Development of somatic embryos in Norway spruce

Embryogenic cell lines of Norway spruce consist of a large number of somatic embryos. The cell lines have been divided into two groups, A and B. The group B embryos are developmentally blocked. Extracts of mature spruce seeds stimulate group B embryos to develop a morphology comparable to group A embryos. However, seed extract inhibits early embryo development. The active components in seed extract were shown probably to be proteins. Extracts of mature seeds contain chitinase-like proteins as recognized by an antibody towards chitinase 4 in sugar beet. Proteins of similar sizes were detected by the same antibody in the conditioned medium of group A, but not in group B. A chitinase 4-related chitinase and a nod factor had a stimulating effect on early embryo development, but did not influence the later stages of embryo development.Key words: Picea abies, somatic embryogenesis, embryo development, seed extract.      

Propagation of Norway spruce via somatic embryogenesis

Somatic embryogenesis combined with cryopreservation is an attractive method to propagate Norway spruce (Picea abies) vegetatively both as a tool in the breeding programme and for large-scale clonal propagation of elite material. Somatic embryos are also a valuable tool for studying regulation of embryo development. Embryogenic cell lines of Norway spruce are established from zygotic embryos. The cell lines proliferate as proembryogenic masses (PEMs). Somatic embryos develop from PEMs. PEM-to-somatic embryo transition is a key developmental switch that determines the yield and quality of mature somatic embryos. Withdrawal of plant growth regulators (PGRs) stimulates PEM-to-somatic embryo transition accompanied by programmed cell death (PCD) in PEMs. This PCD is mediated by a marked decrease in extracellular pH. If the acidification is abolished by buffering the culture medium, PEM-to-somatic embryo transition together with PCD is inhibited. Cell death, induced by withdrawal of PGRs, can be suppressed by extra supply of lipo-chitooligosaccharides (LCOs). Extracellular chitinases are probably involved in production and degradation of LCOs. During early embryogeny, the embryos form an embryonal mass surrounded by a surface layer. The formation of a surface layer is accompanied by a switch in the expression pattern of an Ltp-like gene (Pa18) and a homeobox gene (PaHB1), from ubiquitous expression in PEMs to surface layer-specific in somatic embryos. Ectopic expression of Pa18 and PaHB1 leads to an early developmental block. Transgenic embryos and plants of Norway spruce are routinely produced by using a biolistic approach. The transgenic material is used for studying the importance of specific genes for regulating plant development, but transgenic plants can also be used for identification of candidate genes for use in the breeding programme.     

Metabolism of l[U-14C]-arginine and l[U-14C]-ornithine in maturing and vernalised embryos and megagametophytes of Picea abies

The metabolism of the polyamine precursors arginine and ornithine was studied in maturing and vernalised seeds of Picea abies (L.) Karst. (Norway spruce) in feeding experiments. Incorporation of radioactivity from these 14 C-labelled amino acids into liberated CO₂, amino acids, polyamines, proteins and cell wall fractions, as well as polyamine levels were determined in embryos and megagametophytes. Ornithine and especially arginine decarboxylation was more active in the embryo than in the megagametophytic cells, and vernalisation increased arginine metabolism more than it increased ornithine metabolism. Both precursors were metabolised to each other, to other amino acids, and to polyamines. The only polyamine in which radioactivity incorporated was free putrescine, showing either a slow synthesis or a high degradation rate of spermidine and spermine in maturing spruce seeds. The putrescine level was approximately 10 times higher in the embryo than in the megagametophytic tissues, whereas spermidine and spermine levels were almost the same in both tissues. The label from arginine and ornithine was also incorporated into proteins as amino acids and post-translationally as polyamines. Higher radioactivity was seen in the small ≤14-kDa polypeptides. Protein hydrolysates of the embryo and the megagametophytic tissues contained spermidine and spermine and their degradation product 1,3-diaminopropane (DAP), suggesting that polyamines may play a role in the accumulation of seed storage protein and in the maturation of spruce seeds.     

