Frontiers in Endocrinology (Sep 2023)

Identification of endoplasmic reticulum stress-related biomarkers of diabetes nephropathy based on bioinformatics and machine learning

  • Jiaming Su,
  • Jiaming Su,
  • Jing Peng,
  • Lin Wang,
  • Lin Wang,
  • Huidi Xie,
  • Huidi Xie,
  • Ying Zhou,
  • Ying Zhou,
  • Haimin Chen,
  • Haimin Chen,
  • Yang Shi,
  • Yang Shi,
  • Yan Guo,
  • Yan Guo,
  • Yicheng Zheng,
  • Yicheng Zheng,
  • Yuxin Guo,
  • Yuxin Guo,
  • Zhaoxi Dong,
  • Zhaoxi Dong,
  • Xianhui Zhang,
  • Xianhui Zhang,
  • Hongfang Liu,
  • Hongfang Liu

DOI
https://doi.org/10.3389/fendo.2023.1206154
Journal volume & issue
Vol. 14

Abstract

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BackgroundsDiabetes nephropathy (DN) is a growing public health concern worldwide. Renal dysfunction impairment in DN is intimately linked to ER stress and its related signaling pathways. Nonetheless, the underlying mechanism and biomarkers for this function of ER stress in the DN remain unknown.MethodsMicroarray datasets were retrieved from the Gene Expression Omnibus (GEO) database, and ER stress-related genes (ERSRGs) were downloaded from the MSigDB and GeneCards database. We identified hub ERSRGs for DN progression by intersecting ERSRGs with differentially expressed genes and significant genes in WGCNA, followed by a functional analysis. After analyzing hub ERSRGs with three machine learning techniques and taking the intersection, we did external validation as well as developed a DN diagnostic model based on the characteristic genes. Immune infiltration was performed using CIBERSORT. Moreover, patients with DN were then categorized using a consensus clustering approach. Eventually, the candidate ERSRGs-specific small-molecule compounds were defined by CMap.ResultsSeveral biological pathways driving pathological injury of DN and disordered levels of immune infiltration were revealed in the DN microarray datasets and strongly related to deregulated ERSRGs by bioinformatics multi-chip integration. Moreover, CDKN1B, EGR1, FKBP5, GDF15, and MARCKS were identified as ER stress signature genes associated with DN by machine learning algorithms, demonstrating their potential as DN biomarkers.ConclusionsOur research sheds fresh light on the function of ER stress in DN pathophysiology and the development of early diagnostic and ER stress-related treatment targets in patients with DN.

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