Hypergraph models of biological networks to identify genes critical to pathogenic viral response

Song Feng; Emily Heath; Brett Jefferson; Cliff Joslyn; Henry Kvinge; Hugh D. Mitchell; Brenda Praggastis; Amie J. Eisfeld; Amy C. Sims; Larissa B. Thackray; Shufang Fan; Kevin B. Walters; Peter J. Halfmann; Danielle Westhoff-Smith; Qing Tan; Vineet D. Menachery; Timothy P. Sheahan; Adam S. Cockrell; Jacob F. Kocher; Kelly G. Stratton; Natalie C. Heller; Lisa M. Bramer; Michael S. Diamond; Ralph S. Baric; Katrina M. Waters; Yoshihiro Kawaoka; Jason E. McDermott; Emilie Purvine

doi:10.1186/s12859-021-04197-2

Hypergraph models of biological networks to identify genes critical to pathogenic viral response

Song Feng, Emily Heath, Brett Jefferson, Cliff Joslyn, Henry Kvinge, Hugh D. Mitchell, Brenda Praggastis, Amie J. Eisfeld, Amy C. Sims, Larissa B. Thackray, Shufang Fan, Kevin B. Walters, Peter J. Halfmann, Danielle Westhoff-Smith, Qing Tan, Vineet D. Menachery, Timothy P. Sheahan, Adam S. Cockrell, Jacob F. Kocher, Kelly G. StrattonNatalie C. Heller, Lisa M. Bramer, Michael S. Diamond, Ralph S. Baric, Katrina M. Waters, Yoshihiro Kawaoka, Jason E. McDermott, Emilie Purvine

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38 Scopus citations

Abstract

Background: Representing biological networks as graphs is a powerful approach to reveal underlying patterns, signatures, and critical components from high-throughput biomolecular data. However, graphs do not natively capture the multi-way relationships present among genes and proteins in biological systems. Hypergraphs are generalizations of graphs that naturally model multi-way relationships and have shown promise in modeling systems such as protein complexes and metabolic reactions. In this paper we seek to understand how hypergraphs can more faithfully identify, and potentially predict, important genes based on complex relationships inferred from genomic expression data sets. Results: We compiled a novel data set of transcriptional host response to pathogenic viral infections and formulated relationships between genes as a hypergraph where hyperedges represent significantly perturbed genes, and vertices represent individual biological samples with specific experimental conditions. We find that hypergraph betweenness centrality is a superior method for identification of genes important to viral response when compared with graph centrality. Conclusions: Our results demonstrate the utility of using hypergraphs to represent complex biological systems and highlight central important responses in common to a variety of highly pathogenic viruses.

Original language	English (US)
Article number	287
Journal	BMC bioinformatics
Volume	22
Issue number	1
DOIs	https://doi.org/10.1186/s12859-021-04197-2
State	Published - Dec 2021
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2021, The Author(s).

Keywords

Biological networks
Host response
Hypergraph
Influenza
MERS
SARS
Systems biology
Viral infection
Viral pathogenesis
West Nile Virus

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Feng, S., Heath, E., Jefferson, B., Joslyn, C., Kvinge, H., Mitchell, H. D., Praggastis, B., Eisfeld, A. J., Sims, A. C., Thackray, L. B., Fan, S., Walters, K. B., Halfmann, P. J., Westhoff-Smith, D., Tan, Q., Menachery, V. D., Sheahan, T. P., Cockrell, A. S., Kocher, J. F., ... Purvine, E. (2021). Hypergraph models of biological networks to identify genes critical to pathogenic viral response. BMC bioinformatics, 22(1), Article 287. https://doi.org/10.1186/s12859-021-04197-2

Feng, S, Heath, E, Jefferson, B, Joslyn, C, Kvinge, H, Mitchell, HD, Praggastis, B, Eisfeld, AJ, Sims, AC, Thackray, LB, Fan, S, Walters, KB, Halfmann, PJ, Westhoff-Smith, D, Tan, Q, Menachery, VD, Sheahan, TP, Cockrell, AS, Kocher, JF, Stratton, KG, Heller, NC, Bramer, LM, Diamond, MS, Baric, RS, Waters, KM, Kawaoka, Y, McDermott, JE & Purvine, E 2021, 'Hypergraph models of biological networks to identify genes critical to pathogenic viral response', BMC bioinformatics, vol. 22, no. 1, 287. https://doi.org/10.1186/s12859-021-04197-2

