SLGNN: synthetic lethality prediction in human cancers based on factor-aware knowledge graph neural network
Original Paper
Drug Development
Neoplasms
0206 medical engineering
Humans
Neural Networks, Computer
02 engineering and technology
Synthetic Lethal Mutations
3. Good health
004
Pattern Recognition, Automated
DOI:
10.1093/bioinformatics/btad015
Publication Date:
2023-01-16T13:37:14Z
AUTHORS (5)
ABSTRACT
Abstract
Motivation
Synthetic lethality (SL) is a form of genetic interaction that can selectively kill cancer cells without damaging normal cells. Exploiting this mechanism is gaining popularity in the field of targeted cancer therapy and anticancer drug development. Due to the limitations of identifying SL interactions from laboratory experiments, an increasing number of research groups are devising computational prediction methods to guide the discovery of potential SL pairs. Although existing methods have attempted to capture the underlying mechanisms of SL interactions, methods that have a deeper understanding of and attempt to explain SL mechanisms still need to be developed.
Results
In this work, we propose a novel SL prediction method, SLGNN. This method is based on the following assumption: SL interactions are caused by different molecular events or biological processes, which we define as SL-related factors that lead to SL interactions. SLGNN, apart from identifying SL interaction pairs, also models the preferences of genes for different SL-related factors, making the results more interpretable for biologists and clinicians. SLGNN consists of three steps: first, we model the combinations of relationships in the gene-related knowledge graph as the SL-related factors. Next, we derive initial embeddings of genes through an explicit message aggregation process of the knowledge graph. Finally, we derive the final gene embeddings through an SL graph, constructed using known SL gene pairs, utilizing factor-based message aggregation. At this stage, a supervised end-to-end training model is used for SL interaction prediction. Based on experimental results, the proposed SLGNN model outperforms all current state-of-the-art SL prediction methods and provides better interpretability.
Availability and implementation
SLGNN is freely available at https://github.com/zy972014452/SLGNN.
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