Bioinformatics and machine learning were used to validate glutamine metabolism-related genes and immunotherapy in osteoporosis patients

Bioinformatics and machine learning were used to validate glutamine metabolism-related genes and immunotherapy in osteoporosis patients

Background Osteoporosis (OP), often referred to as the "silent disease of the twenty-first century," poses a significant public health concern due to its severity, chronic nature, and progressive course, predominantly affecting postmenopausal women and elderly individuals. The pathogenesis...

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Veröffentlicht in:Journal of orthopaedic surgery and research 2023-09, Vol.18 (1), p.1-14, Article 685
Hauptverfasser: Wang, Lei, Deng, Chaosheng, Wu, Zixuan, Zhu, Kaidong, Yang, Zhenguo
Format: Artikel
Sprache:eng
Schlagworte:
Alzheimer's disease
Analysis
Bioinformatics
Biomarkers
Channel gating
Cluster analysis
Computational biology
Correlation analysis
Datasets
DEGs
Development and progression
Drug therapy
Genes
Genetic research
Gln-metabolism genes (GlnMgs)
Glutamine
Immunotherapy
Machine learning
Malignancy
Medical prognosis
Metabolic pathways
Metabolism
Orthopedics
Osteoporosis
Osteoporosis (OP)
Physiological aspects
Post-menopause
Postmenopausal women
Public health
Synaptic transmission
WGCNA
γ-Aminobutyric acid
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Zusammenfassung:Background Osteoporosis (OP), often referred to as the "silent disease of the twenty-first century," poses a significant public health concern due to its severity, chronic nature, and progressive course, predominantly affecting postmenopausal women and elderly individuals. The pathogenesis and progression of this disease have been associated with dysregulation in tumor metabolic pathways. Notably, the metabolic utilization of glutamine has emerged as a critical player in cancer biology. While metabolic reprogramming has been extensively studied in various malignancies and linked to clinical outcomes, its comprehensive investigation within the context of OP remains lacking. Methods This study aimed to identify and validate potential glutamine metabolism genes (GlnMgs) associated with OP through comprehensive bioinformatics analysis. The identification of GlnMgs was achieved by integrating the weighted gene co-expression network analysis and a set of 28 candidate GlnMgs. Subsequently, the putative biological functions and pathways associated with GlnMgs were elucidated using gene set variation analysis. The LASSO method was employed to identify key hub genes, and the diagnostic efficacy of five selected GlnMgs in OP detection was assessed. Additionally, the relationship between hub GlnMgs and clinical characteristics was investigated. Finally, the expression levels of the five GlnMgs were validated using independent datasets (GSE2208, GSE7158, GSE56815, and GSE35956). Results Five GlnMgs, namely IGKC, TMEM187, RPS11, IGLL3P, and GOLGA8N, were identified in this study. To gain insights into their biological functions, particular emphasis was placed on synaptic transmission GABAergic, inward rectifier potassium channel activity, and the cytoplasmic side of the lysosomal membrane. Furthermore, the diagnostic potential of these five GlnMgs in distinguishing individuals with OP yielded promising results, indicating their efficacy as discriminative markers for OP. Conclusions This study discovered five GlnMgs that are linked to OP. They shed light on potential new biomarkers for OP and tracking its progression. Keywords: Osteoporosis (OP), Gln-metabolism genes (GlnMgs), DEGs, WGCNA, Bioinformatics
ISSN:1749-799X
1749-799X
DOI:10.1186/s13018-023-04152-2