Abstract
Molecular changes associated with response to powdery mildew (PM) caused by Erysiphe necator have been largely explored in Vitis vinifera cultivars, but little is known on transcriptional and metabolic modifications following application of resistance elicitors against this disease. In this study, the whole transcriptome sequencing, and hormone and metabolite analyses were combined to dissect long-term defense mechanisms induced by molecular reprogramming events in PM-infected ‘Moscato’ and ‘Nebbiolo’ leaves treated with three resistance inducers: acibenzolar-S-methyl, potassium phosphonate, and laminarin. Although all compounds were effective in counteracting the disease, acibenzolar-S-methyl caused the most intense transcriptional modifications in both cultivars. These involved a strong down-regulation of photosynthesis and energy metabolism and changes in carbohydrate accumulation and partitioning that most likely shifted the plant growth-defense trade-off towards the establishment of disease resistance processes. It was also shown that genotype-associated metabolic signals significantly affected the cultivar defense machinery. Indeed, ‘Nebbiolo’ and ‘Moscato’ built up different defense strategies, often enhanced by the application of a specific elicitor, which resulted in either reinforcement of early defense mechanisms (e.g., epicuticular wax deposition and overexpression of pathogenesis-related genes in ‘Nebbiolo’), or accumulation of endogenous hormones and antimicrobial compounds (e.g., high content of abscisic acid, jasmonic acid, and viniferin in ‘Moscato’).
Highlights
Climate change has been seriously impacting the productivity of agricultural ecosystems in the world [1,2]
This finding showed that, Lam was successful in containing powdery mildew (PM) attack [40], the overall transcriptomic changes induced by this eco-friendly compound were poor
The molecular scenario emerging from the elaboration of RNAseq data indicated that AcS-Mt is the compound that causes the most intense transcriptome perturbation in PM-infected leaves, regardless of genotype-associated variability
Summary
Climate change has been seriously impacting the productivity of agricultural ecosystems in the world [1,2]. Grapevine (Vitis vinifera L.) is one of the most economically important fruit crops, worldwide renowned for winemaking and grape consumption. Cultivars of V. vinifera are heavily impacted by environmental variables [6], as they are cultivated in vineyard areas that span diverse climates across the planet [7]. Attacks due to powdery mildews have been seriously worsened by climate alterations, as they are highly favored by increases in CO2 and temperature [10,11]. The enhancing effect of increased CO2 concentrations and high temperatures on powdery mildew was experimentally demonstrated in grapevine plants grown within phytotrons [12]
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