Histological analysis of direct somatic embryogenesis in <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> (L.) Heynh

In Arabidopsis the in vitro culture of immature zygotic embryos (IZEs) at a late stage of development, on the solid medium containing synthetic auxin, leads to formation of somatic embryos via direct somatic embryogenesis (DSE). The presented results provide evidence that in IZE cells competent for DSE are located in the protodermis and subprotodermis of the adaxial side of cotyledons and somatic embryos displayed a single- or multicellular origin. Transgenic Arabidopsis lines expressing the GUS reporter gene, driven by the DR5 and LEC2 promoters, were used to analyse the distribution of auxin to mark embryogenic cells in cultured explants and develop somatic embryos. The analysis showed that at the start of the culture auxin was accumulated in all explant tissues, but from the fourth day onwards its location shifted to the protodermis and subprotodermis of the explant cotyledons. In globular somatic embryos auxin was detected in all cells, with a higher concentration in the protodermis, and in the heart stage its activity was mainly displayed in the shoot, root pole and cotyledon primordia. The embryogenic nature of dividing protodermal and subprotodermal cells accumulating auxin was confirmed by high expression of promoter activity of LEC2 in these cells. Analysis of symplasmic tracer (CFDA) distribution indicated symplasmic isolation between tissues engaged in DSE and other parts of an explant. Symplasmic isolation of somatic embryos from the explant was also detected.     

Cloning and Molecular Characterization of a SERK Gene Transcriptionally Induced During Somatic Embryogenesis in Ananas comosus cv. Shenwan

A somatic embryogenesis receptor-like kinase (SERK) gene, designated as AcSERK1, was isolated from pineapple (Ananas comosus cv. Shenwan). AcSERK1 shared all the characteristic domains of the SERK family, including five leucine-rich repeats, one proline-rich region motif, transmembrane domain, and kinase domains. Somatic embryogenic cultures of pineapple were established following transfer of callus cultures to Murashige and Skoog (1962) medium containing 2,4-dichlorophenoxyacetic acid. The role of AcSERK1 during establishment of somatic embryogenesis in culture was investigated. The AcSERK1 was highly expressed during embryogenic competence acquisition and global embryo formation in culture. These findings were obtained along with morphological changes in callus cultures exhibiting embryogenic potential. Overall, levels of expression of AcSERK1 were lower in nonembryogenic tissues and organs than in embryogenic callus. In situ hybridization analysis revealed that AcSERK1 expression was detected in embryogenic tissues, including single competent cells, meristematic centers wherein embryogenic structures are formed, and global embryos. These results suggested that AcSERK1 expression was associated with induction of somatic embryogenesis and that it could be used as a potential marker gene to monitor the transition of pineapple callus tissues into competent and embryogenic cells and tissues.     

Acquisition of embryogenic potential in carrot cell-suspension cultures

Embryogenic suspension cultures of domesticated carrot (Daucus carota L.) are characterized by the presence of proembryogenic masses (PEMs) from which somatic embryos develop under conditions of low cell density in the absence of phytohormones. A culture system, referred to as starting cultures, was developed that allowed analysis of the emergence of PEMs in newly initiated hypocotyl-derived suspension cultures. Embryogenic potential, reflected by the number of FEMs present, slowly increased in starting cultures over a period of six weeks. Addition of excreted, high-molecular-weight, heat-labile cell factors from an established embryogenic culture considerably accelerated the acquisition of embryogenic potential in starting cultures. Analysis of [³⁵S]methionine-labeled proteins excreted into the medium revealed distinct changes concomitant with the acquisition of embryogenic potential in these cultures. Analysis of the pattern of gene expression by in-vitro translation of total cellular mRNA from starting cultures with different embryogenic potential and subsequent separation of the [³⁵S]methionine-labeled products by two-dimensional polyacrylamide gel electrophoresis demonstrated a small number of abundant in-vitro-translation products to be present in somatic embryos and in embryogenic cells but absent in nonembryogenic cells. Several other in-vitro-translation products were present in explants, non-embryogenic and embryogenic cells but were absent in somatic embryos. Hybridization of an embryoregulated complementary-DNA sequence, Dc3, to RNA extracted from starting cultures showed that the corresponding gene is expressed in somatic embryos and PEMs but not in non-embryogenic cells.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - cDNA complementary DNA - PAGE polyacrylamide gel electrophoresis - PEM proembryogenic mass     

Isolation and characterization of four somatic embryogenesis receptor-like kinase (<Emphasis Type="Italic">RhSERK</Emphasis>) genes from miniature potted rose (<Emphasis Type="Italic">Rosa hybrida</Emphasis> cv. Linda)

The isolation and expression analysis of four partial gene sequences from rose (Rosa hybrida cv. Linda) belonging to the receptor-like kinase gene superfamily are reported. These genes have been designated RhSERK1 to RhSERK4 (Accession No. EF631967 to EF631970) as they exhibit high sequence identities with genes from the somatic embryogenesis receptor-like kinase (SERK) family in other plant species. The RhSERK genes are differentially expressed in non-embryogenic callus, embryogenic callus, mature somatic embryos and a range of tissues from intact plants, indicating a broad role in plant growth and development. However, the expressions of RhSERK3 and RhSERK4 were approximately fivefold higher in embryogenic callus than in non-embryogenic callus, and they are even higher when compared to tissues from intact plants. In addition, RhSERK4 expression was approximately eightfold higher in somatic embryos than in embryogenic callus. These results suggest that the expression pattern of RhSERK3 and RhSERK4 may be used as a marker of somatic embryogenesis.     

