Contrasting age-dependent leaf acclimation strategies drive vegetation greening across deciduous broadleaf forests in mid- to high latitudes

Fangyi Wang; Meimei Xue; Liming Zhou; Christopher E. Doughty; Philippe Ciais; Peter B. Reich; Jiali Shang; Jing Ming Chen; Jane Liu; Julia K. Green; Dalei Hao; Shengli Tao; Yanjun Su; Lingli Liu; Jianyang Xia; Han Wang; Kailiang Yu; Zaichun Zhu; Peng Zhu; Xing Li; Hui Liu; Yelu Zeng; Kai Yan; Liyang Liu; Raffaele Lafortezza; Yongxian Su; Yanqiong Meng; Yixuan Pan; Xueqin Yang; Yongshuo H. Fu; Nianpeng He; Wenping Yuan; Xiuzhi Chen

doi:10.1038/s41477-025-02096-5

Contrasting age-dependent leaf acclimation strategies drive vegetation greening across deciduous broadleaf forests in mid- to high latitudes

Fangyi Wang, Meimei Xue, Liming Zhou, Christopher E. Doughty, Philippe Ciais, Peter B. Reich, Jiali Shang, Jing Ming Chen, Jane Liu, Julia K. Green, Dalei Hao, Shengli Tao, Yanjun Su, Lingli Liu, Jianyang Xia, Han Wang, Kailiang Yu, Zaichun Zhu, Peng Zhu, Xing LiHui Liu, Yelu Zeng, Kai Yan, Liyang Liu, Raffaele Lafortezza, Yongxian Su, Yanqiong Meng, Yixuan Pan, Xueqin Yang, Yongshuo H. Fu, Nianpeng He, Wenping Yuan, Xiuzhi Chen

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

Abstract

Increasing leaf area and extending vegetation growing seasons are two primary drivers of global greening, which has emerged as one of the most significant responses to climate change. However, it remains unclear how these two leaf acclimation strategies would vary across forests at a large spatial scale. Here, using multiple satellite-based datasets and field measurements, we analysed the temporal changes (Δ) in maximal leaf area index (LAI_max) and length of the growing season (LOS) from 2002 to 2021 across deciduous broadleaf forests (DBFs) in the middle to high latitudes. Contrary to the widely held assumption of coordination, our results revealed a negative correlation between ΔLAI_max and ΔLOS. Notably, the trade-offs between ΔLAI_max and ΔLOS were strongly explained by stand age. Younger DBFs, with lower baseline LAI_max, predominantly located in eastern Asia, displayed an increase in LAI_max with small changes in LOS. This acquisitive strategy facilitated younger DBFs to grow more photosynthetically efficient leaves with low leaf mass per area, enhancing their light use efficiency. Conversely, older DBFs with a higher baseline LAI_max, primarily located in North America and Europe, extended their LOS by increasing leaf mass per area. This conservative strategy facilitated older DBFs to produce thicker, but less photosynthetically efficient leaves, resulting in decreased light use efficiency. Our findings offer new insights into the contrasting changes in leaf area and growing season length and highlight their divergent impacts on ecosystem functioning.

Original language	English
Pages (from-to)	1748-1758
Number of pages	11
Journal	Nature Plants
Volume	11
Issue number	9
DOIs	https://doi.org/10.1038/s41477-025-02096-5
Publication status	Published - Sept 2025
Externally published	Yes

Bibliographical note

Publisher Copyright:
© The Author(s), under exclusive licence to Springer Nature Limited 2025.

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10.1038/s41477-025-02096-5

Cite this

Wang, F., Xue, M., Zhou, L., Doughty, C. E., Ciais, P., Reich, P. B., Shang, J., Chen, J. M., Liu, J., Green, J. K., Hao, D., Tao, S., Su, Y., Liu, L., Xia, J., Wang, H., Yu, K., Zhu, Z., Zhu, P., ... Chen, X. (2025). Contrasting age-dependent leaf acclimation strategies drive vegetation greening across deciduous broadleaf forests in mid- to high latitudes. Nature Plants, 11(9), 1748-1758. https://doi.org/10.1038/s41477-025-02096-5

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title = "Contrasting age-dependent leaf acclimation strategies drive vegetation greening across deciduous broadleaf forests in mid- to high latitudes",

abstract = "Increasing leaf area and extending vegetation growing seasons are two primary drivers of global greening, which has emerged as one of the most significant responses to climate change. However, it remains unclear how these two leaf acclimation strategies would vary across forests at a large spatial scale. Here, using multiple satellite-based datasets and field measurements, we analysed the temporal changes (Δ) in maximal leaf area index (LAImax) and length of the growing season (LOS) from 2002 to 2021 across deciduous broadleaf forests (DBFs) in the middle to high latitudes. Contrary to the widely held assumption of coordination, our results revealed a negative correlation between ΔLAImax and ΔLOS. Notably, the trade-offs between ΔLAImax and ΔLOS were strongly explained by stand age. Younger DBFs, with lower baseline LAImax, predominantly located in eastern Asia, displayed an increase in LAImax with small changes in LOS. This acquisitive strategy facilitated younger DBFs to grow more photosynthetically efficient leaves with low leaf mass per area, enhancing their light use efficiency. Conversely, older DBFs with a higher baseline LAImax, primarily located in North America and Europe, extended their LOS by increasing leaf mass per area. This conservative strategy facilitated older DBFs to produce thicker, but less photosynthetically efficient leaves, resulting in decreased light use efficiency. Our findings offer new insights into the contrasting changes in leaf area and growing season length and highlight their divergent impacts on ecosystem functioning.",

