Embryogeny of gymnosperms: advances in synthetic seed technology of conifers

Synthetic seed technology requires the inexpensive production of large numbers of high-quality somatic embryos. Proliferating embryogenic cultures from conifers consist of immature embryos, which undergo synchronous maturation in the presence of abscisic acid and elevated osmoticum. Improvements in conifer somatic embryo quality have been achieved by identifying the conditions in vitro that resemble the conditions during in ovulo development of zygotic embryos. One normal aspect of zygotic embryo development for conifers is maturation drying, which allows seeds to be stored and promotes normal germination. Conditions of culture are described that yield mature conifer somatic embryos that possess normal storage proteins and fatty acids and which survive either partial drying, or full drying to moisture contents similar to those achieved by mature dehydrated zygotic embryos. Large numbers of quiescent somatic embryos can be produced throughout the year and stored for germination in the spring, which simplifies production and provides plants of uniform size. This review focuses on recent advances in conifer somatic embryogenesis and synthetic seed technology, particularly in areas of embryo development, maturation drying, encapsulation and germination. Comparisons of conifer embryogeny are made with other gymnosperms and angiosperms.Abbreviations ABA abscisic acid - LEA late embryogenesis abundant - PEG polyethylene glycol - PGR plant growth regulator - RH relative humidity - TAG triacylglycerol     

Maturation of somatic embryos in conifers: Morphogenesis,physiology, biochemistry,and molecular biology

Summary In the past 15 years tremendons progress has been made towards the development of systems for the induction and development of somatic embryos of coniferous species. Since the first report in 1985, several species have been induced to produce somatic embryos. This has been rendered possible by the development of rational media and improvement of culture conditions, which have resulted in increased embryo quality and higher conversion frequency. Understanding the physiological and biochemical events occurring during in vivo embryogenesis has been fundamental in the design of new protocols for improving the somatic embryogenic process. Specifically, the inclusions of abscisic acid (ABA) and osmotic agents, such as polyethylene glycol (PEG), have been shown to be necessary for the functional development of somatic embryos. In the past few years, physiological and biochemical investigations have been useful in increasing our knowledge on the mode of action of ABA and PEG during embryo development. In comparison with the flowering plants, our understanding on the molecular mechanisms regulating the embryogenic process in coniferous species is still very limited. The application of new molecular techniques is therefore fundamental towards this end. The emphasis of this review is on recent information dealing with the maturation of conifer somatic embryos.     

The role of abscisic acid in plant tissue culture: a review of recent progress

Abscisic acid (ABA) plays a significant role in the regulation of many physiological processes of plants. It is often used in tissue culture systems to promote somatic embryogenesis and enhance somatic embryo quality by increasing desiccation tolerance and preventing precocious germination. ABA is also employed to induce somatic embryos to enter a quiescent state in plant tissue culture systems and during synthetic seed research. Application of exogenous ABA improves in vitro conservation and the adaptive response of plant cell and tissues to various environmental stresses. ABA can act as anti-transpirant during the acclimatization of tissue culture-raised plantlets and reduces relative water loss of leaves during the ex vitro transfer of plantlets even when non-functional stomata are present. This review focuses on the possible roles of ABA in plant tissue culture and recent developments in this area.     

Somatic Embryogenesis in Abies Alba × Abies Alba and Abies Alba × Abies Nordmanniana Hybrids

Maturation and germination of somatic embryos of hybrids A. alba × A. alba and A. alba × A. nordmanniana were followed by protein analysis of single embryogenic -suspensor masses (ESM) and analysis of storage protein accumulation during somatic embryo development. Very important step was one week pre-cultivation of ESM on medium with polyethylene glycol (PEG) and abscisic acid (ABA). Low osmotic potential of maturation medium and addition of ABA supported development of somatic embryo. Also partial drying of somatic embryo during following three weeks was needed for its normal development. In spite of morphologically fully developed, the somatic embryos were not physiologically ready for germination at least in terms of storage protein accumulation.     