Single-cell origin and development of somatic embryos in Picea abies (L.) Karst. (Norway spruce) and P. glauca (Moench) Voss (white spruce)

The origin and development of somatic embryos in calli initiated from immature zygotic embryos of Picea abies (L.) Karst. (Norway spruce) and P. glauca (Moench) Voss (white spruce) was studied. Immature zygotic embryos cultured on callus induction medium produced two types of white calli that were phenotypically different from one another. The callus that proliferated from the hypocotyl region was white to translucent, glossy, mucilaginous and embryogenic. The callus mass which originated from the radicle end was reddish-white, nonmucilaginous and nonembryogenic. Whole mount preparations of the entire explant with two different types of calli showed the presence of embryogenic cells in the mucilaginous callus mass derived from the hypocotyl region of the zygotic embryo. The origin of somatic embryos in both Norway and white spruce could be traced to single cells of the hypocotyl callus.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - BAP 6-benzylaminopurine     

Effect of partial drying and desiccation on somatic seedling quality in Norway and Serbian spruce

Somatic embryo quality is still a problem for many researchers. To improve the efficiency of germination, special procedures are used, such as partial drying of somatic embryos at high relative humidity or desiccation in the presence of supersaturated solutions of salt. In this work, cotyledonary somatic embryos of Norway spruce (Picea abies) and Serbian spruce (P. omorika) were placed on culture media (ME or BM-5) to germinate. We found that after 4 weeks of incubation on these media, hypocotyl and radicle growth of control (non-dried) somatic embryos of both species was not adequate to yield seedlings able to acclimatize to greenhouse conditions. Therefore, somatic embryos were partly dried at relative humidity of 97 % or desiccated at relative humidity of 79 %, for 2 or 3 weeks, and then placed on the Margara (ME) medium. Partial drying of somatic embryos at the higher relative humidity (97 %) enabled an improvement of radicle growth of germinating somatic embryos in both species. The highest conversion rate (45 %) was obtained for embryos of Norway spruce maintained for 2 weeks at relative humidity of 97 %. This treatment contributed to the improvement of germination and conversion efficiency of somatic embryos of Norway spruce, regardless of the drying period. Improved radicle growth facilitated development of better quality seedlings of this spruce species. In Serbian spruce, we did not obtain seedlings of sufficient quality, due to poor hypocotyl growth. Desiccation at humidity of 79 % for 3 weeks proved to be lethal to somatic embryos of both species.     

Robust carbohydrate dynamics based on sucrose resynthesis in developing Norway spruce somatic embryos at variable sugar supply

Growth regulators and carbohydrates are key regulatory factors that affect somatic embryogenesis. Carbohydrates serve as energy and carbon sources, osmotica and osmoprotectants and are important signal molecules. Most information about the role of carbohydrates in somatic embryogenesis in Norway spruce has been obtained with embryos grown on semi-solid media. The aim of the present study was to gain a better understanding of the effects of exogenous carbohydrates through modification of medium components (sugars) and physical state (liquid and semi-solid media). Rafts, floating on liquid medium, were used to allow precise manipulation of carbohydrate availability, though it did not result in the highest embryo yields. Our results indicate the following for Norway spruce somatic embryo development: (1) overall carbohydrate dynamics in somatic embryos cultivated on liquid or semi-solid media were similar; (2) the total carbohydrate content, however, was higher in somatic embryos cultivated on liquid media; (3) sucrose was present in somatic embryos even when they matured on sucrose-free media; (4) sucrose content in liquid sucrose-supplemented maturation media decreased sharply during a 1-wk subculture interval; (5) the accumulation of the raffinose family oligosaccharides during desiccation was determined independently of previous sugar supply; and (6) a decrease of sucrose and an increase of hexoses contents accompanied somatic embryo germination.     

Inhibited polar auxin transport results in aberrant embryo development in Norway spruce

Current hypotheses concerning the role of polar auxin transport in embryo development are entirely based on studies of angiosperms, while little is known about how auxin regulates pattern formation in gymnosperms. In this study, different developmental stages of somatic embryos of Norway spruce (Picea abies) were treated with the polar auxin transport inhibitor 1-N-naphtylphthalamic acid (NPA). Effects of the treatments on auxin content, embryo differentiation and programmed cell death (PCD) were analysed. During early embryo development, NPA-treatment led to increased indole-3-acetic acid (IAA) content, abnormal cell divisions and decreased PCD, resulting in aberrant development of embryonal tube cells and suspensors. Mature embryos that had been treated with NPA showed both apical and basal abnormalities. Typically the embryos had abnormal cotyledon formation and irregular cell divisions in the area of the root meristem. Our results show that polar auxin transport is essential for the correct patterning of both apical and basal parts of conifer embryos throughout the whole developmental process. Furthermore, the aberrant morhologies of NPA-treated spruce embryos are comparable with several auxin response and transport mutants in Arabidopsis. This suggests that the role of polar auxin transport is conserved between angiosperms and gymnosperms.     

