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POS0096 (2022)
SJÖGREN’S DISEASE AND SYSTEMIC LUPUS ERYTHEMATOSUS DDX6-CXCR5 RISK INTERVALS REVEAL COMMON SNPS WITH FUNCTIONAL SIGNIFICANCE IN IMMUNE AND SALIVARY GLAND CELLS
M. M. Wiley1, B. Khatri1, K. L. Tessneer1, M. L. Joachims1, A. M. Stolarczyk1, A. Nagel1, A. Rasmussen1, S. J. Bowman2, L. Radfar3, R. Omdal4, M. Wahren-Herlenius5,6, B. M. Warner7, T. Witte8, R. Jonsson6,9, M. Rischmueller10, P. M. Gaffney1, J. A. James11, L. Ronnblom12, R. H. Scofield11,13,14, X. Mariette15, W. F. Ng16, K. Sivils11, G. Nordmark12, B. Tsao17, C. Lessard1
1Oklahoma Medical Research Foundation, Genes and Human Disease Research Program, Oklahoma City, United States of America
2University Hospitals Birmingham NHS Foundation Trust, Rheumatology Department, Birmingham, United Kingdom
3University of Oklahoma Health Sciences Center, College of Dentistry, Oral Diagnostics and Radiology Department, Oklahoma City, United States of America
4Stavanger University Hospital, Department of Internal Medicine, Clinical Immunology Unit, Stavanger, Norway
5Karolinska Institutet, Department of Medicine, Stockholm, Sweden
6University of Bergen, Department of Clinical Science, Bergen, Norway
7National Institute of Dental and Craniofacial Research, Salivary Disorder Unit, Bethesda, United States of America
8Hannover Medical School, Department of Rheumatology and Immunology, Hannover, Germany
9Haukeland University Hospital, Department of Rheumatology, Bergen, Norway
10University of Adelaide, Discipline of Medicine, Adelaide, Australia
11Oklahoma Medical Research Foundation, Arthritis and Clinical Immunology Research Program, Oklahoma City, United States of America
12Uppsala University, Department of Medical Sciences, Uppsala, Sweden
13University of Oklahoma Health Sciences Center, Department of Medicine, Oklahoma City, United States of America
14US Department of Veterans Affairs Medical Center, US Department of Veterans Affairs Medical Center, Oklahoma City, United States of America
15Université Paris-Saclay, Assistance Publique–Hôpitaux de Paris (AP-HP), Hôpital Bicêtre, Institut National de la Santé et de la Recherche Médicale (INSERM) UMR1184, Le Kremlin Bicêtre, France
16Newcastle University, Translational and Clinical Research Institute, Newcastle Upon Tyne, United Kingdom
17Medical University of South Carolina, College of Medicine, Charleston, United States of America

Background: Sjögren’s Disease (SjD) and Systemic Lupus Erythematosus (SLE) are autoimmune diseases with several shared characteristics and similar genome-wide significant associations with the DDX6-CXCR5 locus. DDX6 suppresses interferon-stimulated gene expression and CXCR5 regulates T cell functions implicated in autoimmunity.


Objectives: To identify and characterize functional SNPs in the DDX6-CXCR5 interval.


Methods: ImmunoChip data from European populations (3785 SLE cases; 1916 SjD cases; 6893 controls) were imputed and SNP-trait associations tested. Bayesian statistics defined a credible SNP set that was refined using bioinformatic analyses (RegulomeDB, Haploreg, ENCODE, promoter capture Hi-C, eQTLs, etc.). Electrophoretic mobility shift assays (EMSAs) and luciferase expression assays were used to test allele-specific SNP function in EBV-transformed B (EBV B) cells, Daudi B cells, Jurkat T cells, THP1 monocytes, and A253 salivary gland cell lines. Chromatin conformation capture with quantitative PCR (3C-qPCR) was used to assess long-range chromatin interactions.


