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ProstaNet: A Novel Geometric Vector Perceptrons-Graph Neural Network Algorithm for Protein Stability Prediction in

Tianjian Liang1, Ze-Yu Sun1, Rieko Ishima2

  • 1Department of Pharmaceutical Sciences, Computational Chemical Genomics Screening Center, and Pharmacometrics and System Pharmacology PharmacoAnalytics, School of Pharmacy, National Center of Excellence for Computational Drug Abuse Research, University of Pittsburgh, Pittsburgh, PA 15261, USA.

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Summary
This summary is machine-generated.

ProstaNet, a deep learning framework, accurately predicts protein stability changes from mutations. It outperforms existing methods for both single and multiple point mutations, aiding protein engineering and drug development.

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Area of Science:

  • Computational Biology
  • Biophysics
  • Machine Learning

Background:

  • Protein stability prediction is crucial for biology and biopharma but experimentally challenging.
  • Deep learning offers an efficient computational approach to predict mutation effects on protein stability.

Purpose of the Study:

  • Introduce ProstaNet, a deep learning framework for predicting protein stability changes caused by single- and multiple-point mutations.
  • Develop a comprehensive dataset (ProstaDB) and innovative methods to train and validate the deep learning model.

Main Methods:

  • Utilized a geometric vector perceptrons-graph neural network for 3D feature processing in ProstaNet.
  • Created ProstaDB with 3,784 single-point and 1,642 multiple-point mutations, employing thermodynamic looping and clustering for data enhancement and testing.
  • Identified residue scoring as a key encoding method for protein property prediction.

Main Results:

  • ProstaNet achieved 0.75 accuracy for single-point mutation prediction, surpassing ThermoMPNN (0.63), PoPMuSiCsym (0.66), MUPRO (0.52), and FoldX (0.71).
  • ProstaNet demonstrated a 1.3-fold increase in accuracy over FoldX for multiple-point mutation predictions.
  • Experimental validation showed 80% accuracy for single-point and 100% for multiple-point mutations in HuJ3 mutants.

Conclusions:

  • ProstaNet accurately predicts thermostability changes for both single- and multiple-point mutations without bias.
  • The framework shows significant potential for advancing protein engineering and drug development through accurate mutation effect prediction.