Reliable and practical methods for cryopreservation of embryogenic cultures and cold storage of somatic embryos of Norway spruce

Somatic embryogenesis (SE) is considered as the most-effective method for vegetative propagation of Norway spruce (Picea abies L. Karst). For mass propagation, a cryopreservation method able to handle large numbers of embryogenic tissues (ETs) reliably and at low costs is needed. The aim of the present study was to compare pretreatments, cryoprotectants and slow-cooling devices for cryopreservation of Norway spruce ETs, with 12 variations of methods and a total of 136 spruce genotypes. Secondly, possible applications for cold storage of mature somatic embryos were studied with the aim of developing a flexible time window for embling production. At best, 100% of the embryogenic lines were recovered following cryopreservation, but the results varied among the sets of lines. Also physiological condition of the tissues, pre-treatment and cryoprotectant applied, as well as the slow-cooling device used were found to affect the recovery. The best option for cryopreservation of Norway spruce is to select fresh growth from young ETs as samples, pretreat them on semi-solid medium with increasing sucrose concentration (0.1 M for 24 h; 0.2 M for another 24 h), apply a mixture of polyethylene glycol 6000, glucose, and dimethylsulfoxide, 10% w/v each, as cryoprotectant and use a programmable freezer with a slow cooling rate (0.17 °C/min). On average, 87% of the genotypes can be recovered, without any effect on their genetic fidelity, as shown by microsatellite markers and embryo production capacity. Mature somatic embryos of Norway spruce can also be safely cold-stored at +4 °C, without adverse effects on their germination ability.     

ABA consumption in norway spruce (Picea abies) and white spruce (Picea glauca) somatic embryo cultures

Summary We investigated abscisic acid (ABA) metabolism among Norway and white spruce somatic embryo cultures which exhibited differences in maturation response when placed on racemic abscisic acid [(±)-ABA]. Differences in metabolic rate among the spruce genotypes could affect the ABA pool available for the maturation process, and might therefore be responsible for the differences in maturation response. The production of cotyledonary (stage 3) somatic embryos in cultures (genotypes) of Norway spruce (PA86:26A and PA88:25B) and of white spruce (WS1F cryoD and WS46) was compared. In each species pair one of the two genotypes failed to show stage 3 embryo development (respectively, PA88:25B and WS46). The investigation of ABA metabolism of each species pair showed that no substantial differences in ABA consumption or in the production of metabolites occurred. In each case ABA was metabolized to phaseic acid and dihydrophaseic acid over the 42-day culture period, metabolites were recoverable from the agar-solidified medium, and the sum of residual ABA and metabolites were equivalent to the ABA initially supplied. The results indicate that the process of ABA metabolism occurs essentially independently of somatic embryo maturation. NRCC no. 37345.     

Improved and synchronized maturation of Norway spruce (<Emphasis Type="Italic">Picea abies</Emphasis> (L.) H.Karst.) somatic embryos in temporary immersion bioreactors

Somatic embryogenesis offers many benefits for clonal propagation in large-scale plant production of conifers. A key rate-limiting step is the conversion from early-stage somatic embryos in pro-embryogenic masses (PEMs) to the maturation stage. Immature embryos in PEMs are present at different developmental stages, where some are unable to respond to the maturation treatment, thus limiting yields of mature embryos. Synchronization of early somatic embryo development in PEMs could greatly improve subsequent yields of mature embryos. A temporary immersion bioreactor designed for Norway spruce (Picea abies (L.) H.Karst.) was used in this study. Through a specific system for dispersion, connected tissue of PEMs, composed of immature embryos grown in liquid medium in the temporary immersion bioreactors or on solid medium as a control, was dispersed and redistributed in a more uniform spatial arrangement. It was demonstrated that development of mature embryos could be significantly stimulated by dispersion, compared to controls, in both medium types. Synchronization of maturation was evaluated by a statistical approach. The present study shows that the yield of mature embryos from dispersed PEMs was three to five times higher than that from non-dispersed controls in three of four cell lines of Norway spruce tested, both in bioreactors and on solid medium.     

