Abstract
The pediatric sepsis (PS) is characterized by severe clinical symptoms and high mortality. There was a lack of studies on the mechanisms of glycolysis and macrophage polarization (MP) in PS. The focus of this study was to identify biomarkers associated with glycolysis and MP in PS and to conduct mechanistic studies. The GSE26440 and GSE13904 datasets, glycolysis-related genes and macrophage polarization-related genes (MPRGs) were used in this study for analysis. First, to identify differentially expressed genes in GSE26440. Next, the weighted gene co-expression network analysis was taken to obtain key modular genes related between glycolysis and MP, and differentially expressed genes were overlapped with key modular genes to identify candidate genes. Subsequently, biomarkers were detected to biomarkers by constructing a protein-protein interaction network, machine learning and expression validation. Finally, based on the biomarkers, functional enrichment, regulatory network, immune microenvironment analysis, and the quantitative real-time polymerase chain reaction were analyzed. After screening, 4 biomarkers (a disintegrin and a metalloprotease9 [ADAM9], transforming growth factor alpha [TGFA], G protein subunit alpha q [GNAQ], and decaprenyl diphosphate synthase subunit 1 [PDSS1]) were obtained. The lysosome and fc gamma r mediated phagocytosis co-targeted 4 biomarkers in gene set enrichment analysis. Spearman correlation analysis showed that ADAM9, TGFA, GNAQ, and PDSS1 were significantly positively related to activated dendritic cells, and had a significantly negative correlation with activated B cells. Next, a long noncoding RNA (lncRNAs)-MicroRNAs (miRNAs)-mRNA network containing 7 microRNAs and 23 lncRNAs was constructed. The hsa-miR-302c-5P co-targeted ADAM9, TGFA, and PDSS1. Finally, quantitative real-time polymerase chain reaction showed that TGFA, GNAQ, and PDSS1 expression levels were significantly elevated in PS samples. In this study, 4 biomarkers (ADAM9, TGFA, GNAQ, and PDSS1) associated with glycolysis and MP were identified to provide scientific theories for the clinical management of PS.