Computational Identification of Gene Networks As a Biomarker of Neuroblastoma Risk

Overview

Journal Cancers (Basel)

Publisher MDPI

Specialty Oncology

Date 2020 Aug 1

PMID 32731407

Citations 3

Authors

Lidan Sun

Libo Jiang

Christa N Grant

Hong-Gang Wang

Claudia Gragnoli

Zhenqiu Liu

Rongling Wu

Affiliations

Soon will be listed here.

Abstract

Neuroblastoma is a common cancer in children, affected by a number of genes that interact with each other through intricate but coordinated networks. Traditional approaches can only reconstruct a single regulatory network that is topologically not informative enough to explain the complexity of neuroblastoma risk. We implemented and modified an advanced model for recovering informative, omnidirectional, dynamic, and personalized networks (idopNetworks) from static gene expression data for neuroblastoma risk. We analyzed 3439 immune genes of neuroblastoma for 217 high-risk patients and 30 low-risk patients by which to reconstruct large patient-specific idopNetworks. By converting these networks into risk-specific representations, we found that the shift in patients from a low to high risk or from a high to low risk might be due to the reciprocal change of hub regulators. By altering the directions of regulation exerted by these hubs, it may be possible to reduce a high risk to a low risk. Results from a holistic, systems-oriented paradigm through idopNetworks can potentially enable oncologists to experimentally identify the biomarkers of neuroblastoma and other cancers.

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