PathExt: a General Framework for Path-based Mining of Omics-integrated Biological Networks

Overview

Journal Bioinformatics

Publisher Oxford University Press

Specialty Biology

Date 2020 Dec 11

PMID 33305329

Citations 9

Authors

Narmada Sambaturu

Vaidehi Pusadkar

Sridhar Hannenhalli

Nagasuma Chandra

Affiliations

Soon will be listed here.

Abstract

Motivation: Transcriptomes are routinely used to prioritize genes underlying specific phenotypes. Current approaches largely focus on differentially expressed genes (DEGs), despite the recognition that phenotypes emerge via a network of interactions between genes and proteins, many of which may not be differentially expressed. Furthermore, many practical applications lack sufficient samples or an appropriate control to robustly identify statistically significant DEGs.

Results: We provide a computational tool-PathExt, which, in contrast to differential genes, identifies differentially active paths when a control is available, and most active paths otherwise, in an omics-integrated biological network. The sub-network comprising such paths, referred to as the TopNet, captures the most relevant genes and processes underlying the specific biological context. The TopNet forms a well-connected graph, reflecting the tight orchestration in biological systems. Two key advantages of PathExt are (i) it can extract characteristic genes and pathways even when only a single sample is available, and (ii) it can be used to study a system even in the absence of an appropriate control. We demonstrate the utility of PathExt via two diverse sets of case studies, to characterize (i) Mycobacterium tuberculosis response upon exposure to 18 antibacterial drugs where only one transcriptomic sample is available for each exposure; and (ii) tissue-relevant genes and processes using transcriptomic data for 39 human tissues. Overall, PathExt is a general tool for prioritizing context-relevant genes in any omics-integrated biological network for any condition(s) of interest, even with a single sample or in the absence of appropriate controls.

Availabilityand Implementation: The source code for PathExt is available at https://github.com/NarmadaSambaturu/PathExt.

Supplementary Information: Supplementary data are available at Bioinformatics online.

Citing Articles

Protocol for identifying key genes using network-based approach as an alternative to differential expression analysis.

Agrawal P, Hannenhalli S STAR Protoc. 2024; 5(4):103472.

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Network-based approach elucidates critical genes in BRCA subtypes and chemotherapy response in triple negative breast cancer.

Agrawal P, Jain N, Gopalan V, Timon A, Singh A, Rajagopal P iScience. 2024; 27(5):109752.

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Systems-level profiling of early peripheral host-response landscape variations across COVID-19 severity states in an Indian cohort.

Banerjee U, Chunchanur S, R A, Balaji K, Singh A, Chakravortty D Genes Immun. 2023; 24(4):183-193.

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Identification of Probucol as a candidate for combination therapy with Metformin for Type 2 diabetes.

Guttapadu R, Korla K, Uk S, Annam V, Ashok P, Chandra N NPJ Syst Biol Appl. 2023; 9(1):18.

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Guttapadu R, Prakash N, M A, Chatterjee R, S M, M J PLoS Negl Trop Dis. 2023; 17(4):e0011263.

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