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(Reference retrieved automatically from SciELO through information on FAPESP grant and its corresponding number as mentioned in the publication by the authors.)

Hydrogen peroxide is involved in drought stress long-distance signaling controlling early stomatal closure in tomato plants

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Author(s):
A. D. P. Reis [1] ; R. F. Carvalho [2] ; I. B. Costa [3] ; R. J. S. Girio [4] ; R. Gualberto [5] ; R. C. Spers [6] ; L. A. Gaion [7]
Total Authors: 7
Affiliation:
[1] Universidade de Marília. Center of Agrarian Sciences - Brasil
[2] Universidade Estadual Paulista. Department of Biology Applied to Agriculture - Brasil
[3] Universidade de Marília. Center of Agrarian Sciences - Brasil
[4] Universidade de Marília. Center of Agrarian Sciences - Brasil
[5] Universidade de Marília. Center of Agrarian Sciences - Brasil
[6] Universidade de Marília. Center of Agrarian Sciences - Brasil
[7] Universidade de Marília. Center of Agrarian Sciences - Brasil
Total Affiliations: 7
Document type: Journal article
Source: Brazilian Journal of Biology; v. 82, 2022-11-14.
Abstract

Abstract It has long been hypothesized that hydrogen peroxide (H2O2) may play an essential role in root-to-shoot long-distance signaling during drought conditions. Thus, to better understand the involvement of H2O2 in drought signaling, two experiments were carried out using tomato plants. In the first experiment, a split-root scheme was used, while in the second experiment, the tomato plants were grown in a single pot and subjected to drought stress. In both experiments, H2O2 and catalase were applied together with irrigation. Control plants continued to be irrigated according to the water loss. In the split-root experiment, it was verified that the application of H2O2 to roots induced a clear reduction in plant transpiration compared to untreated or catalase-treated plants. In the second experiment, we observed that H2O2-treated plants exhibited similar transpiration when compared to untreated and catalase-treated plants under drought stress. Similarly, no difference in water use efficiency was observed. Thus, we conclude that the increase in H2O2 in the root system can act as a long-distance signal leading to reduced transpiration even when there is no water limitation in the shoot. But it has little effect when there is a reduction in the shoot water potential. (AU)

FAPESP's process: 19/20339-9 - Is the hydrogen peroxide involved in long-distance signaling responsible for activating water deficit acclimatization mechanisms?
Grantee:Aline Dell Passo Reis
Support Opportunities: Scholarships in Brazil - Scientific Initiation