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Integrated machine learning framework identifies EPSTI1 as a key diagnostic biomarker for Sjögren's disease: multi-cohort transcriptomic validation and single-cell characterization.

Created on 10 Jul 2026

Authors

Jianbin Li, Renhe Li, Wenwen Wang, Yuzhen Gesang, Wei Liu

Published in

Clinical rheumatology. Jul 10, 2026. Epub Jul 10, 2026.

Abstract

This study aimed to develop a robust transcriptomic diagnostic signature for Sjögren's disease (SjD; formerly Sjögren's syndrome) and elucidate key biomarker functions by integrating machine learning and single-cell analysis.
Three SjD peripheral blood datasets (GSE143153, GSE51092, GSE66795; n = 414) were integrated for training, with GSE84844 and GSE40611 for external validation. Candidate biomarkers were identified through differential expression analysis and WGCNA. A total of 113 machine learning algorithm combinations were evaluated. The top biomarker was characterized through SHAP interpretability analysis, immune infiltration profiling, pathway enrichment, genetic colocalization, ceRNA network construction, and RT-qPCR validation. Single-cell RNA sequencing, CellChat, and virtual gene knockout analyses were performed to investigate cell-type expression and regulatory networks.
Eighty-six core candidate genes were identified. The optimal model (plsRglm + rf) selected 14 diagnostic genes, achieving AUC values of 0.896 (training), 0.871 (GSE84844), and 0.874 (GSE40611). EPSTI1 showed the highest single-gene performance (AUC = 0.844) and significant correlations with IgG (R = 0.64, P = 0.00012) and ANA (R = 0.49, P = 0.0066). SHAP analysis ranked EPSTI1 as the top feature. RT-qPCR in 65 SjD patients and 48 controls confirmed significant EPSTI1 upregulation. Single-cell analysis localized EPSTI1 to monocytes and dendritic cells. CellChat identified enhanced MIF-CD74/CXCR4 signaling, and virtual knockout demonstrated EPSTI1 as a specific downstream effector within the interferon cascade.
This study established an integrated machine learning framework identifying EPSTI1 as a robust SjD diagnostic biomarker predominantly expressed in myeloid cells. Multi-dimensional validation supports its clinical potential for precision diagnosis of SjD, pending prospective confirmation in larger cohorts. Key Points • A systematic evaluation of 113 machine learning algorithm combinations identified a 14-gene diagnostic signature for Sjögren's disease with robust performance across multiple independent cohorts (AUC > 0.87). • EPSTI1 emerged as the top-ranked diagnostic biomarker through convergent evidence from machine learning feature selection, SHAP interpretability analysis, and RT-qPCR validation in clinical samples. • Single-cell RNA sequencing localized EPSTI1 expression predominantly to monocytes and dendritic cells, linking its diagnostic utility to myeloid-mediated immune dysregulation. • Virtual gene knockout analysis positioned EPSTI1 as a specific downstream effector within the interferon signaling cascade, distinguishing it from broad upstream regulators like STAT1.

PMID:
42429909
Bibliographic data and abstract were imported from PubMed on 10 Jul 2026.

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