Expression of the viviparous 1 (Pavp1) and p34cdc2 protein kinase (cdc2Pa) genes during somatic embryogenesis in Norway spruce (Picea abies [L.] Karst)

Detailed expression analysis of the Norway spruce (Picea abies [L.] Karst) Viviparous 1 (Pavp1) and p34cdc2 (cdc2Pa) genes was carried out during somatic embryogenesis. Pavp1, a gene associated with embryo development, was expressed in proliferating embryogenic suspension cultures in the absence of exogenous ABA. When somatic embryo formation was promoting by blocking proliferation, Pavp1 expression was reduced. During maturation, exogenous ABA induced increased Pavp1 expression, which peaked at the early cotyledonary stage of somatic embryogenesis. Following partial desiccation of mature somatic embryos at high relative humidity, Pavp1 expression persisted under germination conditions. Pavp1 expression was also detected in non-dormant immature male strobili and dormant terminal buds. These data confirm the functional conservation of Pavp1 during the evolution of seed plants and extend its function beyond the embryo. Cdc2Pa, a gene associated with the cell cycle, was up-regulated when the proliferation of embryogenic cells was blocked. Expression was again up-regulated in early embryogeny and again during germination. The implications of this up-regulation of cdc2Pa are discussed.     

LECs go crazy in embryo development

We have reviewed studies in which LEC TFs have been used to explore totipotency via SE and regulation of the maturation phase during zygotic embryogenesis. LEC TFs are master regulators of the maturation phase, activating genes encoding seed proteins that define this phase of embryo development. Regulation of the maturation phase seems to involve a feedback loop between the LEC TFs and hormones. LEC TFs stimulate ABA levels and activate genes that repress GA levels, contributing to the high ABA to GA ratio characteristic of the maturation phase. High ABA levels in turn stimulate LEC TFs to activate seed protein genes, and the reduction in GA levels might facilitate LEC TF activity. Although the LEC TFs are master regulators of the maturation phase, LEC genes are initially expressed before the onset of the maturation phase. The cellular process that initiates the maturation phase is not known. Nor is it known how LEC TFs interact with ABA and GA at the molecular level.SE is an outstanding example of totipotency in plants. Ectopic expression of LEC genes causes vegetative or reproductive cells to change their fate and undergo somatic embryo development. LEC TFs, via LEC2, activate auxin biosynthetic enzymes, and we propose that an increase in endogenous auxin levels serves to induce SE (Figure 3). How exogenous or endogenous auxin acts as the induction signal remains to be determined. We suggest that LEC TFs enable cells to become competent to respond to the induction signal by inactivating GA and, perhaps, by increasing ABA levels (Figure 3). Thus, a potential thread between the roles of LEC TFs in the maturation phase and SE might be their involvement in controlling the ABA to GA balance. It remains to be determined whether and how ABA and GA influence embryogenic competence. Although many questions remain, substantial progress has been made in determining how the LEC TFs ‘go crazy’ during embryo development.     

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.     

A clonal propagation system for Atlantic white cedar (<Emphasis Type="Italic">Chamaecyparis thyoides</Emphasis>) via somatic embryogenesis without the use of plant growth regulators

Atlantic white cedar (AWC; Chamaecyparis thyoides), an aromatic evergreen conifer native to swamps and bogs along the Atlantic and Gulf coasts of the eastern United States was once an important species for timber production due to its durable wood. However, native populations have declined over the past two centuries. We established an in vitro propagation system for AWC via somatic embryogenesis (SE) without the use of plant growth regulators (PGRs). Whole megagametophytes with zygotic embryos from immature AWC cones were cultured on a modified half-strength embryo maturation (EM) medium with three different PGR treatments, including one devoid of PGRs. Both PGR treatment and cone collection date had significant effects on embryogenesis induction, with EM with no PGRs giving the highest embryogenesis induction, which ranged as high as 27%. We also conducted experiments to determine the effects of activated carbon (AC) and abscisic acid (ABA) in the maturation medium on production of mature somatic embryos. AC significantly affected this variable, with 2 g l^?1 producing more embryos than 0 g l^?1. Application of exogenous ABA not only failed to improve production of mature somatic embryos, the highest level tested (200 µM), apparently lowered production of mature embryos compared to the 0 ABA control. The highest numbers of mature somatic embryos per ml of plated embryogenic suspension (32–37) were produced on medium with 2 g l^?1 AC and levels of ABA at 100 µM or lower. The SE system described here has the potential to contribute the restoration of Atlantic white cedar to its native habitat.     

