Novel Strategies for Designing Climate-Smart Crops to Ensure Sustainable Agriculture and Future Food Security

Ali Raza; Tushar Khare; Xinyue Zhang; Md Mezanur Rahman; Muzammil Hussain; Sarvajeet Singh Gill; Zhong Hua Chen; Meixue Zhou; Zhangli Hu; Rajeev K. Varshney

doi:10.1002/sae2.70048

Novel Strategies for Designing Climate-Smart Crops to Ensure Sustainable Agriculture and Future Food Security

Ali Raza
, Tushar Khare
, Xinyue Zhang
, Md Mezanur Rahman
, Muzammil Hussain
, Sarvajeet Singh Gill
, Zhong Hua Chen
, Meixue Zhou
, Zhangli Hu
, Rajeev K. Varshney

Research output: Contribution to journal › Review article › peer-review

42 Scopus citations

Abstract

To fulfil food and nutritional demand for nine billion people by the mid-21st century, global food production must increase by 60% regardless of challenges such as environmental pollution, water scarcity and land degradation. Climate change exacerbates the frequency and intensity of biotic and abiotic stresses, which, in turn, severely compromise global crop yields, jeopardize food supply, deteriorate sustainable development goals for achieving global food safety, and limit sustainable climate-smart crop production. Current food production and consumption practices negatively influence the environment, posing a major threat to the global ecosystem and human health. Addressing these critical issues to achieve sustainable agriculture necessitates designing future crops employing cutting-edge breeding strategies for enhanced productivity with minimal environmental footprints. This endeavour requires a comprehensive understanding of plant stress adaptation, signalling pathways and mitigation mechanisms. In this review, we first explain the diverse impacts of ongoing climate change events on crop production. Subsequently, we outline various strategies to tackle climate change, including agronomic practices, and advanced technologies for understanding the physiological and molecular mechanisms of plant stress tolerance. We also discuss breeding and engineering crops with superior stress tolerance and disease resistance and nurturing healthy microbial partnerships between plants and soil to ensure food and nutrition security for current and future populations amidst mounting environmental challenges.

Original language	English
Article number	e70048
Journal	Journal of Sustainable Agriculture and Environment
Volume	4
Issue number	2
DOIs	https://doi.org/10.1002/sae2.70048
State	Published - Jun 2025
Externally published	Yes

Funding

The authors are grateful to many scientists and colleagues for fruitful discussions that have made it possible to develop this article. The author apologizes to all colleagues whose relevant work could not be cited. Zhangli Hu's work was supported by National Natural Science Foundation of China (32273118), Guangxi Major Programme for Science and Technology (GuikeAA24263042), Shenzhen Special Fund for Sustainable Development (KCXFZ20211020164013021), Guangdong Key R&D Project (2022B1111070005), The Engineering Research Centre Support Programme from Development and Reform Commission of Shenzhen Municipality (XMHT20220104019), and Shenzhen University 2035 Programme for Excellent Research (2022B010). Rajeev K. Varshney thanks the Grains Research and Development Corporation (GRDC) and Hort Innovation for supporting R&D projects on wheat (UMU240-4003RTX, WSU230-3001RTX), legume (UMU240-3009RTX, UMU230-3003RTX) and horticultural crops (AS21006, AS23003), and the Food Futures Institute of Murdoch University, Australia. Open access publishing facilitated by Murdoch University, as part of the Wiley - Murdoch University agreement via the Council of Australian University Librarians. The authors are grateful to many scientists and colleagues for fruitful discussions that have made it possible to develop this article. The author apologizes to all colleagues whose relevant work could not be cited. Zhangli Hu's work was supported by National Natural Science Foundation of China (32273118), Guangxi Major Programme for Science and Technology (GuikeAA24263042), Shenzhen Special Fund for Sustainable Development (KCXFZ20211020164013021), Guangdong Key R&D Project (2022B1111070005), The Engineering Research Centre Support Programme from Development and Reform Commission of Shenzhen Municipality (XMHT20220104019), and Shenzhen University 2035 Programme for Excellent Research (2022B010). Rajeev K. Varshney thanks the Grains Research and Development Corporation (GRDC) and Hort Innovation for supporting R&D projects on wheat (UMU240‐4003RTX, WSU230‐3001RTX), legume (UMU240‐3009RTX, UMU230‐3003RTX) and horticultural crops (AS21006, AS23003), and the Food Futures Institute of Murdoch University, Australia. Open access publishing facilitated by Murdoch University, as part of the Wiley ‐ Murdoch University agreement via the Council of Australian University Librarians.

