Challenges to understand plant responses to wind

Yusuke Onoda; Niels P.R. Anten

doi:10.4161/psb.6.7.15635

Challenges to understand plant responses to wind

Yusuke Onoda, Niels P.R. Anten

Research output: Contribution to journal › Comment/Letter to the editor › Academic

56 Citations (Scopus)

Abstract

Understanding plant response to wind is complicated as this factor entails not only mechanical stress, but also affects leaf microclimate. In a recent study, we found that plant responses to mechanical stress (MS) may be different and even in the opposite direction to those of wind. MS-treated Plantago major plants produced thinner more elongated leaves while those in wind did the opposite. The latter can be associated with the drying effect of wind as is further supported by data on petiole anatomy presented here. These results indicate that plant responses to wind will depend on the extent of water stress. It should also be recognized that the responses to wind may differ between different parts of a plant and between plant species. Physiological research on wind responses should thus focus on the signal sensing and transduction of both the mechanical and drought signals associated with wind, and consider both plant size and architecture.

Original language	English
Pages (from-to)	1057-1059
Journal	Plant Signaling and Behavior
Volume	6
Issue number	7
DOIs	https://doi.org/10.4161/psb.6.7.15635
Publication status	Published - 11 Jul 2011
Externally published	Yes

Keywords

Biomechanics
Leaf anatomy
Phenotypic plasticity
Plant architecture
Signal transduction thigmomorphogenesis
Wind

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title = "Challenges to understand plant responses to wind",

abstract = "Understanding plant response to wind is complicated as this factor entails not only mechanical stress, but also affects leaf microclimate. In a recent study, we found that plant responses to mechanical stress (MS) may be different and even in the opposite direction to those of wind. MS-treated Plantago major plants produced thinner more elongated leaves while those in wind did the opposite. The latter can be associated with the drying effect of wind as is further supported by data on petiole anatomy presented here. These results indicate that plant responses to wind will depend on the extent of water stress. It should also be recognized that the responses to wind may differ between different parts of a plant and between plant species. Physiological research on wind responses should thus focus on the signal sensing and transduction of both the mechanical and drought signals associated with wind, and consider both plant size and architecture.",

keywords = "Biomechanics, Leaf anatomy, Phenotypic plasticity, Plant architecture, Signal transduction thigmomorphogenesis, Wind",

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T1 - Challenges to understand plant responses to wind

AU - Onoda, Yusuke

AU - Anten, Niels P.R.

PY - 2011/7/11

Y1 - 2011/7/11

N2 - Understanding plant response to wind is complicated as this factor entails not only mechanical stress, but also affects leaf microclimate. In a recent study, we found that plant responses to mechanical stress (MS) may be different and even in the opposite direction to those of wind. MS-treated Plantago major plants produced thinner more elongated leaves while those in wind did the opposite. The latter can be associated with the drying effect of wind as is further supported by data on petiole anatomy presented here. These results indicate that plant responses to wind will depend on the extent of water stress. It should also be recognized that the responses to wind may differ between different parts of a plant and between plant species. Physiological research on wind responses should thus focus on the signal sensing and transduction of both the mechanical and drought signals associated with wind, and consider both plant size and architecture.

AB - Understanding plant response to wind is complicated as this factor entails not only mechanical stress, but also affects leaf microclimate. In a recent study, we found that plant responses to mechanical stress (MS) may be different and even in the opposite direction to those of wind. MS-treated Plantago major plants produced thinner more elongated leaves while those in wind did the opposite. The latter can be associated with the drying effect of wind as is further supported by data on petiole anatomy presented here. These results indicate that plant responses to wind will depend on the extent of water stress. It should also be recognized that the responses to wind may differ between different parts of a plant and between plant species. Physiological research on wind responses should thus focus on the signal sensing and transduction of both the mechanical and drought signals associated with wind, and consider both plant size and architecture.

KW - Biomechanics

KW - Leaf anatomy

KW - Phenotypic plasticity

KW - Plant architecture

KW - Signal transduction thigmomorphogenesis

KW - Wind

U2 - 10.4161/psb.6.7.15635

DO - 10.4161/psb.6.7.15635

M3 - Comment/Letter to the editor

C2 - 21617382

AN - SCOPUS:79960008208

SN - 1559-2316

VL - 6

SP - 1057

EP - 1059

JO - Plant Signaling and Behavior

JF - Plant Signaling and Behavior

IS - 7

ER -

Challenges to understand plant responses to wind

Abstract

Keywords

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