Convergent evidence for the temperature-dependent emergence of silicification in terrestrial plants

Zhihao Pang; Félix de Tombeur; Sue E. Hartley; Constantin M. Zohner; Miroslav Nikolic; Cyrille Violle; Lidong Mo; Thomas W. Crowther; Dong Xing Guan; Zhongkui Luo; Yong Guan Zhu; Yuxiao Wang; Ping Zhang; Hongyun Peng; Caroline A.E. Strömberg; Nina Nikolic; Yongchao Liang

doi:10.1038/s41467-025-56438-0

Convergent evidence for the temperature-dependent emergence of silicification in terrestrial plants

Zhihao Pang, Félix de Tombeur, Sue E. Hartley, Constantin M. Zohner, Miroslav Nikolic, Cyrille Violle, Lidong Mo, Thomas W. Crowther, Dong Xing Guan, Zhongkui Luo, Yong Guan Zhu, Yuxiao Wang, Ping Zhang, Hongyun Peng, Caroline A.E. Strömberg, Nina Nikolic, Yongchao Liang

School of Biological Sciences

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

Abstract

Research on silicon (Si) biogeochemistry and its beneficial effects for plants has received significant attention over several decades, but the reasons for the emergence of high-Si plants remain unclear. Here, we combine experimentation, field studies and analysis of existing databases to test the role of temperature on the expression and emergence of silicification in terrestrial plants. We first show that Si is beneficial for rice under high temperature (40 °C), but harmful under low temperature (0 °C), whilst a 2 °C increase results in a 37% increase in leaf Si concentrations. We then find that, globally, the average distribution temperature of high-Si plant clades is 1.2 °C higher than that of low-Si clades. Across China, leaf Si concentrations increase with temperature in high-Si plants (wheat and rice), but not in low-Si plants (weeping willow and winter jasmine). From an evolutionary perspective, 77% of high-Si families (>10 mg Si g-1 DW) originate during warming episodes, while 86% of low-Si families (<1 mg Si g-1 DW) originate during cooling episodes. On average, Earth's temperature during the emergence of high-Si families is 3 °C higher than that of low-Si families. Taken together, our evidence suggests that plant Si variation is closely related to global and long-term climate change.

Original language	English
Article number	1155
Pages (from-to)	1-13
Number of pages	13
Journal	Nature Communications
Volume	16
Issue number	1
Early online date	29 Jan 2025
DOIs	https://doi.org/10.1038/s41467-025-56438-0
Publication status	E-pub ahead of print - 29 Jan 2025

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Pang, Z., de Tombeur, F., Hartley, S. E., Zohner, C. M., Nikolic, M., Violle, C., Mo, L., Crowther, T. W., Guan, D. X., Luo, Z., Zhu, Y. G., Wang, Y., Zhang, P., Peng, H., Strömberg, C. A. E., Nikolic, N., & Liang, Y. (2025). Convergent evidence for the temperature-dependent emergence of silicification in terrestrial plants. Nature Communications, 16(1), 1-13. Article 1155. Advance online publication. https://doi.org/10.1038/s41467-025-56438-0

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title = "Convergent evidence for the temperature-dependent emergence of silicification in terrestrial plants",

abstract = "Research on silicon (Si) biogeochemistry and its beneficial effects for plants has received significant attention over several decades, but the reasons for the emergence of high-Si plants remain unclear. Here, we combine experimentation, field studies and analysis of existing databases to test the role of temperature on the expression and emergence of silicification in terrestrial plants. We first show that Si is beneficial for rice under high temperature (40 °C), but harmful under low temperature (0 °C), whilst a 2 °C increase results in a 37% increase in leaf Si concentrations. We then find that, globally, the average distribution temperature of high-Si plant clades is 1.2 °C higher than that of low-Si clades. Across China, leaf Si concentrations increase with temperature in high-Si plants (wheat and rice), but not in low-Si plants (weeping willow and winter jasmine). From an evolutionary perspective, 77% of high-Si families (>10 mg Si g-1 DW) originate during warming episodes, while 86% of low-Si families (<1 mg Si g-1 DW) originate during cooling episodes. On average, Earth's temperature during the emergence of high-Si families is 3 °C higher than that of low-Si families. Taken together, our evidence suggests that plant Si variation is closely related to global and long-term climate change.",

