Prognostic modeling of glioma using epilepsy-related genes highlights PAX3 as a regulator of migration and vorinostat sensitivity
Wei Lin, Haoming Lin, Yaqi Zheng, Jin Wang, Junliang Li, Rui Yang, Zhongfei Zhang, Xiaoping Liu, Xinke Xu

TL;DR
This study creates a four-gene model to predict glioma patient survival and finds that PAX3 promotes cancer spread and drug resistance.
Contribution
A novel four-gene prognostic model using epilepsy-related genes and identification of PAX3's role in glioma migration and drug sensitivity.
Findings
A four-gene model (PAX3, RETN, VEPH1, HTR1A) accurately predicts glioma patient survival with AUC > 0.85.
PAX3 overexpression promotes glioma cell migration and resistance to vorinostat through HDAC regulation.
The model's risk score is an independent prognostic factor validated across multiple datasets.
Abstract
This study aimed to construct and validate a prognostic model for glioma based on epilepsy-related genes (ERGs) and to investigate the functional role of PAX3 in glioma progression and drug response. Transcriptomic and clinical data from TCGA, GEO, and CGGA databases were used to identify differentially expressed ERGs between glioma patients with and without epilepsy. Univariate Cox regression, LASSO regression, and multivariate Cox analysis were employed to establish a four-gene prognostic model comprising PAX3, RETN, VEPH1, and HTR1A. Patients were stratified into high- and low-risk groups based on the median risk score, which was calculated using gene expression levels and corresponding regression coefficients. The model showed robust prognostic performance, with AUC values exceeding 0.85 in the training set and remaining above 0.73 in internal and external validation cohorts.…
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Taxonomy
TopicsMicroRNA in disease regulation · Glioma Diagnosis and Treatment · Chromatin Remodeling and Cancer
