Abstract
The accurate prediction of genetic networks using computational tools is one of the greatest challenges in the postgenomic era. Recurrent Neural Network is one of the most popular but simple approaches to model the network dynamics from time-series microarray data. To date, it has been successfully applied to computationally derive small-scale artificial and real-world genetic networks with high accuracy. However, they underperformed for large-scale genetic networks. Here, a new methodology has been proposed where a hybrid Cuckoo Search-Flower Pollination Algorithm has been implemented with Recurrent Neural Network. Cuckoo Search is used to search the best combination of regulators. Moreover, Flower Pollination Algorithm is applied to optimize the model parameters of the Recurrent Neural Network formalism. Initially, the proposed method is tested on a benchmark large-scale artificial network for both noiseless and noisy data. The results obtained show that the proposed methodology is capable of increasing the inference of correct regulations and decreasing false regulations to a high degree. Secondly, the proposed methodology has been validated against the real-world dataset of the DNA SOS repair network of Escherichia coli. However, the proposed method sacrifices computational time complexity in both cases due to the hybrid optimization process.
Highlights
A gene regulatory network (GRN) represents the regulatory behaviour or dependencies among a group of genes inside a cell
Flower Pollination Algorithm (FPA) is used to train the Recurrent Neural Network (RNN) parameters, and Cuckoo Search (CS) is introduced to find the biologically plausible network architecture to select the best combination of genes that are responsible for modifying the expression of each gene
The maximum connectivity of each gene is restricted to Imax as it is observed that real-life GRNs are sparsely connected; that is, very few genes participate in actual regulations
Summary
A gene regulatory network (GRN) represents the regulatory behaviour or dependencies among a group of genes inside a cell. A GRN is characterized by a directed graph in which nodes denote genes, and regulatory dependencies among genes are depicted by directed edges between the corresponding nodes. There are two types of interaction, namely, activation and inhibition. This kind of network is unique for particular functions within a cell. The study of GRN is essential to ascertain the genetic causes of a particular disease. As a consequence of this, scientists can venture into the development of new and improved techniques for the treatment of a disease [1]
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