2016
DOI: 10.1111/gcb.13503
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Atmospheric CO2 enrichment and drought stress modify root exudation of barley

Abstract: Rising CO concentrations associated with drought stress is likely to influence not only aboveground growth, but also belowground plant processes. Little is known about root exudation being influenced by elements of climate change. Therefore, this study wanted to clarify whether barley root exudation responds to drought and CO enrichment and whether this reaction differs between an old and a recently released malting barley cultivar. Barley plants were grown in pots filled with sand in controlled climate chambe… Show more

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Cited by 58 publications
(26 citation statements)
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“…These findings are interesting with respect to the discussion that plants or microbes engineered to overproduce trehalose survive better under drought stress (Glick, ). Changes in the composition and amounts of metabolites, such as organic acids, released in root exudates from drought‐affected plants probably contribute to changes in the root microbiome and function (Bouskill et al ., ; Calvo et al ., ; Naylor and Coleman‐Derr, ).…”
Section: Probiotic Trait: the Significance Of Biofilm Formation By Thmentioning
confidence: 99%
“…These findings are interesting with respect to the discussion that plants or microbes engineered to overproduce trehalose survive better under drought stress (Glick, ). Changes in the composition and amounts of metabolites, such as organic acids, released in root exudates from drought‐affected plants probably contribute to changes in the root microbiome and function (Bouskill et al ., ; Calvo et al ., ; Naylor and Coleman‐Derr, ).…”
Section: Probiotic Trait: the Significance Of Biofilm Formation By Thmentioning
confidence: 99%
“…This C efflux contributes to 4‐ to 20‐fold increases in microbial biomass and up to 3‐fold increases in the rates of decomposition of organic substrates in the rhizosphere compared to the bulk soil (Blagodatskaya, Blagodatsky, Anderson, & Kuzyakov, ). Plant roots release up to 20–30% of total photosynthetically‐fixed C into the rhizosphere (Calvo et al, ), which is metabolized by microorganisms and incorporated into soil C pools. However, elevated atmospheric CO 2 (eCO 2 ) concentration not only increases the quantity of rhizodeposits but also alters their quality in many plant species (Jin et al, ).…”
Section: Introductionmentioning
confidence: 99%
“…In view of this increase in performance and productivity promoted by high [CO 2 ], even in the presence of abiotic stresses, should we really be concerned about the dynamics of the distribution and survival of forest species under a climate change scenario? The answer to this question is extremely complex because the beneficial effects of high [CO 2 ] found in some studies (Drake et al, 2011;Idso & Kimbal, 1997;Oliveira et al, 2016;Pérez-Jiménez, Hernández-Munuera, Piñero, López-Ortega, & del Amor, 2018;Radoglou & Jarvis, 1990;Rodrigues et al, 2016;Roy et al, 2016;Swann et al, 2016;Yu et al, 2014) are in direct contrast to the results of several other reports (Calvo et al, 2017;Clark, Clark, & Oberbauer, 2010;Faralli et al, 2017;Feeley, Joseph Wright, Nur Supardi, Kassim, & Davies, 2007;Voelker et al, 2017).…”
Section: The Controver S Ial Role Of C Arbon D I Oxide: a P Otentiamentioning
confidence: 99%