Storage of encapsulated somatic embryos of carrot

Summary A study was conducted to determine the germination frequencies of encapsulated somatic embryos of carrot after long periods of storage. The embryos were placed into hormone-free Murasige-Skoog (MS) liquid medium and stored at 4°C in the dark. The germination frequency for encapsulated somatic embryos stored for three months was more than 95% when grown on polyester fiber supports containing hormone-free MS medium, while the germination frequency for non-encapsulated somatic embryos was less than 5% after storage for three months.     

Growth conditions influence regeneration of encapsulated carrot somatic embryos into plantlets

Summary Carrot somatic embryos were encapsulated in calcium alginate beads, with or without a maturation step, to produce synthetic seeds. Germination and plantlet regeneration frequencies were compared for liquid or solid nutritive media, and with sucrose supply and sterilization or not. Germination rates were greater than 80% in all treatments except in non-sterilized sand. No conversion occured on a liquid MS medium. Normal plantlets were 7–22% on agar and 4–40% on sand. Abnormal plantlets were only observed on agar due to secondary embryogenesis. A sterilized sand growth support supplied with sucrose appears to be most appropriate to assess morphologically normal plantlet regeneration.Corresponding author     

Effect of sole and combined pre-treatments on reserve accumulation, survival and germination of encapsulated and dehydrated carrot somatic embryos

In order to obtain dry artificial seeds, carrot somatic embryos were pre-treated before being encapsulated into calcium-alginate-gellan gum, and slowly dehydrated unitil 15% RH (relative humidity of the chamber). ABA (1 to 10 μM), 1 to 5 mM proline, an osmotic pressure of ±520 mOsm, or heat (35°C) enhanced the desiccation tolerance of encapsulated somatic embryos. Some treatments were complementary, like 10 μM ABA and 10% sucrose, 10 μM ABA and heat (35°C), or 10% sucrose and cold (4°C). In such conditions, complete or almost total (95.6–100% germination) desiccation tolerance was then obtained. These treatments may act by the acquisition of sufficient-and well-balanced-protein and starch reserves. osmotic treatments, ABA, and above all proline, promoted protein accumulation, meanwhile starch reserves were slightly depleted by 10–20 μM ABA, proline, and poor sucrose-osmotic treatments (8% trehalose). All the treatments were found to enhance viability during dehydration, as observed by fluorescence. Sucrose may be partly replaced by other osmotica. Alone, it has a negative effect on the depletion of starch reserves. Cold (4°C) with 10% sucrose may favor the glassy state transition. ABA and proline appear to be involved in the same process leading to the acquisition of partial desiccation tolerance. Heat (35°C), or 10% sucrose, have been found to complement ABA action in the acquisition of full desiccation tolerance.     

Germination and growth of encapsulated somatic embryos of carrot for mass propagation

Summary Shoot growth and root development of plantlets germinated from encapsulated somatic embryos of carrot were promoted by transferring the embryos from a culture medium containing sucrose (1.5%) to a culture vessel with a similar medium without sucrose, which was kept under a constant relative humidity condition (90%) during the culture period. The length and dry weight of plantlet shoots placed on medium supports (ceramic wool) containing a liquid culture medium without sucrose from three weeks after placing encapsulated somatic embryos were approximately two times greater than those placed on medium supports containing a culture medium with sucrose throughout the five-week culture period.     

Physico-chemical properties of the encapsulation matrix and germination of carrot somatic embryos

Carrot somatic embryos were encapsulated in alginate gel beads. To improve the quality of a "synthetic seed" coating, the rheology and dehydration properties of different matrices were tested. By increasing alginate and CaCl(2) concentrations, additional mineral elements were shown to increase resistance to rupture, and to depress the germination of somatic embryos. A polysaccharide addition was found to slow the alginate matrix dehydration; alginate-gellan gum and alginate-kaolin matrices could preserve the viability of somatic embryos at low relative humidities (30% to 35% germinations at 50% relative humidity) to a greater extent than other matrices. (c) 1995 John Wiley & Sons, Inc.     

