The somatic embryogenesis and establishment of transformation experiment system in Larix principis-Rupprechtii]

Larix principis-Rupprechtii is one of the superior afforestation forest trees growing in north China. Embryogenic cultures were initiated from immature zygotic embryos of Larix principis-Rupprechtii on S culture medium containing 2, 4-D 0-2.2 mg/L, KT and BA each at 0-0. 8 mg/L. Embryogenic calli were subcultured and multiplicated on S + B culture medium containing dropping off each hormone concentration. We set up 33 steady-going embryogenic cell lines; We studied on the growth stage and genotype differences of every embryogenic cell lines; and Finded more than 10 high-frequency somatic embryogenesis cell lines such as 2K, 2T, 2I, 2J, 3C etc.. The number of 2T somatic embryos reaches 314/per gram of embryogenic tissue and the number of 3C somatic embryos is 185/per gram of embryogenic tissue. The re-induction method of Larix principis-Rupprechtii from somatic embryos was used to produce renewable embryogenic cultures and steady-going embryogenic cell lines effectively. Mature somatic embryos can germinate and develop further into plantlets when they are isolated and cultured on a hormone-free WPM culture medium. The regeneration plantlets were obtained. Furthermore, the transformation with a truncated gene of Bacillus thuringensis (B. t) were carried out, the PCR showed positive results, because of this, embryogenic cell line of Larix principis-Rupprechtii can be used for transformation experiments to support further breeding in forestry.     

Stress-induced somatic embryogenesis in vegetative tissues of Arabidopsis thaliana

Somatic embryogenesis is an obvious experimental evidence of totipotency, and is used as a model system for studying the mechanisms of de-differentiation and re-differentiation of plant cells. Although Arabidopsis is widely used as a model plant for genetic and molecular biological studies, there is no available tissue culture system for inducing somatic embryogenesis from somatic cells in this plant. We established a new tissue culture system using stress treatment to induce somatic embryogenesis in Arabidopsis. In this system, stress treatment induced formation of somatic embryos from shoot-apical-tip and floral-bud explants. The somatic embryos grew into young plantlets with normal morphology, including cotyledons, hypocotyls, and roots, and some embryo-specific genes (ABI3 and FUS3) were expressed in these embryos. Several stresses (osmotic, heavy metal ion, and dehydration stress) induced somatic embryogenesis, but the optimum stress treatment differed between different stressors. When we used mannitol to cause osmotic stress, the optimal conditions for somatic embryogenesis were 6-9 h of culture on solid B5 medium containing 0.7 m mannitol, after which the explants were transferred to B5 medium containing 2,4-dichlorophenoxyacetic acid (2,4-D, 4.5 microm), but no mannitol. Using this tissue culture system, we induced somatic embryogenesis in three major ecotypes of Arabidopsis thaliana-Ws, Col, and Ler.     

AtSERK1 expression precedes and coincides with early somatic embryogenesis in Arabidopsis thaliana.

The Arabidopsis thaliana primordia timing (pt) mutant was transformed with an AtSERK1::GUS construct. Liquid cultures of this line were used to study the relationship between somatic embryogenesis and the expression of SOMATIC EMBRYOGENESIS RECEPTOR-LIKE KINASE (AtSERK1) as a marker for cells competent to form embryos. In order to search for the expression of AtSERK1::GUS during early stages of somatic embryogenesis, histochemical as well as immunochemical approaches were used for the detection of beta-glucuronidase (GUS). Four sites of AtSERK1 expression were found in the embryogenic cultures: in embryogenic callus, where primary somatic embryos developed; in the basal parts of primary somatic embryos; in the outer layers of cotyledons of primary somatic embryos where secondary embryos were formed; and in provascular and vascular strands of developing somatic embryos. The in vitro expression of AtSERK1::GUS coincides with embryogenic development up to the heart-shaped stage. Prior to the expression in embryos, AtSERK1 was expressed in single cells and small cell clusters, indicating that AtSERK1 indeed marks embryogenic competence. Its expression in (pro)vascular strands, suggests that embryogenic cells in tissue culture retain at least in part their original identity.     

