Your search keyword '"Sun, Yanmei"' showing total 2 results

1. A microbial knowledge graph-based deep learning model for predicting candidate microbes for target hosts.

Author

Pan, Jie, Zhang, Zhen, Li, Ying, Yu, Jiaoyang, You, Zhuhong, Li, Chenyu, Wang, Shixu, Zhu, Minghui, Ren, Fengzhi, Zhang, Xuexia, Sun, Yanmei, and Wang, Shiwei

Subjects

ARTIFICIAL neural networks, DEEP learning, KNOWLEDGE graphs, MICROBIAL genetics, MICROORGANISMS, PATHOGENIC bacteria, NATURAL language processing

Abstract

Predicting interactions between microbes and hosts plays critical roles in microbiome population genetics and microbial ecology and evolution. How to systematically characterize the sophisticated mechanisms and signal interplay between microbes and hosts is a significant challenge for global health risks. Identifying microbe-host interactions (MHIs) can not only provide helpful insights into their fundamental regulatory mechanisms, but also facilitate the development of targeted therapies for microbial infections. In recent years, computational methods have become an appealing alternative due to the high risk and cost of wet-lab experiments. Therefore, in this study, we utilized rich microbial metagenomic information to construct a novel heterogeneous microbial network (HMN)-based model named KGVHI to predict candidate microbes for target hosts. Specifically, KGVHI first built a HMN by integrating human proteins, viruses and pathogenic bacteria with their biological attributes. Then KGVHI adopted a knowledge graph embedding strategy to capture the global topological structure information of the whole network. A natural language processing algorithm is used to extract the local biological attribute information from the nodes in HMN. Finally, we combined the local and global information and fed it into a blended deep neural network (DNN) for training and prediction. Compared to state-of-the-art methods, the comprehensive experimental results show that our model can obtain excellent results on the corresponding three MHI datasets. Furthermore, we also conducted two pathogenic bacteria case studies to further indicate that KGVHI has excellent predictive capabilities for potential MHI pairs. [ABSTRACT FROM AUTHOR]

Published

2024

2. PTBGRP: predicting phage–bacteria interactions with graph representation learning on microbial heterogeneous information network.

Author

Pan, Jie, You, Zhuhong, You, Wencai, Zhao, Tian, Feng, Chenlu, Zhang, Xuexia, Ren, Fengzhi, Ma, Sanxing, Wu, Fan, Wang, Shiwei, and Sun, Yanmei

Subjects

REPRESENTATIONS of graphs, BACTERIOPHAGES, INFORMATION networks, BIOLOGICAL networks, KLEBSIELLA pneumoniae, BACTERIAL diseases

Abstract

Identifying the potential bacteriophages (phage) candidate to treat bacterial infections plays an essential role in the research of human pathogens. Computational approaches are recognized as a valid way to predict bacteria and target phages. However, most of the current methods only utilize lower-order biological information without considering the higher-order connectivity patterns, which helps to improve the predictive accuracy. Therefore, we developed a novel microbial heterogeneous interaction network (MHIN)–based model called PTBGRP to predict new phages for bacterial hosts. Specifically, PTBGRP first constructs an MHIN by integrating phage–bacteria interaction (PBI) and six bacteria–bacteria interaction networks with their biological attributes. Then, different representation learning methods are deployed to extract higher-level biological features and lower-level topological features from MHIN. Finally, PTBGRP employs a deep neural network as the classifier to predict unknown PBI pairs based on the fused biological information. Experiment results demonstrated that PTBGRP achieves the best performance on the corresponding ESKAPE pathogens and PBI dataset when compared with state-of-art methods. In addition, case studies of Klebsiella pneumoniae and Staphylococcus aureus further indicate that the consideration of rich heterogeneous information enables PTBGRP to accurately predict PBI from a more comprehensive perspective. The webserver of the PTBGRP predictor is freely available at http://120.77.11.78/PTBGRP/. [ABSTRACT FROM AUTHOR]

Published

2023