Growing-season temperature and precipitation are independent drivers of global variation in xylem hydraulic conductivity

Pengcheng He; Sean M. Gleason; Ian J. Wright; Ensheng Weng; Hui Liu; Shidan Zhu; Mingzhen Lu; Qi Luo; Ronghua Li; Guilin Wu; Enrong Yan; Yanjun Song; Xiangcheng Mi; Guangyou Hao; Peter B. Reich; Yingping Wang; David S. Ellsworth; Qing Ye

doi:10.1111/gcb.14929

Growing-season temperature and precipitation are independent drivers of global variation in xylem hydraulic conductivity

Pengcheng He, Sean M. Gleason, Ian J. Wright, Ensheng Weng, Hui Liu, Shidan Zhu, Mingzhen Lu, Qi Luo, Ronghua Li, Guilin Wu, Enrong Yan, Yanjun Song, Xiangcheng Mi, Guangyou Hao, Peter B. Reich, Yingping Wang, David S. Ellsworth, Qing Ye

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Abstract

Stem xylem-specific hydraulic conductivity (K_S) represents the potential for plant water transport normalized by xylem cross section, length, and driving force. Variation in K_S has implications for plant transpiration and photosynthesis, growth and survival, and also the geographic distribution of species. Clarifying the global-scale patterns of K_S and its major drivers is needed to achieve a better understanding of how plants adapt to different environmental conditions, particularly under climate change scenarios. Here, we compiled a xylem hydraulics dataset with 1,186 species-at-site combinations (975 woody species representing 146 families, from 199 sites worldwide), and investigated how K_S varied with climatic variables, plant functional types, and biomes. Growing-season temperature and growing-season precipitation drove global variation in K_S independently. Both the mean and the variation in K_S were highest in the warm and wet tropical regions, and lower in cold and dry regions, such as tundra and desert biomes. Our results suggest that future warming and redistribution of seasonal precipitation may have a significant impact on species functional diversity, and is likely to be particularly important in regions becoming warmer or drier, such as high latitudes. This highlights an important role for K_S in predicting shifts in community composition in the face of climate change.

Original language	English (US)
Pages (from-to)	1833-1841
Number of pages	9
Journal	Global change biology
Volume	26
Issue number	3
DOIs	https://doi.org/10.1111/gcb.14929
State	Published - Mar 1 2020

Bibliographical note

Publisher Copyright:
© 2019 John Wiley & Sons Ltd

Keywords

biome
climate
functional types
hydraulic diversity
species distribution
water transport

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He, P., Gleason, S. M., Wright, I. J., Weng, E., Liu, H., Zhu, S., Lu, M., Luo, Q., Li, R., Wu, G., Yan, E., Song, Y., Mi, X., Hao, G., Reich, P. B., Wang, Y., Ellsworth, D. S., & Ye, Q. (2020). Growing-season temperature and precipitation are independent drivers of global variation in xylem hydraulic conductivity. Global change biology, 26(3), 1833-1841. https://doi.org/10.1111/gcb.14929

He, P, Gleason, SM, Wright, IJ, Weng, E, Liu, H, Zhu, S, Lu, M, Luo, Q, Li, R, Wu, G, Yan, E, Song, Y, Mi, X, Hao, G, Reich, PB, Wang, Y, Ellsworth, DS & Ye, Q 2020, 'Growing-season temperature and precipitation are independent drivers of global variation in xylem hydraulic conductivity', Global change biology, vol. 26, no. 3, pp. 1833-1841. https://doi.org/10.1111/gcb.14929

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abstract = "Stem xylem-specific hydraulic conductivity (KS) represents the potential for plant water transport normalized by xylem cross section, length, and driving force. Variation in KS has implications for plant transpiration and photosynthesis, growth and survival, and also the geographic distribution of species. Clarifying the global-scale patterns of KS and its major drivers is needed to achieve a better understanding of how plants adapt to different environmental conditions, particularly under climate change scenarios. Here, we compiled a xylem hydraulics dataset with 1,186 species-at-site combinations (975 woody species representing 146 families, from 199 sites worldwide), and investigated how KS varied with climatic variables, plant functional types, and biomes. Growing-season temperature and growing-season precipitation drove global variation in KS independently. Both the mean and the variation in KS were highest in the warm and wet tropical regions, and lower in cold and dry regions, such as tundra and desert biomes. Our results suggest that future warming and redistribution of seasonal precipitation may have a significant impact on species functional diversity, and is likely to be particularly important in regions becoming warmer or drier, such as high latitudes. This highlights an important role for KS in predicting shifts in community composition in the face of climate change.",

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AU - He, Pengcheng

AU - Gleason, Sean M.

AU - Wright, Ian J.

AU - Weng, Ensheng

AU - Liu, Hui

AU - Zhu, Shidan

AU - Lu, Mingzhen

AU - Luo, Qi

AU - Li, Ronghua

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AU - Yan, Enrong

AU - Song, Yanjun

AU - Mi, Xiangcheng

AU - Hao, Guangyou

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AB - Stem xylem-specific hydraulic conductivity (KS) represents the potential for plant water transport normalized by xylem cross section, length, and driving force. Variation in KS has implications for plant transpiration and photosynthesis, growth and survival, and also the geographic distribution of species. Clarifying the global-scale patterns of KS and its major drivers is needed to achieve a better understanding of how plants adapt to different environmental conditions, particularly under climate change scenarios. Here, we compiled a xylem hydraulics dataset with 1,186 species-at-site combinations (975 woody species representing 146 families, from 199 sites worldwide), and investigated how KS varied with climatic variables, plant functional types, and biomes. Growing-season temperature and growing-season precipitation drove global variation in KS independently. Both the mean and the variation in KS were highest in the warm and wet tropical regions, and lower in cold and dry regions, such as tundra and desert biomes. Our results suggest that future warming and redistribution of seasonal precipitation may have a significant impact on species functional diversity, and is likely to be particularly important in regions becoming warmer or drier, such as high latitudes. This highlights an important role for KS in predicting shifts in community composition in the face of climate change.

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KW - water transport

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Growing-season temperature and precipitation are independent drivers of global variation in xylem hydraulic conductivity

Abstract

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Keywords

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