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Many proteins form complexes to carry out their functions, making protein-protein interactions (PPIs) essential for an organism's survival. Most PPIs are stabilized by numerous weak noncovalent chemical forces. The physical shape of the interfaces determines the way two proteins interact. Many globular proteins have closely-matching shapes on their surfaces, which form a large number of weak bonds. Additionally, many PPIs occur between two helices or between a surface cleft and a...
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Facilitating Machine Learning-Guided Protein Engineering with Smart Library Design and Massively Parallel Assays.

Hoi Yee Chu1, Alan S L Wong1,2

  • 1Laboratory of Combinatorial Genetics and Synthetic Biology School of Biomedical Sciences The University of Hong Kong Hong Kong 852 China.

Advanced Genetics (Hoboken, N.J.)
|January 9, 2023
PubMed
Summary
This summary is machine-generated.

Machine learning predicts protein variant fitness, accelerating protein engineering. This approach guides focused library creation, reducing experimental effort and speeding up the discovery of beneficial protein variants.

Keywords:
combinatorial mutagenesisfunctionality predictioninfologsmachine learningprotein engineering

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Area of Science:

  • Protein engineering and computational biology.
  • Biophysics and molecular biology.

Background:

  • Protein design is crucial for medical advances like antibody and vaccine development.
  • Traditional methods like mutational screens and directed evolution are limited by scale for combinatorial mutations.
  • High-throughput screening and Next-Generation Sequencing increase read-out scale but cannot survey all variants.

Purpose of the Study:

  • To describe advances in massive-scale variant screens.
  • To explain the integration of machine learning and mutagenesis for accelerated protein engineering.
  • To examine strategies for economical, informative, and effective variant discovery.

Main Methods:

  • Utilizing in-silico approaches with machine learning to predict variant fitness.
  • Employing a subset of empirical measurements to train machine learning models.
  • Integrating machine learning with mutagenesis strategies and massive-scale variant screens.

Main Results:

  • Machine learning models predict fitness of novel protein variants.
  • Models can guide the search for high-fitness variants and resolve epistasis.
  • Machine learning facilitates the creation of focused libraries, reducing experimental burden.

Conclusions:

  • Machine learning-guided protein engineering accelerates the optimization process.
  • Integrated strategies enhance the economy, informativeness, and effectiveness of variant discovery.
  • This approach fast-tracks the development of useful protein variants for various applications.