Plants (Aug 2020)

Early Molecular Responses of Tomato to Combined Moderate Water Stress and Tomato Red Spider Mite <i>Tetranychus evansi</i> Attack

  • Vicent Arbona,
  • Miguel G. Ximénez-Embún,
  • Alberto Echavarri-Muñoz,
  • Marcos Martin-Sánchez,
  • Aurelio Gómez-Cadenas,
  • Félix Ortego,
  • Miguel González-Guzmán

DOI
https://doi.org/10.3390/plants9091131
Journal volume & issue
Vol. 9, no. 9
p. 1131

Abstract

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Interaction between plants and their environment is changing as a consequence of the climate change and global warming, increasing the performance and dispersal of some pest species which become invasive species. Tetranychus evansi also known as the tomato red spider mite, is an invasive species which has been reported to increase its performance when feeding in the tomato cultivar Moneymaker (MM) under water deficit conditions. In order to clarify the underlying molecular events involved, we examined early plant molecular changes occurring on MM during T. evansi infestation alone or in combination with moderate drought stress. Hormonal profiling of MM plants showed an increase in abscisic acid (ABA) levels in drought-stressed plants while salicylic acid (SA) levels were higher in drought-stressed plants infested with T. evansi, indicating that SA is involved in the regulation of plant responses to this stress combination. Changes in the expression of ABA-dependent DREB2, NCED1, and RAB18 genes confirmed the presence of drought-dependent molecular responses in tomato plants and indicated that these responses could be modulated by the tomato red spider mite. Tomato metabolic profiling identified 42 differentially altered compounds produced by T. evansi attack, moderate drought stress, and/or their combination, reinforcing the idea of putative manipulation of tomato plant responses by tomato red spider mite. Altogether, these results indicate that the tomato red spider mite acts modulating plant responses to moderate drought stress by interfering with the ABA and SA hormonal responses, providing new insights into the early events occurring on plant biotic and abiotic stress interaction.

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