Leaf stiffness of two Moraceae species based on leaf tensity determined by compressing different external gripping forces under dehydration stress

Leaf stiffness of two Moraceae species based on leaf tensity determined by compressing different external gripping forces under dehydration stress

Leaf water status determination based on mechanical and electrophysiological properties helps determine the inherent as well as instantaneous leaf dehydration tolerance synchronously. The leaf water potential (ΨL), physiological capacitance (CP) and gripping force (F) were determined with leaves of...

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Bibliographic Details
Main Authors: Deke Xing, Xiaole Chen, Yanyou Wu, Qian Chen, Lin Li, Weiguo Fu, Yu Shu
Format: Article
Language:English
Published: Taylor & Francis Group 2019-01-01
Series:Journal of Plant Interactions
Subjects:
leaf stiffness
leaf tensity
pressure resistance
cellular water loss
drought resistance
Online Access:http://dx.doi.org/10.1080/17429145.2019.1686182
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spelling doaj-0ab16d6907eb4895a5366159720d652d2021-03-18T15:12:48ZengTaylor & Francis GroupJournal of Plant Interactions1742-91451742-91532019-01-0114161061610.1080/17429145.2019.16861821686182Leaf stiffness of two Moraceae species based on leaf tensity determined by compressing different external gripping forces under dehydration stressDeke Xing0Xiaole Chen1Yanyou Wu2Qian Chen3Lin Li4Weiguo Fu5Yu Shu6Key Laboratory of Modern Agricultural Equipment and Technology, Ministry of Education, Institute of Agricultural Engineering, Jiangsu UniversityKey Laboratory of Modern Agricultural Equipment and Technology, Ministry of Education, Institute of Agricultural Engineering, Jiangsu UniversityResearch Center for Environmental Bio-Science and Technology, State Key Laboratory of Environmental Geochemistry, Chinese Academy of Sciences, Institute of GeochemistryKey Laboratory of Modern Agricultural Equipment and Technology, Ministry of Education, Institute of Agricultural Engineering, Jiangsu UniversityKey Laboratory of Modern Agricultural Equipment and Technology, Ministry of Education, Institute of Agricultural Engineering, Jiangsu UniversityKey Laboratory of Modern Agricultural Equipment and Technology, Ministry of Education, Institute of Agricultural Engineering, Jiangsu UniversityKey Laboratory of Modern Agricultural Equipment and Technology, Ministry of Education, Institute of Agricultural Engineering, Jiangsu UniversityLeaf water status determination based on mechanical and electrophysiological properties helps determine the inherent as well as instantaneous leaf dehydration tolerance synchronously. The leaf water potential (ΨL), physiological capacitance (CP) and gripping force (F) were determined with leaves of Broussonetia papyrifera (L.) Vent. and Morus alba L. Real-time leaf stiffness (LCSrt) and maximum leaf stiffness (LCSmax) were investigated by compressing a leaf with external gripping force. Results indicated that LT displayed good correlation with F. Compared to M. alba, a better instantaneous dehydration tolerance or pressure resistance in B. papyrifera was correlated to its persistent stronger LCSrt or LCSmax, respectively. B. papyrifera showed better flexibility and tolerance to wider range of pressure than M. alba. The higher leaf mechanical strength helped to maintain a higher outward pulling force of cell walls; thus, the subsequent negative pressure effectively inhibited cellular water loss. B. papyrifera exhibited better drought resistance than M. alba.http://dx.doi.org/10.1080/17429145.2019.1686182leaf stiffnessleaf tensitypressure resistancecellular water lossdrought resistance
collection DOAJ
language English
format Article
sources DOAJ
author Deke Xing
Xiaole Chen
Yanyou Wu
Qian Chen
Lin Li
Weiguo Fu
Yu Shu
spellingShingle Deke Xing
Xiaole Chen
Yanyou Wu
Qian Chen
Lin Li
Weiguo Fu
Yu Shu
Leaf stiffness of two Moraceae species based on leaf tensity determined by compressing different external gripping forces under dehydration stress
Journal of Plant Interactions
leaf stiffness
leaf tensity
pressure resistance
cellular water loss
drought resistance
author_facet Deke Xing
Xiaole Chen
Yanyou Wu
Qian Chen
Lin Li
Weiguo Fu
Yu Shu
author_sort Deke Xing
title Leaf stiffness of two Moraceae species based on leaf tensity determined by compressing different external gripping forces under dehydration stress
title_short Leaf stiffness of two Moraceae species based on leaf tensity determined by compressing different external gripping forces under dehydration stress
title_full Leaf stiffness of two Moraceae species based on leaf tensity determined by compressing different external gripping forces under dehydration stress
title_fullStr Leaf stiffness of two Moraceae species based on leaf tensity determined by compressing different external gripping forces under dehydration stress
title_full_unstemmed Leaf stiffness of two Moraceae species based on leaf tensity determined by compressing different external gripping forces under dehydration stress
title_sort leaf stiffness of two moraceae species based on leaf tensity determined by compressing different external gripping forces under dehydration stress
publisher Taylor & Francis Group
series Journal of Plant Interactions
issn 1742-9145
1742-9153
publishDate 2019-01-01
description Leaf water status determination based on mechanical and electrophysiological properties helps determine the inherent as well as instantaneous leaf dehydration tolerance synchronously. The leaf water potential (ΨL), physiological capacitance (CP) and gripping force (F) were determined with leaves of Broussonetia papyrifera (L.) Vent. and Morus alba L. Real-time leaf stiffness (LCSrt) and maximum leaf stiffness (LCSmax) were investigated by compressing a leaf with external gripping force. Results indicated that LT displayed good correlation with F. Compared to M. alba, a better instantaneous dehydration tolerance or pressure resistance in B. papyrifera was correlated to its persistent stronger LCSrt or LCSmax, respectively. B. papyrifera showed better flexibility and tolerance to wider range of pressure than M. alba. The higher leaf mechanical strength helped to maintain a higher outward pulling force of cell walls; thus, the subsequent negative pressure effectively inhibited cellular water loss. B. papyrifera exhibited better drought resistance than M. alba.
topic leaf stiffness
leaf tensity
pressure resistance
cellular water loss
drought resistance
url http://dx.doi.org/10.1080/17429145.2019.1686182
work_keys_str_mv AT dekexing leafstiffnessoftwomoraceaespeciesbasedonleaftensitydeterminedbycompressingdifferentexternalgrippingforcesunderdehydrationstress
AT xiaolechen leafstiffnessoftwomoraceaespeciesbasedonleaftensitydeterminedbycompressingdifferentexternalgrippingforcesunderdehydrationstress
AT yanyouwu leafstiffnessoftwomoraceaespeciesbasedonleaftensitydeterminedbycompressingdifferentexternalgrippingforcesunderdehydrationstress
AT qianchen leafstiffnessoftwomoraceaespeciesbasedonleaftensitydeterminedbycompressingdifferentexternalgrippingforcesunderdehydrationstress
AT linli leafstiffnessoftwomoraceaespeciesbasedonleaftensitydeterminedbycompressingdifferentexternalgrippingforcesunderdehydrationstress
AT weiguofu leafstiffnessoftwomoraceaespeciesbasedonleaftensitydeterminedbycompressingdifferentexternalgrippingforcesunderdehydrationstress
AT yushu leafstiffnessoftwomoraceaespeciesbasedonleaftensitydeterminedbycompressingdifferentexternalgrippingforcesunderdehydrationstress
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