The Arabidopsis Somatic Embryogenesis Receptor Kinase 1 Gene Is Expressed in Developing Ovules and Embryos and Enhances Embryogenic Competence in Culture

We report here the isolation of the Arabidopsis SOMATIC EMBRYOGENESIS RECEPTOR-LIKE KINASE 1 (AtSERK1) gene and we demonstrate its role during establishment of somatic embryogenesis in culture. The AtSERK1 gene is highly expressed during embryogenic cell formation in culture and during early embryogenesis. The AtSERK1 gene is first expressed in planta during megasporogenesis in the nucellus [corrected] of developing ovules, in the functional megaspore, and in all cells of the embryo sac up to fertilization. After fertilization, AtSERK1 expression is seen in all cells of the developing embryo until the heart stage. After this stage, AtSERK1 expression is no longer detectable in the embryo or in any part of the developing seed. Low expression is detected in adult vascular tissue. Ectopic expression of the full-length AtSERK1 cDNA under the control of the cauliflower mosaic virus 35S promoter did not result in any altered plant phenotype. However, seedlings that overexpressed the AtSERK1 mRNA exhibited a 3- to 4-fold increase in efficiency for initiation of somatic embryogenesis. Thus, an increased AtSERK1 level is sufficient to confer embryogenic competence in culture.     

Dynamics of morphological and anatomical changes in leaf tissues of an interspecific hybrid of oil palm during acquisition and development of somatic embryogenesis

Oil palm is an economically important plant species due to its high oil production per unit area. Large-scale clonal propagation of the species’s elite specimens is only possible through somatic embryogenesis, although methodology is partially still unknown and insufficiently understood. Current study characterizes in morphological and anatomical terms the acquisition and development stages of somatic embryogenesis of the oil palm’s immature leaves. The respective embryogenic stages were analyzed and characterized: immature leaves (initial explants); leaves with calli formation; leaves which failed to respond to calli formation; leaves with formation of root structures; primary calli; primary calli with differentiation of embryogenic calli; embryogenic calli; pro-embryogenic calli; calli with differentiated somatic embryos; somatic embryos at globular and torpedo stage; and mature fruit zygotic embryos. Cell masses emerged after approximately 60 days of cultivation through the proliferation of cells associated to initial explants´ vascular bundles. Consequently, the formation of two different types of calli was identified, namely, primary and embryogenic, respectively consisting partially and completely of meristematic cell clusters. After 420 days of cultivation, the propagules formed somatic embryos with no connection to source tissues, initially composed (globular stage) of a very characteristic ground meristem and protoderm. After 480 days of cultivation, as the cultures matured (torpedo stage), procambial strands, a structural characteristic also observed in mature zygotic embryos, were reported. The results provide an in-depth understanding of somatic embryogenesis of immature leaves of oil palm. Further, current analysis develops morphological markers at different stages of development obtained during the process.     

Histology of somatic embryogenesis in <Emphasis Type="Italic">Coffea arabica</Emphasis> L.

The objective of this study was to characterize the histodifferentiation of somatic embryogenesis obtained from leaf explants of C. arabica. Therefore, we histologically analyzed the respective stages of the process: leaf segments at 0, 4, 7, 15 and 30 days of cultivation, Type 1 primary calli (primary calli with embryogenic competence) and 2 (primary calli with no embryogenic competence), embryogenic calli, globular, torpedo and cotyledonary embryos, and mature zygotic embryos. Callus formation occurred after seven days of culture, with successive divisions of procambium cell. In this cultivation phase, it was found that Type 1 primary calli are basically formed by parenchymal cells with reduced intercellular spacing, whereas Type 2 primary calli are predominantly composed of parenchymal cells with ample intercellular spaces and embryogenic calli composed entirely of meristematic cells. After 330 days, it was evident from the differentiation of somatic embryogenesis that there was formation of globular somatic embryos, consisting of a characteristic protoderm surrounding the fundamental meristem. With the maturation of these propagules after 360 days, torpedo-stage somatic embryos arose, in which tissue polarization and early differentiation of procambial strands were verified. After 390 days, cotyledonary somatic embryos were obtained, where the onset of vessel elements differentiation was verified, a characteristic also observed in mature zygotic embryos. We concluded that somatic embryogenesis obtained from C. arabica leaves initiates from procambium cell divisions that, in the course of cultivation, produce mature somatic embryos suitable for regenerating whole plants.     

