Elevated temperature has more pronounced effect on anthesis tomato plant than cadmium stress and reduced nitrogen supply

Rong Zhou; Xiaqing Yu; Yankai Li; Yanhai Ji; Xiaoming  Song; Hanne Lakkenborg Kristensen; Carl-Otto Ottosen; Fangling Jiang; Zhen  Wu

doi:10.1016/j.plaphy.2025.109498

Elevated temperature has more pronounced effect on anthesis tomato plant than cadmium stress and reduced nitrogen supply

Rong Zhou
, Xiaqing Yu
, Yankai Li
, Yanhai Ji
, Xiaoming Song
, Hanne Lakkenborg Kristensen
, Carl-Otto Ottosen
, Fangling Jiang
, Zhen Wu

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

Abstract

Plants are often exposed to combined stress, e.g. heat and cadmium (Cd) stress under natural conditions. Nitrogen (N) fertilizer is usually applied in excess, even though it is an essential nutrition for plants. We aimed to clarify the effects of elevated temperature, Cd stress, reduced N fertilizer and their interaction on leaf physiology and metabolism of anthesis tomato plants. Tomato plants at anthesis stage were subjected to unique combinations of elevated temperature (34˚C/30˚C), Cd stress (0.1 mM CdCl2) and half N (N = 95 ppm) treatment. The elevated temperature generally decreased leaf intracellular CO2 concentration and stomatal conductance, but increased transpiration rate with no significant changes in net photosynthetic rate, as compared with control. The plants under elevated temperature exhibited higher chlorophyll content as well as lower anthocyanin than under control temperature. The temperature had significant impacts on open flowers in the 1st inflorescence counting from bottom, open flower percentage in the 1st inflorescence, fresh and dry weight of flowers. Temperature played a predominant role in the changes of metabolites among the three factors based on metabolome. The Cd stress and reduced N supply also affected leaf metabolites of tomato plants, even though the effects on metabolites and physiology were less than that of elevated temperature. Trend analysis of the metabolites showed eight types in tomatoes under eight treatments. Biosynthesis of secondary metabolites, phenylpropanoid biosynthesis, linoleic acid metabolism and ABC transporters pathways positively responded to the elevated temperature. Moreover, there were significant interactions between the three factors (temperature, CdCl2 and N) on tomato physiological and morphological parameters. We concluded that the physiological and metabolic responses of tomato plants were more pronounced to the elevated temperatures as compared with cadmium stress and reduced nitrogen fertilizer. This study can support the understanding of complex regulatory mechanisms in plants responding to multiple environmental changes due to climate change, management practice and environmental pollution.

Original language	English
Article number	109498
Journal	Plant Physiology and Biochemistry
Volume	220
ISSN	0981-9428
DOIs	https://doi.org/10.1016/j.plaphy.2025.109498
Publication status	Published - Mar 2025

Keywords

Cadmium stress
Elevated temperature
Leaf gas exchange and metabolomics
Nitrogen nutrient
Tomato

Access to Document

10.1016/j.plaphy.2025.109498

Library access?

Check availability with the Royal Danish Library

Cite this

@article{88205b709af146529b694f94ae2df1f1,

title = "Elevated temperature has more pronounced effect on anthesis tomato plant than cadmium stress and reduced nitrogen supply",

abstract = "Plants are often exposed to combined stress, e.g. heat and cadmium (Cd) stress under natural conditions. Nitrogen (N) fertilizer is usually applied in excess, even though it is an essential nutrition for plants. We aimed to clarify the effects of elevated temperature, Cd stress, reduced N fertilizer and their interaction on leaf physiology and metabolism of anthesis tomato plants. Tomato plants at anthesis stage were subjected to unique combinations of elevated temperature (34˚C/30˚C), Cd stress (0.1 mM CdCl2) and half N (N = 95 ppm) treatment. The elevated temperature generally decreased leaf intracellular CO2 concentration and stomatal conductance, but increased transpiration rate with no significant changes in net photosynthetic rate, as compared with control. The plants under elevated temperature exhibited higher chlorophyll content as well as lower anthocyanin than under control temperature. The temperature had significant impacts on open flowers in the 1st inflorescence counting from bottom, open flower percentage in the 1st inflorescence, fresh and dry weight of flowers. Temperature played a predominant role in the changes of metabolites among the three factors based on metabolome. The Cd stress and reduced N supply also affected leaf metabolites of tomato plants, even though the effects on metabolites and physiology were less than that of elevated temperature. Trend analysis of the metabolites showed eight types in tomatoes under eight treatments. Biosynthesis of secondary metabolites, phenylpropanoid biosynthesis, linoleic acid metabolism and ABC transporters pathways positively responded to the elevated temperature. Moreover, there were significant interactions between the three factors (temperature, CdCl2 and N) on tomato physiological and morphological parameters. We concluded that the physiological and metabolic responses of tomato plants were more pronounced to the elevated temperatures as compared with cadmium stress and reduced nitrogen fertilizer. This study can support the understanding of complex regulatory mechanisms in plants responding to multiple environmental changes due to climate change, management practice and environmental pollution.",

keywords = "Cadmium stress, Elevated temperature, Leaf gas exchange and metabolomics, Nitrogen nutrient, Tomato",

author = "Rong Zhou and Xiaqing Yu and Yankai Li and Yanhai Ji and Xiaoming Song and Kristensen, \{Hanne Lakkenborg\} and Carl-Otto Ottosen and Fangling Jiang and Zhen Wu",

year = "2025",

month = mar,

doi = "10.1016/j.plaphy.2025.109498",

language = "English",

volume = "220",

journal = "Plant Physiology and Biochemistry",

issn = "0981-9428",

publisher = "Elsevier Masson",

}

Elevated temperature has more pronounced effect on anthesis tomato plant than cadmium stress and reduced nitrogen supply. / Zhou, Rong; Yu, Xiaqing; Li, Yankai et al.
In: Plant Physiology and Biochemistry, Vol. 220, 109498, 03.2025.

