Abstract
With the great significance of biomolecular flexibility in biomolecular dynamics and functional analysis, various experimental and theoretical models are developed. Experimentally, Debye-Waller factor, also known as B-factor, measures atomic mean-square displacement and is usually considered as an important measurement for flexibility. Theoretically, elastic network models, Gaussian network model, flexibility-rigidity model, and other computational models have been proposed for flexibility analysis by shedding light on the biomolecular inner topological structures. Recently, a topology-based machine learning model has been proposed. By using the features from persistent homology, this model achieves a remarkable high Pearson correlation coefficient (PCC) in protein B-factor prediction. Motivated by its success, we propose weighted-persistent-homology (WPH)-based machine learning (WPHML) models for RNA flexibility analysis. Our WPH is a newly-proposed model, which incorporate physical, chemical and biological information into topological measurements using a weight function. In particular, we use local persistent homology (LPH) to focus on the topological information of local regions. Our WPHML model is validated on a well-established RNA dataset, and numerical experiments show that our model can achieve a PCC of up to 0.5822. The comparison with the previous sequence-information-based learning models shows that a consistent improvement in performance by at least 10% is achieved in our current model.
Highlights
Biomolecular functions usually can be analyzed by their structural properties through quantitative structure-property relationship (QSPR) models (or quantitative structure-activity relationship (QSAR) models)
We demonstrate the performance of our weighted-persistent-homology-based machine learning (WPHML) model
We propose the weighted-persistent-homology-based machine learning (WPHML) models and use them in the RNA B-factor prediction
Summary
Biomolecular functions usually can be analyzed by their structural properties through quantitative structure-property relationship (QSPR) models (or quantitative structure-activity relationship (QSAR) models). Among all the structural properties, biomolecular flexibility is of unique importance, as it can be directly or indirectly measured by experimental tools. DebyeWaller factor or B-factor, which is the atomic mean-square displacement, provides a quantitative characterization of the flexibility and rigidity of biomolecular structures. With the strong relationship between structure flexibility and functions, various theoretical and computational methods have been proposed to model the flexibility of a biomolecular.
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