Calcium-dependent mechanism of somatic embryogenesis in oncogene rolC expressing cell cultures of Panax ginseng

It was shown earlier, that ginseng embryogenic cell culture 2c3 was obtained as a result of callus cells transformation with the Agrobacterium rhizogenes rolC oncogene. In the present report we determine that inhibitors of Ca2+-channels (LaCl3, verapamil, niflumic acid) certainly lowered the quantity of somatic embryos in the 2c3 cell culture. This is the evidence of the influence of calcium-dependent signal system on plant embryogenesis. Protein kinases inhibitors W7 and H7 also caused the lowering of somatic embryos quantity in the 2c3 cell culture. We analysed changes of CDPK genes expression in embryogenic 2c3 cell culture. Total expression decreased 1.2-1.5 times comparing with the control callus culture. CDPK expression in the 2c3 embryogenic culture lowered by the inhibition of expression of the gene subfamilies PgCDPK1 (PgCDPK1a and PgCDPK1b) and PgCDPK3 (PgCDPK3a). At the same time, expression of PgCDPK2 gene subfamily (PgCDPK2b and PgCDPK2d) was increased. We suppose that genes of PgCDPK2 subfamily might be responsible for the embryogenesis initiation in the 2c3 ginseng cell culture. It was shown for the first time that the rolC gene and the process of embryogenesis could change expression of particular forms of CDPK genes.     

Efficient somatic embryogenesis in sugar beet (<Emphasis Type="Italic">Beta vulgaris</Emphasis> L.) breeding lines

Efficient regeneration via somatic embryogenesis (SE) would be a valuable system for the micropropagation and genetic transformation of sugar beet. This study evaluated the effects of basic culture media (MS and PGo), plant growth regulators, sugars and the starting plant material on somatic embryogenesis in nine sugar beet breeding lines. Somatic embryos were induced from seedlings of several genotypes via an intervening callus phase on PGo medium containing N⁶-benzylaminopurine (BAP). Calli were mainly induced from cotyledons. Maltose was more effective for the induction of somatic embryogenesis than was sucrose. There were significant differences between genotypes. HB 526 and SDM 3, which produced embryogenic calli at frequencies of 25–50%, performed better than SDM 2, 8, 9 and 11. The embryogenic calli and embryos produced by this method were multiplied by repeated subculture. Histological analysis of embryogenic callus cultures indicated that somatic embryos were derived from single- or a small number of cells. 2,4-dichlorophenoxyacetic acid (2,4-D) was ineffective for the induction of somatic embryogenesis from seedlings but induced direct somatic embryogenesis from immature zygotic embryos (IEs). Somatic embryos were mainly initiated from hypocotyls derived from the cultured IEs in line HB 526. Rapid and efficient regeneration of plants via somatic embryogenesis may provide a system for studying the molecular mechanism of SE and a route for the genetic transformation of sugar beet.     

松柏类植物体细胞胚胎发生的研究进展

松柏类植物的体细胞胚胎发生既是繁育的一种手段,又是研究胚胎发育过程中结构、生理和分子事件的一种重要的模式系统.整个体细胞胚胎发生过程主要包括3个步骤:胚性组织的诱导和增殖、体细胞胚的成熟以及体细胞胚的萌发和转换.过去为了提高胚胎发育过程所做的努力主要都集中在胚的成熟阶段,这是因为一直认为能否成功再生的关键在于胚发育成熟阶段的处理.然而,在过去几年里,结合生理生化以及分子生物学的研究发现,胚胎发生的早期阶段对于完成整个发育过程也是至关重要的,早期阶段培养条件的优化可以显著提高培养过程中体细胞胚的数量和质量.此外,萌发过程培养条件的调节对于提高成熟体细胞胚的萌发率和转换率也很重要.因此,这些新的研究成果对于改善松柏类植物体细胞胚胎发生中的胚的诱导率和转换率低的现象具有重要的意义.     

