Grape cytochrome P450 CYP90D1 regulates brassinosteroid biosynthesis and increases vegetative growth.

Vine vigor or vegetative growth is an important factor related to berry quality and vinicultural training management, but brassinosteroid (BR)-induced molecular mechanisms underlying vine growth remain unclear. In this study, the hypothesis that the Vitis vinifera CYP90D1 gene VvCYP90D1, one of the genes for BR biosynthesis, plays a critical role in shoot elongation was tested. RNA sequencing analysis of shoots collected from the vigorous cultivar Koshu (KO) and the reference cultivar Pinot Noir (PN) 7 days after bud break showed higher expression levels of various genes in the BR biosynthesis pathway in KO than in PN. The VvCYP90D1 expression level in KO was highest in meristems, followed by internodes and leaves. Cluster analysis of amino acid sequences including those in other plant species showed that the isolated gene belonged to the CYP90D1 group. The vegetative growth and the endogenous BR (brassinolide; BL) content were significantly higher in VvCYP90D1-overexpressing Arabidopsis than in wild type. VvCYP90D1-overexpressing Arabidopsis treated with brassinazole (Brz), a BR biosynthesis inhibitor, showed recovery of vegetative growth. These results indicate that VvCYP90D1 in grapevine has a vegetative growth promoting effect via BR biosynthesis. Our findings on the mechanism of BR-induced grape shoot growth will contribute to the development of new shoot control techniques for grapevine.

Electrical Stimulation Enhances Plant Defense Response in Grapevine through Salicylic Acid-Dependent Defense Pathway.

Concern over environmental pollution generated by chemical fungicides has led to the introduction of alternative pest management strategies to chemical fungicide application. One of those strategies is the induction of plant defense response by an abiotic elicitor. In the present study, field-grown grapevines were subjected to electrical stimulation using a solar panel from two weeks before flowering to harvest in the 2016 and 2020 growing seasons. In both years, electrical stimulation decreased the incidence of gray mold and/or ripe rot on bunches and downy mildew on leaves of the field-grown grapevine. Transcription of a gene encoding ß-1,3-glucanase but not class IV chitinase in leaves of potted grapevine seedlings was upregulated 20 days after electrical stimulation, suggesting that electrical stimulation acts as an abiotic elicitor of plant defense response to fungal diseases. The gene expression of PR1 but not PDF1.2 was upregulated in Arabidopsis plants subjected to electrical stimulation. On the other hand, PR1 gene expression was not induced in salicylic acid (SA)-insensitive Arabidopsis mutant npr1-5 subjected to electrical stimulation. Taken together, electrical stimulation is responsible for plant defense response through the SA-dependent defense pathway. These findings would help us develop a novel and innovative practical technique that uses electrical stimulation in integrated pest management.

Crosstalk Pathway between Trehalose Metabolism and Cytokinin Degradation for the Determination of the Number of Berries per Bunch in Grapes.

In grapes, the number of flowers per inflorescence determines the compactness of grape bunches. Grape cultivars with tight bunches and thin-skinned berries easily undergo berry splitting, especially in growing areas with heavy rainfall during the grapevine growing season, such as Japan. We report herein that grape cytokinin oxidase/dehydrogenase 5 (VvCKX5) determines the number of berries per inflorescence in grapes. The number of berries per bunch was inversely proportional to the VvCKX5 expression level in juvenile inflorescences among the cultivars tested. VvCKX5 overexpression drastically decreased the number of flower buds per inflorescence in Arabidopsis plants, suggesting that VvCKX5 might be one of the negative regulators of the number of flowers per inflorescence in grapes. Similarly, the overexpression of grape sister of ramose 3 (VvSRA), which encodes trehalose 6-phosphate phosphatase that catalyzes the conversion of trehalose-6-phosphate into trehalose, upregulated AtCKX7 expression in Arabidopsis plants, leading to a decrease in the number of flower buds per Arabidopsis inflorescence. VvCKX5 gene expression was upregulated in grapevine cultured cells and juvenile grape inflorescences treated with trehalose. Finally, injecting trehalose into swelling buds nearing bud break using a microsyringe decreased the number of berries per bunch by half. VvCKX5 overexpression in Arabidopsis plants had no effect on the number of secondary inflorescences from the main inflorescence, and similarly trehalose did not affect pedicel branching on grapevine inflorescences, suggesting that VvCKX5, as well as VvSRA-mediated trehalose metabolism, regulates flower formation but not inflorescence branching. These findings may provide new information on the crosstalk between VvSRA-mediated trehalose metabolism and VvCKX-mediated cytokinin degradation for determining the number of berries per bunch. Furthermore, this study is expected to contribute to the development of innovative cultivation techniques for loosening tight bunches.

Exogenous allantoin improves anthocyanin accumulation in grape berry skin at early stage of ripening.

Anthocyanin accumulation in grape berry skin is a crucial determinant of red/black grape berry quality. Recently, viticulture has been hampered by the issue of global warming, which has led to loss of anthocyanin accumulation in berry skin. The objectives of this study were to investigate the effect of allantoin on anthocyanin accumulation in berry skins of field-grown grapevines and to elucidate the molecular mechanism of the allantoin-induced anthocyanin accumulation in the berry skins. Allantoin enhanced anthocyanin accumulation in grape cultured cells and berry skins from field-grown grapevines at the early stage of ripening. MybA1 and UFGT, which encode the key transcription factor and enzyme in anthocyanin biosynthesis, were upregulated in allantoin-treated berry skins. Allantoin seems to increase the contents of delphinidin-based anthocyanin 3-glucosides in berry skins through the upregulation of F3'5'H gene that drives the synthesis of delphinidin-based anthocyanin 3-glucosides, compared with control berry skins. Allantoin increased soluble sugar contents in berries 10 days after treatment and upregulated abscisic acid (ABA)-responsible HT6 gene that encodes a key hexose transporter in sugar accumulation during ripening, in berry skins. These results suggested that physiological changes in allantoin-treated grape berries occurred in an ABA-dependent manner. Allantoin produced bioactive ABA through the ß-glucosidase-catalyzed hydrolysis of glucose-conjugated ABA but not through the ABA biosynthesis by NCED, a key enzyme in ABA biosynthesis, in berry skins. Allantoin application in viticulture under global warming conditions is expected to contribute to mitigating loss of red/black berry skin color.