What question did this study set out to answer?

The objective was to examine how different canopy heights influence berry quality in specific grape cultivars using advanced profiling techniques.

May 20, 2026Open Access

Canopy Height Regulates Berry Quality in Wine Grapes: A Cultivar-Specific Insight from Metabolic Profiling and Machine Learning

Key Points

The objective was to examine how different canopy heights influence berry quality in specific grape cultivars using advanced profiling techniques.
Conducted a two-year field experiment with three different canopy heights (100 cm, 120 cm, 140 cm)
Used metabolic profiling and machine learning techniques to analyze berry quality parameters
Evaluated two grape cultivars, ‘Chardonnay’ and ‘Merlot’, to uncover cultivar-specific responses.
High canopy (T3) increased total soluble solids and decreased titratable acidity across both cultivars.
Chardonnay displayed higher total polyphenol accumulation under lower canopy heights, while Merlot benefited from moderate-to-high canopy heights for anthocyanin production.
Key biomarkers were identified through SHAP analysis for both cultivars, aiding in precision viticulture.

Abstract

A two-year field experiment was conducted in the eastern foothills of Helan Mountain, Ningxia, China, to investigate the effects of three canopy heights (T1: 100 cm, T2: 120 cm, T3: 140 cm) on berry quality parameters of Vitis vinifera L. cvs. ‘Chardonnay’ (CH) and ‘Merlot’ (ML). Metabolic profiling, chemometrics, and machine learning methods were integrated to reveal cultivar-specific responses. Increasing canopy height significantly promoted total soluble solids (TSS) accumulation and reduced titratable acidity (TA) in both cultivars, with ML showing higher sensitivity. Phenolic and volatile organic compounds (VOCs) exhibited distinct cultivar-dependent patterns. CH accumulated higher contents of total polyphenols and non-anthocyanin phenolics under T1 and T2, while ML was richer in polyphenols, anthocyanins, and non-anthocyanin phenolics under T2 and T3. T3 significantly enhanced methylated anthocyanins, whereas T2 favored acylated anthocyanins in ML. Total VOCs were the highest in CH under T1, but in ML under T2 and T3, with alcohols and esters being the most responsive classes. Based on SHAP analysis of the optimal support vector machine (SVM) for CH and random forest (RF) models for ML, trans -ferulic acid, 1-butanol, and ethyl caprylate served as key biomarkers for CH, while gentisuric acid, malvidin-3- O -(6- O -coumaroyl)-glucoside, and TSS represented those for ML. This study provides a theoretical basis for precise canopy management and targeted improvement of wine grape quality in this region. • Metabolic profiling, chemometrics and machine learning were integrated to clarify canopy height regulation on grape quality. • High canopy (T3) promoted sugar accumulation and reduced titratable acidity in berries. • Canopy height regulated phenolic and flavor properties with distinct cultivar specificity in wine grapes. • Low-to-moderate canopy (T1, T2) benefited phenolics and volatiles in CH; moderate-to-high canopy (T2, T3) favored ML. • Interpretable SHAP analysis identified key biomarkers for cultivar-specific canopy responses.

Read Full Paperexternally

Bookmark

View Full Paper

Cite This Study

Xie et al. (Fri,) studied this question.

synapsesocial.com/papers/6a0d50bdf03e14405aa9cc46 https://doi.org/https://doi.org/10.1016/j.jafr.2026.103004

Bookmark

View Full Paper