Author
Listed:
- Bin Huang
(University of Science and Technology of China)
- Yang Xu
(University of Science and Technology of China)
- Xiuhong Hu
(University of Science and Technology of China)
- Yongrui Liu
(University of Science and Technology of China)
- Shanhui Liao
(University of Science and Technology of China)
- Jiahai Zhang
(University of Science and Technology of China)
- Chengdong Huang
(University of Science and Technology of China
University of Science and Technology of China)
- Jingjun Hong
(University of Science and Technology of China)
- Quan Chen
(University of Science and Technology of China
University of Science and Technology of China)
- Haiyan Liu
(University of Science and Technology of China
University of Science and Technology of China
University of Science and Technology of China)
Abstract
A protein backbone structure is designable if a substantial number of amino acid sequences exist that autonomously fold into it1,2. It has been suggested that the designability of backbones is governed mainly by side chain-independent or side chain type-insensitive molecular interactions3–5, indicating an approach for designing new backbones (ready for amino acid selection) based on continuous sampling and optimization of the backbone-centred energy surface. However, a sufficiently comprehensive and precise energy function has yet to be established for this purpose. Here we show that this goal is met by a statistical model named SCUBA (for Side Chain-Unknown Backbone Arrangement) that uses neural network-form energy terms. These terms are learned with a two-step approach that comprises kernel density estimation followed by neural network training and can analytically represent multidimensional, high-order correlations in known protein structures. We report the crystal structures of nine de novo proteins whose backbones were designed to high precision using SCUBA, four of which have novel, non-natural overall architectures. By eschewing use of fragments from existing protein structures, SCUBA-driven structure design facilitates far-reaching exploration of the designable backbone space, thus extending the novelty and diversity of the proteins amenable to de novo design.
Suggested Citation
Bin Huang & Yang Xu & Xiuhong Hu & Yongrui Liu & Shanhui Liao & Jiahai Zhang & Chengdong Huang & Jingjun Hong & Quan Chen & Haiyan Liu, 2022.
"A backbone-centred energy function of neural networks for protein design,"
Nature, Nature, vol. 602(7897), pages 523-528, February.
Handle:
RePEc:nat:nature:v:602:y:2022:i:7897:d:10.1038_s41586-021-04383-5
DOI: 10.1038/s41586-021-04383-5
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Cited by:
- Shuangjia Zheng & Tao Zeng & Chengtao Li & Binghong Chen & Connor W. Coley & Yuedong Yang & Ruibo Wu, 2022.
"Deep learning driven biosynthetic pathways navigation for natural products with BioNavi-NP,"
Nature Communications, Nature, vol. 13(1), pages 1-9, December.
- Peicong Lin & Yumeng Yan & Huanyu Tao & Sheng-You Huang, 2023.
"Deep transfer learning for inter-chain contact predictions of transmembrane protein complexes,"
Nature Communications, Nature, vol. 14(1), pages 1-16, December.
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