Signal transduction pathway(s) in guard cells after prolonged exposure to low vapour pressure deficit

Keywords: Abscisic acid, Arabidopsis thaliana, calcium, CYP707As, desiccation, environmental factors, guard cells’ signalling pathway, hydrogen peroxide, natural variation, nitric oxide, photosystem II efficiency, RD29A, relative water content, secondary messengers, stomata, vapour pressure deficit, Vicia faba In short-term, guard cells close stomata in response to an increase in vapour pressure deficit (VPD) and they open the stomata after exposure to low VPDs. However, in long-term responses to low VPD, adaptation processes occur which make stomata less sensitive to stimuli which usually induce stomatal closure (stomatal malfunctioning). Cellular mechanism(s) leading to occurrence of stomatal malfunctioning is (are) still unknown. The aim of this project was to elucidate the processes that are involved in the malfunctioning of stomata after long-term exposure to low VPD. To elucidate whether the problem of stomatal malfunctioning is due to alterations in stomatal morphology and leaf anatomy or in the ABA signalling pathway, fava bean plants were grown at low or moderate VPDs and some plants that developed their leaves at moderate VPD were then transferred for four days to low VPD. Leaf anatomical and stomatal morphological alterations due to low VPD were not the main reason of stomatal malfunctioning in response to ABA and desiccation. Within one day exposure to low VPD, the level of foliar ABA decreased to the same level as in low VPD-grown plants, while the level of ABA-glucose ester was not affected. Spraying ABA during a 4-day exposure to low VPD maintained closing ability of the stomata after 4-day low VPD-exposure. Therefore, alteration in the signalling pathways due to low foliar ABA level was recognized as the main reason for stomatal malfunctioning after long-term low VPD-exposure. Coincidence in changes of Ca2+, ABA receptors, and positive and negative regulators of ABA signalling are proposed as early steps for stomatal malfunctioning induced by low VPD-exposure. Transcriptional activators, transcriptional repressors as well as E3 ligases are proposed for long-term adaptation of cellular processes which consequently cause decreased stomatal response to closing stimuli afterwards. In order to find the molecular mechanism(s) of stomatal malfunctioning, possible variation in stomatal response to closing stimuli was studied among Arabidopsis thaliana accessions after a 4-day low VPD-exposure. Accessions could be grouped to very sensitive, moderately sensitive and less sensitive to closing stimuli using principle component analysis. A positive correlation was found between foliar ABA level (before desiccation) and stomatal closure response to ABA (but not to desiccation) after exposure to different VPDs. Stomatal response to desiccation was positively correlated with the foliar ABA level after desiccation. In order to elucidate the molecular network underlying stomatal malfunctioning in response to ABA due to long-term low VPD-exposure, two groups of Arabidopsis accessions were used as accessions that maintained responsiveness to ABA after low VPD-exposure and accessions with low VPD induced non-ABA-responsive stomata. The foliar ABA content in all accessions correlated with the stomatal response to ABA: only when the ABA level was above a threshold value, stomata responded to ABA. After low VPD-exposure, mainly due to catabolism of ABA, the foliar ABA content decreased. This decrease in ABA level resulted in down regulation of RD29A, which caused decreased stomatal responsiveness to ABA.

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Bibliographic Details
Main Author: Ali Niaei Fard, S.
Other Authors: Woltering, Ernst
Format: Doctoral thesis biblioteca
Language:English
Published: Wageningen University
Subjects:abscisic acid, arabidopsis thaliana, desiccation, plant physiology, signal transduction, stomata, vapour pressure, vicia faba, abscisinezuur, dampdruk, huidmondjes, plantenfysiologie, signaaltransductie, verdroging,
Online Access:https://research.wur.nl/en/publications/signal-transduction-pathways-in-guard-cells-after-prolonged-expos
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institution WUR NL
collection DSpace
country Países bajos
countrycode NL
component Bibliográfico
access En linea
databasecode dig-wur-nl
tag biblioteca
region Europa del Oeste
libraryname WUR Library Netherlands
language English
topic abscisic acid
arabidopsis thaliana
desiccation
plant physiology
signal transduction
stomata
vapour pressure
vicia faba
abscisinezuur
arabidopsis thaliana
dampdruk
huidmondjes
plantenfysiologie
signaaltransductie
verdroging
vicia faba
abscisic acid
arabidopsis thaliana
desiccation
plant physiology
signal transduction
stomata
vapour pressure
vicia faba
abscisinezuur
arabidopsis thaliana
dampdruk
huidmondjes
plantenfysiologie
signaaltransductie
verdroging
vicia faba
spellingShingle abscisic acid
arabidopsis thaliana
desiccation
plant physiology
signal transduction
stomata
vapour pressure
vicia faba
abscisinezuur
arabidopsis thaliana
dampdruk
huidmondjes
plantenfysiologie
signaaltransductie
verdroging
vicia faba
abscisic acid
arabidopsis thaliana
desiccation
plant physiology
signal transduction
stomata
vapour pressure
vicia faba
abscisinezuur
arabidopsis thaliana
dampdruk
huidmondjes
plantenfysiologie
signaaltransductie
verdroging
vicia faba
Ali Niaei Fard, S.