Effect of exogenous ABA on embryo maturation and quantification of endogenous levels of ABA and IAA in <Emphasis Type="Italic">Quercus suber</Emphasis> somatic embryos

Knowledge of the relationship between indole-3-acetic acid (IAA) and abscisic acid (ABA) is relevant to control the development and the maturation of cork oak (Quercus suber L.) somatic embryos. The addition of 1 M ABA to the culture medium significantly promoted somatic embryo maturation and increased both fresh and dry matter without affecting the relative water content. This effect was parallel to the pattern of variation observed in the endogenous ABA level, which increased from the immature to the mature stage. Endogenous ABA content during the occurrence of secondary embryogenesis was similar to that of the immature stage, showing that embryos with lower ABA levels produced secondary embryos. In contrast, IAA showed the highest concentration during early embryo development and decreased afterwards. Only in somatic embryos subjected to 1-week desiccation followed by stratification at 4 °C for 2 weeks, was a moderate increment of endogenous IAA content observed. IAA and ABA showed opposite levels during the development and maturation of cork oak somatic embryos and characterised specific stages of the embryonic development.     

Gene expression patterns, and uptake and fate of fed ABA in white spruce somatic embryo tissues2

Changes in cellular protein accumulation and in in vivo andin vitro protein synthesis, in somatic embryo tissues of whitespruce during a 42 d maturation period were followed by two-dimensionalsodium dodecyl sulphate-polyacrylamide gel electrophoresis (2-DSDS-PAGE). These investigations were complemented by an analysisof uptake and fate of fed abscisic acid (ABA) in somatic embryotissues grown on maturation medium. When Stage 1 somatic embryoswere cultured on ABA-containing maturation medium, many changeswere observed in patterns of gene expression and in proteinsynthesis and accumulation which could be associated with embryodevelopment. The polypeptides observed could be categorizedas constitutive, embryo-abundant, embryo maturation-relatedand embryo stage-related, as well as those with non-specificchanges. Accumulation of label from fed ³H-(+)-ABA in embryotissues reached a plateau 3 d after Stage 1 somatic embryoswere placed on maturation medium. ABA taken into tissues wasrapidly metabolized, and 40% of radioactivity in tissues after1 d of culture resulted from ABA metabolites. This value increasedto 90% after 3 weeks culture. Conjugated ABA and oxidized ABA(phaseic acid and dihydrophaseic acid) were major forms of ABAmetabolites in spruce embryo tissues. Using a single 42 d cultureperiod following transfer to medium with ABA, the conditionsthat stimulate the sequence of developmental changes of somaticembryo maturation during the first 21 d do not reoccur duringthe second 21 d. Unless greater synchronization of Stage 1 culturescan be achieved, it is therefore unlikely that yields of maturesomatic embryos will be increased by this method. Key words: Abscisic acid, gene expression, Picea glauca (Moench) Voss, protein synthesis, somatic embryo maturation     

Abscisic acid induces somatic embryogenesis and enables the capture of high-value genotypes in Douglas fir (Pseudotsuga menziesii [MIRB.] Franco)

