants, with only the exception of ATG5, in which the minor allele frequencies (MAF) in Turks (MAF case/control = 0.113/0.107) were half the ones reported for Europeans (MAF case/control = 0.241/0.185)5,6. However, it should be noted that ATG5 represents the SSc marker with a lower effect on the susceptibility (reported OR for Europeans = 1.19) among those included in our study6. In addition, the OR observed in the Turkish cohort had the same direction toward risk (1.06). Therefore, a larger case series would be needed to definitively discard a possible influence of this gene in SSc risk in Turkey.
On the other hand, our data are also in agreement with the reported phenotype-specific associations of the Immunochip study6 because IL12A-rs77583790 and DNASE1L3-rs35677470 showed trends of association with lcSSc and ACA positivity, respectively, when the case subgroups were compared against the control population. The loss of these tendencies after comparing cases with and without the corresponding features was probably a consequence of insufficient power in the stratified analyses. Indeed, DNASE1L3-rs35677470 is a low-frequency variant (MAF < 5%) and IL12A-rs77583790 can be considered a rare variant (MAF < 1%)6.
Altogether, our results suggest that the genetic background of SSc in Turks is similar to that in Europeans. Confirmation of identified associations in other populations than those of European ancestry (with different genetic structures) is not only necessary to validate initial findings, but also to have a broader overview of the genetic basis of human disease14. In this context, considering that the causal variants of most SSc associations and their specific relationship with the clinical outcomes remain unknown7, studies such as the one reported here may be useful in the challenging endeavor of identifying reliable diagnostic and prognostic markers for a better management of this severe condition.
Acknowledgment
The authors thank Sofia Vargas and Sonia García for their excellent technical assistance and all the patients and control donors for their essential collaboration.
Footnotes
Supported by SAF2012-34435 from the Spanish Ministry of Economy and Competitiveness, BIO-1395 from Junta de Andalucía, and RD12/0009/0004 from the RETICS (Networks for Cooperative Research in Health) Program of Instituto de Salud Carlos III. FDC was supported by the “Ramón y Cajal” program of the Spanish Ministry of Economy and Competitiveness.
- Accepted for publication March 31, 2016.
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