Characterization of expressed sequence tags obtained by SSH during somatic embryogenesis in <Emphasis Type="Italic">Cichorium intybus</Emphasis> L

Background  

Somatic embryogenesis (SE) is an asexual propagation pathway requiring a somatic-to-embryonic transition of differentiated somatic cells toward embryogenic cells capable of producing embryos in a process resembling zygotic embryogenesis. In chicory, genetic variability with respect to the formation of somatic embryos was detected between plants from a population of Cichorium intybus L. landrace Koospol. Though all plants from this population were self incompatible, we managed by repeated selfing to obtain a few seeds from one highly embryogenic (E) plant, K59. Among the plants grown from these seeds, one plant, C15, was found to be non-embryogenic (NE) under our SE-inducing conditions. Being closely related, we decided to exploit the difference in SE capacity between K59 and its descendant C15 to study gene expression during the early stages of SE in chicory.     

AtLTP1 luciferase expression during carrot somatic embryogenesis

The carrot (Daucus carota L.) EP2 gene encodes a Lipid Transfer Protein (LTP) which is expressed during protoderm formation in developing embryos. To develop a vital reporter system for gene expression during somatic embryo development a 1.1 kB fragment of the Arabidopsis thaliana LTP1 promoter was fused to the firefly luciferase (LUC) coding sequence. The AtLTP1 luciferase expression pattern in transformed carrot suspension cultures was identical to the expression pattern of the endogenous carrot EP2 gene. Cell tracking experiments revealed that all somatic embryos were derived from AtLTP1 luciferase expressing cell clusters. However, not all cell clusters that expressed the AtLTP1 luciferase reporter gene developed into a somatic embryo, suggesting that initiation of an embryogenic pathway in tissue culture does not always lead to development of a somatic embryo.     

<Emphasis Type="Italic">LEAFY COTYLEDON1</Emphasis>, <Emphasis Type="Italic">FUSCA3</Emphasis> expression and auxin treatment in relation to somatic embryogenesis induction in Arabidopsis

The expression pattern of the LEC1 and FUS3 genes during somatic embryogenesis in Arabidopsis explants (immature zygotic embryos) induced in vitro was analysed, using Real-time quantitative PCR (qRT-PCR). The analysis revealed differential expression of LEC1 but not FUS3 within a 30 day time course of somatic embryo development, and a significant auxin-dependent upregulation of LEC1 was found over the time course. In contrast to embryogenic culture, the level of LEC1 and FUS3 expression was noticeably lower in non-embryogenic callus of Col-0 and hormonal mutants (cbp20 and axr4-1) with low SE-efficiency. In addition, the expression profile of LEC1 and FUS3 was followed in the embryogenic culture derived from 35S::LEC2-GR explants. A significant increase of LEC1 but not FUS3 activity was observed under LEC2 overexpression induced in auxin-treated explants. The work provides further experimental evidence on LEC gene involvement in the embryogenic response in Arabidopsis somatic cells, and also implicates LEC1 function in more advanced stages of SE culture in relation to somatic embryo differentiation and development.     

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.     

<Emphasis Type="Italic">Arabidopsis tanmei/emb2757</Emphasis> embryo mutant is defective for in vitro plant morphogenesis

A mutation in the Arabidopsis TANMEI/EMB2757 (TAN) gene with an embryo defective phenotype was analysed for its effect on the morphogenic potential of somatic tissue cultured under in vitro conditions. The capacity for in vitro morphogenesis was evaluated using cultures of immature zygotic embryos, and seedling explants of the tan mutant and the parental Col-0 genotype. The explants were cultured on media supplemented with different plant growth regulators, and the capacity for two alternative pathways of morphogenesis, somatic embryogenesis (SE) and shoot organogenesis, was evaluated. Reporter genes (GUS, GFP) were used to monitor auxin and LEC2 and FUS3 gene activity in the tan explants. Moreover, the expression pattern of the TAN gene was analyzed during SE and in callus tissue of Col-0. It was indicated that the tan mutation resulted in a total lost of embryogenic and organogenic capacity of cultured tissues, suggesting the involvement of the TAN gene in basic cellular processes related to cell growth and differentiation. However, differential expression of the TAN gene during SE, and its increased activity at advanced stages of embryogenesis, implicate a specific role for the gene in the development of somatic embryos.     