Shoot apex explants for induction of somatic embryogenesis in mature Quercus robur L. trees

A procedure for inducing somatic embryos in shoot apex explants (2 mm) excised from shoot proliferation cultures established from adult oak trees (Quercus robur) was investigated. Embryogenesis was induced in shoot tip as well as leaf explants in three out of the five genotypes evaluated. Somatic embryos were formed by culture in induction medium supplemented with 21.48 μM naphthalene acetic acid and 2.22 μM benzyladenine for 8 weeks, and successive transfer of explants to expression media with a low concentration of growth regulators and without them. Both types of explants formed callus tissue from which somatic embryos developed, indicating indirect embryogenesis. Although the embryogenic frequencies were lower than 12%, it did not prevent the establishment of clonal embryogenic lines maintained by repetitive embryogenesis. Histological study confirmed an indirect somatic embryogenesis process from shoot tip explants, in which leaf primordia and the corresponding axial zones were involved in generating callus, whereas the apical meristem itself did not proliferate. The origin of embryogenic cells appeared to be associated with dedifferentiation of certain parenchymal cells in callus regions after transfer of explants to expression media without auxin. Division of embryogenic cells gave rise to proembryo aggregates of unicellular origin, although a multicellular origin from bulging embryogenic areas would also seem possible. Further development led to the formation of cotyledonary-stage somatic embryos and nodular embryogenic structures that may be considered as anomalous embryos with no clear bipolarity. Inducement of somatic embryos from explants isolated from shoot cultures ensures plant material all year round, thus providing a significant advantage over the use of leaf explants from field-grown trees.     

The sensitivity of transgenic spruce (Picea glauca (Moench) Voss) cotyledonary somatic embryos and somatic seedlings to kanamycin selection

Transformed white spruce cultures containing immature Stage I somatic embryos, were developed after particle bombardment of somatic embryos with pBI 426, carrying an expression cassette with a gus::nptII fusion gene. These Stage I cultures did not show tolerance to kanamycin concentrations above 3 to 5 mg l–1, although assays for GUS and NPTII showed that functional enzymes were present in the transgenic tissue. Embryonic liquid suspension cultures were initiated from this transformed tissue. After treatment on agar-solidified maturation medium with 48 m (±)-ABA high numbers of Stage III (cotyledonary) somatic embryos were produced. When subjected to an embryogenesis re-induction process with 2,4-D and BA, these Stage III embryos produced a new generation of Stage I embryogenic tissues which could tolerate 5--10 mg l–1 kanamycin. Stage III somatic embryos could alternatively be placed onto germination medium for the development of somatic seedlings. When germinated in the presence of 20 mg l–1 kanamycin, 77% of inoculants were resistant. The stability of integration of the gus::nptII fusion gene in the genome of white spruce Stage III somatic embryos and somatic seedlings was confirmed through Southern blot analysis     

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.     

Cloning and molecular characterisation of a potato SERK gene transcriptionally induced during initiation of somatic embryogenesis

Somatic embryogenesis offers great potential in plant propagation, long-term germplasm conservation, and as a suitable model system for deciphering early events during embryogenesis. The up-regulation and ectopic expression of a SOMATIC EMBRYOGENESIS RECEPTOR-LIKE KINASE (SERK) gene has been shown to mark and enhance embryogenic competence in somatic cells of model plant species. We have cloned and characterised a SERK gene (StSERK1) from potato (Solanum tuberosum L.), an important crop plant. Sequence analysis of StSERK1 revealed high levels of similarity to other plant SERKs, as well as a conserved intron/exon structure which is unique to members of the SERK family. Furthermore, StSERK clustered most closely with SERK gene family members such as MtSERK1, CuSERK1, AtSERK1, and DcSERK, implicated in evoking somatic embryogenesis. Monitoring of SERK expression during progression of potato somatic embryogenesis revealed increased StSERK expression during the induction phase. Subsequently, during the embryo transition phases, StSERK expression was unchanged and did not vary among embryo-forming and inhibitory conditions. However, in isolated somatic embryos StSERK expression was again up-regulated. In other plant parts (leaves, true potato seeds, microtubers and flower buds), StSERK showed different levels of expression. Expression analysis suggests that the isolated StSERK could be a functional SERK orthologue. The possible role of SERK as a marker of pluripotency, rather than embryogenesis alone, is discussed.     

