CO2                                                  elevation modulates the response of leaf gas exchange to progressive soil drying in tomato plants

Jie Liu; Tiantian Hu; Liang Fang; Xiaoying Peng; Fulai Liu

doi:10.1016/j.agrformet.2019.01.026

CO₂ elevation modulates the response of leaf gas exchange to progressive soil drying in tomato plants

Jie Liu, Tiantian Hu^*, Liang Fang, Xiaoying Peng, Fulai Liu

^*Corresponding author af dette arbejde

14 Citationer (Scopus)

Abstract

The objective of this study was to investigate the response of leaf gas exchange of tomato plant to progressive drought stress under ambient (a[CO ₂ ], 400 ppm) and elevated (e[CO ₂ ], 800 ppm) atmospheric CO ₂ concentration. The fraction of transpirable soil water (FTSW) was used to evaluate soil water status in the pots. The results showed that stomatal conductance (g _s ) and transpiration rate (T _r ) were significantly lower while the net photosynthetic rate (A _n ) was significantly higher in plants grown under e[CO ₂ ] than those under a[CO ₂ ] at onset of drought stress. Along with soil drying, the FTSW thresholds at which g _s and A _n started to decrease were significantly lower in plants grown under e[CO ₂ ] as compared to plants grown under a[CO ₂ ]. The intrinsic water use efficiency and instantaneous water use efficiency of plants grown under e[CO ₂ ] was significantly higher than those under a[CO ₂ ]. Under e[CO ₂ ], the drought-stressed plants had greater leaf area, dry matter and water use efficiency than those grown under a[CO ₂ ]. e[CO ₂ ] notably enhanced shoot C concentration while decreased shoot N concentration hereby increased the C:N ratio. With the decrease of FTSW, the concentration of abscisic acid in leaf ([ABA] _leaf ) and xylem sap ([ABA] _xylem ) increased exponentially. When FTSW > 0.2, under both CO ₂ environments, g _s decreased linearly with increasing [ABA] _leaf and [ABA] _xylem ; and similar slopes but different intercepts were noticed for the regression lines, indicating that the responsiveness of g _s to ABA was unaffected by CO ₂ . In conclusion, CO ₂ elevation retarded the response of leaf gas exchange to progressive soil drying in tomato plants. This result provides novel knowledge for more precise prediction of plant response to drought stress in a future CO ₂ -enriched environment.

Originalsprog	Engelsk
Tidsskrift	Agricultural and Forest Meteorology
Vol/bind	268
Sider (fra-til)	181-188
Antal sider	8
ISSN	0168-1923
DOI	https://doi.org/10.1016/j.agrformet.2019.01.026
Status	Udgivet - 15 apr. 2019

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@article{49cfd613cb4e418f8c98d9fdbe9107b6,

title = "CO2 elevation modulates the response of leaf gas exchange to progressive soil drying in tomato plants",

abstract = " The objective of this study was to investigate the response of leaf gas exchange of tomato plant to progressive drought stress under ambient (a[CO 2 ], 400 ppm) and elevated (e[CO 2 ], 800 ppm) atmospheric CO 2 concentration. The fraction of transpirable soil water (FTSW) was used to evaluate soil water status in the pots. The results showed that stomatal conductance (g s ) and transpiration rate (T r ) were significantly lower while the net photosynthetic rate (A n ) was significantly higher in plants grown under e[CO 2 ] than those under a[CO 2 ] at onset of drought stress. Along with soil drying, the FTSW thresholds at which g s and A n started to decrease were significantly lower in plants grown under e[CO 2 ] as compared to plants grown under a[CO 2 ]. The intrinsic water use efficiency and instantaneous water use efficiency of plants grown under e[CO 2 ] was significantly higher than those under a[CO 2 ]. Under e[CO 2 ], the drought-stressed plants had greater leaf area, dry matter and water use efficiency than those grown under a[CO 2 ]. e[CO 2 ] notably enhanced shoot C concentration while decreased shoot N concentration hereby increased the C:N ratio. With the decrease of FTSW, the concentration of abscisic acid in leaf ([ABA] leaf ) and xylem sap ([ABA] xylem ) increased exponentially. When FTSW > 0.2, under both CO 2 environments, g s decreased linearly with increasing [ABA] leaf and [ABA] xylem ; and similar slopes but different intercepts were noticed for the regression lines, indicating that the responsiveness of g s to ABA was unaffected by CO 2 . In conclusion, CO 2 elevation retarded the response of leaf gas exchange to progressive soil drying in tomato plants. This result provides novel knowledge for more precise prediction of plant response to drought stress in a future CO 2 -enriched environment. ",

keywords = "Abscisic acid, Climate change, Drought stress, Gas exchange",

author = "Jie Liu and Tiantian Hu and Liang Fang and Xiaoying Peng and Fulai Liu",

year = "2019",

month = apr,

day = "15",

doi = "10.1016/j.agrformet.2019.01.026",

language = "English",

volume = "268",

pages = "181--188",

journal = "Agricultural and Forest Meteorology",

issn = "0168-1923",

publisher = "Elsevier",

}

TY - JOUR

T1 - CO2 elevation modulates the response of leaf gas exchange to progressive soil drying in tomato plants

