Perturbation-based gene regulatory network inference to unravel oncogenic mechanisms [article]

Daniel Morgan, Matthew Studham, Andreas Tjärnberg, Fredrik J Swartling, Holger Weishaupt, Torbjörn E.M. Nordling, Erik L.L. Sonnhammer
2019 bioRxiv   pre-print
The gene regulatory network (GRN) of human cells encodes mechanisms to ensure proper functioning. However, if this GRN is dysregulated, the cell may enter into a disease state such as cancer. Understanding the GRN as a system can therefore help identify novel mechanisms underlying disease, which can lead to new therapies. Reliable inference of GRNs is however still a major challenge in systems biology. To deduce regulatory interactions relevant to cancer, we applied a recent computational
more » ... nce framework to data from perturbation experiments in squamous carcinoma. GRNs were inferred using several methods, and the false discovery rate was controlled by the NestBoot framework. We developed a novel approach to assess the predictiveness of inferred GRNs against validation data, despite the lack of a gold standard. The best GRN was significantly more predictive than the null model, both in crossvalidated benchmarks and for an independent dataset of the same genes under a different perturbation design. It agrees with many known links, in addition to predicting a large number of novel interactions, a subset of which were experimentally validated. The inferred GRN captures regulatory interactions central to cancer-relevant processes and thus provides mechanistic insights that are useful for future cancer research.
doi:10.1101/735514 fatcat:vtk6qsbgw5able7wjebp7hg6ei