Structural Changes in Senescing Oilseed Rape Leaves at Tissue and Subcellular Levels Monitored by Nuclear Magnetic Resonance Relaxometry through Water Status

Musse, Maja; Franceschi, Loriane De; Cambert, Mireille; Sorin, Clément; Cahérec, Françoise Le; Burel, Agnès; Bouchereau, Alain; Mariette, François; Leport, Laurent

doi:10.1104/pp.113.223123

Cited by 33 publications

(60 citation statements)

References 62 publications

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“…The transverse relaxation of each water pool can be distinguished thanks to the slow diffusion process between cell compartments compared to the NMR relaxation process. In oilseed rape leaves, a new attribution was recently demonstrated [30]. The palisade and spongy cells of young oilseed rape leaves are similar in size but develop differently, resulting in cells of very different size between the tissues in old leaves.…”

Section: Introductionmentioning

confidence: 99%

“…The NMR spectra of oilseed rape leaves have been extensively studied and an attribution of the different water peaks has been proposed [30]. In young oilseed rape leaves, the water NMR signal consists of three peaks: the first one characterized by a T 2 around 2 ms was associated with the water interacting with polysaccharides (cell wall, starch), the second one characterized by a T 2 around 15 ms was associated with the water in plastids and other small vacuoles, and the last one, the highest in terms of intensity and with the longest T 2 around 150 ms, was associated with the water inside the cell vacuoles [35].…”

Section: Leaves At Two Developmental Stages Monitored Through Nmrmentioning

confidence: 99%

“…The palisade and spongy cells of young oilseed rape leaves are similar in size but develop differently, resulting in cells of very different size between the tissues in old leaves. NMR relaxation was shown to be able to finely describe the changes in cell size that occur during leaf development and can be used to monitor the water in vacuoles of palisade or spongy cells in old leaves separately [30]. Applied on a wide leaf panel collected from plant grown in both controlled and field conditions, the low field NMR relaxometry was shown to provide precise and robust markers of development of oilseed rape leaves [30].…”

Section: Introductionmentioning

confidence: 99%

“…NMR relaxation was shown to be able to finely describe the changes in cell size that occur during leaf development and can be used to monitor the water in vacuoles of palisade or spongy cells in old leaves separately [30]. Applied on a wide leaf panel collected from plant grown in both controlled and field conditions, the low field NMR relaxometry was shown to provide precise and robust markers of development of oilseed rape leaves [30]. NMR relaxation is thus a powerful tool to monitor changes in water relations inside the leaf caused by development or different stress as Nitrogen deficiency [35] or thermal stress [36].…”

Section: Introductionmentioning

confidence: 99%

“…These effects of drought stress can be effectively monitored using NMR (nuclear magnetic resonance) relaxometry. NMR relaxation is a powerful technique to study changes in the status and distribution of water in plant tissues and has also been used to investigate water status in seeds [26], fruit [27], stem [28] leaves [29][30][31] or to monitor water relations in trees [32]. In plant tissues, the NMR transverse relaxation (T 2 relaxation) is always described by multi-exponential decay.…”

Section: Introductionmentioning

confidence: 99%

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Leaf Development Monitoring and Early Detection of Water Deficiency by Low Field Nuclear Magnetic Resonance Relaxation in Nicotiana tabacum Plants

et al. 2018

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Drought is the main abiotic stress worldwide affecting harvest quality and quantity of numerous crops. To enable better water management, low field NMR (nuclear magnetic resonance) relaxometry was assessed as a developmental marker and a new method for early detection of water deficiency. The effect of a foliar biostimulant against water stress was also investigated. Two leaves of different ranks (four and eight) were studied. The leaves of different ranks were characterized by different NMR T 2 spectra which validated the ability of NMR to describe the developmental stage of tobacco. Results also showed that T 2 NMR relaxation spectra allow the detection of mild water stress (80% of the field capacity) through the precise characterization of the leaf water status while other water stress markers (relative water content, photosynthetic related parameters . . . )were not yet impacted. The agricultural impact of the mild water stress was determined through the nitrogen rate in shoots and amino acids assay six weeks after the beginning of the stress and results shows that foliar application of biostimulant limits the negative consequences of drought. Our results demonstrate the sensitivity of NMR to detect slight changes triggered in the leaf by water stress at the tissue level.

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Section: Introductionmentioning

confidence: 99%

Section: Leaves At Two Developmental Stages Monitored Through Nmrmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Leaf Development Monitoring and Early Detection of Water Deficiency by Low Field Nuclear Magnetic Resonance Relaxation in Nicotiana tabacum Plants

et al. 2018

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NMR study of fresh cut salads: Influence of temperature and storage time on leaf structure and water distribution in escarole

Sorin¹,

Mariette²,

Musse³

2019

Magnetic Reson in Chemistry

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Consumption of fresh‐cut vegetables has rapidly increased over the past decades. Among salads, escarole is one of the most popular varieties. Specific packaging limits gas exchange and consequently water loss and bacterial respiration, increasing the shelf life of salads. Although the major cause of quality loss for minimally processed salads is the leaf textural changes, this aspect has rarely been investigated. Therefore, investigating structural changes of leaves during storage is important in order to understand and minimize quality loss of salads. In this study, we focused on the impact of storage duration and temperature on the escarole leaf structure. The complex leaf structure was investigated by relaxation NMR, via transverse relaxation times, which allows the specific description of vacuolar water compartment of the cell. The storage duration (maximum 12 days) and temperatures (4°C, 7°C, 10°C, and 12°C) have been chosen in order to represent the conditions registered in factory. The results showed that the temperature did not have significant impact on the salad structure during the first week. During the second week, changes in the water distribution and changes in the relaxation time T2 have been observed. The changes in transverse relaxation times associated with vacuolar water are related to lost of cell membrane and wall integrity. The NMR results confirmed the effect of storage temperature on the degradation process of the cell before visual detection of the salad leaf degradation. The present study confirmed the sensibility of NMR relaxometry for monitoring water changes in the leaf.

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Quantitative MRI analysis of structural changes in tomato tissues resulting from dehydration

Leforestier

Fleury

Mariette

et al. 2022

Magnetic Reson in Chemistry

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A quantitative magnetic resonance imaging (MRI) analysis at 1.5T of the effects of different dehydration regimes on transverse relaxation parameters measured in tomato tissue is presented. Multi-exponential T 2 maps have been estimated for the first time, providing access to spatialized microstructural information at voxel scale. The objective was to provide a better understanding of the changes in the multi-exponential transverse relaxation parameters induced by dehydration in tomato tissues and to unravel the effects of microstructure and composition on relaxation parameters. The results led to the hypothesis that the multi-exponential relaxation signal reflects cell compartmentation and tissue heterogeneity, even at the voxel scale. Multi-exponential relaxation times provided information about water loss from specific cell compartments and seem to indicate that the dehydration process mainly affects

show abstract

Structural Changes in Senescing Oilseed Rape Leaves at Tissue and Subcellular Levels Monitored by Nuclear Magnetic Resonance Relaxometry through Water Status

Cited by 33 publications

References 62 publications

Leaf Development Monitoring and Early Detection of Water Deficiency by Low Field Nuclear Magnetic Resonance Relaxation in Nicotiana tabacum Plants

Leaf Development Monitoring and Early Detection of Water Deficiency by Low Field Nuclear Magnetic Resonance Relaxation in Nicotiana tabacum Plants

NMR study of fresh cut salads: Influence of temperature and storage time on leaf structure and water distribution in escarole

Quantitative MRI analysis of structural changes in tomato tissues resulting from dehydration

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