Abscisic acid and stress treatment are essential for the acquisition of embryogenic competence by carrot somatic cells

Studies of carrot embryogenesis have suggested that abscisic acid (ABA) is involved in somatic embryogenesis. A relationship between endogenous ABA and the induction of somatic embryogenesis was demonstrated using stress-induced system of somatic embryos. The embryonic-specific genes C-ABI3 and embryogenic cell proteins (ECPs) were expressed during stress treatment prior to the formation of somatic embryos. The stress-induction system for embryogenesis was clearly distinguished by two phases: the acquisition of embryogenic competence and the formation of a somatic embryo. Somatic embryo formation was inhibited by the application of fluridone (especially at 10⁻⁴ M), a potent inhibitor of ABA biosynthesis, during stress treatment. The inhibitory effect of fluridone was nullified by the simultaneous application of fluridone and ABA. The level of endogenous ABA increased transiently during stress. However, somatic embryogenesis was not significantly induced by the application of only ABA to the endogenous level, in the absence of stress. These results suggest that the induction of somatic embryogenesis, in particular the acquisition of embryogenic competence, is caused not only by the presence of ABA but also by physiological responses that are directly controlled by stresses.     

Embryogenesis in flowering plants: Recent approaches and prospects

The overall architectural pattern of the mature plant is established during embryogenesis. Very little is known about the molecular processes that underlie embryo morphogenesis. Last decade has, nevertheless, seen a burst of information on the subject. The synchronous somatic embryogenesis system of carrot is largely being used as the experimental system. Information on the molecular regulation of embryogenesis obtained with carrot somatic embryos as well as observations on sandalwood embryogenic system developed in our laboratory are summarized in this review. The basic experimental strategy of molecular analysis mostly relied on a comparison between genes and proteins being expressed in embryogenic and non-embryogenic cells as well as in the different stages of embryogenesis. Events such as expression of totipotency of cells and establishment of polarity which are so critical for embryo development have been characterized using the strategy. Several genes have been identified and cloned from the carrot system. These include sequences that encode certain extracellular proteins (EPs) that influence cell proliferation and embryogenesis in specific ways and sequences of the abscisic acid (ABA) inducible late embryogenesis abundant (LEA) proteins which are most abundant and differentially expressed mRNAs in somatic embryos. That LEAs are expressed in the somatic embryos of a tree flora also is evidenced from studies on sandalwood. Several undescribed or novel sequences that are enhanced in embryos were identified. A sequence of this nature exists in sandalwood embryos was demonstrated using aCuscuta haustorial (organ-specific) cDNA probe. Somatic embryogenesis systems have been used to assess the expression of genes isolated from non-embryogenic tissues. Particular attention has been focused on both cell cycle and histone genes     

Evidence for in vitro induced mutation which improves somatic embryogenesis in Asparagus officinalis L.

Summary Somatic embryogenesis from different genotypes of Asparagus officinalis L. could be obtained by in vitro culture of shoot apices. Apices were first cultured on an auxin-rich inducing medium and then transferred onto a hormone-free development medium. All genotypes tested in this way produced a few somatic embryos. In some experiments, during the development phase, a new kind of friable highly embryogenic tissue appeared in a random manner. These tissues could be continuously subcultured on a hormone-free medium and were named embryogenic lines. Five of these embryogenic lines regenerated plants from somatic embryos. These regenerated plants exhibited an increased embryogenic response compared to the parent plants; e.g. apex culture produced somatic embryos without any auxin treatments. For one of the embryogenic lines, a genetic analysis showed that the improved embryogenic response of regenerated plants was controlled by a mendelian dominant monogenic mutation.Abbreviations LSEA low somatic embryogenesis ability - HSEA high somatic embryogenesis ability - NAA 1-naphthaleneacetic acid     

