MOLECULAR RESPONSE OF COCOA (Theobroma cacao) TO WATER DEFICIT CONDITIONS

Authors: Jhon Montenegro, Jaime Morante, Milena Acosta, Ramón Jaimez, Mercedes Carranza, Roque Bru, Víctor Huebla, Laura Morante, Néstor Sepúlveda, Fernando Abasolo, John Quiñones
Journal: Journal of Animal and Plant Sciences (JAPS)
ISSN: 1018-7081 (Print), 2309-8694 (Online)
Volume: 33  Issue: 6  Pages: 1314-1321
Year: 2023
DOI: https://doi.org/10.36899/JAPS.2023.6.0671
URL: https://doi.org/https://doi.org/10.36899/JAPS.2023.6.0671
Publisher: Pakistan Agricultural Scientists Forum

Abstract:
<p><em><span lang="EN-US">Theobroma cacao</span></em><span lang="EN-US">&nbsp;is very important in the economy of many tropical countries, especially in Ecuador. The development and production of&nbsp;<em>Theobroma cacao</em>&nbsp;have been limited by the attack of diseases, pests, and currently by the impact caused by the water deficit. The loss of water in the crop causes a low production of the plantations. In addition, when genetic diversity is scarce, the possible combinations of genes capable of conferring biological adaptation and, consequently, the capacity to adapt to environmental variations, are reduced. Therefore, a viable option is to identify genes capable of conferring adaptation to water deficit stress. The objective of this research was to characterize genes of&nbsp;<em>Theobroma cacao</em>&nbsp;in response to water deficit. The sequencing and characterization of genes related to water stress were achieved and, finally, the hybridization profile of the genes (ABA, ODC, DEH, and ABS) in response to Actin (ACT) was analyzed. The ABS gene hybridized 100 % with DNA from rootstock EET399 in roots and 80 % with DNA from graft T24 in leaves. The OCD gene hybridized 80 % with DNA from rootstock IMC6 and 25 % with the T800 graft in leaves. The DEH gene hybridized below the normalizing gene (ACT) in both rootstock EET400 (10 %) in root DNA and graft T12 (5 %) in leaves. Finally, the ABA gene did not hybridize with the DNA of the CCN51 rootstock or with the graft (T801) in both roots and leaves, respectively. This research is key to understand some molecular mechanisms of&nbsp;<em>T. cacao&nbsp;</em>in response to water deficit and can be considered as a viable strategy to reduce crop agronomic losses under the current environmental scenario.</span></p>

Keywords: Genes- Hybridization-Rootstock-Grafts,-Water deficit-Local Species