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Abstract
Whatever the in vitro regeneration pathway, it would be of interest to be able to distinguish regeneration-competent from non-regenerating cells and tissues, and as early in culture as possible, as this would allow a dramatic improvement of biotechnology breeding, particularly for the so-called recalcitrant species. With this aim, we examined a range of genotypes of pea (Pisum sativum) and grass pea (Lathyrus sativus), and of the two model species Medicago truncatula, another legume, and Arabidopsis thaliana. This was done by comparing cell suspension cultures of different ages (young [<6 transfers-old]vs. mature [>6 transfers-old]), densities (dense [>107 cells/ml] or sparse [<106 cells/ml]) and regeneration abilities (non-embryogenic vs. embryogenic), in order to identify early indicators of competence for somatic embryogenesis. All such cell suspensions were subcultured every 14 days and several parameters were assessed every 3–4 days during each 14-day cycle. These included the time course pH and osmolarity of the culture medium, the internal osmolarity of cells, the cell surface and the cell wall thickness (by examining cellulose accumulation in Calcofluor White-stained cells under UV light). As cells underwent embryogenesis they enlarged. Cellulose accumulated in the walls of non-embryogenic cells, but walls became thinner with the onset of embryogenesis, and diminished further as embryos matured. Although medium osmolarity decreased at the onset of embryogenesis, this was never observed for non-embryogenic cell suspensions. Conversely, there was a concomitant increase in intracellular osmolarity for embryogenic cells. Medium pH (analysed with the model species only) was not significantly correlated with regeneration competence of cells. For all genotypes and species, the kinetics of cell wall thickness and cell surface, and that of medium and cell osmolarity were reliable early indicators of the competence of cells to undergo somatic embryogenesis. The implication of these results for biotechnological breeding of grain legumes and for plant regeneration competence in general are discussed.
Acknowledgements
The authors thank C. Conreux and L. Jacas for technical assistance, and R.S. Sangwan for providing the seeds of A. thaliana ‘hoc’ and critical reading of the manuscript.