Keywords

abiotic and biotic stress
crop genomics
gene editing
microbiomes
multi-omics

Access to Document

10.1002/sae2.70048

Cite this

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title = "Novel Strategies for Designing Climate-Smart Crops to Ensure Sustainable Agriculture and Future Food Security",

abstract = "To fulfil food and nutritional demand for nine billion people by the mid-21st century, global food production must increase by 60\% regardless of challenges such as environmental pollution, water scarcity and land degradation. Climate change exacerbates the frequency and intensity of biotic and abiotic stresses, which, in turn, severely compromise global crop yields, jeopardize food supply, deteriorate sustainable development goals for achieving global food safety, and limit sustainable climate-smart crop production. Current food production and consumption practices negatively influence the environment, posing a major threat to the global ecosystem and human health. Addressing these critical issues to achieve sustainable agriculture necessitates designing future crops employing cutting-edge breeding strategies for enhanced productivity with minimal environmental footprints. This endeavour requires a comprehensive understanding of plant stress adaptation, signalling pathways and mitigation mechanisms. In this review, we first explain the diverse impacts of ongoing climate change events on crop production. Subsequently, we outline various strategies to tackle climate change, including agronomic practices, and advanced technologies for understanding the physiological and molecular mechanisms of plant stress tolerance. We also discuss breeding and engineering crops with superior stress tolerance and disease resistance and nurturing healthy microbial partnerships between plants and soil to ensure food and nutrition security for current and future populations amidst mounting environmental challenges.",

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author = "Ali Raza and Tushar Khare and Xinyue Zhang and Rahman, \{Md Mezanur\} and Muzammil Hussain and Gill, \{Sarvajeet Singh\} and Chen, \{Zhong Hua\} and Meixue Zhou and Zhangli Hu and Varshney, \{Rajeev K.\}",

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AU - Raza, Ali

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AU - Rahman, Md Mezanur

AU - Hussain, Muzammil

AU - Gill, Sarvajeet Singh

AU - Chen, Zhong Hua

AU - Zhou, Meixue

AU - Hu, Zhangli

AU - Varshney, Rajeev K.

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AB - To fulfil food and nutritional demand for nine billion people by the mid-21st century, global food production must increase by 60% regardless of challenges such as environmental pollution, water scarcity and land degradation. Climate change exacerbates the frequency and intensity of biotic and abiotic stresses, which, in turn, severely compromise global crop yields, jeopardize food supply, deteriorate sustainable development goals for achieving global food safety, and limit sustainable climate-smart crop production. Current food production and consumption practices negatively influence the environment, posing a major threat to the global ecosystem and human health. Addressing these critical issues to achieve sustainable agriculture necessitates designing future crops employing cutting-edge breeding strategies for enhanced productivity with minimal environmental footprints. This endeavour requires a comprehensive understanding of plant stress adaptation, signalling pathways and mitigation mechanisms. In this review, we first explain the diverse impacts of ongoing climate change events on crop production. Subsequently, we outline various strategies to tackle climate change, including agronomic practices, and advanced technologies for understanding the physiological and molecular mechanisms of plant stress tolerance. We also discuss breeding and engineering crops with superior stress tolerance and disease resistance and nurturing healthy microbial partnerships between plants and soil to ensure food and nutrition security for current and future populations amidst mounting environmental challenges.

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KW - gene editing

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ER -

Novel Strategies for Designing Climate-Smart Crops to Ensure Sustainable Agriculture and Future Food Security

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Keywords

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