Signal transduction pathway(s) in guard cells after prolonged exposure to low vapour pressure deficit
description Keywords: Abscisic acid, Arabidopsis thaliana, calcium, CYP707As, desiccation, environmental factors, guard cells’ signalling pathway, hydrogen peroxide, natural variation, nitric oxide, photosystem II efficiency, RD29A, relative water content, secondary messengers, stomata, vapour pressure deficit, Vicia faba In short-term, guard cells close stomata in response to an increase in vapour pressure deficit (VPD) and they open the stomata after exposure to low VPDs. However, in long-term responses to low VPD, adaptation processes occur which make stomata less sensitive to stimuli which usually induce stomatal closure (stomatal malfunctioning). Cellular mechanism(s) leading to occurrence of stomatal malfunctioning is (are) still unknown. The aim of this project was to elucidate the processes that are involved in the malfunctioning of stomata after long-term exposure to low VPD. To elucidate whether the problem of stomatal malfunctioning is due to alterations in stomatal morphology and leaf anatomy or in the ABA signalling pathway, fava bean plants were grown at low or moderate VPDs and some plants that developed their leaves at moderate VPD were then transferred for four days to low VPD. Leaf anatomical and stomatal morphological alterations due to low VPD were not the main reason of stomatal malfunctioning in response to ABA and desiccation. Within one day exposure to low VPD, the level of foliar ABA decreased to the same level as in low VPD-grown plants, while the level of ABA-glucose ester was not affected. Spraying ABA during a 4-day exposure to low VPD maintained closing ability of the stomata after 4-day low VPD-exposure. Therefore, alteration in the signalling pathways due to low foliar ABA level was recognized as the main reason for stomatal malfunctioning after long-term low VPD-exposure. Coincidence in changes of Ca2+, ABA receptors, and positive and negative regulators of ABA signalling are proposed as early steps for stomatal malfunctioning induced by low VPD-exposure. Transcriptional activators, transcriptional repressors as well as E3 ligases are proposed for long-term adaptation of cellular processes which consequently cause decreased stomatal response to closing stimuli afterwards. In order to find the molecular mechanism(s) of stomatal malfunctioning, possible variation in stomatal response to closing stimuli was studied among Arabidopsis thaliana accessions after a 4-day low VPD-exposure. Accessions could be grouped to very sensitive, moderately sensitive and less sensitive to closing stimuli using principle component analysis. A positive correlation was found between foliar ABA level (before desiccation) and stomatal closure response to ABA (but not to desiccation) after exposure to different VPDs. Stomatal response to desiccation was positively correlated with the foliar ABA level after desiccation. In order to elucidate the molecular network underlying stomatal malfunctioning in response to ABA due to long-term low VPD-exposure, two groups of Arabidopsis accessions were used as accessions that maintained responsiveness to ABA after low VPD-exposure and accessions with low VPD induced non-ABA-responsive stomata. The foliar ABA content in all accessions correlated with the stomatal response to ABA: only when the ABA level was above a threshold value, stomata responded to ABA. After low VPD-exposure, mainly due to catabolism of ABA, the foliar ABA content decreased. This decrease in ABA level resulted in down regulation of RD29A, which caused decreased stomatal responsiveness to ABA.
author2 Woltering, Ernst
author_facet Woltering, Ernst
Ali Niaei Fard, S.
format Doctoral thesis
topic_facet abscisic acid
arabidopsis thaliana
desiccation
plant physiology
signal transduction
stomata
vapour pressure
vicia faba
abscisinezuur
arabidopsis thaliana
dampdruk
huidmondjes
plantenfysiologie
signaaltransductie
verdroging
vicia faba
author Ali Niaei Fard, S.
author_sort Ali Niaei Fard, S.