Patterns of somatic embryo formation in Siberian larch: Embryological aspects

Somatic embryogenesis was induced in Siberian larch by in vitro culturing zygotic embryos at different developmental stages. Cultures were grown in modified Murashige and Skoog medium supplemented with hormones 2,4-dichlorophenoxyacetic acid (2 mg/l) and 6-benzylaminopurine (0.5–1 mg/l). The success of somatic embryogenesis in this species depended on the tree genotype and developmental stage of embryos used for culturing. Somatic embryogenesis from immature zygotic embryos at the stage of cotyledon initiation was most active. After 5–10 days, such embryos formed the embryogenic tissue including two cell types—elongated highly vacuolated embryonic tubes and small embryonic cells. Somatic embryos were isolated from proliferating embryogenic tissues after 2 months of culture.     

松柏类植物体细胞胚胎发生的研究进展

松柏类植物的体细胞胚胎发生既是繁育的一种手段,又是研究胚胎发育过程中结构、生理和分子事件的一种重要的模式系统。整个体细胞胚胎发生过程主要包括3个步骤：胚性组织的诱导和增殖、体细胞胚的成熟以及体细胞胚的萌发和转换。过去为了提高胚胎发育过程所做的努力主要都集中在胚的成熟阶段,这是因为一直认为能否成功再生的关键在于胚发育成熟阶段的处理。然而,在过去几年里,结合生理生化以及分子生物学的研究发现,胚胎发生的早期阶段对于完成整个发育过程也是至关重要的,早期阶段培养条件的优化可以显著提高培养过程中体细胞胚的数量和质量。此外,萌发过程培养条件的调节对于提高成熟体细胞胚的萌发率和转换率也很重要。因此,这些新的研究成果对于改善松柏类植物体细胞胚胎发生中的胚的诱导率和转换率低的现象具有重要的意义。     

In vitro propagation and cryopreservation of Thuja koraiensis Nakai via somatic embryogenesis

Korean arbor vitae (KAV; Thuja koraiensis Nakai) is a critically endangered coniferous tree in Korea. Here, we report the somatic embryogenesis (SE) and cryopreservation system that can be used for micropropagation of KAV and long-term storage of KAV cultures. To induce SE in KAV, the influence of the developmental stage of zygotic embryos and the effect of basal medium on embryogenesis induction were examined. The developmental stage of zygotic embryos had a significant effect on the embryogenesis induction (P < 0.0001). The highest frequency of embryogenesis induction occurred in megagametophytes with zygotic embryos at precotyledonary (P) and late embryogeny (L1) stage (36%). The highest frequency of embryogenesis induction was obtained on initiation medium containing IM basal salts with 2.2 μM 6-benzylaminopurine and 4.5 μM 2,4-dichlorophenoxyacetic acid (35%). The effect of abscisic acid (ABA) on production of somatic embryos was tested. The highest number of somatic embryos per 50 mg of embryogenic tissue was achieved on maturation medium with levels of 100 μM ABA (24.0 ± 2.4). The effect of cryopreservation treatment to embryogenic tissues on the maturation capacity of somatic embryos was also tested. No significant differences between noncryopreservation and cryopreservation treatment were observed (P = 0.1896), and the highest mean number of somatic embryo per 50 mg of embryogenic tissues was obtained in noncryopreserved cell line (28.17 ± 5.66). Finally, the genetic identities of the plantlets regenerated from non- and cryopreserved embryogenic cell lines were verified and there was no genetic variation in the regenerated plantlets from cryostored embryogenic cell lines. This study is the first report on SE and the successful cryopreservation of embryogenic culture of the genus Thuja.

