Cloning of Pinus sylvestris SCARECROW gene and its expression pattern in the pine root system, mycorrhiza and NPA-treated short roots

The SCARECROW (SCR) gene is central to root radial patterning. Its expression has not been investigated in conifers with morphologically different root types. Additional interest in SCR functions in the Pinus sylvestris root system comes from the effect of ectomycorrhiza formation on the short root apical structure. Here, the P. sylvestris SCR gene (PsySCR) was cloned and its expression investigated by northern blot and in situ hybridization of primary, lateral and short roots and mycorrhiza. Short root dichotomization was induced by auxin transport inhibitor (N-1-naphthylphthalamic acid (NPA)). PsySCR has conserved GRAS family protein motifs at the C-terminus and a variable N-terminus. PsySCR expression occurred in young root tissue and mycorrhiza. In root sections the PsySCR signal runs through the tip in initials for stele and root cap column and becomes upwards-restricted to endodermis in all root types. The PsySCR expression pattern suggests for the first time a regulatory role for SCR in maintaining the endodermal characteristics and radial patterning of roots with open meristem organization. The specific PsySCR localization is also an excellent marker for investigation of the dichotomization process in short roots.     

Expression of the QrCPE gene is associated with the induction and development of oak somatic embryos

Somatic embryogenesis is a powerful tool for plant regeneration and also provides a suitable material for investigating the molecular events that control the induction and development of somatic embryos. This study focuses on expression analysis of the QrCPE gene (which encodes a glycine-rich protein) during the initiation of oak somatic embryos from leaf explants and also during the histodifferentiation of somatic embryos. Northern blot and in situ hybridization were used to determine the specific localisation of QrCPE mRNA. The results showed that the QrCPE gene is developmentally regulated during the histodifferentiation of somatic embryos and that its expression is tissue- and genotype-dependent. QrCPE was strongly expressed in embryogenic cell aggregates and in embryogenic nodular structures originated in leaf explants as well as in the protodermis of somatic embryos from which new embryos are generated by secondary embryogenesis. This suggests a role for the gene during the induction of somatic embryos and in the maintenance of embryogenic competence. The QrCPE gene was highly expressed in actively dividing cells during embryo development, suggesting that it participates in embryo histodifferentiation. The localised expression in the root cap initial cells of cotyledonary somatic embryos and in the root cap of somatic seedlings also suggests that the gene may be involved in the fate of root cap cells.     

Molecular analysis of SCARECROW function reveals a radial patterning mechanism common to root and shoot

Mutation of the SCARECROW (SCR) gene results in a radial pattern defect, loss of a ground tissue layer, in the root. Analysis of the shoot phenotype of scr mutants revealed that both hypocotyl and shoot inflorescence also have a radial pattern defect, loss of a normal starch sheath layer, and consequently are unable to sense gravity in the shoot. Analogous to its expression in the endodermis of the root, SCR is expressed in the starch sheath of the hypocotyl and inflorescence stem. The SCR expression pattern in leaf bundle sheath cells and root quiescent center cells led to the identification of additional phenotypic defects in these tissues. SCR expression in a pin-formed mutant background suggested the possible origins of the starch sheath in the shoot inflorescence. Analysis of SCR expression and the mutant phenotype from the earliest stages of embryogenesis revealed a tight correlation between defective cell divisions and SCR expression in cells that contribute to ground tissue radial patterning in both embryonic root and shoot. Our data provides evidence that the same molecular mechanism regulates the radial patterning of ground tissue in both root and shoot during embryogenesis as well as postembryonically.     

The histodifferentiation events involved during the acquisition and development of somatic embryogenesis in oil palm (Elaeis guineensis Jacq.)

Understanding the fate and dynamics of cells during callus formation is essential to understanding totipotency and the somatic embryogenesis (SE) mechanisms. In the present study, the histodifferentiation events involved during the acquisition and development of somatic embryogenesis in oil palm (Elaeis guineensis Jacq.) was investigated. Zygotic embryos were inoculated on SE induction medium, and at 14 days the first divisions of the procambial and perivascular cells were observed. This region progressed to the formation of meristematic masses at 21 days, indicating their procambial and perivascular origin. Primary calli emerged at 45 days of culture, followed by progression to embryogenic calli at 90 days. The formation of proembryos (PE) from the meristematic cells occurred at 135 days of cultivation. The PE were isolated from the tissue of origin by the slight thickening of the cell wall, indicating their unicellular origin. When transferred to the maturation phase, differentiation of the somatic embryos at different developmental stages (globular and torpedo) was observed. The differentiated somatic embryos presented protoderm, procambial strands and plumules. Afterwards, they were transferred to culture medium without growth regulators in which conversion of the somatic embryos from torpedo stage into plants was observed. These results enable a greater understanding of the SE process and plantlet formation in E. guineensis.     

