Network-based prediction approach for cancer-specific driver missense mutations using a graph neural network

Background In cancer genomic medicine, finding driver mutations involved in cancer development and tumor growth is crucial.

Machine-learning methods to predict driver missense mutations have been developed because variants are frequently detected by genomic sequencing.

However, even though the abnormalities in molecular networks are associated with cancer, many of these methods focus on individual variants and do not consider molecular networks.

Here we propose a new network-based method, Net-DMPred, to predict driver missense mutations considering molecular networks.

Net-DMPred consists of the graph part and the prediction part.

In the graph part, molecular networks are learned by a graph neural network (GNN).

The prediction part learns whether variants are driver variants using features of individual variants combined with the graph features learned in the graph part.

Results Net-DMPred, which considers molecular networks, performed better than conventional methods.

Furthermore, the prediction performance differed by the molecular network structure used in learning, suggesting that it is important to consider not only the local network related to cancer but also the large-scale network in living organisms.

Conclusions We propose a network-based machine learning method, Net-DMPred, for predicting cancer driver missense mutations.

Our method enables us to consider the entire graph architecture representing the molecular network because it uses GNN.

Net-DMPred is expected to detect driver mutations from a lot of missense mutations that are not known to be associated with cancer.