The role of sucrose during maturation of black spruce (Picea mariana) and white spruce (Picea glauca) somatic embryos

The present study was conducted to understand the role of sucrose in the medium on the maturation of black spruce and white spruce somatic embryos. A maturation medium containing 6% sucrose, which hydrolyzed into glucose and fructose, gave significantly more embryos than a medium containing 3.16% of each glucose and fructose. Preventing the complete sucrose hydrolysis by a daily transfer of the tissues onto fresh medium significantly decreased the yield of somatic embryos compared to when sucrose was allowed to complete its hydrolysis. This reduction was not due to the manipulation of the tissues during the transfer, since a daily in situ transfer did not affect embryo production. To verify if the better embryo production observed on a medium containing 6% sucrose was due to the increasing osmotic pressure of the medium, this increasing osmotic pressure was simulated with a sequence of media containing different concentrations of glucose and fructose. Unexpectedly and for both species, this simulation did not improve somatic embryo production, which stayed similar to the one obtained on constant osmotic pressure. To understand these results, embryos produced on the different treatments were analyzed in terms of sucrose, glucose, fructose and starch levels and protein contents. The embryo carbohydrate content was independent from the carbohydrate used in the maturation medium. However, embryos matured on 6% sucrose allowed to hydrolyze during the maturation period contained significantly more soluble and insoluble proteins than embryos matured on any other treatment. Furthermore, embryos with a higher protein content also exhibited a higher epicotyl appearance frequency. The role of sucrose as a regulatory factor during the maturation of spruce somatic embryos is discussed.     

Storage protein accumulation during zygotic and somatic embryo development in Picea abies (Norway spruce)

Total protein was extracted from zygotic embryos and from somatic embryos of Picea abies (L.) Karst. (Norway spruce) cultured in vitro at different times during their development. An analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and 2-dimensional gel electrophoresis of the protein extracts showed that protein composition and the temporal changes in protein abundance were very similar in the two embryo types. Both zygotic and somatic embryos accumulated storage proteins in abundance during their maturation phase of growth; the somatic embryos when cultured on medium containing 90 m M sucrose and 7.6 μ M ABA. The major storage proteins are composed of polypeptides with molecular masses of about 22, 28, 33 and 42 kDa and they are identical in both embryo types according to their molecular mass and average isoelectric points. These proteins are also the most abundant proteins in the female gametophytic tissue of the mature seed.     

Importance of arabinogalactan proteins for the development of somatic embryos of Norway spruce (Picea abies)

The morphology of somatic embryos of Norway spruce ( Picea abies ) varies among different cell lines, from less developed somatic embryos with small embryonic regions (group B) to well developed embryos with large embryonic regions (group A). Only well developed somatic embryos will undergo a maturation process after a treatment with ABA and develop into mature somatic embryos, which is required for plant regeneration. We have previously shown that the presence of specific extracellular proteins can be correlated with the morphology of the somatic embryos. In the present study we show that extracellular proteins concentrated from group A cell lines can stimulate group B embryos to develop further and that seed extract can stably convert B embryos into A embryos. The arabinogalactan protein (AGP) fraction of the extracellular proteins and of the seed extract was shown to be an active component for stimulating B embryos to develop further. Furthermore, the amount and type of extracellular AGPs, as detected with β-glucosyl Yariv reagent and monoclonal antibodies, varied among different types of tissues and cell lines. The data show that development of somatic embryos in Norway spruce is associated with particular extracellular AGPs, which have a regulatory function.     

The effect of osmoticum on ascorbate and glutathione metabolism during white spruce (Picea glauca) somatic embryo development.

Water stress is an important factor which regulates organized development of both zygotic and somatic embryos. Somatic embryos of white spruce were cultured in the presence of polyethylene glycol (PEG), a non-plasmolyzing agent which increases embryo quality and number, and mannitol, a plasmolyzing agent. The effects of these two compounds on both ascorbate and glutathione metabolism were investigated at different stages of embryo development. Compared to control and mannitol-treated embryos, embryos treated with PEG accumulated higher levels of endogenous ascorbate (ASC) in its reduced form, especially during the first half of the maturation period. This increase, also observed in immature seeds, was mainly the result of two different processes: activation of the de novo ASC machinery, and recycling of ASC from ascorbate free radicals (AFR) which was modulated by the activity of ascorbate free radical reductase (AFRR, EC. 1.6.5.4). The activity of this enzyme increased during the early phases of development in both PEG-treated somatic embryos and seeds. Compared to control somatic embryos, mannitol and PEG were shown to change the levels of reduced (GSH) and oxidized glutathione (GSSG). In particular, a constant decline in the GSH/GSSG ratio was observed in the presence of PEG. This pattern was also observed in maturing white spruce seeds. Overall, these data indicate that applications of non-plasmolyzing agents in the culture medium of spruce somatic embryos result in seed-like fluctuations of the ascorbate-glutathione metabolism, which may have a positive effect on embryo yield.     

