Hom-complex-based machine learning (HCML) for the prediction of protein–protein binding affinity changes upon mutation
Protein-protein interactions (PPIs) are involved in almost all biological processes in the cell. Understanding protein-protein interactions holds the key for the understanding of biological functions, diseases and the development of therapeutics. Recently, artificial intelligence (AI) models have de...
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sg-ntu-dr.10356-1634362022-12-06T06:14:54Z Hom-complex-based machine learning (HCML) for the prediction of protein–protein binding affinity changes upon mutation Liu, Xiang Feng, Huitao Wu, Jie Xia, Kelin School of Physical and Mathematical Sciences Science::Mathematics Artificial Intelligence Biological Process Protein-protein interactions (PPIs) are involved in almost all biological processes in the cell. Understanding protein-protein interactions holds the key for the understanding of biological functions, diseases and the development of therapeutics. Recently, artificial intelligence (AI) models have demonstrated great power in PPIs. However, a key issue for all AI-based PPI models is efficient molecular representations and featurization. Here, we propose Hom-complex-based PPI representation, and Hom-complex-based machine learning models for the prediction of PPI binding affinity changes upon mutation, for the first time. In our model, various Hom complexes Hom(G1, G) can be generated for the graph representation G of protein-protein complex by using different graphs G1, which reveal G1-related inner connections within the graph representation G of protein-protein complex. Further, for a specific graph G1, a series of nested Hom complexes are generated to give a multiscale characterization of the PPIs. Its persistent homology and persistent Euler characteristic are used as molecular descriptors and further combined with the machine learning model, in particular, gradient boosting tree (GBT). We systematically test our model on the two most-commonly used data sets, that is, SKEMPI and AB-Bind. It has been found that our model outperforms all the existing models as far as we know, which demonstrates the great potential of our model for the analysis of PPIs. Our model can be used for the analysis and design of efficient antibodies for SARS-CoV-2. Ministry of Education (MOE) Nanyang Technological University This work was supported in part by Nanyang Technological University Startup Grant M4081842 and Singapore Ministry of Education Academic Research fund Tier 1 RG109/19, MOET2EP20120-0013, and MOE-T2EP20220-0010. The first author was supported by Nankai Zhide foundation. The second author was supported by Natural Science Foundation of China (NSFC Grant No. 11221091, 11271062, 11571184). The third author was supported by Natural Science Foundation of China (NSFC Grant No. 11971144), High-level Scientific Research Foundation of Hebei Province and the start-up research fund from BIMSA. 2022-12-06T06:14:53Z 2022-12-06T06:14:53Z 2022 Journal Article Liu, X., Feng, H., Wu, J. & Xia, K. (2022). Hom-complex-based machine learning (HCML) for the prediction of protein–protein binding affinity changes upon mutation. Journal of Chemical Information and Modeling, 62(17), 3961-3969. https://dx.doi.org/10.1021/acs.jcim.2c00580 1549-9596 https://hdl.handle.net/10356/163436 10.1021/acs.jcim.2c00580 36040839 2-s2.0-85138042183 17 62 3961 3969 en M4081842 RG109/19 MOET2EP20120-0013 MOE-T2EP20220-0010 Journal of Chemical Information and Modeling © 2022 American Chemical Society. All rights reserved. |
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Science::Mathematics Artificial Intelligence Biological Process Liu, Xiang Feng, Huitao Wu, Jie Xia, Kelin Hom-complex-based machine learning (HCML) for the prediction of protein–protein binding affinity changes upon mutation |
| description |
Protein-protein interactions (PPIs) are involved in almost all biological processes in the cell. Understanding protein-protein interactions holds the key for the understanding of biological functions, diseases and the development of therapeutics. Recently, artificial intelligence (AI) models have demonstrated great power in PPIs. However, a key issue for all AI-based PPI models is efficient molecular representations and featurization. Here, we propose Hom-complex-based PPI representation, and Hom-complex-based machine learning models for the prediction of PPI binding affinity changes upon mutation, for the first time. In our model, various Hom complexes Hom(G1, G) can be generated for the graph representation G of protein-protein complex by using different graphs G1, which reveal G1-related inner connections within the graph representation G of protein-protein complex. Further, for a specific graph G1, a series of nested Hom complexes are generated to give a multiscale characterization of the PPIs. Its persistent homology and persistent Euler characteristic are used as molecular descriptors and further combined with the machine learning model, in particular, gradient boosting tree (GBT). We systematically test our model on the two most-commonly used data sets, that is, SKEMPI and AB-Bind. It has been found that our model outperforms all the existing models as far as we know, which demonstrates the great potential of our model for the analysis of PPIs. Our model can be used for the analysis and design of efficient antibodies for SARS-CoV-2. |
| author2 |
School of Physical and Mathematical Sciences |
| author_facet |
School of Physical and Mathematical Sciences Liu, Xiang Feng, Huitao Wu, Jie Xia, Kelin |
| format |
Article |
| author |
Liu, Xiang Feng, Huitao Wu, Jie Xia, Kelin |
| author_sort |
Liu, Xiang |
| title |
Hom-complex-based machine learning (HCML) for the prediction of protein–protein binding affinity changes upon mutation |
| title_short |
Hom-complex-based machine learning (HCML) for the prediction of protein–protein binding affinity changes upon mutation |
| title_full |
Hom-complex-based machine learning (HCML) for the prediction of protein–protein binding affinity changes upon mutation |
| title_fullStr |
Hom-complex-based machine learning (HCML) for the prediction of protein–protein binding affinity changes upon mutation |
| title_full_unstemmed |
Hom-complex-based machine learning (HCML) for the prediction of protein–protein binding affinity changes upon mutation |
| title_sort |
hom-complex-based machine learning (hcml) for the prediction of protein–protein binding affinity changes upon mutation |
| publishDate |
2022 |
| url |
https://hdl.handle.net/10356/163436 |
| _version_ |
1751548539835514880 |