Identification of differentially expressed cDNA sequences and histological characteristics of Hevea brasiliensis calli in relation to their embryogenic and regenerative capacities.

Different friable Hevea callus lines from the same genotype can display different embryogenic and regenerative potentials. These lines can not be distinguished on the basis of macroscopic criteria. A histological and molecular study was undertaken to characterize the differences existing between five callus lines with different potentials. The genes differentially expressed during induction were analyzed using the differential display (DD-RT) technique. Twenty-eight cDNAs were found to be differentially expressed during induction in the embryogenic regenerating line (ER). Embryogenic nodules were formed earlier in the ER lines than in the embryogenic non-regenerating lines and were completely absent in the non-embryogenic line. Of these 28 cDNAs, five could be used to distinguish between calli prior to induction, thereby enabling an early diagnosis of friable Hevea callus embryogenic potential.

Differential carbohydrate metabolism conducts morphogenesis in embryogenic callus of Hevea brasiliensis (Müll. Arg.).

Somatic embryogenesis in Hevea is stimulated when the embryogenesis induction medium contains maltose, rather than glucose, fructose, or sucrose, in equimolarity (Blanc et al., 1999). Kinetic analyses were carried out on various physiological and biochemical indicators over the 8 weeks that the induction phase then expression of somatic embryogenesis can take. Embryogenesis induction in the presence of glucose, fructose or sucrose revealed strong callus growth in the first 3-4 weeks, associated with a high intra- and extracellular hexose content, a high starch content and a substantial decline in protein synthesis. In the presence of maltose, callus growth was slow and only half that seen with sucrose. This morphogenetic behaviour is associated with a drop in endogenous hexose and starch contents, and an increase in protein synthesis in the first three weeks of culture. The induction of embryogenesis in the presence of maltose was uniform and twice as fast as with sucrose supply. At the end of culture, peroxidase activity, antioxidant and membrane protein contents increased in these calluses; these characteristics may be associated with somatic embryo organization and with the maintenance of effective membrane integrity within a nutrient environment that has become limiting. These new results tally with data in the literature on the roles of sugars, and provide some precise information with regard to the 'carbohydrate deficit' hypothesis usually put forward to explain maltose action. An analysis of these results led to the hypothesis that regulation of endogenous hexose contents at a low level, through slow maltose hydrolysis, was a key element of the biochemical signal leading this callus towards somatic embryogenesis.