Soil Temperature Prior to Veraison Alters Grapevine Carbon Partitioning, Xylem Sap Hormones, and Fruit Set

Stewart K. Field; Jason P. Smith; Erin N. Morrison; R.J. Neil Emery; Bruno Holzapfel

Ayuda

Soil Temperature Prior to Veraison Alters Grapevine Carbon Partitioning, Xylem Sap Hormones, and Fruit Set

Stewart K. Field ^[1] ; Jason P. Smith ^[1] ; Erin N. Morrison ^[2] ; R.J. Neil Emery ^[2] ; Bruno P. Holzapfel ^[1]
1. [1] Charles Sturt University
  
  Charles Sturt University
  
  Australia
2. [2] Trent University
  
  Trent University
  
  Canadá
Localización: American Journal of Enology and Viticulture, ISSN 0002-9254, Vol. 71, Nº 1, 2020, págs. 52-61
Idioma: inglés
Texto completo no disponible (Saber más ...)
Resumen
- To gain a better understanding of environmental effects on grapevines and the physiological regulation of acclimation, we determined the effects of soil temperature (14 or 24°C) between anthesis and veraison on growth, nonstructural carbohydrates, cytokinins, abscisic acid, and leaf function of potted Vitis vinifera cv. Shiraz. Plants of each regime were selected from two groups that had been grown in a glasshouse from three weeks prior to budbreak at an average soil temperature of either 13 or 23°C. Soil temperature between anthesis and veraison affected utilization and restoration of root and trunk nonstructural carbohydrates and changes in biomass of major plant organs. Soil warming promoted shoot growth via utilization of starch reserves, while soil cooling promoted starch storage in both the root and wood and shifted overall biomass partitioning to the roots. A change in soil temperature from warm to cool through flowering was also associated with reduced fruit set. Diurnal courses of photosynthesis, transpiration, and stomatal conductance after fruit set were significantly affected by soil temperature. Phytohormones (cytokinin and abscisic acid) were measured in the xylem sap and leaves at fruit set and veraison. Differences between these two sample types during grapevine development highlight a phytohormone shift likely involved in postveraison fruit ripening. We conclude that soil temperature significantly affects grapevine growth and that the responses are mediated largely by an influence of temperature on mobilization of nonstructural carbohydrates from the roots.