The genetic basis for the adaptation of E-coli to sugar synthesis from CO2

Elad Herz; Niv Antonovsky; Yinon Bar-On; Dan Davidi; Shmuel Gleizer; Noam Prywes; Lianet Noda-Garcia; Keren Lyn Frisch; Yehudit Zohar; David G. Wernick; Alon Savidor; Uri Barenholz; Ron Milo

doi:10.1038/s41467-017-01835-3

The genetic basis for the adaptation of E-coli to sugar synthesis from CO2

Elad Herz, Niv Antonovsky, Yinon Bar-On, Dan Davidi, Shmuel Gleizer, Noam Prywes, Lianet Noda-Garcia, Keren Lyn Frisch, Yehudit Zohar, David G. Wernick, Alon Savidor, Uri Barenholz, Ron Milo^*

^*Corresponding author for this work

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

41 Citations (Scopus)

Abstract

Understanding the evolution of a new metabolic capability in full mechanistic detail is challenging, as causative mutations may be masked by non-essential "hitchhiking" mutations accumulated during the evolutionary trajectory. We have previously used adaptive laboratory evolution of a rationally engineered ancestor to generate an Escherichia coli strain able to utilize CO2 fixation for sugar synthesis. Here, we reveal the genetic basis underlying this metabolic transition. Five mutations are sufficient to enable robust growth when a non-native Calvin-Benson-Bassham cycle provides all the sugar-derived metabolic building blocks. These mutations are found either in enzymes that affect the efflux of intermediates from the autocatalytic CO2 fixation cycle toward biomass (prs, serA, and pgi), or in key regulators of carbon metabolism (crp and ppsR). Using suppressor analysis, we show that a decrease in catalytic capacity is a common feature of all mutations found in enzymes. These findings highlight the enzymatic constraints that are essential to the metabolic stability of autocatalytic cycles and are relevant to future efforts in constructing non-native carbon fixation pathways.

Original language	English
Article number	1705
Number of pages	10
Journal	Nature Communications
Volume	8
Issue number	1
DOIs	https://doi.org/10.1038/s41467-017-01835-3
Publication status	Published - 22 Nov 2017

Funding

This work was funded by the European Research Council (projects SYMPAC 260392 and NOVCARBFIX 646827), Israel Science Foundation 740/16, Dana and Yossie Hollander, the Helmsley Charitable Foundation, the Larson Charitable Foundation, the Estate of David Arthur Barton, the Anthony Stalbow Charitable Trust, and Stella Gelerman, Canada. R.M. is the Charles and Louise Gartner professional chair. D.G.W. is supported by the United States–Israel Education Foundation. We thank Elad Noor, Arren Bar Even, Avi Flamholz, Gal Ofir, Gil Amitai, Rotem Sorek, Avigdor Eldar, Ahuva Cooperstein, Shaked Cahanovitc, Elad Itzhaki, Amit Bachar, Sagit Yahav, Lior Zelcbuch, Adar Lopez, Ghil Jona, and the bacteriology team, Shlomit Gilad, Sima Benjamin, and the INCPM genomics team, Yishai Levin, Dan Yakir, Roy Kishony, Idan Yelin, Dan Tawfik, and Tomer Shlomi. E.H., N.A., and R.M. designed the project. E.H., K.L.F., Y.Z., and L.N.-G. conducted the experiments. E.H., N.A., and Y.B.O. analyzed the sequencing data. A.S. and S.G. performed and analyzed the proteomics assay. E.H., N.A., U.B., D.D., and Y.B.O. performed the computational analysis. E.H and D.G.W performed plasmid engineering. E.H., S.G., and N.A. performed and analyzed the LC/GS–MS assays. E.H., N.A., Y.B.O., N.P., and RM wrote the paper.

All Science Journal Classification (ASJC) codes

General Chemistry
General Biochemistry,Genetics and Molecular Biology
General Physics and Astronomy

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title = "The genetic basis for the adaptation of E-coli to sugar synthesis from CO2",

abstract = "Understanding the evolution of a new metabolic capability in full mechanistic detail is challenging, as causative mutations may be masked by non-essential {"}hitchhiking{"} mutations accumulated during the evolutionary trajectory. We have previously used adaptive laboratory evolution of a rationally engineered ancestor to generate an Escherichia coli strain able to utilize CO2 fixation for sugar synthesis. Here, we reveal the genetic basis underlying this metabolic transition. Five mutations are sufficient to enable robust growth when a non-native Calvin-Benson-Bassham cycle provides all the sugar-derived metabolic building blocks. These mutations are found either in enzymes that affect the efflux of intermediates from the autocatalytic CO2 fixation cycle toward biomass (prs, serA, and pgi), or in key regulators of carbon metabolism (crp and ppsR). Using suppressor analysis, we show that a decrease in catalytic capacity is a common feature of all mutations found in enzymes. These findings highlight the enzymatic constraints that are essential to the metabolic stability of autocatalytic cycles and are relevant to future efforts in constructing non-native carbon fixation pathways.",

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AU - Gleizer, Shmuel

AU - Prywes, Noam

AU - Noda-Garcia, Lianet

AU - Frisch, Keren Lyn

AU - Zohar, Yehudit

AU - Wernick, David G.

AU - Savidor, Alon

AU - Barenholz, Uri

AU - Milo, Ron

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The genetic basis for the adaptation of E-coli to sugar synthesis from CO2

Abstract

Funding

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