Design principles of autocatalytic cycles constrain enzyme kinetics and force low substrate saturation at flux branch points

Uri Barenholz; Dan Davidi; Ed Reznik; Yinon Bar-On; Niv Antonovsky; Elad Noor; Ron Milo

doi:10.7554/eLife.20667

Design principles of autocatalytic cycles constrain enzyme kinetics and force low substrate saturation at flux branch points

Uri Barenholz, Dan Davidi, Ed Reznik, Yinon Bar-On, Niv Antonovsky, Elad Noor, Ron Milo

Department of Plant and Environmental Sciences

Weizmann Institute of Science

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

Abstract

A set of chemical reactions that require a metabolite to synthesize more of that metabolite is an autocatalytic cycle. Here, we show that most of the reactions in the core of central carbon metabolism are part of compact autocatalytic cycles. Such metabolic designs must meet specific conditions to support stable fluxes, hence avoiding depletion of intermediate metabolites. As such, they are subjected to constraints that may seem counter-intuitive: the enzymes of branch reactions out of the cycle must be overexpressed and the affinity of these enzymes to their substrates must be relatively weak. We use recent quantitative proteomics and fluxomics measurements to show that the above conditions hold for functioning cycles in central carbon metabolism of E. coli. This work demonstrates that the topology of a metabolic network can shape kinetic parameters of enzymes and lead to seemingly wasteful enzyme usage.

Original language	English
Article number	20667
Number of pages	32
Journal	eLife
Volume	6
DOIs	https://doi.org/10.7554/eLife.20667
State	Published - 7 Feb 2017

All Science Journal Classification (ASJC) codes

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

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10.7554/eLife.20667License: CC BY

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title = "Design principles of autocatalytic cycles constrain enzyme kinetics and force low substrate saturation at flux branch points",

abstract = "A set of chemical reactions that require a metabolite to synthesize more of that metabolite is an autocatalytic cycle. Here, we show that most of the reactions in the core of central carbon metabolism are part of compact autocatalytic cycles. Such metabolic designs must meet specific conditions to support stable fluxes, hence avoiding depletion of intermediate metabolites. As such, they are subjected to constraints that may seem counter-intuitive: the enzymes of branch reactions out of the cycle must be overexpressed and the affinity of these enzymes to their substrates must be relatively weak. We use recent quantitative proteomics and fluxomics measurements to show that the above conditions hold for functioning cycles in central carbon metabolism of E. coli. This work demonstrates that the topology of a metabolic network can shape kinetic parameters of enzymes and lead to seemingly wasteful enzyme usage.",

author = "Uri Barenholz and Dan Davidi and Ed Reznik and Yinon Bar-On and Niv Antonovsky and Elad Noor and Ron Milo",

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AU - Barenholz, Uri

AU - Davidi, Dan

AU - Reznik, Ed

AU - Bar-On, Yinon

AU - Antonovsky, Niv

AU - Noor, Elad

AU - Milo, Ron

N1 - Israel Science Foundation [740/16]; Beck-Canadian Center for Alternative Energy Research; Leona M. and Harry B. Helmsley Charitable Trust; The Larson Charitable Foundation; Wolfson Family Charitable Trust; Alternative Sustainable Energy Research Initiative Graduate Student Fellowship; European Research Council [NOVCARBFIX 646827] Israel Science Foundation 740/16 Uri Barenholz Dan Davidi Yinon Bar-On Niv Antonovsky Ron Milo; Beck-Canadian Center for Alternative Energy Research Uri Barenholz Dan Davidi Yinon Bar-On Niv Antonovsky Ron Milo; Dana and Yossie Hollander Uri Barenholz Dan Davidi Yinon Bar-On Niv Antonovsky Ron Milo; Leona M. and Harry B. Helmsley Charitable Trust Uri Barenholz Dan Davidi Yinon Bar-On Niv Antonovsky Ron Milo; The Larson Charitable Foundation Uri Barenholz Dan Davidi Yinon Bar-On Niv Antonovsky Ron Milo; Wolfson Family Charitable Trust Uri Barenholz Dan Davidi Yinon Bar-On Niv Antonovsky Ron Milo Charles Rothchild Uri Barenholz Dan Davidi Yinon Bar-On Niv Antonovsky Ron Milo; Selmo Nussenbaum Uri Barenholz Dan Davidi Yinon Bar-On Niv Antonovsky Ron Milo; Alternative Sustainable Energy Research Initiative Graduate Student Fellowship Uri Barenholz; European Research Council NOVCARBFIX 646827 Uri Barenholz Dan Davidi Yinon Bar-On Niv Antonovsky Ron Milo

PY - 2017/2/7

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N2 - A set of chemical reactions that require a metabolite to synthesize more of that metabolite is an autocatalytic cycle. Here, we show that most of the reactions in the core of central carbon metabolism are part of compact autocatalytic cycles. Such metabolic designs must meet specific conditions to support stable fluxes, hence avoiding depletion of intermediate metabolites. As such, they are subjected to constraints that may seem counter-intuitive: the enzymes of branch reactions out of the cycle must be overexpressed and the affinity of these enzymes to their substrates must be relatively weak. We use recent quantitative proteomics and fluxomics measurements to show that the above conditions hold for functioning cycles in central carbon metabolism of E. coli. This work demonstrates that the topology of a metabolic network can shape kinetic parameters of enzymes and lead to seemingly wasteful enzyme usage.

AB - A set of chemical reactions that require a metabolite to synthesize more of that metabolite is an autocatalytic cycle. Here, we show that most of the reactions in the core of central carbon metabolism are part of compact autocatalytic cycles. Such metabolic designs must meet specific conditions to support stable fluxes, hence avoiding depletion of intermediate metabolites. As such, they are subjected to constraints that may seem counter-intuitive: the enzymes of branch reactions out of the cycle must be overexpressed and the affinity of these enzymes to their substrates must be relatively weak. We use recent quantitative proteomics and fluxomics measurements to show that the above conditions hold for functioning cycles in central carbon metabolism of E. coli. This work demonstrates that the topology of a metabolic network can shape kinetic parameters of enzymes and lead to seemingly wasteful enzyme usage.

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M3 - مقالة

SN - 2050-084X

VL - 6

JO - eLife

JF - eLife

M1 - 20667

ER -

Design principles of autocatalytic cycles constrain enzyme kinetics and force low substrate saturation at flux branch points

Abstract

All Science Journal Classification (ASJC) codes

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