研究者ら、癌ドライバーの探索を改善(Researchers improve search for cancer drivers)

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2024-09-11 ワシントン州立大学(WSU)

ワシントン州立大学(WSU)の研究チームは、新しいコンピュータアルゴリズム「DiWANN」を開発し、がんの遺伝データから効率的に共存する突然変異や遺伝的パターンを特定できるようになりました。このモデルは、膨大な遺伝情報の解析を効率化し、がんのドライバー遺伝子や治療標的の特定に役立ちます。研究では、膵臓がんで頻繁に共存する2つの突然変異が確認され、がん治療への新たな手がかりとなる可能性があります。

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ヒト癌におけるドライバー遺伝子のネットワーク解析
Network analysis of driver genes in human cancers

Shruti S. Patil,Steven A. Roberts,Assefaw H. Gebremedhin
Frontiers in Bioinformatics  Published:08 July 2024
DOI:https://doi.org/10.3389/fbinf.2024.1365200

研究者ら、癌ドライバーの探索を改善(Researchers improve search for cancer drivers)

Cancer is a heterogeneous disease that results from genetic alteration of cell cycle and proliferation controls. Identifying mutations that drive cancer, understanding cancer type specificities, and delineating how driver mutations interact with each other to establish disease is vital for identifying therapeutic vulnerabilities. Such cancer specific patterns and gene co-occurrences can be identified by studying tumor genome sequences, and networks have proven effective in uncovering relationships between sequences. We present two network-based approaches to identify driver gene patterns among tumor samples. The first approach relies on analysis using the Directed Weighted All Nearest Neighbors (DiWANN) model, which is a variant of sequence similarity network, and the second approach uses bipartite network analysis. A data reduction framework was implemented to extract the minimal relevant information for the sequence similarity network analysis, where a transformed reference sequence is generated for constructing the driver gene network. This data reduction process combined with the efficiency of the DiWANN network model, greatly lowered the computational cost (in terms of execution time and memory usage) of generating the networks enabling us to work at a much larger scale than previously possible. The DiWANN network helped us identify cancer types in which samples were more closely connected to each other suggesting they are less heterogeneous and potentially susceptible to a common drug. The bipartite network analysis provided insight into gene associations and co-occurrences. We identified genes that were broadly mutated in multiple cancer types and mutations exclusive to only a few. Additionally, weighted one-mode gene projections of the bipartite networks revealed a pattern of occurrence of driver genes in different cancers. Our study demonstrates that network-based approaches can be an effective tool in cancer genomics. The analysis identifies co-occurring and exclusive driver genes and mutations for specific cancer types, providing a better understanding of the driver genes that lead to tumor initiation and evolution.

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