Two SERK genes are markers of pluripotency in Cyclamen persicum Mill

The genetic basis of stem cell specification in somatic embryogenesis and organogenesis is still obscure. SOMATIC EMBRYOGENESIS RECEPTOR-LIKE KINASE (SERK) genes are involved in embryogenesis and organogenesis in numerous species. In vitro culture of Cyclamen persicum immature ovules provides a system for investigating stem cell formation and maintenance, because lines forming either organs or embryos or callus without organs/embryos are available for the same cultivar and plant growth regulator conditions. The present aim was to exploit this property of cyclamen cultures to understand the role of SERK(s) in stem cell formation and maintenance in somatic embryogenesis and organogenesis in vitro, in comparison with expression in planta. CpSERK1 and CpSERK2 were isolated from embryogenic callus. CpSERK1 and CpSERK2 levels by RT-PCR showed that expression is high in embryogenic, moderate in organogenic, and null in recalcitrant calli. in situ hybridizations showed that the expression of both genes started in clumps of pluripotent stem cells, from which both pre-embryogenic aggregates and organ meristemoids derived, and continued in their trans-amplifying, meristem-like, derivatives. Expression declined in organ meristemoids, in parallel with a partial loss of meristematization. In mature somatic embryos, and in shoot and root primordia, CpSERK1 and CpSERK2 were expressed in meristems, and similar patterns occurred in zygotic embryo and primary meristems in planta. The results point to SERK1 and SERK2 as markers of pluripotency in cyclamen. It is proposed that the high expression of these genes in the trans-amplifying derivatives of the stem cells maintains a pluripotent condition leading to totipotency and, consequently, somatic embryogenesis.     

Somatic embryogenesis and plantlet formation in Santalum album and S. spicatum

A reproducible system for somatic embryogenesis and plantlet formation of sandalwood has been developed. A high frequency (100%) of somatic embryos were induced directly from various explants in MS (Murashige and Skoog, 1962) medium with thidiazuron (1 or 2 M) or indirectly in medium containing 2,4-D plus thidiazuron. Within 8 weeks, white globular somatic embryos or friable embryogenic tissue developed on cultured explants. In S. album the globular somatic embryos were transferred to MS medium supplemented with IAA (6 M) and kinetin (1 and M) where they developed further, multiplied and maintained friable embryogenic tissue. After 15-30 d, mature somatic embryos (1-2 mm) with well-developed cotyledons were separated and subcultured on to medium containing GA3 (6 M) for germination. Once germinated, elongated somatic embryos (10-20 mm long) grew further in MS supplemented with lower GA3 (3 M). In S. spicatum, the addition of casein hydrolysate and coconut milk was necessary for plantlet development from somatic embryos. From histological studies, it appeared that primary somatic embryos arose from single cells or had a multicellular origin from the epidermis or cortical parenchyma. Secondary somatic embryos and friable embryogenic tissue differentiated from groups of proembryogenic cells from a superficial layer of the primary somatic embryos.Keywords: Santalum album, Santalum spicatum, somatic embryogenesis, histological studies.      

Growth regulators affect primary and secondary somatic embryogenesis in Madagaskar periwinkle (<Emphasis Type="Italic">Catharanthus roseus</Emphasis> (L.) G. Don) at morphological and biochemical levels

An efficient somatic embryogenesis system has been established in Catharanthus roseus (L.) G. Don in which primary and secondary embryogenic calluses were developed from hypocotyls and primary cotyledonary somatic embryos (PCSEs), respectively. Two types of calluses were different in morphology and growth behaviour. Hypocotyl-derived embryogenic callus (HEC) was friable and fast-growing, while secondary callus derived from PCSE was compact and slow-growing. HEC differentiated into somatic embryos which proliferated quickly on medium supplemented with NAA (1.0 mg l⁻¹) and BA (1.5 mg l⁻¹). Although differentiation and proliferation of somatic embryos were faster in primary HEC, maturation and germination efficiency were better in somatic embryos developed from primary cotyledonary somatic embryo-derived secondary embryogenic callus (PCSEC). At the biochemical level, two somatic embryogenesis systems were different. Both primary and secondary/adventive somatic embryogenesis and the role of plant growth regulators in two modes of somatic embryo formation have been discussed.     

