Background/Purpose: Growing evidence supports the role of chemical exposures as contributors to the development of Systemic lupus erythematosus (SLE)1. Several of the gene variants associated with SLE appear to be responsive to various environmental substances. We aimed to classify SLE-associated loci based on gene-chemical connection and to reveal potential exposure-based differences. We performed functional enrichment analysis, constructed polygenic risk scores (PRSs) and analyzed clinical phenotype associations.

Methods: A total of 155 genome-wide association study (GWAS) significant (p=5e-8) SLE single nucleotide variants (SNVs) were selected (based on European ancestry). Comparative Toxicogenomics Database (CTD2) was scanned for chemical exposure connection with these genes. A gene-chemical interaction analysis was performed. The top 1/3 of the genes with the highest number of gene–chemical connections were selected and denoted as total (TOT). Separately, we analyzed the number of interactions for endocrine-disrupting chemicals (EDCs)3.Scandinavian patients with SLE (n=1419), fulfilling ≥4 ACR-97 criteria, were genotyped by Illumina Global Screening Array. Clinical data was collected from charts. SLE environmental exposure weighted polygenic risk scores (PRSs) were developed including the TOT and EDC risk loci. Regression analysis compared the top quartile to the remaining individuals adjusting for sex and age. Functional enrichment was carried out using KEGG, TRRUS4 and Reactome databases.

Results: In total, 19 of top genes identified in the CTD database were included exclusively in the TOT-PRS (including IL7R and STAT4), and 17 were specific to the EDC-PRS (including ATXN2 and TYK2). The highest number of interactions was observed for IL10 (n=3169).Pathway analysis showed enrichment of Toll-like receptor signaling in both groups (p=1.0e-4), while B-cell receptor signaling (p=1.6e-3) was enriched in TOT-PRS only. Both scores were associated with higher risk of malar rash (OR 1.6, p=4.4e-8, TOT-PRS; OR 1.6, p=6.9e-8, EDC-PRS), nephritis (OR 1.7, p=8.1e-14, TOT-PRS; OR 1.6, p=9.2e-14, EDC-PRS) and serositis (OR 1.5, p=7.8e-7, TOT-PRS; OR 1.5, p=5.1e-7, EDC-PRS). No association was observed for discoid rash or arthritis (both p >0.05). Further, the PRSs showed association with thrombocytopenia (OR 1.1, p=0.02, TOT-PRS; OR 1.5, p=5.5e-3, EDC-PRS) and leukopenia/lymphopenia (OR 1.3, p=2.4e-4, TOT-PRS; OR 1.7, p=2.8e-5, EDC-PRS).

Conclusion: We demonstrated that classification of SLE loci based on gene-chemical connections can identify potential connections between selected risk genes and chemical compounds. A strong association between specific risk genes and a large number of chemical compounds suggests that these genes may be important targets when investigating the role of environmental exposures to risk for disease. Leveraging public functional gene-based information can also help to reveal exposome-associated mechanisms behind SLE clinical heterogeneity. References:1. Kosarek et al. 2024, doi:10.1007/s40572-024-00444-9.2. Davis et al. 2024, doi:10.1093/nar/gkae883.3. Liu et al. 2022, doi:10.1016/j.ecoenv.2022.113382.4. Han et al. 2017, doi:10.1093/nar/gkx1013.

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ACR Meeting Abstracts - https://acrabstracts.org/abstract/sle-genetic-risk-loci-in-the-context-of-environmental-exposure-a-gene-based-classification-and-clinical-insight/