Douglas fir (Pseudotsuga menziesii) is one of Europe’s most important non-native tree species due to its drought tolerance as well as timber quality and yield. To obtain superior seed from selected parental trees, breeding programs had been established in seed orchards. Douglas fir seed is used as source material for somatic embryogenesis with the aim to select elite genotypes invaluable for clonal mass propagation. To improve given protocols for somatic embryo initiation, we used immature Douglas fir zygotic embryos as explants and abscisic acid (ABA) as plant growth regulator in contrast to the application of auxins and cytokinins. With ABA supplementation, induction frequencies were slightly but in mean higher than with auxin/cytokinin, showing also a strong genotype effect. This offered the possibility to capture SE cultures from otherwise recalcitrant crosses. Furthermore, we observed remarkable differences between the two sets of plant growth regulators concerning the morphological development of the explants, including the absence of non-embryogenic callus by using ABA as inducer. This simplifies the detection of events and the handling of the obtained cultures. Nevertheless, a histological approach suggested, that the same competent cells are addressed by the different hormonal stimulation. Besides, we studied the influence of different points in time of cone harvest, two different basal media and different genetic backgrounds of the explants as well as the maturation ability of the induced embryogenic cultures. In sum, we were able to improve the first steps of somatic embryogenesis and to maintain a significantly higher number of high-value genotypes.

     

Somatic embryogenesis in Pinus halepensis Mill.: an important ecological species from the Mediterranean forest

Pinus halepensis Mill. is a common forest species in the Mediterranean area and it is important for environmental conservation. This study established a method of regenerating Pinus halepensis Mill. through somatic embryogenesis. The effect of culture medium (mineral salts, nitrogen source and plant growth regulators), collection date and seed family on embryogenic tissue initiation and proliferation in Pinus halepensis was analysed during the first steps of embryogenesis process. This study showed a marked effect of the culture medium tested as well as some significant differences among collection dates. Furthermore, the embryogenic tissue initiation was affected by the amino acid mixture in the culture medium and the proliferation stage was significantly affected by the combination of plant growth regulators. At the end of the maturation phase the presence of activated charcoal was also evaluated. Finally, maturation of embryogenic tissue was affected by the nitrogen source in the culture medium and these results were different for high and low mature embryo producing cell lines. To the best of our knowledge, this is the first report on Aleppo pine somatic embryogenesis describing a simple and efficient procedure for large-scale somatic embryo production.     

OBPC Symposium: Maize 2004 &; beyond-developmental and molecular genetics of embryogenesis in plants

Summary Embryo development is a very key phase in the life cycle of seed plants. At maturity, the embryo contains the complete machinery to elaborate the entire plant body. While the embryogenic process is an innate feature of the zygote, gametic and somatic cells can undergo embryogenesis under the appropriate culture conditions. Embryogenesis is a highly regulated process and the use of mutants, especially in Arabidopsis, has allowed the identification of genes regulating pattern formation during this process. The use of such mutants has revealed the eritical roles of auxin levels and transport in the establishment of embryo axis. Root and shoot apical meristem function and integrity, have been defined by examination of genes involved in their identity and function. Further knowledge of the molecular and biochemical aspects of zygotic embryogenesis should contribute to our understanding of the underlying regulatory pathways and networks and also provide critical insights into unique totipotent features of the plant cell.     

Endogenous abscisic acid signaling towards storage reserve filling in developing seed tissues of castor bean (Ricinus communis L.)

Abscisic acid (ABA; free form) is a naturally occurring physiological growth hormone of higher plants. A detailed study involving the time course growth of developing seed tissues associated with endogenous levels of free ABA were investigated using a novel enzyme-linked immunosorbent assay. Seed filling in castor (Ricinuc communis L.) endosperm, embryo, and pod is marked with a rapid increase in fresh weight during the mid-developmental stages [21–42 days after pollination (DAP)], followed by a steady decline at the maturation stages (42–63 DAP) accompanied with a rapid lipid synthesis (in endosperm and embryo) during the same period, except for in pod. Endogenous ABA levels in endosperm (0.001–0.32 μg/g) and embryo (0.003–0.13 μg/g) followed a concurrent pattern with seed reserve filling, showing a rapid increase during the mid-developmental stages 21–42 DAP, whereas ABA levels in seed pod (0.2–22.9 μg/g) showed a different accumulation pattern with rapid increase and decline during the early-mid developmental stages, preceded by the maximal increase during the maturation stage (63 DAP). Together, our results provide evidence for the association of endogenous ABA in seed filling as well as in reserve deposition and provides clue for the effective usage of exogenous ABA concentrations in developing seeds with a focus, on improving seed reserve complex in castor.     