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abstract = "Background: Representing biological networks as graphs is a powerful approach to reveal underlying patterns, signatures, and critical components from high-throughput biomolecular data. However, graphs do not natively capture the multi-way relationships present among genes and proteins in biological systems. Hypergraphs are generalizations of graphs that naturally model multi-way relationships and have shown promise in modeling systems such as protein complexes and metabolic reactions. In this paper we seek to understand how hypergraphs can more faithfully identify, and potentially predict, important genes based on complex relationships inferred from genomic expression data sets. Results: We compiled a novel data set of transcriptional host response to pathogenic viral infections and formulated relationships between genes as a hypergraph where hyperedges represent significantly perturbed genes, and vertices represent individual biological samples with specific experimental conditions. We find that hypergraph betweenness centrality is a superior method for identification of genes important to viral response when compared with graph centrality. Conclusions: Our results demonstrate the utility of using hypergraphs to represent complex biological systems and highlight central important responses in common to a variety of highly pathogenic viruses.",

keywords = "Biological networks, Host response, Hypergraph, Influenza, MERS, SARS, Systems biology, Viral infection, Viral pathogenesis, West Nile Virus",

author = "Song Feng and Emily Heath and Brett Jefferson and Cliff Joslyn and Henry Kvinge and Mitchell, {Hugh D.} and Brenda Praggastis and Eisfeld, {Amie J.} and Sims, {Amy C.} and Thackray, {Larissa B.} and Shufang Fan and Walters, {Kevin B.} and Halfmann, {Peter J.} and Danielle Westhoff-Smith and Qing Tan and Menachery, {Vineet D.} and Sheahan, {Timothy P.} and Cockrell, {Adam S.} and Kocher, {Jacob F.} and Stratton, {Kelly G.} and Heller, {Natalie C.} and Bramer, {Lisa M.} and Diamond, {Michael S.} and Baric, {Ralph S.} and Waters, {Katrina M.} and Yoshihiro Kawaoka and McDermott, {Jason E.} and Emilie Purvine",

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month = dec,

doi = "10.1186/s12859-021-04197-2",

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AU - Feng, Song

AU - Heath, Emily

AU - Jefferson, Brett

AU - Joslyn, Cliff

AU - Kvinge, Henry

AU - Mitchell, Hugh D.

AU - Praggastis, Brenda

AU - Eisfeld, Amie J.

AU - Sims, Amy C.

AU - Thackray, Larissa B.

AU - Fan, Shufang

AU - Walters, Kevin B.

AU - Halfmann, Peter J.

AU - Westhoff-Smith, Danielle

AU - Tan, Qing

AU - Menachery, Vineet D.

AU - Sheahan, Timothy P.

AU - Cockrell, Adam S.

AU - Kocher, Jacob F.

AU - Stratton, Kelly G.

AU - Heller, Natalie C.

AU - Bramer, Lisa M.

AU - Diamond, Michael S.

AU - Baric, Ralph S.

AU - Waters, Katrina M.

AU - Kawaoka, Yoshihiro

AU - McDermott, Jason E.

AU - Purvine, Emilie

PY - 2021/12

Y1 - 2021/12

N2 - Background: Representing biological networks as graphs is a powerful approach to reveal underlying patterns, signatures, and critical components from high-throughput biomolecular data. However, graphs do not natively capture the multi-way relationships present among genes and proteins in biological systems. Hypergraphs are generalizations of graphs that naturally model multi-way relationships and have shown promise in modeling systems such as protein complexes and metabolic reactions. In this paper we seek to understand how hypergraphs can more faithfully identify, and potentially predict, important genes based on complex relationships inferred from genomic expression data sets. Results: We compiled a novel data set of transcriptional host response to pathogenic viral infections and formulated relationships between genes as a hypergraph where hyperedges represent significantly perturbed genes, and vertices represent individual biological samples with specific experimental conditions. We find that hypergraph betweenness centrality is a superior method for identification of genes important to viral response when compared with graph centrality. Conclusions: Our results demonstrate the utility of using hypergraphs to represent complex biological systems and highlight central important responses in common to a variety of highly pathogenic viruses.

AB - Background: Representing biological networks as graphs is a powerful approach to reveal underlying patterns, signatures, and critical components from high-throughput biomolecular data. However, graphs do not natively capture the multi-way relationships present among genes and proteins in biological systems. Hypergraphs are generalizations of graphs that naturally model multi-way relationships and have shown promise in modeling systems such as protein complexes and metabolic reactions. In this paper we seek to understand how hypergraphs can more faithfully identify, and potentially predict, important genes based on complex relationships inferred from genomic expression data sets. Results: We compiled a novel data set of transcriptional host response to pathogenic viral infections and formulated relationships between genes as a hypergraph where hyperedges represent significantly perturbed genes, and vertices represent individual biological samples with specific experimental conditions. We find that hypergraph betweenness centrality is a superior method for identification of genes important to viral response when compared with graph centrality. Conclusions: Our results demonstrate the utility of using hypergraphs to represent complex biological systems and highlight central important responses in common to a variety of highly pathogenic viruses.

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KW - Host response

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KW - MERS

KW - SARS

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KW - Viral infection

KW - Viral pathogenesis

KW - West Nile Virus

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ER -

Hypergraph models of biological networks to identify genes critical to pathogenic viral response

Abstract

Bibliographical note

Keywords

UN SDGs

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