AU - Liu, Jie

AU - Hu, Tiantian

AU - Fang, Liang

AU - Peng, Xiaoying

AU - Liu, Fulai

PY - 2019/4/15

Y1 - 2019/4/15

N2 - The objective of this study was to investigate the response of leaf gas exchange of tomato plant to progressive drought stress under ambient (a[CO 2 ], 400 ppm) and elevated (e[CO 2 ], 800 ppm) atmospheric CO 2 concentration. The fraction of transpirable soil water (FTSW) was used to evaluate soil water status in the pots. The results showed that stomatal conductance (g s ) and transpiration rate (T r ) were significantly lower while the net photosynthetic rate (A n ) was significantly higher in plants grown under e[CO 2 ] than those under a[CO 2 ] at onset of drought stress. Along with soil drying, the FTSW thresholds at which g s and A n started to decrease were significantly lower in plants grown under e[CO 2 ] as compared to plants grown under a[CO 2 ]. The intrinsic water use efficiency and instantaneous water use efficiency of plants grown under e[CO 2 ] was significantly higher than those under a[CO 2 ]. Under e[CO 2 ], the drought-stressed plants had greater leaf area, dry matter and water use efficiency than those grown under a[CO 2 ]. e[CO 2 ] notably enhanced shoot C concentration while decreased shoot N concentration hereby increased the C:N ratio. With the decrease of FTSW, the concentration of abscisic acid in leaf ([ABA] leaf ) and xylem sap ([ABA] xylem ) increased exponentially. When FTSW > 0.2, under both CO 2 environments, g s decreased linearly with increasing [ABA] leaf and [ABA] xylem ; and similar slopes but different intercepts were noticed for the regression lines, indicating that the responsiveness of g s to ABA was unaffected by CO 2 . In conclusion, CO 2 elevation retarded the response of leaf gas exchange to progressive soil drying in tomato plants. This result provides novel knowledge for more precise prediction of plant response to drought stress in a future CO 2 -enriched environment.

AB - The objective of this study was to investigate the response of leaf gas exchange of tomato plant to progressive drought stress under ambient (a[CO 2 ], 400 ppm) and elevated (e[CO 2 ], 800 ppm) atmospheric CO 2 concentration. The fraction of transpirable soil water (FTSW) was used to evaluate soil water status in the pots. The results showed that stomatal conductance (g s ) and transpiration rate (T r ) were significantly lower while the net photosynthetic rate (A n ) was significantly higher in plants grown under e[CO 2 ] than those under a[CO 2 ] at onset of drought stress. Along with soil drying, the FTSW thresholds at which g s and A n started to decrease were significantly lower in plants grown under e[CO 2 ] as compared to plants grown under a[CO 2 ]. The intrinsic water use efficiency and instantaneous water use efficiency of plants grown under e[CO 2 ] was significantly higher than those under a[CO 2 ]. Under e[CO 2 ], the drought-stressed plants had greater leaf area, dry matter and water use efficiency than those grown under a[CO 2 ]. e[CO 2 ] notably enhanced shoot C concentration while decreased shoot N concentration hereby increased the C:N ratio. With the decrease of FTSW, the concentration of abscisic acid in leaf ([ABA] leaf ) and xylem sap ([ABA] xylem ) increased exponentially. When FTSW > 0.2, under both CO 2 environments, g s decreased linearly with increasing [ABA] leaf and [ABA] xylem ; and similar slopes but different intercepts were noticed for the regression lines, indicating that the responsiveness of g s to ABA was unaffected by CO 2 . In conclusion, CO 2 elevation retarded the response of leaf gas exchange to progressive soil drying in tomato plants. This result provides novel knowledge for more precise prediction of plant response to drought stress in a future CO 2 -enriched environment.

KW - Abscisic acid

KW - Climate change

KW - Drought stress

KW - Gas exchange

UR - http://www.scopus.com/inward/record.url?scp=85060296221&partnerID=8YFLogxK

U2 - 10.1016/j.agrformet.2019.01.026

DO - 10.1016/j.agrformet.2019.01.026

M3 - Journal article

AN - SCOPUS:85060296221

SN - 0168-1923

VL - 268

SP - 181

EP - 188

JO - Agricultural and Forest Meteorology

JF - Agricultural and Forest Meteorology

ER -