农杆菌介导的苜蓿次级体细胞胚的遗传转化

采用农杆菌菌株GV3101感染子叶期苜蓿体细胞胚来研究苜蓿次级体细胞胚的遗传转化方法。农杆菌菌株GV3101双相载体pCAMBIA2301,此双相载体具有gus报告基因和nptⅡ抗卡那霉素筛选基因。感染的子叶期苜蓿体细胞在75 mg/L卡那霉素筛选压下,经过一系列诱导培养,最终获得转基因植株。然后,通过GUS组织化学定位分析来检测转基因植株不同器官中的GUS表达,并进一步通过PCR和Southern杂交确定转基因的稳定整合和转化率。结果表明转基因植株不同器官均有GUS表达,整合的nptⅡ基因的拷贝数是1~4,获得的转基因植株的转化率是65.82%。     

Stable transformation via particle bombardment in two different soybean regeneration systems

The Biolistics^® particle delivery system for the transformation of soybean (Glycine max L. Merr.) was evaluated in two different regeneration systems. The first system was multiple shoot proliferation from shoot tips obtained from immature zygotic embryos of the cultivar Williams 82, and the second was somatic embryogenesis from a long term proliferative suspension culture of the cultivar Fayette. Bombardment of shoot tips with tungsten particles, coated with precipitated DNA containing the gene for -glucuronidase (GUS), produced GUS-positive sectors in 30% of the regenerated shoots. However, none of the regenerants which developed into plants continued to produce GUS positive tissue. Bombardment of embryogenic suspension cultures produced GUS positive globular somatic embryos which proliferated into GUS positive somatic embryos and plants. An average of 4 independent transgenic lines were generated per bombarded flask of an embryogenic suspension. Particle bombardment delivered particles into the first two cell layers of either shoot tips or somatic embryos. Histological analysis indicated that shoot organogenesis appeared to involve more than the first two superficial cell layers of a shoot tip, while somatic embryo proliferation occurred from the first cell layer of existing somatic embryos. The different transformation results obtained with these two systems appeared to be directly related to differences in the cell types which were responsible for regeneration and their accessibility to particle penetration.     

Secondary somatic embryogenesis and plant regeneration in myrtle (Myrtus communis L.)

Immature seeds, as well as hypocotyls and cotyledons excised from seedlings of Myrtus communis L., were cultured on media containing half-strength Murashige and Skoog macronutrients (MS/2) with combinations of auxins and cytokinins, in order to study their morphogenetic competence. Somatic embryogenesis was obtained from cotyledons, hypocotyls and 2-month-old immature seeds with 0.1 mg/l 2,4-dichlorophenoxyacetic acid (2,4-D). The percentage of explants showing this primary somatic embryogenesis ranged from 4% for hypocotyls to 12% for 2-month-old immature seeds. In the latter, somatic embryogenesis was also obtained in media containing 2,4-D plus a cytokinin, and with only a cytokinin. Somatic embryos obtained from hypocotyls, cotyledons or immature seeds were able to develop on MS/2 medium without plant growth regulators. Subculture of primary somatic embryos obtained from immature seeds on MS/2 medium without plant growth regulators gave rise to clusters with secondary somatic embryos and embryogenic calli. These clusters were subcultured every 8 weeks, and they were the source of highly embryogenic cultures. An average of 10% of the secondary somatic embryos developed into plantlets in each subculture. Therefore, the same culture on MS/2 medium without growth regulators yielded both plantlets and de novo secondary embryos. Received: 6 April 1998 / Revision received: 10 July 1998 / Accepted: 21 July 1998     

4-Hydroxybenzyl alcohol accumulates in suspension-cell cultures and inhibits somatic embryogenesis in carrot

Somatic embryogenesis in carrot ( Daucus carota L.) is strongly inhibited by certain factors that accumulate in culture medium of high-density cultures of embryogenic cells. We previously identified 4-hydroxybenzyl alcohol (4HBA) as one of the inhibitory factors. In this study, we analyzed the accumulation pattern of 4HBA in the cultures of carrot suspension cells. When somatic embryogenesis was induced by culturing embryogenic cells in phytohormone-free Murashige and Skoog medium at various initial cell densities, 4HBA accumulated in the culture medium. The concentration of 4HBA in high cell density cultures was higher than in low cell density cultures. The accumulation of 4HBA in high cell density cultures was rapid during the early days of culture. This rapid accumulation of 4HBA in high cell density cultures might result in the strong inhibition of somatic embryogenesis. The production of 4HBA decreased as the somatic embryos developed. In addition, embryogenic cells released larger amount of 4HBA into the culture medium compared with non-embryogenic cells. These results suggest that the production of 4HBA is both related to embryogenic competence and developmentally regulated during somatic embryogenesis.     

