In vitro somatic embryogenesis, an

In vitro somatic embryogenesis, an asexual form of plant
propagation in nature in which an embryo forms through the
developmental pathway of zygotic embryogenesis (Von Arnold
et al., 2002), is an important prerequisite for genetic improvement
and an efficient vegetative propagation pathway for cyclamen
(Winkelmann et al., 2006; Siddiqui et al., 2009). Propagation of trueto-
type plans via somatic embryogenesis lead to the production of
elite and new genotypes in a short time frame (Kamle et al., 2011).
There are advantages and disadvantages of somatic embryogenesis
in large-scale plant multiplication. The major advantages are largescale
somatic embryo production in bioreactors, encapsulation,
cryopreservation, genetic transformation and clonal propagation.
The major limitations are genotypic dependence of somatic embryo
production and poor germination rate (Rout et al., 2006).
Micropropagation of cyclamen via organogenesis or via somatic
embryogenesis has already been reported (Kiviharju et al., 1992;
Kreuger et al., 1995; Takamura et al., 1995; Schwenkel and
Winkelmann, 1998; Seyring et al., 2009; Jalali et al., 2010a,b). One
aim of somatic embryogenesis is to find a protocol for the production
of synthetic seeds that can replace the generative propagation
technique used to date (Lyngved et al., 2008). Other more specialist
applications include the production of high-value compounds
by somatic embryos grown in bioreactors (Dunwell, 2009). Consequently,
somatic embryogenesis has been deemed as an efficient
system for in vitro clonal propagation (Bian et al., 2010).
Another aspect of breeding objectives is that conventional interspecific
hybridization between C. persicum cultivars and other