Agrobacterium tumefaciens– mediated transformation of soybean [Glycine max (L.) Merrill.] using immature zygotic cotyledon explants

Agrobacterium tumefaciens -mediated transformation of soybean [Glycine max (L.) Merrill. cv. Jack] using immature zygotic cotyledons was investigated to identify important factors that affected transformation efficiency and resulted in the production of transgenic soybean somatic embryos. The factors evaluated were initial immature zygotic cotyledon size, Agrobacterium concentration during inoculation and co-culture and the selection regime. Our results showed that 8- to 10-mm zygotic cotyledons exhibited a higher transformation rate, as indicated by transient GUS gene expression, whereas the smaller zygotic cotyledons, at less than 5 mm, died shortly after co-cultivation. However, the smaller zygotic cotyledon explants were found to have a higher embryogenic potential. Analysis of Agrobacterium and immature cotyledon explant interactions involved two Agrobacterium concentrations for the inoculation phase and three co-culture regimes. No differences in explant survival or somatic embyogenic potential were observed between the two Agrobacterium concentrations tested. Analysis of co-culture regimes revealed that the shorter co-culture times resulted in higher explant survival and higher somatic embryo production on the explants, whereas the co-culture time of 4 days severely reduced survival of the cotyledon explants and lowered their embryogenic potential. Analysis of selection regimes revealed that direct placement of cotyledon explants on hygromycin 25 mg/l was detrimental to explant survival, whereas 10 mg/l gave continued growth and subsequent somatic embryo development and plant regeneration. The overall transformation frequency in these experiments, from initial explant to whole plant, was 0.03 %. Three fertile soybean plants were obtained during the course of these experiments. Enzymatic GUS assays and Southern blot hybridizations confirmed the integration of T-DNA and expression of the GUS-intron gene in the three primary transformants. Analysis of 48 progeny revealed that three copies of the transgene were inherited as a single Mendelian locus. Received: 6 December 1999 / Revised: 11 February 2000 / Accepted: 14 March 2000     

Monoclonal antibody against a cell wall marker protein for embryogenic potential of <Emphasis Type="Italic">Dactylis glomerata</Emphasis> L. suspension cultures

We identified and isolated a monoclonal antibody (MAb 3G2) raised against extracellular proteins from microcluster cells of orchard grass (Dactylis glomerata L.) embryogenic suspension culture. MAb 3G2 recognized with high specificity an antigen ionically bound within the primary cell wall and in the culture medium of microcluster cells. Two-dimensional polyacrylamide gel analysis and blotting of proteins on PVDF membrane showed that MAb 3G2 detected a single polypeptide of apparent molecular mass of 48 kDa and an isoelectric point (pI) of 5.2, designated EP48. A transient expression during somatic embryogenesis was observed for EP48. Indirect immunofluorescence showed that this protein highly accumulated in the cell walls of some single cells, microclusters and partly in proembryogenic masses (PEMs), but not in globular embryos of the embryogenic cell line and microclusters from the non-embryogenic cell line. Signal intensity varied between individual cells of the same population and in successive stages of somatic embryo development. Screening of several D. glomerata L. embryogenic and non-embryogenic cell lines with MAb 3G2 indicated the presence of ECP48 in only embryogenic suspension cultures at early stages of embryo development long before morphological changes have taken place and thus it could serve as an early marker for embryogenic potential in D. glomerata L. suspension cultures.     

Effects of kanamycin on tissue culture and somatic embryogenesis in cotton

The aminoglycoside antibiotic kanamycin was evaluated for its effects on callus initiation from hypocotyl and cotyledon explants, proliferation of non-embryogenic and embryogenic calli, initiation and development of somatic embryos in cotton (Gossypium hirsutum L.). On this basis, the potential use of kanamycin as a selective agent in genetic transformation with the neomycin phosphotransferase II gene as the selective marker gene was evaluated. Cotton cotyledon and hypocotyl explants, and embryogenic calluses were highly sensitive to kanamycin. Kanamycin at 10 mg/L or higher concentrations reduced callus formation, with complete inhibition at 60 mg/L. Kanamycin inhibited embryogenic callus growth and proliferation, as well as the initiation and development of cotton somatic embryos. The sensitivity of embryogenic callus and somatic embryos to kanamycin was different during the initiation and development stages. Kanamycin was considered as a suitable selective agent for transformed callus formation and growth of non-embryogenic callus. Forty to sixty mg/L was the optimal kanamycin concentration for the induction and proliferation of transformed callus. The concentration of kanamycin must be increased (from 50 to 200 mg/L) for the selection of transformation embryogenic callus and somatic embryos. A scheme for selection of transgenic cotton plants when kanamycin is used as the selection agent is discussed.