Gene regulatory network inference: evaluation and application to ovarian cancer allows the prioritization of drug targets

Madhamshettiwar, Piyush B.; Maetschke, Stefan; Davis, Melissa J.; Reverter, Antônio; Ragan, Mark A.

doi:10.1186/gm340

Cited by 148 publications

(102 citation statements)

References 80 publications

(97 reference statements)

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“…Deciphering GRNs from rapidly growing microarray expression databases has been shown to be a very promising approach e.g. in cancer research [16,17]. Many tools are emerging and have been used for constructing, inferring and analyzing such GRNs.…”

Section: Gene Regulatory Networkmentioning

confidence: 99%

On Different Aspects of Network Analysis in Systems Biology

et al. 2013

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Network analysis is an essential component of systems biology approaches toward understanding the molecular and cellular interactions underlying biological systems functionalities and their perturbations in disease. Regulatory and signalling pathways involve DNA, RNA, proteins and metabolites as key elements to coordinate most aspects of cellular functioning. Cellular processes depend on the structure and dynamics of gene regulatory networks and can be studied by employing a network representation of molecular interactions. This chapter describes several types of biological networks, how combination of different analytic approaches can be used to study diseases, and provides a list of selected tools for network visualization and analysis. It also introduces proteinprotein interaction networks, gene regulatory networks, signalling networks and metabolic networks to illustrate concepts underlying network representation of cellular processes and molecular interactions. It finally discusses how the level of An erratum to this chapter is available at

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Section: Gene Regulatory Networkmentioning

confidence: 99%

On Different Aspects of Network Analysis in Systems Biology

et al. 2013

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“…Phenotype to genotype research has produced informatics resources such as the Phenoscape Knowledgebase (Phenoscape KB; http://kb.phenoscape.org) [14] and the Phenotype-Genotype Integrator (PhenGenI; www.ncbi.nlm.nih.gov/gap/phegeni) [20]; researchers using these resources have been able to verify key phenotype-genotype relationships [19]. Many tools also exist for the reverse engineering of GRNs from microarray datasets [15][25] [16]. Networks obtained from reverse engineered microarrays or next generation sequencing (NGS) datasets constitute a big knowledge opportunity for studying the connections between intracellular systems, metabolic interaction models, and transcriptomics [7].…”

Section: Introductionmentioning

confidence: 99%

Pheno2GRN

Weinandt

Jackson

Gnimpieba

et al. 2014

Proceedings of the 5th ACM Conference on Bioinformatics, Computational Biology, and Health Informatics

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While efforts have been made to both retrieve genes associated with a phenotype, and model gene regulatory networks (GRNs), no such progress has been made regarding the creation of GRNs from phenotype keywords and reverse engineered large-scale gene expression datasets, such as microarray data. In this work, we describe a Java web application called Pheno2GRN (available at http://jacksons.usd.edu/Pheno2GRN), which allows users to select a phenotype keyword and be presented with a visualization of the GRN associated with the phenotype. The GRN created from the phenotype can be compared with one reverse engineered from microarray datasets. Pheno2GRN also incorporates analytic tools for modeling phenotype gene intersections and gathers all results in a useful, downloadable reporting section.

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“…However, it has been shown that including other kinds of information leads to biologically more accurate results [5]. Of great interest is the Machine Learning category, under which are included algorithms based on Random Forest (GENIE3 [6]), Support Vector Machines (SVM) (SIRENE [7]) and Neural Networks (ENFRN [8]), because by construction these methods can embed a priori knowledge.…”

Section: Introductionmentioning

confidence: 99%

Supervised method for construction of microRNA-mRNA networks: Application in cardiac tissue aging dataset

Dimitrakopoulos

Dimitrakopoulou

Maraziotis

et al. 2014

2014 36th Annual International Conference of the IEEE Engineering in Medicine and Biology Society

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MicroRNAs play an important role in regulation of gene expression, but still detection of their targets remains a challenge. In this work we present a supervised regulatory network inference method with aim to identify potential target genes (mRNAs) of microRNAs. Briefly, the proposed method exploiting mRNA and microRNA expression trains Random Forests on known interactions and subsequently it is able to predict novel ones. In parallel, we incorporate different available data sources, such as Gene Ontology and ProteinProtein Interactions, to deliver biologically consistent results. Application in both benchmark data and an experiment studying aging showed robust performance.

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Gene regulatory network inference: evaluation and application to ovarian cancer allows the prioritization of drug targets

Cited by 148 publications

References 80 publications

On Different Aspects of Network Analysis in Systems Biology

On Different Aspects of Network Analysis in Systems Biology

Pheno2GRN

Supervised method for construction of microRNA-mRNA networks: Application in cardiac tissue aging dataset

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