From callus to embryo: a proteomic view on the development and maturation of somatic embryos in <Emphasis Type="Italic">Cyclamen persicum</Emphasis>

In this study, the proteome structures following the pathway in somatic embryogenesis of Cyclamen persicum were analysed via high-resolution 2D-SDS-PAGE with two objectives: (1) to identify the significant physiological processes during somatic embryogenesis in Cyclamen and (2) to improve the maturation of somatic embryos. Therefore, the effects of maturation-promoting plant growth regulator abscisic acid (ABA) and high sucrose levels on torpedo-shaped embryos were investigated. In total, 108 proteins of differential abundance were identified using a combination of tandem mass spectrometry and a digital proteome reference map. In callus, enzymes related to energy supply were especially distinct, most likely due to energy demand caused by fast growth and cell division. The switch from callus to globular embryo as well as from globular to torpedo-shaped embryo was associated with controlled proteolysis via the ubiquitin-26S proteasome pathway. Storage compound accumulation was first detected 21 days after transfer to plant growth regulator (PGR)-free medium in early torpedo-shaped embryos. Increase in abundance of auxin-amidohydrolase during embryogenesis suggests a possible increase in auxin release in the late embryo stages of Cyclamen. A development-specific isoelectric point switch of catalases has been reported for the first time for somatic embryogenesis. Several proteins were identified to represent markers for the different developmental stages analysed. High sucrose levels and ABA treatment promoted the accumulation of storage compounds in torpedo-shaped embryos. Additionally, proteins of the primary metabolic pathways were decreased in the proteomes of ABA-treated embryos. Thus, ABA and high sucrose concentration in the culture medium improved maturation and consequently the quality of somatic embryos in C. persicum.     

Hormonal Complex and Ultrastructure of Maturing Aesculus hippocastanum Seeds

The content and temporal changes in the endogenous IAA, cytokinins, gibberellin-like compounds (GLC), and ABA were determined during horse chestnut (Aesculus hippocastanum L.) seed development (the stages of embryo axis development, its active growth, and storage compound deposition). The active growth of the embryo was characterized by the highest amounts of free phytohormones. Later, by the end of seed maturation, we observed the accumulation of the bound forms of IAA and ABA and a trend to a decrease in the content of free IAA, zeatin, and GLC (butanol fraction). The electron-microscopic examination of the embryo from the mature seed demonstrated that some structural components of the cytoplasm were similar in the cells of embryo axes and cotyledons. During the entire period of maturation, the embryo cells preserved native vacuoles and protein bodies were not formed. Thus, the structure of cotyledonary and axial cells and the distribution of free and bound phytohormones in the horse-chestnut seeds are similar to those in maturing seeds characterized by exogenous dormancy.     

Control of hyperhydricity of mango somatic embryos

Hyperhydricity of immature somatic embryos has been a limiting factor for the development of highly embryogenic suspension cultures of many important mango cultivars. Reversion of hyperhydricity was achieved in two ways: 1) heart-stage somatic embryos (2–3 mm length) were partially dehydrated under controlled conditions at high relative humidity (RH) for 24–48 h and 2) the gelling agent (Gel-Gro) concentration of the plant growth medium was increased from 2.0 to 6.0 g l^-1. Partially dehydrated immature somatic embryos were normal in appearance. Somatic embryos that were partially dehydrated germinated precociously when cultured on maturation medium. Although abscisic acid (ABA) did not reverse hyperhydricity of primary somatic embryos, ABA did stimulate the reversal of this abnormal pattern of development among secondary embryos. ABA (500 M) inhibited precocious germination and permitted somatic embryo maturation. Partially dehydrated, immature somatic embryos (4–7 mm long) remained viable for up to 32 days in the absence of maturation medium under high RH.Abbreviations 2,4-d 2,4-dichlorophenoxyacetic acid - ABA abscisic acid - BA 6-benzyladenine - RH relative humidity