Prediction of enzymatic pathways by integrative pathway mapping

Sara Calhoun; Magdalena Korczynska; Daniel J. Wichelecki; Brian San Francisco; Suwen Zhao; Dmitry A. Rodionov; Matthew W. Vetting; Nawar F. Al-Obaidi; Henry Lin; Matthew J. O’Meara; David A. Scott; John H. Morris; Daniel Russel; Steven C. Almo; Andrei L. Osterman; John A. Gerlt; Matthew P. Jacobson; Brian K. Shoichet; Andrej Sali

doi:10.7554/eLife.31097

Prediction of enzymatic pathways by integrative pathway mapping

Sara Calhoun, Magdalena Korczynska, Daniel J. Wichelecki, Brian San Francisco, Suwen Zhao, Dmitry A. Rodionov, Matthew W. Vetting, Nawar F. Al-Obaidi, Henry Lin, Matthew J. O’Meara, David A. Scott, John H. Morris, Daniel Russel, Steven C. Almo, Andrei L. Osterman, John A. Gerlt, Matthew P. Jacobson, Brian K. Shoichet, Andrej Sali

Biochemistry

Research output: Contribution to journal › Article › peer-review

28 Scopus citations

Abstract

The functions of most proteins are yet to be determined. The function of an enzyme is often defined by its interacting partners, including its substrate and product, and its role in larger metabolic networks. Here, we describe a computational method that predicts the functions of orphan enzymes by organizing them into a linear metabolic pathway. Given candidate enzyme and metabolite pathway members, this aim is achieved by finding those pathways that satisfy structural and network restraints implied by varied input information, including that from virtual screening, chemoinformatics, genomic context analysis, and ligand -binding experiments. We demonstrate this integrative pathway mapping method by predicting the L-gulonate catabolic pathway in Haemophilus influenzae Rd KW20. The prediction was subsequently validated experimentally by enzymology, crystallography, and metabolomics. Integrative pathway mapping by satisfaction of structural and network restraints is extensible to molecular networks in general and thus formally bridges the gap between structural biology and systems biology.

Original language	English (US)
Article number	e31097
Journal	eLife
Volume	7
DOIs	https://doi.org/10.7554/eLife.31097
State	Published - Jan 29 2018

ASJC Scopus subject areas

General Neuroscience
General Biochemistry, Genetics and Molecular Biology
General Immunology and Microbiology

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10.7554/eLife.31097

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Calhoun, S., Korczynska, M., Wichelecki, D. J., San Francisco, B., Zhao, S., Rodionov, D. A., Vetting, M. W., Al-Obaidi, N. F., Lin, H., O’Meara, M. J., Scott, D. A., Morris, J. H., Russel, D., Almo, S. C., Osterman, A. L., Gerlt, J. A., Jacobson, M. P., Shoichet, B. K., & Sali, A. (2018). Prediction of enzymatic pathways by integrative pathway mapping. eLife, 7, Article e31097. https://doi.org/10.7554/eLife.31097

Calhoun, S, Korczynska, M, Wichelecki, DJ, San Francisco, B, Zhao, S, Rodionov, DA, Vetting, MW, Al-Obaidi, NF, Lin, H, O’Meara, MJ, Scott, DA, Morris, JH, Russel, D, Almo, SC, Osterman, AL, Gerlt, JA, Jacobson, MP, Shoichet, BK & Sali, A 2018, 'Prediction of enzymatic pathways by integrative pathway mapping', eLife, vol. 7, e31097. https://doi.org/10.7554/eLife.31097

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title = "Prediction of enzymatic pathways by integrative pathway mapping",

abstract = "The functions of most proteins are yet to be determined. The function of an enzyme is often defined by its interacting partners, including its substrate and product, and its role in larger metabolic networks. Here, we describe a computational method that predicts the functions of orphan enzymes by organizing them into a linear metabolic pathway. Given candidate enzyme and metabolite pathway members, this aim is achieved by finding those pathways that satisfy structural and network restraints implied by varied input information, including that from virtual screening, chemoinformatics, genomic context analysis, and ligand -binding experiments. We demonstrate this integrative pathway mapping method by predicting the L-gulonate catabolic pathway in Haemophilus influenzae Rd KW20. The prediction was subsequently validated experimentally by enzymology, crystallography, and metabolomics. Integrative pathway mapping by satisfaction of structural and network restraints is extensible to molecular networks in general and thus formally bridges the gap between structural biology and systems biology.",

author = "Sara Calhoun and Magdalena Korczynska and Wichelecki, {Daniel J.} and {San Francisco}, Brian and Suwen Zhao and Rodionov, {Dmitry A.} and Vetting, {Matthew W.} and Al-Obaidi, {Nawar F.} and Henry Lin and O{\textquoteright}Meara, {Matthew J.} and Scott, {David A.} and Morris, {John H.} and Daniel Russel and Almo, {Steven C.} and Osterman, {Andrei L.} and Gerlt, {John A.} and Jacobson, {Matthew P.} and Shoichet, {Brian K.} and Andrej Sali",

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AU - Calhoun, Sara

AU - Korczynska, Magdalena

AU - Wichelecki, Daniel J.

AU - San Francisco, Brian

AU - Zhao, Suwen

AU - Rodionov, Dmitry A.

AU - Vetting, Matthew W.

AU - Al-Obaidi, Nawar F.

AU - Lin, Henry

AU - O’Meara, Matthew J.

AU - Scott, David A.

AU - Morris, John H.

AU - Russel, Daniel

AU - Almo, Steven C.

AU - Osterman, Andrei L.

AU - Gerlt, John A.

AU - Jacobson, Matthew P.

AU - Shoichet, Brian K.

AU - Sali, Andrej

PY - 2018/1/29

Y1 - 2018/1/29

N2 - The functions of most proteins are yet to be determined. The function of an enzyme is often defined by its interacting partners, including its substrate and product, and its role in larger metabolic networks. Here, we describe a computational method that predicts the functions of orphan enzymes by organizing them into a linear metabolic pathway. Given candidate enzyme and metabolite pathway members, this aim is achieved by finding those pathways that satisfy structural and network restraints implied by varied input information, including that from virtual screening, chemoinformatics, genomic context analysis, and ligand -binding experiments. We demonstrate this integrative pathway mapping method by predicting the L-gulonate catabolic pathway in Haemophilus influenzae Rd KW20. The prediction was subsequently validated experimentally by enzymology, crystallography, and metabolomics. Integrative pathway mapping by satisfaction of structural and network restraints is extensible to molecular networks in general and thus formally bridges the gap between structural biology and systems biology.

AB - The functions of most proteins are yet to be determined. The function of an enzyme is often defined by its interacting partners, including its substrate and product, and its role in larger metabolic networks. Here, we describe a computational method that predicts the functions of orphan enzymes by organizing them into a linear metabolic pathway. Given candidate enzyme and metabolite pathway members, this aim is achieved by finding those pathways that satisfy structural and network restraints implied by varied input information, including that from virtual screening, chemoinformatics, genomic context analysis, and ligand -binding experiments. We demonstrate this integrative pathway mapping method by predicting the L-gulonate catabolic pathway in Haemophilus influenzae Rd KW20. The prediction was subsequently validated experimentally by enzymology, crystallography, and metabolomics. Integrative pathway mapping by satisfaction of structural and network restraints is extensible to molecular networks in general and thus formally bridges the gap between structural biology and systems biology.

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Prediction of enzymatic pathways by integrative pathway mapping

Abstract

ASJC Scopus subject areas

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