Does root‐sourced ABA have a role in mediating growth and stomatal responses to soil compaction in tomato ( Lycopersicon esculentum )?

Isogenic wild‐type (Ailsa Craig) and abscisic acid (ABA)‐deficient mutant ( flacca ) genotypes of tomato were used to examine the role of root‐sourced ABA in mediating growth and stomatal responses to compaction. Plants were grown in uniform soil columns providing low to moderate bulk densities (1.1–1.5 g cm −3 ), or in a split‐pot system, which allowed the roots to divide between soils of the same or differing bulk density (1.1/1.5 g cm −3 ). Root and shoot growth and leaf expansion were reduced when plants were grown in compacted soil (1.5 g cm −3 ) but leaf water status was not altered. However, stomatal conductance was affected, suggesting that non‐hydraulic signal(s) transported in the transpiration stream were responsible for the observed effects. Xylem sap and foliar ABA concentrations increased with bulk density for 10 and 15 days after emergence (DAE), respectively, but were thereafter poorly correlated with the observed growth responses. Growth was reduced to a similar extent in both genotypes in compacted soil (1.5 g cm −3 ), suggesting that ABA is not centrally involved in mediating growth in this severely limiting ‘critical’ compaction stress treatment. Growth performance in the 1.1/1.5 g cm −3 split‐pot treatment of Ailsa Craig was intermediate between the uniform 1.1 and 1.5 g cm −3 treatments, whereas stomatal conductance was comparable to the compacted 1.5 g cm −3 treatment. In contrast, shoot dry weight and leaf area in the split‐pot treatment of flacca were similar to the 1.5 g cm −3 treatment, but stomatal conductance was comparable to uncompacted control plants. These results suggest a role for root‐sourced ABA in regulating growth and stomatal conductance during ‘sub‐critical’ compaction stress, when genotypic differences in response are apparent. The observed genotypic differences are comparable to those previously reported for barley, but occurred at a much lower bulk density, reflecting the greater sensitivity of tomato to compaction. By alleviating the severe growth reductions induced when the entire root system encounters compacted soil, the split‐pot approach has important applications for studies of the role of root‐sourced signals in compaction‐sensitive species such as tomato.