Induction of somatic embryos of celery by control of gaseous compositions and other physical conditions

Abstract

The celery (Tall Utah, Apium graveolens var. dulce) was adopted as a model system to investigate effective methods for enhancing embryogenesis. The focus was placed on attaining the optimum gaseous composition and the mixing intensity and viscosity of culture systems. The mixing intensity was investigated by using creased flasks and evaluated by shear force index (SFI). By using different closures with different ventilation coefficients, K w, to adjust the gaseous composition in the flasks, it was found that embryo frequency (EF) increased with high \(P_{{\rm O}_2}\) or low ethylene concentration in the headspace of the culture flasks. Cultivating the embryogenic cells under controlled ethylene concentrations depressed EF at ethylene concentrations higher than 0.08 ppm. Moreover, 0.1 μM of CoCl2 remarkably repressed the ethylene formation in the culture medium and enhanced EF. \(P_{{\rm CO}_2}\) and \(P_{{\rm O}_2}\) around 3% and 30%, respectively, favored EF. For non-creased flasks, addition of CMC (carboxymethyl cellulose) decreased the EF and DO level of the medium, due to lowered mass transfer rate attributed to high viscosity. For creased flasks, supplementation of 0.4 g/ 100 ml CMC reduced the ill-effects of high shear stress and maximized EF (7.22%). Our results are potentially applicable to other species and large-scale embryo production systems.