Somatic embryogenesis and plant regeneration in zygotic embryos of Trifolium nigrescens (Viv.)

This study developed a plant regeneration protocol for Trifolium nigrescens (Viv.) via somatic embryogenesis (SE). Immature zygotic embryos at torpedo (TsE) and cotyledonary (CsE) stage were cultured on media with different auxins and cytokinins at different concentrations. The cultural requirements for SE differed between the explants used: the addition of 6-furfurylaminopurine (kinetin) or N⁶-[2-isopentenyl]-adenine (2iP) along with 2,4-dihydrophenoxyacetic acid (2,4-D) or 1-naphthaleneacetic acid (NAA) was needed to elicit the embryogenic response of CsE, but an exogenous cytokinin totally inhibited 2,4-D-induced SE from TsE. When applied alone, neither the cytokinin nor NAA induced SE in TsE or CsE. In all effective cultures the first somatic embryos appeared directly from the upper part of the hypocotyl (TsE and CsE) and from the margin of cotyledons (TsE) on day 7. Embryogenic callus occurred on CsE after 10 days. At comparable concentrations 2,4-D was a more potent SE inducer than NAA, but most of the embryoids induced on media with 2,4-D displayed morphological abnormalities, whereas those produced in the presence of NAA generally resembled zygotic embryos. Plant regeneration was achieved after transfer of somatic embryos or embryo-derived first shoots to medium without plant growth regulators (PGRs). The frequency of plant recovery was about 30% for embryoids obtained on media containing 2,4-D, and for material from media with NAA the recovery rates were 44–68% (somatic embryos) and 72–100% (embryoid-derived shoots). Regenerants appeared identical to each other and to wild plants; they produced flowers and had the chromosome complement typical for the species, 2n = 16, in root tip cells.     

Expression pattern of empty-spiracles,a conserved head-patterning gene,in honeybee (Apis mellifera) embryos

Empty-spiracle class homeodomain proteins have similar roles in anterior and head development in many animal species. We have identified a honeybee empty-spiracles gene and examined its expression in honeybee ovaries and embryos. The expression of honeybee empty-spiracles in embryos is similar to that reported for Drosophila and Tribolium, implying broad conservation of the role of this gene in insect embryogenesis. We also identify expression in somatic and germ-line cells of the ovary, not previously seen in other insect species.     

Somatic embryogenesis and plant regeneration from cotyledons of walnut,Juglans regia L.

Immature cotyledons of open-pollinated seeds from five walnut (Juglans regia L.) cultivars were excised from fruits at 6–11 weeks after full pistillate bloom and grown on a sequence of media to induce somatic embryogenesis. Globular, heart, cotyledonary and complete somatic embryos were obtained. Embryogenic cultures were maintained for more than a year by repetitive embryogenesis in which the roots, cotyledons and hypocotyls of somatic embryos formed additional adventive somatic embryos. Mature somatic embryos required a cold treatment of 8–10 weeks at 2–4°C to overcome apical dormancy. Selected plantlets derived from these somatic embryos were grown to young plants in soil. In addition, somatic embryogenesis was induced in J. hindsii (Jeps.), Jeps., and in Pterocarya sp., another member of the Juglandaceae.     

Epigenetics of long-term somatic embryogenesis in <Emphasis Type="Italic">Theobroma cacao</Emphasis> L.: DNA methylation and recovery of embryogenic potential

In Theobroma cacao L., declined embryogenic potential was observed in regenerated somatic embryos from long-term secondary somatic embryogenesis (SE). In order to explore the relationship between DNA methylation and the long-term secondary SE, the embryogenic potential and global DNA methylation levels in young (12 months-old), aged (36 months-old) and extra somatic embryogenesis (39 months-old) subjected to different 5-Azacytidine (5-azaC) treatments were comparatively assessed. Global DNA methylation levels increased in aged somatic embryos with long-term in vitro culture, but 5-azaC-supplemented treatments resulted in unaltered levels. In addition, DNA methylation pattern during SE was not affected by 5-azaC. DNA methylation increased during SE expression. Interestingly, the extra SE induction showed that aged somatic embryos can recovery the embryogenic potential in treatment supplemented with 5-azaC at specific concentration. The outcome of this study suggested that the long-term SE in cacao induced the decline on embryogenic potential, which can be reversible trough 5-azaC supplementation. Besides, increased DNA methylation levels might be a response to the stress conditions that plant cells were exposed to during SE.