Ultrastructure of Early Secondary Embryogenesis by Multicellular and Unicellular Pathways in Cork Oak (Quercus suber L.)

Early cellular events during secondary embryogenesis were studiedin a cork oak recurrent embryogenic system in which embryosarise either in a multicellular budding pathway from a compactmass of proliferation or from isolated single cells in friablecallus. The compact mass of proliferation originated from theepidermal cells at the hypocotyl whose growth and convolutionwas characterized by a decrease in the nucleus/cytoplasm ratioand a marked increase in storage products. The transition fromthe compact mass to meristematic primordia occurred at the peripheryand was accompanied by cell dedifferentiation and a drasticreduction of storage products. Meristematic primordia evolvedto globular embryos by the organization of a protodermis andtwo internal centres. Microscope analysis of friable callusshowed an hypothetical sequence from single cells to aggregatesof a few cells, meristematic cell clusters and globular embryos.Single cells showed typical features of embryogenic cells suchas rich cytoplasm and a large number of starch grains and lipidbodies. A progressive cell dedifferentiation and a drastic reductionof storage products was observed when aggregates of a few cellsand meristematic cell clusters were compared. Progressive bipolarizationin large meristematic cell clusters initiated globular embryoformation. The comparison of both embryogenic pathways at theultrastructural level showed that subcellular changes followa similar sequential pattern, especially with regard to thestorage products. The possible role of plastid extrusions andmultivesicular bodies in the changing pattern of starch metabolismduring embryogenesis is discussed. Copyright 2001 Annals ofBotany Company Quercus suber L, cork oak, somatic embryogenesis, multicellular budding, friable callus, ultrastructural studies     

Histology of Organogenic and Embryogenic Responses in Cotyledons of Somatic Embryos of Quercus Suber L

In cork oak (Quercus suber L.), recurrent embryogenesis is produced in vitro through autoembryony without exogenous plant growth regulators (PGRs); secondary embryos appear on the embryo axis but seldom on cotyledons. Focusing mainly on the histological origin of neoformations, we investigated the influence of the embryo axis and exogenous PGRs on the embryogenic potential of somatic embryo cotyledons. Isolated cotyledons of somatic embryos became necrotic when cultured on PGR-free medium but gave secondary embryos when cultured on media containing benzyladenine and naphthaleneacetic acid. Cotyledons of cork oak somatic embryos are competent to give embryogenic responses. Isolated cotyledons without a petiole showed a lower percentage of embryogenic response than did those with a petiole. In petioles, somatic embryos arose from inner parenchyma tissues following a multicellular budding pattern. Joined to the embryo axis, cotyledons did not show morphogenic responses when cultured on PGR-free medium but revealed budlike and phylloid formations when cultured on medium with PGRs. The different morphogenic behavior displayed by somatic cotyledons indicates an influence of the embryo axis and indicates a relationship between organogenic and embryogenic regeneration pathways.     

Developmentally and stress-induced small heat shock proteins in cork oak somatic embryos

The timing and tissue localization of small heat shock proteins (sHSPs) during cork oak somatic embryo development was investigated under normal growing culture conditions and in response to stress. Western blot analyses using polyclonal antibodies raised against cork oak recombinant HSP17 showed a transient accumulation of class I sHSPs during somatic embryo maturation and germination. Moreover, the amount of protein increased at all stages of embryo development in response to exogenous stress. The developmentally accumulated proteins localized to early differentiating, but not the highly dividing, regions of the root and shoot apical meristems. By contrast, these highly dividing regions were strongly immunostained after heat stress. Findings support the hypothesis of a distinct control for developmentally and stress-induced accumulation of class I sHSPs. The possible role of sHSPs is discussed in relation to their tissue specific localization.