A Synthetic Facultative CAM-Like Shuttle in C3 Rice Plants

Suting Wu; Kaining Jin; Haoshu Li; Guoxin Chen; Liying Zhang; Jinwen Yang; Shanshan Zhai; Yanni Li; Xuehui Sun; Xuean Cui; Jing Sun; Tiegang Lu; Zhiguo Zhang

doi:10.1002/advs.202500418

A Synthetic Facultative CAM-Like Shuttle in C₃ Rice Plants

Suting Wu, Kaining Jin, Haoshu Li, Guoxin Chen, Liying Zhang, Jinwen Yang, Shanshan Zhai, Yanni Li, Xuehui Sun, Xuean Cui, Jing Sun, Tiegang Lu^*, Zhiguo Zhang^*

^*Corresponding author for this work

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

Abstract

Crassulacean acid metabolism (CAM) is one of the three major forms of photosynthesis, known for its efficient carbon sequestration mechanism. CAM plants store malate at night, which undergoes decarboxylation and promotes Rubisco carboxylation during the day. Despite its potential benefits, CAM engineering is not applied to C₃ crops. This paper introduces a designed facultative CAM bypass (CBP) in rice by incorporating codon-optimized nocturnal carboxylation and decarboxylation modules, a malate transporter module, and a stomatal regulation module using the transgene stacking system. The CBP plants are correctly assembled by detection at the gene level, transcription level, protein level, and enzyme activity. Malate, CAM metabolism product, accumulated significantly at night in CBP plants. Metabolic analysis revealed that the malate is directed to the citric acid cycle and impacted carbon sequestration. The CBP plants showed a significant increase of ≈21% and ≈27% in photosynthetic rate and carboxylation efficiency, respectively. Additionally, CBP plants exhibited ≈20% increase in grain yield and biomass over the 2-year field trials. Unexpectedly, the water use efficiency and drought resistance do not improve in CBP plants. This study is the first to attempt CAM engineering in C₃ and demonstrates the potential of facultative CAM carbon sequestration in rice.

Original language	English
Number of pages	15
Journal	Advanced Science
DOIs	https://doi.org/10.1002/advs.202500418
Publication status	E-pub ahead of print - 7 Feb 2025

Keywords

C rice
carbon sequestration
crassulacean acid metabolism
multi-transgene stacking systems

Access to Document

10.1002/advs.202500418Licence: CC BY

https://edepot.wur.nl/688421Licence: CC BY

Cite this

@article{098bc2187e4d4fd5936f47c6f401a797,

title = "A Synthetic Facultative CAM-Like Shuttle in C3 Rice Plants",

abstract = "Crassulacean acid metabolism (CAM) is one of the three major forms of photosynthesis, known for its efficient carbon sequestration mechanism. CAM plants store malate at night, which undergoes decarboxylation and promotes Rubisco carboxylation during the day. Despite its potential benefits, CAM engineering is not applied to C3 crops. This paper introduces a designed facultative CAM bypass (CBP) in rice by incorporating codon-optimized nocturnal carboxylation and decarboxylation modules, a malate transporter module, and a stomatal regulation module using the transgene stacking system. The CBP plants are correctly assembled by detection at the gene level, transcription level, protein level, and enzyme activity. Malate, CAM metabolism product, accumulated significantly at night in CBP plants. Metabolic analysis revealed that the malate is directed to the citric acid cycle and impacted carbon sequestration. The CBP plants showed a significant increase of ≈21% and ≈27% in photosynthetic rate and carboxylation efficiency, respectively. Additionally, CBP plants exhibited ≈20% increase in grain yield and biomass over the 2-year field trials. Unexpectedly, the water use efficiency and drought resistance do not improve in CBP plants. This study is the first to attempt CAM engineering in C3 and demonstrates the potential of facultative CAM carbon sequestration in rice.",

keywords = "C rice, carbon sequestration, crassulacean acid metabolism, multi-transgene stacking systems",

author = "Suting Wu and Kaining Jin and Haoshu Li and Guoxin Chen and Liying Zhang and Jinwen Yang and Shanshan Zhai and Yanni Li and Xuehui Sun and Xuean Cui and Jing Sun and Tiegang Lu and Zhiguo Zhang",

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T1 - A Synthetic Facultative CAM-Like Shuttle in C3 Rice Plants

AU - Wu, Suting

AU - Jin, Kaining

AU - Li, Haoshu

AU - Chen, Guoxin

AU - Zhang, Liying

AU - Yang, Jinwen

AU - Zhai, Shanshan

AU - Li, Yanni

AU - Sun, Xuehui

AU - Cui, Xuean

AU - Sun, Jing

AU - Lu, Tiegang

AU - Zhang, Zhiguo

PY - 2025/2/7

Y1 - 2025/2/7

N2 - Crassulacean acid metabolism (CAM) is one of the three major forms of photosynthesis, known for its efficient carbon sequestration mechanism. CAM plants store malate at night, which undergoes decarboxylation and promotes Rubisco carboxylation during the day. Despite its potential benefits, CAM engineering is not applied to C3 crops. This paper introduces a designed facultative CAM bypass (CBP) in rice by incorporating codon-optimized nocturnal carboxylation and decarboxylation modules, a malate transporter module, and a stomatal regulation module using the transgene stacking system. The CBP plants are correctly assembled by detection at the gene level, transcription level, protein level, and enzyme activity. Malate, CAM metabolism product, accumulated significantly at night in CBP plants. Metabolic analysis revealed that the malate is directed to the citric acid cycle and impacted carbon sequestration. The CBP plants showed a significant increase of ≈21% and ≈27% in photosynthetic rate and carboxylation efficiency, respectively. Additionally, CBP plants exhibited ≈20% increase in grain yield and biomass over the 2-year field trials. Unexpectedly, the water use efficiency and drought resistance do not improve in CBP plants. This study is the first to attempt CAM engineering in C3 and demonstrates the potential of facultative CAM carbon sequestration in rice.

AB - Crassulacean acid metabolism (CAM) is one of the three major forms of photosynthesis, known for its efficient carbon sequestration mechanism. CAM plants store malate at night, which undergoes decarboxylation and promotes Rubisco carboxylation during the day. Despite its potential benefits, CAM engineering is not applied to C3 crops. This paper introduces a designed facultative CAM bypass (CBP) in rice by incorporating codon-optimized nocturnal carboxylation and decarboxylation modules, a malate transporter module, and a stomatal regulation module using the transgene stacking system. The CBP plants are correctly assembled by detection at the gene level, transcription level, protein level, and enzyme activity. Malate, CAM metabolism product, accumulated significantly at night in CBP plants. Metabolic analysis revealed that the malate is directed to the citric acid cycle and impacted carbon sequestration. The CBP plants showed a significant increase of ≈21% and ≈27% in photosynthetic rate and carboxylation efficiency, respectively. Additionally, CBP plants exhibited ≈20% increase in grain yield and biomass over the 2-year field trials. Unexpectedly, the water use efficiency and drought resistance do not improve in CBP plants. This study is the first to attempt CAM engineering in C3 and demonstrates the potential of facultative CAM carbon sequestration in rice.

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KW - multi-transgene stacking systems

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