     

Patterns of somatic embryo formation in Siberian larch: embryological aspects

Somatic embryogenesis was induced in Siberian larch by in vitro culturing zygotic embryos at different developmental stages. Cultures were grown in modified Murashige and Skoog medium supplemented with hormones 2,4-dichlorophenoxyacetic acid (2 mg/l) and 6-benzylaminopurine (0.5-1 mg/l). The success of somatic embryogenesis in this species depended on the tree genotype and developmental stage of embryos used for culturing. Somatic embryogenesis from immature zygotic embryos at the stage of cotyledon initiation was most active. After 5-10 days, such embryos formed the embryogenic tissue including two cell types--elongated highly vacuolated embryonic tubes and small embryonic cells. Somatic embryos were isolated from proliferating embryogenic tissues after 2 months of culture.     

Genotype effects on proliferative embryogenesis and plant regeneration of soybean

Summary Proliferative somatic embryogenesis is a regeneration system suitable for mass propagation and genetic transformation of soybean [Glycine max (L.) Merr.]. The objective of this study was to examine genotypic effects on induction and maintenance of proliferative embryogenic cultures, and on yield, germination, and conversion of mature somatic embryos. Somatic embryos were induced from eight genotypes by explanting 100 immature cotyledons per genotype on induction medium. Differences in frequency of induction were observed among genotypes. However, this step was not limiting for plant regeneration because induction frequency in the least responding genotype was sufficient to initiate and maintain proliferative embryogenic cultures. Six genotypes selected for further study were used to initiate embryogenic cultures in liquid medium. Cultures were evaluated for propagation of globular-stage tissue in liquid medium, yield of cotyledon-stage somatic embryos on differentiation medium, and plant recovery of cotyledon-stage embryos. Genotypes also differed for weight and volume increase of embryogenic tissue in liquid cultures, for yield of cotyledon-stage embryos on differentiation medium, and for plant recovery from cotyledon-stage embryos. Rigorous selection for a proliferative culture phenotype consisting of nodular, compact, green spheres increased embryo yield over that of unselected cultures, but did not affect the relative ranking of genotypes. In summary, the genotypes used in this study differed at each stage of plant regeneration from proliferative embryogenic cultures, but genotypic effects were partially overcome by protocol modifications.     

Repetitive somatic embryogenesis in carnation on picloram supplemented media

An efficient method of repetitive somatic embryogenesis and plant regeneration of two carnation cultivars (Sagres and Impulse) was established using a two-step protocol. In the first step, embryogenic tissue were induced from petal explants on MS culture medium containing 9% sucrose (w/v), 9 μM 2,4-D and 0.8 μM BA. In the second step, embryogenic tissue transferred onto the MS medium containing 3% sucrose supplemented with different concentrations of picloram (0.8, 2, 4, 8 and 16 μM) to produce primary somatic embryos. Precotyledonary clumps and cotyledonary somatic embryos were then isolated and subcultured onto the same media as the second step where they formed secondary somatic embryos in repetitive cycles. Cotyledony somatic embryos were converted into plantlets when they transferred onto the growth regulator-free half-strength MS medium followed by being acclimated to the greenhouse conditions.     

A temporary immersion system improves in vitro regeneration of peach palm through secondary somatic embryogenesis

Background and Aims

Secondary somatic embryogenesis has been postulated to occur during induction of peach palm somatic embryogenesis. In the present study this morphogenetic pathway is described and a protocol for the establishment of cycling cultures using a temporary immersion system (TIS) is presented.

Methods

Zygotic embryos were used as explants, and induction of somatic embryogenesis and plantlet growth were compared in TIS and solid culture medium. Light microscopy, scanning electron microscopy (SEM) and transmission electron microscopy (TEM) were used to describe in vitro morphogenesis and accompany morpho-histological alterations during culture.

