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Auteurs principaux: Wang, Kun, Li, Binhan, Xu, Miao, Ding, Dailin, Zheng, Qihui, Tian, Geng, Zeng, Xueying, Yang, Jialiang
Format: Artículo científico
Langue:en
Publié: BMC biology 2025
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Accès en ligne:https://pubmed.ncbi.nlm.nih.gov/41340127/
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author Wang, Kun
Li, Binhan
Xu, Miao
Ding, Dailin
Zheng, Qihui
Tian, Geng
Zeng, Xueying
Yang, Jialiang
author_facet Wang, Kun
Li, Binhan
Xu, Miao
Ding, Dailin
Zheng, Qihui
Tian, Geng
Zeng, Xueying
Yang, Jialiang
Wang, Kun
Li, Binhan
Xu, Miao
Ding, Dailin
Zheng, Qihui
Tian, Geng
Zeng, Xueying
Yang, Jialiang
collection PubMed - marine biology
contents MCLRP: enhanced prediction of anticancer drug response through low-rank matrix completion and transcriptomic profiling. Wang, Kun Li, Binhan Xu, Miao Ding, Dailin Zheng, Qihui Tian, Geng Zeng, Xueying Yang, Jialiang Antineoplastic Agents Humans Gene Expression Profiling Cell Line, Tumor Principal Component Analysis Transcriptome Accurate prediction of anticancer drug responses remains a significant challenge due to the intricate interplay between genomic features and pharmacological mechanisms. We present Matrix Completion with Low-rank Regularization and Principal Component Analysis (MCLRP), a multimodal framework that synergistically integrates low-rank matrix completion with transcriptomic principal component analysis through dual-stream feature interaction. This innovative architecture not only leverages the similarities among drugs and mutation patterns in cell lines via matrix completion but also preserves gene-level interpretability of response patterns by incorporating gene expression data into the model. Benchmarked against seven computational paradigms (including matrix completion, ridge regression, SRMF, and their hybrid variants) across the Genomics of Drug Sensitivity in Cancer (GDSC) and Cancer Cell Line Encyclopedia (CCLE) repositories, MCLRP demonstrated superior predictive performance for 75% of drug responses, alongside enhanced biological plausibility. Notably, the model identified imatinib as a potential therapeutic alternative for M14 melanoma cell lines through cross-drug response extrapolation, suggesting innovative strategies for overcoming doxorubicin resistance. Interestingly, our mutation-response mapping revealed that BRAF-mutated lineages exhibited a 4.7-fold increase in sensitivity (p These findings establish MCLRP as a dual-purpose predictive-analytical tool that not only enhances drug response forecasting but also uncovers mutation-specific pharmacological vulnerabilities through systems-level pattern recognition.
format Artículo científico
id pubmed_41340127
institution PubMed
language en
publishDate 2025
publisher BMC biology
record_format pubmed
spellingShingle MCLRP: enhanced prediction of anticancer drug response through low-rank matrix completion and transcriptomic profiling.
Wang, Kun
Li, Binhan
Xu, Miao
Ding, Dailin
Zheng, Qihui
Tian, Geng
Zeng, Xueying
Yang, Jialiang
Antineoplastic Agents
Humans
Gene Expression Profiling
Cell Line, Tumor
Principal Component Analysis
Transcriptome
MCLRP: enhanced prediction of anticancer drug response through low-rank matrix completion and transcriptomic profiling. Wang, Kun Li, Binhan Xu, Miao Ding, Dailin Zheng, Qihui Tian, Geng Zeng, Xueying Yang, Jialiang Antineoplastic Agents Humans Gene Expression Profiling Cell Line, Tumor Principal Component Analysis Transcriptome Accurate prediction of anticancer drug responses remains a significant challenge due to the intricate interplay between genomic features and pharmacological mechanisms. We present Matrix Completion with Low-rank Regularization and Principal Component Analysis (MCLRP), a multimodal framework that synergistically integrates low-rank matrix completion with transcriptomic principal component analysis through dual-stream feature interaction. This innovative architecture not only leverages the similarities among drugs and mutation patterns in cell lines via matrix completion but also preserves gene-level interpretability of response patterns by incorporating gene expression data into the model. Benchmarked against seven computational paradigms (including matrix completion, ridge regression, SRMF, and their hybrid variants) across the Genomics of Drug Sensitivity in Cancer (GDSC) and Cancer Cell Line Encyclopedia (CCLE) repositories, MCLRP demonstrated superior predictive performance for 75% of drug responses, alongside enhanced biological plausibility. Notably, the model identified imatinib as a potential therapeutic alternative for M14 melanoma cell lines through cross-drug response extrapolation, suggesting innovative strategies for overcoming doxorubicin resistance. Interestingly, our mutation-response mapping revealed that BRAF-mutated lineages exhibited a 4.7-fold increase in sensitivity (p These findings establish MCLRP as a dual-purpose predictive-analytical tool that not only enhances drug response forecasting but also uncovers mutation-specific pharmacological vulnerabilities through systems-level pattern recognition.
title MCLRP: enhanced prediction of anticancer drug response through low-rank matrix completion and transcriptomic profiling.
topic Antineoplastic Agents
Humans
Gene Expression Profiling
Cell Line, Tumor
Principal Component Analysis
Transcriptome
url https://pubmed.ncbi.nlm.nih.gov/41340127/