author = "Fangyi Wang and Meimei Xue and Liming Zhou and Doughty, {Christopher E.} and Philippe Ciais and Reich, {Peter B.} and Jiali Shang and Chen, {Jing Ming} and Jane Liu and Green, {Julia K.} and Dalei Hao and Shengli Tao and Yanjun Su and Lingli Liu and Jianyang Xia and Han Wang and Kailiang Yu and Zaichun Zhu and Peng Zhu and Xing Li and Hui Liu and Yelu Zeng and Kai Yan and Liyang Liu and Raffaele Lafortezza and Yongxian Su and Yanqiong Meng and Yixuan Pan and Xueqin Yang and Fu, {Yongshuo H.} and Nianpeng He and Wenping Yuan and Xiuzhi Chen",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature Limited 2025.",

year = "2025",

month = sep,

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Wang, F, Xue, M, Zhou, L, Doughty, CE, Ciais, P, Reich, PB, Shang, J, Chen, JM, Liu, J, Green, JK, Hao, D, Tao, S, Su, Y, Liu, L, Xia, J, Wang, H, Yu, K, Zhu, Z, Zhu, P, Li, X, Liu, H, Zeng, Y, Yan, K, Liu, L, Lafortezza, R, Su, Y, Meng, Y, Pan, Y, Yang, X, Fu, YH, He, N, Yuan, W & Chen, X 2025, 'Contrasting age-dependent leaf acclimation strategies drive vegetation greening across deciduous broadleaf forests in mid- to high latitudes', Nature Plants, vol. 11, no. 9, pp. 1748-1758. https://doi.org/10.1038/s41477-025-02096-5

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T1 - Contrasting age-dependent leaf acclimation strategies drive vegetation greening across deciduous broadleaf forests in mid- to high latitudes

AU - Wang, Fangyi

AU - Xue, Meimei

AU - Zhou, Liming

AU - Doughty, Christopher E.

AU - Ciais, Philippe

AU - Reich, Peter B.

AU - Shang, Jiali

AU - Chen, Jing Ming

AU - Liu, Jane

AU - Green, Julia K.

AU - Hao, Dalei

AU - Tao, Shengli

AU - Su, Yanjun

AU - Liu, Lingli

AU - Xia, Jianyang

AU - Wang, Han

AU - Yu, Kailiang

AU - Zhu, Zaichun

AU - Zhu, Peng

AU - Li, Xing

AU - Liu, Hui

AU - Zeng, Yelu

AU - Yan, Kai

AU - Liu, Liyang

AU - Lafortezza, Raffaele

AU - Su, Yongxian

AU - Meng, Yanqiong

AU - Pan, Yixuan

AU - Yang, Xueqin

AU - Fu, Yongshuo H.

AU - He, Nianpeng

AU - Yuan, Wenping

AU - Chen, Xiuzhi

PY - 2025/9

Y1 - 2025/9

N2 - Increasing leaf area and extending vegetation growing seasons are two primary drivers of global greening, which has emerged as one of the most significant responses to climate change. However, it remains unclear how these two leaf acclimation strategies would vary across forests at a large spatial scale. Here, using multiple satellite-based datasets and field measurements, we analysed the temporal changes (Δ) in maximal leaf area index (LAImax) and length of the growing season (LOS) from 2002 to 2021 across deciduous broadleaf forests (DBFs) in the middle to high latitudes. Contrary to the widely held assumption of coordination, our results revealed a negative correlation between ΔLAImax and ΔLOS. Notably, the trade-offs between ΔLAImax and ΔLOS were strongly explained by stand age. Younger DBFs, with lower baseline LAImax, predominantly located in eastern Asia, displayed an increase in LAImax with small changes in LOS. This acquisitive strategy facilitated younger DBFs to grow more photosynthetically efficient leaves with low leaf mass per area, enhancing their light use efficiency. Conversely, older DBFs with a higher baseline LAImax, primarily located in North America and Europe, extended their LOS by increasing leaf mass per area. This conservative strategy facilitated older DBFs to produce thicker, but less photosynthetically efficient leaves, resulting in decreased light use efficiency. Our findings offer new insights into the contrasting changes in leaf area and growing season length and highlight their divergent impacts on ecosystem functioning.

AB - Increasing leaf area and extending vegetation growing seasons are two primary drivers of global greening, which has emerged as one of the most significant responses to climate change. However, it remains unclear how these two leaf acclimation strategies would vary across forests at a large spatial scale. Here, using multiple satellite-based datasets and field measurements, we analysed the temporal changes (Δ) in maximal leaf area index (LAImax) and length of the growing season (LOS) from 2002 to 2021 across deciduous broadleaf forests (DBFs) in the middle to high latitudes. Contrary to the widely held assumption of coordination, our results revealed a negative correlation between ΔLAImax and ΔLOS. Notably, the trade-offs between ΔLAImax and ΔLOS were strongly explained by stand age. Younger DBFs, with lower baseline LAImax, predominantly located in eastern Asia, displayed an increase in LAImax with small changes in LOS. This acquisitive strategy facilitated younger DBFs to grow more photosynthetically efficient leaves with low leaf mass per area, enhancing their light use efficiency. Conversely, older DBFs with a higher baseline LAImax, primarily located in North America and Europe, extended their LOS by increasing leaf mass per area. This conservative strategy facilitated older DBFs to produce thicker, but less photosynthetically efficient leaves, resulting in decreased light use efficiency. Our findings offer new insights into the contrasting changes in leaf area and growing season length and highlight their divergent impacts on ecosystem functioning.

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Contrasting age-dependent leaf acclimation strategies drive vegetation greening across deciduous broadleaf forests in mid- to high latitudes

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