Thomas Bartlett1. 1. University College London, Gower Street, London, WC1E 6BT, UK. thomas.bartlett.10@ucl.ac.uk.
Abstract
BACKGROUND: Network models are well-established as very useful computational-statistical tools in cell biology. However, a genomic network model based only on gene expression data can, by definition, only infer gene co-expression networks. Hence, in order to infer gene regulatory patterns, it is necessary to also include data related to binding of regulatory factors to DNA. RESULTS: We propose a new dynamic genomic network model, for inferring patterns of genomic regulatory influence in dynamic processes such as development. Our model fuses experiment-specific gene expression data with publicly available DNA-binding data. The method we propose is computationally efficient, and can be applied to genome-wide data with tens of thousands of transcripts. Thus, our method is well suited for use as an exploratory tool for genome-wide data. We apply our method to data from human fetal cortical development, and our findings confirm genomic regulatory patterns which are recognised as being fundamental to neuronal development. CONCLUSIONS: Our method provides a mathematical/computational toolbox which, when coupled with targeted experiments, will reveal and confirm important new functional genomic regulatory processes in mammalian development.
BACKGROUND: Network models are well-established as very useful computational-statistical tools in cell biology. However, a genomic network model based only on gene expression data can, by definition, only infer gene co-expression networks. Hence, in order to infer gene regulatory patterns, it is necessary to also include data related to binding of regulatory factors to DNA. RESULTS: We propose a new dynamic genomic network model, for inferring patterns of genomic regulatory influence in dynamic processes such as development. Our model fuses experiment-specific gene expression data with publicly available DNA-binding data. The method we propose is computationally efficient, and can be applied to genome-wide data with tens of thousands of transcripts. Thus, our method is well suited for use as an exploratory tool for genome-wide data. We apply our method to data from human fetal cortical development, and our findings confirm genomic regulatory patterns which are recognised as being fundamental to neuronal development. CONCLUSIONS: Our method provides a mathematical/computational toolbox which, when coupled with targeted experiments, will reveal and confirm important new functional genomic regulatory processes in mammalian development.
Authors: Christopher A Jackson; Dayanne M Castro; Richard Bonneau; David Gresham; Giuseppe-Antonio Saldi Journal: Elife Date: 2020-01-27 Impact factor: 8.140
Authors: Tomasz J Nowakowski; Aparna Bhaduri; Alex A Pollen; Beatriz Alvarado; Mohammed A Mostajo-Radji; Elizabeth Di Lullo; Maximilian Haeussler; Carmen Sandoval-Espinosa; Siyuan John Liu; Dmitry Velmeshev; Johain Ryad Ounadjela; Joe Shuga; Xiaohui Wang; Daniel A Lim; Jay A West; Anne A Leyrat; W James Kent; Arnold R Kriegstein Journal: Science Date: 2017-12-08 Impact factor: 47.728