title Signal transduction pathway(s) in guard cells after prolonged exposure to low vapour pressure deficit
title_short Signal transduction pathway(s) in guard cells after prolonged exposure to low vapour pressure deficit
title_full Signal transduction pathway(s) in guard cells after prolonged exposure to low vapour pressure deficit
title_fullStr Signal transduction pathway(s) in guard cells after prolonged exposure to low vapour pressure deficit
title_full_unstemmed Signal transduction pathway(s) in guard cells after prolonged exposure to low vapour pressure deficit
title_sort signal transduction pathway(s) in guard cells after prolonged exposure to low vapour pressure deficit
publisher Wageningen University
url https://research.wur.nl/en/publications/signal-transduction-pathways-in-guard-cells-after-prolonged-expos
work_keys_str_mv AT aliniaeifards signaltransductionpathwaysinguardcellsafterprolongedexposuretolowvapourpressuredeficit
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spelling dig-wur-nl-wurpubs-4563112024-12-03 Ali Niaei Fard, S. Woltering, Ernst van Meeteren, Uulke Doctoral thesis Signal transduction pathway(s) in guard cells after prolonged exposure to low vapour pressure deficit 2014 Keywords: Abscisic acid, Arabidopsis thaliana, calcium, CYP707As, desiccation, environmental factors, guard cells’ signalling pathway, hydrogen peroxide, natural variation, nitric oxide, photosystem II efficiency, RD29A, relative water content, secondary messengers, stomata, vapour pressure deficit, Vicia faba In short-term, guard cells close stomata in response to an increase in vapour pressure deficit (VPD) and they open the stomata after exposure to low VPDs. However, in long-term responses to low VPD, adaptation processes occur which make stomata less sensitive to stimuli which usually induce stomatal closure (stomatal malfunctioning). Cellular mechanism(s) leading to occurrence of stomatal malfunctioning is (are) still unknown. The aim of this project was to elucidate the processes that are involved in the malfunctioning of stomata after long-term exposure to low VPD. To elucidate whether the problem of stomatal malfunctioning is due to alterations in stomatal morphology and leaf anatomy or in the ABA signalling pathway, fava bean plants were grown at low or moderate VPDs and some plants that developed their leaves at moderate VPD were then transferred for four days to low VPD. Leaf anatomical and stomatal morphological alterations due to low VPD were not the main reason of stomatal malfunctioning in response to ABA and desiccation. Within one day exposure to low VPD, the level of foliar ABA decreased to the same level as in low VPD-grown plants, while the level of ABA-glucose ester was not affected. Spraying ABA during a 4-day exposure to low VPD maintained closing ability of the stomata after 4-day low VPD-exposure. Therefore, alteration in the signalling pathways due to low foliar ABA level was recognized as the main reason for stomatal malfunctioning after long-term low VPD-exposure. Coincidence in changes of Ca2+, ABA receptors, and positive and negative regulators of ABA signalling are proposed as early steps for stomatal malfunctioning induced by low VPD-exposure. Transcriptional activators, transcriptional repressors as well as E3 ligases are proposed for long-term adaptation of cellular processes which consequently cause decreased stomatal response to closing stimuli afterwards. In order to find the molecular mechanism(s) of stomatal malfunctioning, possible variation in stomatal response to closing stimuli was studied among Arabidopsis thaliana accessions after a 4-day low VPD-exposure. Accessions could be grouped to very sensitive, moderately sensitive and less sensitive to closing stimuli using principle component analysis. A positive correlation was found between foliar ABA level (before desiccation) and stomatal closure response to ABA (but not to desiccation) after exposure to different VPDs. Stomatal response to desiccation was positively correlated with the foliar ABA level after desiccation. In order to elucidate the molecular network underlying stomatal malfunctioning in response to ABA due to long-term low VPD-exposure, two groups of Arabidopsis accessions were used as accessions that maintained responsiveness to ABA after low VPD-exposure and accessions with low VPD induced non-ABA-responsive stomata. The foliar ABA content in all accessions correlated with the stomatal response to ABA: only when the ABA level was above a threshold value, stomata responded to ABA. After low VPD-exposure, mainly due to catabolism of ABA, the foliar ABA content decreased. This decrease in ABA level resulted in down regulation of RD29A, which caused decreased stomatal responsiveness to ABA. en Wageningen University application/pdf https://research.wur.nl/en/publications/signal-transduction-pathways-in-guard-cells-after-prolonged-expos 10.18174/312324 https://edepot.wur.nl/312324 abscisic acid arabidopsis thaliana desiccation plant physiology signal transduction stomata vapour pressure vicia faba abscisinezuur arabidopsis thaliana dampdruk huidmondjes plantenfysiologie signaaltransductie verdroging vicia faba Wageningen University & Research