Abstract
Tobacco exposure is one of the major risks for the initiation and progress of lung cancer. The exact corresponding mechanisms, however, are mainly unknown. Recently, a growing body of evidence has been collected supporting the involvement of DNA methylation in the regulation of gene expression in cancer cells. The identification of tobacco-related signature methylation probes and the analysis of their regulatory networks at different molecular levels may be of a great help for understanding tobacco-related tumorigenesis. Three independent lung adenocarcinoma (LUAD) datasets were used to train and validate the tobacco exposure pattern classification model. A deep selecting method was proposed and used to identify methylation signature probes from hundreds of thousands of the whole epigenome probes. Then, BIMC (biweight midcorrelation coefficient) algorithm, SRC (Spearman's rank correlation) analysis, and shortest path tracing method were explored to identify associated genes at gene regulation level and protein-protein interaction level, respectively. Afterwards, the KEGG (Kyoto Encyclopedia of Genes and Genomes) pathway analysis and GO (Gene Ontology) enrichment analysis were used to analyze their molecular functions and associated pathways. 105 probes were identified as tobacco-related DNA methylation signatures. They belong to 95 genes which are involved in hsa04512, hsa04151, and other important pathways. At gene regulation level, 33 genes are uncovered to be highly related to signature probes by both BIMC and SRC methods. Among them, FARSB and other eight genes were uncovered as Hub genes in the gene regulatory network. Meanwhile, the PPI network about these 33 genes showed that MAGOH, FYN, and other five genes were the most connected core genes among them. These analysis results may provide clues for a clear biological interpretation in the molecular mechanism of tumorigenesis. Moreover, the identified signature probes may serve as potential drug targets for the precision medicine of LUAD.
Highlights
Lung cancer has been the leading cause of cancer-related mortality throughout the world for decades [1]
Being the major form of lung cancer associated with never-smokers [5,6,7], when considering therapies for lung adenocarcinoma (LUAD) patients, the carcinogenic mechanisms of smokers are believed to differ from those of never-smokers. e rising trend in the BioMed Research International proportion of never-smokers in LUAD urgently requires the understanding of such differences on molecular levels for the development of precision medicine
We identified 48 genes whose promoter DNA methylation levels were highly related to tobacco exposure for LUAD patients
Summary
Lung cancer has been the leading cause of cancer-related mortality throughout the world for decades [1]. Smoking during cancer therapy may influence radiotherapy and chemotherapy outcomes [2]. Being the major form of lung cancer associated with never-smokers [5,6,7], when considering therapies for lung adenocarcinoma (LUAD) patients, the carcinogenic mechanisms of smokers are believed to differ from those of never-smokers. DNA methylation, a useful and stable surrogate of the genetic response, has recently been suggested to be one of the potential mechanisms for smoking-related health outcomes [8,9,10,11]. Epigenomewide association studies (EWAS) have opened a new avenue for lung cancer research. E cumulative smoking dose (pack-years) has been shown to correlate well with the frequency of methylation in cancer-free heavy smokers [13]. The highly reproducible DNA methylation markers linked to smoking and their corresponding mechanism remain unclear
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