TY - JOUR
T1 - Design and in vitro realization of carbon-conserving photorespiration
AU - Trudeau, Devin L.
AU - Edlich-Muth, Christian
AU - Zarzycki, Jan
AU - Scheffen, Marieke
AU - Goldsmith, Moshe
AU - Khersonsky, Olga
AU - Avizemer, Ziv
AU - Fleishman, Sarel J.
AU - Cotton, Charles A. R.
AU - Erb, Tobias J.
AU - Tawfik, Dan S.
AU - Bar-Even, Arren
N1 - We thank Pascal Pfister for collecting X-ray data at beamline P13 operated by European Molecular Biology Laboratory Hamburg at the PETRA III storage ring Deutsches Elektronen-Synchrotron (DESY) and on beamline ID30B at the European Synchrotron Radiation Facility (ESRF). We thank Guillaume Pompidor at DESY for assistance with beamline P13 and Gianluca Santoni at the ESRF for assistance with beamline ID30B. We also thank Kesava Cherukuri for assistance with LC-MS and chemical synthesis. This study is funded by the Max Planck Society (C.E.-M., C.A.R.C., and A.B.-E.) and the European Union’s Horizon 2020 FET Programme Grant 686330 (FutureAgriculture). D.L.T. was supported by the Alternative Energy Research Initiative at the Weizmann Institute of Science and a fellowship from the Azrieli Foundation. D.S.T. is the Nella and Leo Benoziyo Professor of Biochemistry. D.L.T. and C.E.-M. contributed equally to this work. Author contributions: D.L.T., C.E.-M., T.J.E., D.S.T., and A.B.-E. designed research; D.L.T., C.E.-M., J.Z., M.S., M.G., O.K., and Z.A. performed research; M.S. contributed new reagents/analytic tools; D.L.T., C.E.-M., J.Z., M.S., S.J.F., T.J.E., D.S.T., and A.B.-E. analyzed data; and D.L.T., C.E.-M., C.A.R.C., D.S.T., and A.B.-E. wrote the paper.
PY - 2018/12/4
Y1 - 2018/12/4
N2 - Photorespiration recycles ribulose-1,5-bisphosphate carboxylase/oxygenase ( Rubisco) oxygenation product, 2-phosphoglycolate, back into the Calvin Cycle. Natural photorespiration, however, limits agricultural productivity by dissipating energy and releasing CO2. Several photorespiration bypasses have been previously suggested but were limited to existing enzymes and pathways that release CO2. Here, we harness the power of enzyme and metabolic engineering to establish synthetic routes that bypass photorespiration without CO2 release. By defining specific reaction rules, we systematically identified promising routes that assimilate 2-phosphoglycolate into the Calvin Cycle without carbon loss. We further developed a kinetic-stoichiometric model that indicates that the identified synthetic shunts could potentially enhance carbon fixation rate across the physiological range of irradiation and CO2, even if most of their enzymes operate at a tenth of Rubisco's maximal carboxylation activity. Glycolate reduction to glycolaldehyde is essential for several of the synthetic shunts but is not known to occur naturally. We, therefore, used computational design and directed evolution to establish this activity in two sequential reactions. An acetyl-CoA synthetase was engineered for higher stability and glycolyl-CoA synthesis. A propionyl-CoA reductase was engineered for higher selectivity for glycolyl-CoA and for use of NADPH over NAD(+), thereby favoring reduction over oxidation. The engineered glycolate reduction module was then combined with downstream condensation and assimilation of glycolaldehyde to ribulose 1,5-bisphosphate, thus providing proof of principle for a carbonconserving photorespiration pathway.
AB - Photorespiration recycles ribulose-1,5-bisphosphate carboxylase/oxygenase ( Rubisco) oxygenation product, 2-phosphoglycolate, back into the Calvin Cycle. Natural photorespiration, however, limits agricultural productivity by dissipating energy and releasing CO2. Several photorespiration bypasses have been previously suggested but were limited to existing enzymes and pathways that release CO2. Here, we harness the power of enzyme and metabolic engineering to establish synthetic routes that bypass photorespiration without CO2 release. By defining specific reaction rules, we systematically identified promising routes that assimilate 2-phosphoglycolate into the Calvin Cycle without carbon loss. We further developed a kinetic-stoichiometric model that indicates that the identified synthetic shunts could potentially enhance carbon fixation rate across the physiological range of irradiation and CO2, even if most of their enzymes operate at a tenth of Rubisco's maximal carboxylation activity. Glycolate reduction to glycolaldehyde is essential for several of the synthetic shunts but is not known to occur naturally. We, therefore, used computational design and directed evolution to establish this activity in two sequential reactions. An acetyl-CoA synthetase was engineered for higher stability and glycolyl-CoA synthesis. A propionyl-CoA reductase was engineered for higher selectivity for glycolyl-CoA and for use of NADPH over NAD(+), thereby favoring reduction over oxidation. The engineered glycolate reduction module was then combined with downstream condensation and assimilation of glycolaldehyde to ribulose 1,5-bisphosphate, thus providing proof of principle for a carbonconserving photorespiration pathway.
UR - http://www.scopus.com/inward/record.url?scp=85057614578&partnerID=8YFLogxK
U2 - https://doi.org/10.1073/pnas.1812605115
DO - https://doi.org/10.1073/pnas.1812605115
M3 - مقالة
SN - 0027-8424
VL - 115
SP - E11455-E11464
JO - Proceedings Of The National Academy Of Sciences Of The United States Of America-Physical Sciences
JF - Proceedings Of The National Academy Of Sciences Of The United States Of America-Physical Sciences
IS - 49
ER -