author = "Zhihao Pang and {de Tombeur}, F{\'e}lix and Hartley, {Sue E.} and Zohner, {Constantin M.} and Miroslav Nikolic and Cyrille Violle and Lidong Mo and Crowther, {Thomas W.} and Guan, {Dong Xing} and Zhongkui Luo and Zhu, {Yong Guan} and Yuxiao Wang and Ping Zhang and Hongyun Peng and Str{\"o}mberg, {Caroline A.E.} and Nina Nikolic and Yongchao Liang",

note = "Publisher Copyright: {\textcopyright} 2025. The Author(s).",

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month = jan,

day = "29",

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Pang, Z, de Tombeur, F, Hartley, SE, Zohner, CM, Nikolic, M, Violle, C, Mo, L, Crowther, TW, Guan, DX, Luo, Z, Zhu, YG, Wang, Y, Zhang, P, Peng, H, Strömberg, CAE, Nikolic, N & Liang, Y 2025, 'Convergent evidence for the temperature-dependent emergence of silicification in terrestrial plants', Nature Communications, vol. 16, no. 1, 1155, pp. 1-13. https://doi.org/10.1038/s41467-025-56438-0

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T1 - Convergent evidence for the temperature-dependent emergence of silicification in terrestrial plants

AU - Pang, Zhihao

AU - de Tombeur, Félix

AU - Hartley, Sue E.

AU - Zohner, Constantin M.

AU - Nikolic, Miroslav

AU - Violle, Cyrille

AU - Mo, Lidong

AU - Crowther, Thomas W.

AU - Guan, Dong Xing

AU - Luo, Zhongkui

AU - Zhu, Yong Guan

AU - Wang, Yuxiao

AU - Zhang, Ping

AU - Peng, Hongyun

AU - Strömberg, Caroline A.E.

AU - Nikolic, Nina

AU - Liang, Yongchao

PY - 2025/1/29

Y1 - 2025/1/29

N2 - Research on silicon (Si) biogeochemistry and its beneficial effects for plants has received significant attention over several decades, but the reasons for the emergence of high-Si plants remain unclear. Here, we combine experimentation, field studies and analysis of existing databases to test the role of temperature on the expression and emergence of silicification in terrestrial plants. We first show that Si is beneficial for rice under high temperature (40 °C), but harmful under low temperature (0 °C), whilst a 2 °C increase results in a 37% increase in leaf Si concentrations. We then find that, globally, the average distribution temperature of high-Si plant clades is 1.2 °C higher than that of low-Si clades. Across China, leaf Si concentrations increase with temperature in high-Si plants (wheat and rice), but not in low-Si plants (weeping willow and winter jasmine). From an evolutionary perspective, 77% of high-Si families (>10 mg Si g-1 DW) originate during warming episodes, while 86% of low-Si families (<1 mg Si g-1 DW) originate during cooling episodes. On average, Earth's temperature during the emergence of high-Si families is 3 °C higher than that of low-Si families. Taken together, our evidence suggests that plant Si variation is closely related to global and long-term climate change.

AB - Research on silicon (Si) biogeochemistry and its beneficial effects for plants has received significant attention over several decades, but the reasons for the emergence of high-Si plants remain unclear. Here, we combine experimentation, field studies and analysis of existing databases to test the role of temperature on the expression and emergence of silicification in terrestrial plants. We first show that Si is beneficial for rice under high temperature (40 °C), but harmful under low temperature (0 °C), whilst a 2 °C increase results in a 37% increase in leaf Si concentrations. We then find that, globally, the average distribution temperature of high-Si plant clades is 1.2 °C higher than that of low-Si clades. Across China, leaf Si concentrations increase with temperature in high-Si plants (wheat and rice), but not in low-Si plants (weeping willow and winter jasmine). From an evolutionary perspective, 77% of high-Si families (>10 mg Si g-1 DW) originate during warming episodes, while 86% of low-Si families (<1 mg Si g-1 DW) originate during cooling episodes. On average, Earth's temperature during the emergence of high-Si families is 3 °C higher than that of low-Si families. Taken together, our evidence suggests that plant Si variation is closely related to global and long-term climate change.

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DO - 10.1038/s41467-025-56438-0

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EP - 13

JO - Nature Communications

JF - Nature Communications

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ER -

Convergent evidence for the temperature-dependent emergence of silicification in terrestrial plants

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