Extracellular proteins in embryogenic suspension cultures of Norway spruce (Picea abies)

Embryogenic cell lines of Norway spruce ( Picea abies ) varying in growth habit and morphology were compared as regards profiles of extracellular proteins. Similar proteins were detected in the culture medium by SDS PAGE and in vivo labeling experiments, indicating that the proteins were secreted. Approximately 20 protein bands could be detected in the medium of each cell line. Three of the bands represented glycosylated proteins, as revealed by Concanavalin A staining. Some of the secreted proteins were similar for all tested embryogenic lines of Norway spruce, others were either specific for a group of cell lines or for individual cell lines. A correlation was observed between the morphology of the somatic embryos in a cell line and the presence of secreted proteins. The embryogenic cell lines of Norway spruce can be divided into two main groups. A and B, where A is characterized by somatic embryos with dense embryoheads and B by somatic embryos with loosely aggregated cells in their embryoheads. When proteins secreted from a cell line belonging to group A were added to cell lines belonging to group B, the somatic embryos of the B type developed further and became more similar in morphology to A-type embryos. These observations indicate that cell lines belonging to group A secrete certain proteins to the culture medium that are essential for the development of somatic embryos of Norway spruce.     

Endogenous Nod-factor-like signal molecules promote early somatic embryo development in Norway spruce

Embryogenic cultures of Norway spruce (Picea abies) are composed of pro-embryogenic masses (PEMs) and somatic embryos of various developmental stages. Auxin is important for PEM formation and proliferation. In this report we show that depletion of auxin blocks PEM development and causes large-scale cell death. Extracts of the media conditioned by embryogenic cultures stimulate development of PEM aggregates in auxin-deficient cultures. Partial characterization of the conditioning factor shows that it is a lipophilic, low-molecular-weight molecule, which is sensitive to chitinase and contains GlcNAc residues. On the basis of this information, we propose that the factor is a lipophilic chitin oligosaccharide (LCO). The amount of LCO correlates to the developmental stages of PEMs and embryos, with the highest level in the media conditioned by developmentally blocked cultures. LCO is not present in nonembryogenic cultures. Cell death, induced by withdrawal of auxin, is suppressed by extra supply of endogenous LCO or Nod factor from Rhizobium sp. NGR234. The effect can be mimicked by a chitotetraose or chitinase from Streptomyces griseus. Taken together, our data suggest that endogenous LCO acts as a signal molecule stimulating PEM and early embryo development in Norway spruce.     

A method for quantification of the level of somatic embryogenesis among Norway spruce callus lines

A method for quantitative determination of the level of somatic embryogenesis in Norway spruce embryogenic callus is described. Embryogenic callus was dispersed in liquid by agitation and plated in a thin layer of medium containing 0.6% low melting point agarose. The number of embedded somatic embryos per mg of callus ranged from 0.2 to 1.5 among 11 embryogenic callus lines surveyed. Each callus line was derived from an individual immature embryo explant. Further development occurred as somatic embryos grew out of the agarose layer. This method was useful for identifying highly embryogenic callus lines among phenotypically similar lines, and should be useful for quantitatively determining the effect of medium and growth regulator modifications on somatic embryo density and developmental capacity.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - BAP 6-benzylaminopurine - IBA indole-3-butyric acid - ABA abscisic acid     

Improved Norway spruce somatic embryo development through the use of abscisic acid combined with activated carbon

The combination of abscisic acid (ABA) and activated carbon increased Norway spruce (Picea abies L., Karst.) cotyledonary somatic embryo yields, increased the number of genotypes forming cotyledonary embryos, caused embryos to form that exhibited improved maturation characteristics, and reduced embryo production costs. Somatic embryos increased in size, showed larger apical regions, became more zygotic-like in shape, and showed higher percentages of epicotyl development upon germination. Analyses of medium for free ABA in the presence of activated charcoal showed a rapid decrease within a few hours followed by a gradual decline over the next few days with little change from 2 to 6 weeks. Gelling agents strongly affected ABA adsorption, with agar decreasing the adsorption of ABA compared to gellan gum (Gelrite, Phytagel). Over 4,000 somatic seedlings from 20 clones were produced and established in a greenhouse using the methods discussed, and approximately 1,250 seedlings representing seven clones were established in a field setting.