可解释性
互补性(分子生物学)
人工智能
机器学习
结合亲和力
亲缘关系
支持向量机
特征选择
计算生物学
能量学
计算机科学
DNA微阵列
氢键
可扩展性
随机森林
分子动力学
序列(生物学)
化学
结合位点
结合能
特征(语言学)
可达表面积
生物系统
序列母题
集合(抽象数据类型)
回归
抄写(语言学)
计算模型
转录因子
结合选择性
分子描述符
DNA
DNA测序
生物信息学
朴素贝叶斯分类器
线性回归
生物
模式识别(心理学)
基因组学
数据挖掘
作者
Carmen Al Masri,Jin Yu
标识
DOI:10.1021/acs.jcim.5c01143
摘要
Transcription factors (TFs) are essential regulators of gene expression, and variations in their target DNA sequences due to altering TF-DNA binding affinity and specificity lead to diseases ranging from developmental disorders to cancer. Computational methods that integrate physics-based models with machine learning (ML) hold promise to accurately predict protein-DNA binding affinities while ensuring interpretability and generalizability. Here, we present an approach combining all-atom molecular dynamics (MD) simulations and Molecular Mechanics-Generalized Born Surface Area (MMGBSA) energy calculations with ML model constructions (neural networks, random forests, and support vector machines) to predict DNA binding affinities and specificities for the dimeric TF Myc/Max. Using high-quality experimental data from genomic-context protein-binding microarrays (gcPBM), we constructed a balanced data set of 168 DNA sequences reflecting physiologically relevant genomic environments. Multiple independent simulations were conducted per sequence for each TF-DNA complex to capture structural dynamic and interaction properties, with physically essential energetic descriptors extracted, including van der Waals, electrostatic, solvation, hydrogen bonding, and additional energy corrections. Our models achieved a Pearson correlation of ∼0.73 and a mean absolute error of 0.4, substantially improving upon conventional MMGBSA prediction. Feature importance analyses highlighted TF-DNA interfacial complementarity and hydrophobic interactions as primary determinants of binding affinity and specificity, though TF-DNA interfacial hydrogen bonding contributions remain to be better characterized physically for sequence dependency. This physics-informed ML framework thus aims at both predictive accuracy and mechanistic interpretability, paving the way toward universal scalable prediction of interpretable protein-DNA interactions.
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