Water Stress in Dwarfing Cherry Rootstocks: Increased Carbon Partitioning to Roots Facilitates Improved Tolerance of Drought

Cherry orchards are transitioning to high-density plantings and dwarfing rootstocks to maximize production, but the response of these rootstocks to drought stress is poorly characterized. We used a 16-container, automated lysimeter system to apply repeated water stress to ungrafted Krymsk(R) 5 and 6 rootstocks during two growing cycles. Drought stress was imposed by withholding irrigation until the daily transpiration rate of each tree was 25% and 30% of the unstressed rate during the first trial and second trial, respectively. After this point was reached, the root-zone water status was restored to field capacity. Whole-tree transpiration measurements were supplemented with leaf-level gas-exchange measurements. Krymsk(R) 6 had a higher rate of photosynthesis, more vigorous vegetative growth and less conservative stomatal regulation during incipient drought than Krymsk(R) 5. At harvest, carbon partitioning to roots was greater in Krymsk(R) 6 than Krymsk(R) 5. The conservative rate of water use in Krymsk(R) 5 could be a function of greater stomatal control or reduced carbon partitioning to roots, which thereby limited transpiration rates. Further studies are needed to confirm that these results are applicable to trees grown using a common grafted scion under field conditions.

Automated summary

The study found that Krymsk(R) 6 rootstock exhibited higher photosynthesis rate, more vigorous vegetative growth, and less conservative stomatal regulation during incipient drought compared to Krymsk(R) 5. On the other hand, Krymsk(R) 5 showed a more conservative water use efficiency, likely due to greater stomatal control or reduced carbon partitioning to roots. Further research is needed to confirm the applicability of these results to grafted scion trees grown under field conditions.