Research output: Contribution to journal/Conference contribution in journal/Contribution to newspaper › Journal article › Research › peer-review

TY - JOUR

T1 - Elevated temperature has more pronounced effect on anthesis tomato plant than cadmium stress and reduced nitrogen supply

AU - Zhou, Rong

AU - Yu, Xiaqing

AU - Li, Yankai

AU - Ji, Yanhai

AU - Song, Xiaoming

AU - Kristensen, Hanne Lakkenborg

AU - Ottosen, Carl-Otto

AU - Jiang , Fangling

AU - Wu, Zhen

PY - 2025/3

Y1 - 2025/3

N2 - Plants are often exposed to combined stress, e.g. heat and cadmium (Cd) stress under natural conditions. Nitrogen (N) fertilizer is usually applied in excess, even though it is an essential nutrition for plants. We aimed to clarify the effects of elevated temperature, Cd stress, reduced N fertilizer and their interaction on leaf physiology and metabolism of anthesis tomato plants. Tomato plants at anthesis stage were subjected to unique combinations of elevated temperature (34˚C/30˚C), Cd stress (0.1 mM CdCl2) and half N (N = 95 ppm) treatment. The elevated temperature generally decreased leaf intracellular CO2 concentration and stomatal conductance, but increased transpiration rate with no significant changes in net photosynthetic rate, as compared with control. The plants under elevated temperature exhibited higher chlorophyll content as well as lower anthocyanin than under control temperature. The temperature had significant impacts on open flowers in the 1st inflorescence counting from bottom, open flower percentage in the 1st inflorescence, fresh and dry weight of flowers. Temperature played a predominant role in the changes of metabolites among the three factors based on metabolome. The Cd stress and reduced N supply also affected leaf metabolites of tomato plants, even though the effects on metabolites and physiology were less than that of elevated temperature. Trend analysis of the metabolites showed eight types in tomatoes under eight treatments. Biosynthesis of secondary metabolites, phenylpropanoid biosynthesis, linoleic acid metabolism and ABC transporters pathways positively responded to the elevated temperature. Moreover, there were significant interactions between the three factors (temperature, CdCl2 and N) on tomato physiological and morphological parameters. We concluded that the physiological and metabolic responses of tomato plants were more pronounced to the elevated temperatures as compared with cadmium stress and reduced nitrogen fertilizer. This study can support the understanding of complex regulatory mechanisms in plants responding to multiple environmental changes due to climate change, management practice and environmental pollution.

AB - Plants are often exposed to combined stress, e.g. heat and cadmium (Cd) stress under natural conditions. Nitrogen (N) fertilizer is usually applied in excess, even though it is an essential nutrition for plants. We aimed to clarify the effects of elevated temperature, Cd stress, reduced N fertilizer and their interaction on leaf physiology and metabolism of anthesis tomato plants. Tomato plants at anthesis stage were subjected to unique combinations of elevated temperature (34˚C/30˚C), Cd stress (0.1 mM CdCl2) and half N (N = 95 ppm) treatment. The elevated temperature generally decreased leaf intracellular CO2 concentration and stomatal conductance, but increased transpiration rate with no significant changes in net photosynthetic rate, as compared with control. The plants under elevated temperature exhibited higher chlorophyll content as well as lower anthocyanin than under control temperature. The temperature had significant impacts on open flowers in the 1st inflorescence counting from bottom, open flower percentage in the 1st inflorescence, fresh and dry weight of flowers. Temperature played a predominant role in the changes of metabolites among the three factors based on metabolome. The Cd stress and reduced N supply also affected leaf metabolites of tomato plants, even though the effects on metabolites and physiology were less than that of elevated temperature. Trend analysis of the metabolites showed eight types in tomatoes under eight treatments. Biosynthesis of secondary metabolites, phenylpropanoid biosynthesis, linoleic acid metabolism and ABC transporters pathways positively responded to the elevated temperature. Moreover, there were significant interactions between the three factors (temperature, CdCl2 and N) on tomato physiological and morphological parameters. We concluded that the physiological and metabolic responses of tomato plants were more pronounced to the elevated temperatures as compared with cadmium stress and reduced nitrogen fertilizer. This study can support the understanding of complex regulatory mechanisms in plants responding to multiple environmental changes due to climate change, management practice and environmental pollution.

KW - Cadmium stress

KW - Elevated temperature

KW - Leaf gas exchange and metabolomics

KW - Nitrogen nutrient

KW - Tomato

UR - https://www.scopus.com/pages/publications/85215090169

U2 - 10.1016/j.plaphy.2025.109498

DO - 10.1016/j.plaphy.2025.109498

M3 - Journal article

C2 - 39826348

SN - 0981-9428

VL - 220

JO - Plant Physiology and Biochemistry

JF - Plant Physiology and Biochemistry

M1 - 109498

ER -

Elevated temperature has more pronounced effect on anthesis tomato plant than cadmium stress and reduced nitrogen supply

Abstract

Keywords

Access to Document

Library access?

Other files and links

Cite this