Key Results

The development of secondary somatic embryos occurs early during the induction of primary somatic embryos. Secondary somatic embryos were observed to develop continually in culture, resulting in non-synchronized development of these somatic embryos. Using these somatic embryos as explants allowed development of cycling cultures. Somatic embryos had high embryogenic potential (65·8 ± 3·0 to 86·2 ± 5·0 %) over the period tested. The use of a TIS greatly improved the number of somatic embryos obtained, as well as subsequent plantlet growth. Histological analyses showed that starch accumulation precedes the development of somatic embryos, and that these cells presented high nucleus/cytoplasm ratios and high mitotic indices, as evidenced by DAPI staining. Morphological and SEM observations revealed clusters of somatic embryos on one part of the explants, while other parts grew further, resulting in callus tissue. A multicellular origin of the secondary somatic embryos is hypothesized. Cells in the vicinity of callus accumulated large amounts of phenolic substances in their vacuoles. TEM revealed that these cells are metabolically very active, with the presence of numerous mitochondria and Golgi apparatuses. Light microscopy and TEM of the embryogenic sector revealed cells with numerous amyloplasts, large nuclei and nucleoli, and numerous plasmodesmata. Plantlets were obtained and after 3 months in culture their growth was significantly better in TIS than on solid culture medium. However, during acclimatization the survival rate of TIS-grown plantlets was lower.

Conclusions

The present study confirms the occurrence of secondary somatic embryos in peach palm and describes a feasible protocol for regeneration of peach palm in vitro. Further optimizations include the use of explants obtained from adult palms and improvement of somatic embryo conversion rates.     

A novel method of cryopreservation without a cryoprotectant for immature somatic embryos of conifer

Cryopreservation of embryogenic tissue is an essential storage step in genotype selection and seedling production through somatic embryogenesis. To date, immature conifer somatic embryos, at the proliferation step, were only able to tolerate ultra low temperature after prior cryoprotectant treatments. We report a novel cryopreservation method for conifer (interior spruce and Douglas-fir) embryogenic tissue focusing on the maturation step of developing embryos that forgoes such cryoprotectant treatment. In this study, somatic embryos matured on culture media containing abscisic acid (ABA) at 20°C for 8 weeks. Typically, matured embryos in this manner were able to survive cryopreservation. The embryogenicity, however, decreased with increasing embryo maturity. Non-freezing low temperatures, such as 5°C, not only inhibited cotyledon development but also maintained embryogenicity. Cryotolerance was successfully induced when embryos were matured (or pretreated) under 5°C for a suitable culture period, typically 4–8 weeks. These embryos were able to survive a rapid cooling process and liquid nitrogen storage without the addition of any cryoprotectants. After cryopreservation, embryogenic tissue was recovered in both interior spruce and Douglas-fir. Embryo maturation tests indicated no difference in mature embryo yields with or without cryopreservation in interior spruce. The key factors inducing cryotolerance included ABA supplementation in culture media and low temperature pretreatment. Optimum combinations of these factors can result in high rates of tissue survival and high embryogenicity after cryopreservation.     

Acquisition of embryogenic competence during somatic embryogenesis

This review focuses on investigation in acquisition of embryogenic competence during somatic embryogenesis in the last five decades. In tissue culture, differentiated somatic cells acquire embryogenic competence and proliferate as embryogenic cells during the induction phase. These embryogenic cells are important because they differentiate to form somatic embryos at a later time. Various molecular and structural markers for detecting embryogenic cells or enhancing embryogenic competence are summarized and implications of the findings are discussed.     

华北落叶松体细胞胚胎发生及遗传转化实验系统的建立(简报)

华北落叶松(Larix principis-Rupprechtii)是我国北方中高山地区重要的针叶速生用材树种,进行其体细胞胚胎发生和植株再生的研究,在针叶树无性快速繁殖及基因工程育种上有其特殊的用途,既可为针叶树无性系林业提供产业化途径,也可作为目的基因遗传转化实验系统。针叶树的基因转化相对较难,再生更属不易,Lelu等报道过杂种落叶松与欧洲落叶松体细胞胚胎发生方面的研究;而我国尚未见有落叶松体细胞胚胎发生的研究报道。我们