Differential correlations informed metabolite set enrichment analysis to decipher metabolic heterogeneity of disease
Metabolic pathways are regarded as functional and basic components of the biological system. In metabolomics, metabolite set enrichment analysis (MSEA) is often used to identify the altered metabolic pathways (metabolite sets) associated with phenotypes of interest (POI), e.g., disease. However, in...
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my.utm.1050222024-04-01T07:49:59Z http://eprints.utm.my/105022/ Differential correlations informed metabolite set enrichment analysis to decipher metabolic heterogeneity of disease Lin, Genjin Dong, Liheng Cheng, Kian-Kai Xu, Xiangnan Wang, Yongpei Deng, Lingli Raftery, Daniel Dong, Jiyang TP Chemical technology Metabolic pathways are regarded as functional and basic components of the biological system. In metabolomics, metabolite set enrichment analysis (MSEA) is often used to identify the altered metabolic pathways (metabolite sets) associated with phenotypes of interest (POI), e.g., disease. However, in most studies, MSEA suffers from the limitation of low metabolite coverage. Random walk (RW)-based algorithms can be used to propagate the perturbation of detected metabolites to the undetected metabolites through a metabolite network model prior to MSEA. Nevertheless, most of the existing RW-based algorithms run on a general metabolite network constructed based on public databases, such as KEGG, without taking into consideration the potential influence of POI on the metabolite network, which may reduce the phenotypic specificities of the MSEA results. To solve this problem, a novel pathway analysis strategy, namely, differential correlation-informed MSEA (dci-MSEA), is proposed in this paper. Statistically, differential correlations between metabolites are used to evaluate the influence of POI on the metabolite network, so that a phenotype-specific metabolite network is constructed for RW-based propagation. The experimental results show that dci-MSEA outperforms the conventional RW-based MSEA in identifying the altered metabolic pathways associated with colorectal cancer. In addition, by incorporating the individual-specific metabolite network, the dci-MSEA strategy is easily extended to disease heterogeneity analysis. Here, dci-MSEA was used to decipher the heterogeneity of colorectal cancer. The present results highlight the clustering of colorectal cancer samples with their cluster-specific selection of differential pathways and demonstrate the feasibility of dci-MSEA in heterogeneity analysis. Taken together, the proposed dci-MSEA may provide insights into disease mechanisms and determination of disease heterogeneity. American Chemical Society 2023 Article PeerReviewed Lin, Genjin and Dong, Liheng and Cheng, Kian-Kai and Xu, Xiangnan and Wang, Yongpei and Deng, Lingli and Raftery, Daniel and Dong, Jiyang (2023) Differential correlations informed metabolite set enrichment analysis to decipher metabolic heterogeneity of disease. Analytical Chemistry, 95 (33). pp. 12505-12513. ISSN 0003-2700 http://dx.doi.org/10.1021/acs.analchem.3c02246 DOI : 10.1021/acs.analchem.3c02246 |
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TP Chemical technology Lin, Genjin Dong, Liheng Cheng, Kian-Kai Xu, Xiangnan Wang, Yongpei Deng, Lingli Raftery, Daniel Dong, Jiyang Differential correlations informed metabolite set enrichment analysis to decipher metabolic heterogeneity of disease |
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Metabolic pathways are regarded as functional and basic components of the biological system. In metabolomics, metabolite set enrichment analysis (MSEA) is often used to identify the altered metabolic pathways (metabolite sets) associated with phenotypes of interest (POI), e.g., disease. However, in most studies, MSEA suffers from the limitation of low metabolite coverage. Random walk (RW)-based algorithms can be used to propagate the perturbation of detected metabolites to the undetected metabolites through a metabolite network model prior to MSEA. Nevertheless, most of the existing RW-based algorithms run on a general metabolite network constructed based on public databases, such as KEGG, without taking into consideration the potential influence of POI on the metabolite network, which may reduce the phenotypic specificities of the MSEA results. To solve this problem, a novel pathway analysis strategy, namely, differential correlation-informed MSEA (dci-MSEA), is proposed in this paper. Statistically, differential correlations between metabolites are used to evaluate the influence of POI on the metabolite network, so that a phenotype-specific metabolite network is constructed for RW-based propagation. The experimental results show that dci-MSEA outperforms the conventional RW-based MSEA in identifying the altered metabolic pathways associated with colorectal cancer. In addition, by incorporating the individual-specific metabolite network, the dci-MSEA strategy is easily extended to disease heterogeneity analysis. Here, dci-MSEA was used to decipher the heterogeneity of colorectal cancer. The present results highlight the clustering of colorectal cancer samples with their cluster-specific selection of differential pathways and demonstrate the feasibility of dci-MSEA in heterogeneity analysis. Taken together, the proposed dci-MSEA may provide insights into disease mechanisms and determination of disease heterogeneity. |
| format |
Article |
| author |
Lin, Genjin Dong, Liheng Cheng, Kian-Kai Xu, Xiangnan Wang, Yongpei Deng, Lingli Raftery, Daniel Dong, Jiyang |
| author_facet |
Lin, Genjin Dong, Liheng Cheng, Kian-Kai Xu, Xiangnan Wang, Yongpei Deng, Lingli Raftery, Daniel Dong, Jiyang |
| author_sort |
Lin, Genjin |
| title |
Differential correlations informed metabolite set enrichment analysis to decipher metabolic heterogeneity of disease |
| title_short |
Differential correlations informed metabolite set enrichment analysis to decipher metabolic heterogeneity of disease |
| title_full |
Differential correlations informed metabolite set enrichment analysis to decipher metabolic heterogeneity of disease |
| title_fullStr |
Differential correlations informed metabolite set enrichment analysis to decipher metabolic heterogeneity of disease |
| title_full_unstemmed |
Differential correlations informed metabolite set enrichment analysis to decipher metabolic heterogeneity of disease |
| title_sort |
differential correlations informed metabolite set enrichment analysis to decipher metabolic heterogeneity of disease |
| publisher |
American Chemical Society |
| publishDate |
2023 |
| url |
http://eprints.utm.my/105022/ http://dx.doi.org/10.1021/acs.analchem.3c02246 |
| _version_ |
1797905891383574528 |