Transcriptome and metabolome reveal the effects of three canopy types on the flavonoids and phenolic acids in 'Merlot' (Vitis vinifera L.) berry pericarp.

The flavonoids and phenolic acids in grape berries greatly influence the quality of wine. Various methods are used to shape and prune grapevines, but their effects on the flavonoids and phenolic acids remain unclear. The flavonoids and phenolic acids in the berry pericarps from grapevines pruned using three types of leaf canopy, namely, V-shaped, T-shaped, and vertical shoot-positioned (VSP) canopies, were compared in this study. Results showed that the V-shaped canopy was more favorable for the accumulation of flavonoids and phenolic acids. Transcriptome and metabolome analyses revealed that the differentially expressed genes (DEGs) and differentially regulated metabolites (DRMs) were significantly enriched in the flavonoid and phenylpropanoid biosynthesis pathways. A total of 96 flavonoids and 32 phenolic acids were detected among the DRMs. Their contents were higher in the V-shaped canopy than in the T-shaped and VSP canopies. Conjoint analysis of transcriptome and metabolome showed that nine DEGs (e.g., cytochrome P450 98A9 and 98A2) were significantly correlated to nine phenolic acids (e.g., gentisic acid and neochlorogenic acid) and three genes (i.e., chalcone isomerase, UDP-glycosyltransferase 88A1, and caffeoyl-CoA O-methyltransferase) significantly correlated to 15 flavonoids (e.g., baimaside and tricin-7-O-rutinoside). These genes may be involved in the regulation of various flavonoids and phenolic acids in grape berries, but their functions need validation. This study provides novel insights into the effects of leaf canopy on flavonoids and phenolic acids in the skin of grape berries and reveals the potential regulatory networks involved in this phenomenon.

Effects of fruit tree canopy shading on grain filling of intercropping winter wheat.

Fruit tree-wheat intercropping system is the main agricultural production pattern in sou-thern Xinjiang. In this study, almond (Amygdalus communis)-winter wheat (Xindong 20 (Triticum aestivum, var. Xindong 20) intercropping system was used as the research object. Four tree forms of delayed open-central shape (DC), open-center shape (OC), high stem-shape (HS), and semicircle small-canopy shape (SC) and three intercropping distances (wheat intercropping area respectively 1.5, 2.5 and 3.5 m from the tree trunk) were set to create tree canopy shading treatments, with monoculture wheat as the control. The environmental factors and the grain filling characteristic of winter wheat under different treatment conditions were measured, and the correlation between grain filling characteristics and 1000-grain weight and environmental factors was established to provide information for selecting the best management standards and optimizing the intercropping system. The results showed that under the almond tree-winter wheat intercropping system, the PAR, red/far-red light (R/FR), and temperature above the wheat canopy were significantly decreased due to canopy shading, resulting in a significant increase in humidity. The degree of variation was affected by tree form and distance. The PAR decrease degree of the four treatments was DC＞OC/HS＞SC, except for HS. The PAR decrease of the other tree form treatments was 1.5 m＞2.5 m＞3.5 m. The PAR decrease was distributed in the range of 35.5%-86.6%. A cubic polynomial equation represented the grain filling process, and the specific property of grain filling and 1000-grain weight was assessed using the correlation analysis. The decrease in the 1000-grain weight in the intercropping system was closely associated with the decreases in average grain-filling rate (V), maximum grain-filling rate (Vmax), effective grain-filling duration (Se), and effective grain-filling duration (Vs). The shortening of Se and the reduction in the grain filling rate were related with the reduction in the PAR incidence above the wheat canopy. In the fruit tree-winter wheat intercropping system, the reduction of PAR, dry matter accumulation after flowering, and Se were reduced by tree canopy shading consequently for the decrease in the 1000-grain weight of the intercropping wheat. When the distance between the intercropping area and the tree trunk was greater than 75% of tree height, and shading intensity was less than 35.5% of the natural light intensity, the intercropping with the almond tree could increase the 1000-grain weight of wheat by increasing the effective grain-filling duration.