Results: Fine mapping of the SjD and SLE associations found similar SNP associations. Bioinformatic analyses identified 5 common SNPs with strong evidence of functionality in immune cell types: rs57494551 in an intron of DDX6, and rs4938572, rs4936443, rs7117261, and rs4938573 in the promoter/enhancer region of DDX6 and CXCR5 . EMSAs and luciferase experiments showed cell type-specific differences in protein binding and promoter or enhancer activity, respectively, at each SNP. Risk allele of rs57494551 increased enhancer activity in B cells and A253 cells (p<0.001), but decreased promoter activity in T cells and A253 cells (p<0.01). SNP rs4938572 is an eQTL of DDX6 in T cells, and the risk allele significantly increased protein binding, promoter and enhancer activity in T cells (p<0.01). Risk allele of rs4938572 also increased promoter activity in A253 cells (p<0.001), but had no effect on promoter or enhancer activity in B cells. SNP rs4936443 showed no promoter or enhancer activity in immune cells, but the risk allele showed significant promoter and enhancer (p<0.001) activity in A253 cells. SNP rs7117261 showed decreased enhancer activity in EBV B cells, T cells, and A253 cells (p<0.05) and increased promoter activity in A253 cells (p<0.001). SNP rs4938573 showed decreased promoter activity in EBV B cells, T cell and A253 cells (p<0.05), decreased promoter activity in EBV B cells (p<0.05), and increased enhancer activity in A253 cells (p<0.0001). Overall, A253 cells exhibited more allele-specific effects on promoter and enhancer activity across the five SNPs compared to tested immune cells. In addition to DDX6 and CXCR5 , rs57494551 and/or rs4938572 are reported eQTLs for several other genes of interest in the local chromatin regulatory network: IL10RA in T cells, TRAPPC4 in salivary gland and activated macrophages, and long non-coding (lnc)RNA AP002954.1 in T cells and whole blood. 3C-qPCR in EBV B and A253 cells showed that the two regulatory regions carrying rs4938572 or rs57494551 interacted with a region upstream of DDX6 that includes AP002954.1 . Hi-C data showed looping between AP002954.1 and the regulatory region carrying rs4938572 and rs57494551 in T cells.


Conclusion: SjD and SLE share similar genomic architecture across the DDX6-CXCR5 risk interval with several common SNPs showing immune and salivary gland cell type-specific allelic effects on protein binding and/or enhancer/promoter activity. Extensive bioinformatic analyses suggest that the SNPs likely work within the local chromatin regulatory network to regulate cell type-specific expression of several genes on the interval. Ongoing studies will use 3C-qPCR to assess allele-specific chromatin interactions between the SNPs and these genes in different cells types, and CRISPR to determine how the risk alleles alters expression.


Disclosure of Interests: Mandi M Wiley: None declared, Bhuwan Khatri: None declared, Kandice L Tessneer: None declared, Michelle L Joachims: None declared, Anna M Stolarczyk: None declared, Anna Nagel: None declared, Astrid Rasmussen: None declared, Simon J. Bowman Consultant of: Abbvie, Galapagos, and Novartis in 2020-2021, Lida Radfar: None declared, Roald Omdal: None declared, Marie Wahren-Herlenius: None declared, Blake M Warner: None declared, Torsten Witte: None declared, Roland Jonsson: None declared, Maureen Rischmueller: None declared, Patrick M Gaffney: None declared, Judith A. James: None declared, Lars Ronnblom: None declared, R Hal Scofield: None declared, Xavier Mariette: None declared, Wan Fai Ng: None declared, Kathy Sivils Employee of: current employee of Janssen., Gunnel Nordmark: None declared, Betty Tsao: None declared, Christopher Lessard: None declared

Citation: , volume 81, supplement 1, year 2022, page 269
Session: Pathogenesis of SLE, Sjön’s and antiphospholipid sydrome (Poster Tours)