Apomixis (asexual reproduction through seeds) is considered a deviation of the sexual
reproductive pathway leading to the formation of clonal progenies genetically identical to the
mother plant. It has been suggested that apomixis might be a consequence of epigenetic alterations,
such as interspecific hybridization and polyploidization, resulting in a wide deregulation of
reproductive development. Studies on epigenetic are transforming our actual idea of the structural
variation and diversity that prevails at key steps of plant female gametogenesis, with deep
implications for understanding the evolutionary trends that model innovation in reproductive
development and adaptation. Recent results have provided evidences indicating that epigenetic
mechanisms are crucial to control events that distinguish sexual from apomictic development.
Therefore, the epigenetic regulation of apomixis is an attractive theory as it potentially accounts for
the facultative nature of apomixis as well as the ability of apomictic to revert back to sexuality. In
this work we used the Methylation-Sensitive Amplification Polymorphism (MSAP) technique to
characterize floral genome cytosine methylation patterns occurring in sexual and aposporous
Paspalum notatum genotypes, in order to identify epigenetically-controlled genes putatively
involved in apomixis development. A partial and rather divergent methylation reprogramming was
detected in apomictic genotypes. From twelve polymorphic MSAP-derived sequences, one
(PN_6.6, renamed PN_SCD1) was selected due to its relevant annotation and differential
representation in 454 floral transcriptome libraries of sexual and apomictic P. notatum. PN_6.6
encodes the DENN domain/WD repeat-containing protein SCD1, which interacts with RAB
GTPases- and/or MAPKs to promote specialized cell division, functions in clathrin-mediated
membrane transport and was defined as potential substrate receptor of CUL4 E3 ubiquitin ligases.
Quantitative RT-PCR and comparative RNAseq analyses of laser microdissected nucellar cells
confirmed PN_SCD1 upregulation in florets of apomictic plants and revealed that overexpression
takes place just before the onset of apospory initials. Moreover, we found that several SCD1
molecular partners are upregulated in florets of P. notatum apomictic plants. Our results revealed a
specific vesicle trafficking molecular pathway epigenetically modulated during apomixis. Results
will be presented and critically discussed