Hari Krishna Yalamanchili1, Bin Yan, Mulin Jun Li, Jing Qin, Zhongying Zhao, Francis Y L Chin, Junwen Wang. 1. Department of Biochemistry, LKS Faculty of Medicine, The University of Hong Kong, Hong Kong, Shenzhen Institute of Research and Innovation, The University of Hong Kong, Shenzhen, Department of Biology, Hong Kong Baptist University, Kowloon, Department of Computer Science, Faculty of Engineering and Centre for Genomic Sciences, LKS Faculty of Medicine, The University of Hong Kong, Hong Kong, China.
Abstract
MOTIVATION: Inferring gene-regulatory networks is very crucial in decoding various complex mechanisms in biological systems. Synthesis of a fully functional transcriptional factor/protein from DNA involves series of reactions, leading to a delay in gene regulation. The complexity increases with the dynamic delay induced by other small molecules involved in gene regulation, and noisy cellular environment. The dynamic delay in gene regulation is quite evident in high-temporal live cell lineage-imaging data. Although a number of gene-network-inference methods are proposed, most of them ignore the associated dynamic time delay. RESULTS: Here, we propose DDGni (dynamic delay gene-network inference), a novel gene-network-inference algorithm based on the gapped local alignment of gene-expression profiles. The local alignment can detect short-term gene regulations, that are usually overlooked by traditional correlation and mutual Information based methods. DDGni uses 'gaps' to handle the dynamic delay and non-uniform sampling frequency in high-temporal data, like live cell imaging data. Our algorithm is evaluated on synthetic and yeast cell cycle data, and Caenorhabditis elegans live cell imaging data against other prominent methods. The area under the curve of our method is significantly higher when compared to other methods on all three datasets. AVAILABILITY: The program, datasets and supplementary files are available at http://www.jjwanglab.org/DDGni/.
MOTIVATION: Inferring gene-regulatory networks is very crucial in decoding various complex mechanisms in biological systems. Synthesis of a fully functional transcriptional factor/protein from DNA involves series of reactions, leading to a delay in gene regulation. The complexity increases with the dynamic delay induced by other small molecules involved in gene regulation, and noisy cellular environment. The dynamic delay in gene regulation is quite evident in high-temporal live cell lineage-imaging data. Although a number of gene-network-inference methods are proposed, most of them ignore the associated dynamic time delay. RESULTS: Here, we propose DDGni (dynamic delay gene-network inference), a novel gene-network-inference algorithm based on the gapped local alignment of gene-expression profiles. The local alignment can detect short-term gene regulations, that are usually overlooked by traditional correlation and mutual Information based methods. DDGni uses 'gaps' to handle the dynamic delay and non-uniform sampling frequency in high-temporal data, like live cell imaging data. Our algorithm is evaluated on synthetic and yeast cell cycle data, and Caenorhabditis elegans live cell imaging data against other prominent methods. The area under the curve of our method is significantly higher when compared to other methods on all three datasets. AVAILABILITY: The program, datasets and supplementary files are available at http://www.jjwanglab.org/DDGni/.
Authors: Daphne Ezer; Samuel J K Shepherd; Anna Brestovitsky; Patrick Dickinson; Sandra Cortijo; Varodom Charoensawan; Mathew S Box; Surojit Biswas; Katja E Jaeger; Philip A Wigge Journal: Plant Physiol Date: 2017-09-01 Impact factor: 8.340
Authors: Hari Krishna Yalamanchili; Zhaoyuan Li; Panwen Wang; Maria P Wong; Jianfeng Yao; Junwen Wang Journal: Nucleic Acids Res Date: 2014-07-17 Impact factor: 16.971