Regeneration of Acacia mangium through somatic embryogenesis

 Somatic embryogenesis and whole plant regeneration were achieved in callus cultures derived from immature zygotic embryos of Acacia mangium. Embryogenic callus was induced on MS medium containing combinations of TDZ (1–2 mg/l), IAA (0.25–2 mg/l) and a mixture of amino acids. Globular embryos developed on embryogenic callus cultured on the induction medium. Nearly 42% of embryogenic cultures with globular embryos produced torpedo- and cotyledonary-stage embryos by a two-step maturation phase. The first stage occurred on 1/2-strength MS basal medium containing 30 g/l sucrose and 5 mg/l GA₃ followed by the second stage on 1/2-strength MS basal medium containing 50 g/l sucrose. Of the cotyledonary-stage somatic embryos, 11% germinated into seedlings that could be successfully transferred to pots. Light- and scanning electron microscopy showed that the somatic embryos originated from single cells of the embryogenic callus. Further, a single cell layer could be detected beneath the developing somatic embryos that appeared to be a demarcation layer isolating the somatic proembryonic structure from the rest of the maternal callus. A suspensor-like structure connected the globular embryos to the demarcation layer. This is the first successful report of plant regeneration through somatic embryogenesis for this economically important tropical forest species. Received: 20 January 2000 / Revision received: 28 September 2000 / Accepted: 29 September     

Cold-enhanced somatic embryogenesis in cell suspension cultures of Astragalus adsurgens Pall.: relationship with exogenous calcium during cold pretreatment

The inter-relationship between exogenous calcium (Ca²⁺) during cold pretreatment and cold-enhanced somatic embryogenesis was investigated using cell suspension cultures of Astragalus adsurgens Pall. Cell suspension was obtained from embryogenic callus and could be induced to form somatic embryos in the differentiation medium. Suspension cells, after cold-treatment at 8 °C for 2 to 3 wk, displayed an enhanced capacity for somatic embryogenesis as compared to those without cold pretreatment. Longer cold pretreatment (> 4 wk) resulted in the inhibition of somatic embryogenesis. The enhanced embryogenic response of cells to cold pretreatment was dependent on the Ca²⁺ level in the pretreatment medium. Ca²⁺ levels below 1 mM suppressed the cold-enhanced response. Addition of lanthanum into the pretreatment medium completely abolished the cold induced enhancement of somatic embryogenesis. These results suggest that embryogenic cells require a minimal concentration of Ca²⁺ during pretreatment for the expression of this cold-enhanced capacity for somatic embryogenesis in A.adsurgens and the influx of exogenous Ca²⁺ during pretreatment might also be involved.     

Origin of somatic embryos from repetitively embryogenic cultures of walnut (Juglans regia L.): Implications forAgrobacterium-mediated transformation

Early stages of somatic embryo development from embryogenic cultures ofJuglans regia (Persian or English walnut) are described. Histological examination reveals that secondary somatic embryos arise from cotyledons and hypocotyls of primary embryos cultured in the dark. The embryos originate by transverse to oblique divisions of surface cells. Single-cell origin of the secondary embryos confirms the potential of the repetitive embryogenesis system forAgrobacterium-mediated transformation and regeneration of non-chimeric, transgenic walnut plants.     

Proliferation and maintenance of embryogenic capacity in elm embryogenic cultures

Summary This paper investigates maintenance and proliferation of somatic embryogenesis systems for Ulmus minor and U. glabra. Proliferation occurred with subculture of embryogenic calluses. The calluses were mainly formed by friable nodules composed of meristematic cells organized into proembryogenic cell masses (PEMs) and thin-walled vacuolated parenchymatic cells. Cotyledonary embryos, with procambial strands and differentiation of their vascular tissues as well as visible root meristems, were identifiable after 18d of culture on a proliferation medium with 0.44 μM benzyladenine (BA). The shoot meristem was only occasionally well developed. Somatic embryo multiplication from elm embryogenic calluses is a clearly asynchronic system, and PEMs as well as embryos at all stages of development are observed simultaneously at the end of subculture period. Factors affecting the proliferation of elm embryogenic callus, such as culture medium, carbon source and genotype, were studied. Basal medium (MS) or medium supplemented with 0.44 μM BA produced the highest number of somatic embryos. Somatic embryo production was higher with sucrose or glucose than with maltose, and significant differences were also found among the four embryogenic lines tested. The use of liquid medium with filter paper support is an essential step for the survival of isolated somatic embryos during the germination stage. The addition of 0.22 μM BA′ to liquid MS medium was the best treatment for germination and plantlet conversion of elm somatic embryos.