Topological feature generation for link prediction in biological networks
Özet
Graph or network embedding is a powerful method for extracting missing or
potential information from interactions between nodes in biological networks. Graph
embedding methods learn representations of nodes and interactions in a graph with
low-dimensional vectors, which facilitates research to predict potential interactions
in networks. However, most graph embedding methods suffer from high
computational costs in the form of high computational complexity of the embedding
methods and learning times of the classifier, as well as the high dimensionality of
complex biological networks. To address these challenges, in this study, we use the
Chopper algorithm as an alternative approach to graph embedding, which
accelerates the iterative processes and thus reduces the running time of the iterative
algorithms for three different (nervous system, blood, heart) undirected
protein-protein interaction (PPI) networks. Due to the high dimensionality of the
matrix obtained after the embedding process, the data are transformed into a smaller
representation by applying feature regularization techniques. We evaluated the
performance of the proposed method by comparing it with state-of-the-art methods.
Extensive experiments demonstrate that the proposed approach reduces the learning
time of the classifier and performs better in link prediction. We have also shown that
the proposed embedding method is faster than state-of-the-art methods on three
different PPI datasets.