Isolation of protoplasts from somatic embryos of carrot

Protoplasts were isolated enzymatically from synchronously induced globular somatic embryos from a carrot suspension culture. Among the macerating enzymes tested, Driselase was the most effective for release of protoplasts from embryos. A higher medium osmolarity was required for the isolation of protoplasts from embryos than from undifferentiated cells. Protoplasts from embryos were smaller than protoplasts from undifferentiated cells. On step gradients of Ficoll, protoplasts from embryos gave one major band. Protoplasts from undifferentiated cells gave two major bands, one lighter and the other heavier than the protoplasts from embryos.     

Production of carrot somatic embryos in a bioreactor

Somatic carrot embryos were grown as batch cultures in a stirred 10-l bioreactor. Embryo production in the bioreactor was comparable to that obtained in shake-flasks. A production of about 50·10³ embryos/l per day was commonly achieved with an inoculum density of 0.1% volume of tissues/volume of medium. Regularly changing of the medium increased embryo viability. A filtering unit coupled to the bioreactor was developed in order to calibrate embryos. The characteristics of the population of harvested embryos are described. Correspondence to: J.-P. Ducos     

Stage-specific nitrogen metabolism in developing carrot somatic embryos

The physiology of individual somatic embryo developmental stages otDaucus carota L. was examined by in vivo nuclear magnetic resonance (NMR) spectroscopy, amino acid analysis and ¹⁴C-labeling. ¹⁵N NMR spectroscopy was used to examine the uptake and incorporation of ¹⁵N isotopically labeled inorganic nitrogen sources. NMR spectra of proembryogenic masses (PEMs) contained resonances for histidine, amino sugars, glutamine, arginine, urea, alanine. α-amino nitrogen, serine, aliphatic amines and several unknowns. Similar resonances were found in various embryo developmental stages. However, resonances for arginine and aliphatic amines peaked during globular and torpedo stages and substantially decreased in germinating stage embryos. The dominant resonances observed in non-embryogenic cells and germinating embryos were glutamine and α-amino nitrogen. Amino acid analysis of the various embryo stages showed that glutamate, glutamine and arginine were the major contributors to the soluble amino acid profiles. During development, glutamate and glutamine continued to increase in concentration whereas arginine and its related metabolites (i.e. ornithine and y-aminobutyric acid [GABA]) were biphasic; increasing in globular and torpedo stage embryos and decreasing in germinating embryos. Carbon-14 labeling indicated that labeled glutamine pools in non-embryogenic and germinating embryos were greatest compared to other embryo stages, whereas labeled GABA pools were greatest in globular and torpedo stage embryos. Taken together, these data indicate that the physiology of each embryo developmental stage is distinct. They also suggest that during somatic embryo development, a switch takes place in metabolism whereby the glutamine synthetase/glutamate synthase (GS/GOGAT) pathway is predominant in non-embryogenic cells and germinating stage embryos. Furthermore, during early to mid-embryo development (PEMs, globular and torpedo stage embryos), metabolism utilizing the omithine cycle is enhanced and predominant.     

Maturation and germination of walnut somatic embryos

Walnut somatic embryos were multiplied by repetitive embryogenesis on a solid basal DKW medium at 25°C in the dark. When the embryos were isolated at early cotyledonary stage (1–2 mm long) from the primary embryos and cultured on the medium for 3 weeks, they developed into mature embryos showing white, enlarged cotyledons and shoot and root apex. After transfer to light on solid germination medium, however, few mature embryos (0–5%) germinated. Germination percentage increased to about 10% when the mature embryos were pretreated by a storage at 4°C in the dark for 2 months, or by desiccation at 25°C in the dark for 3 or 5 days under an air-humidity conditioned by saturated salt solutions (Mg(NO₃)₂.6H₂O, or ZnSO₄.7H₂O). Similar results were obtained by the addition of gibberellic acid (GA₃) to the germination medium. When mature embryos were desiccated and then placed on medical cotton compresses in liquid germination medium, 45% of the embryos germinated into complete plantlets. These plantlets continued their growth after transplanting to a mixture of peat and vermiculite in pots.Abbreviations GA₃ gibberellic acid - DKW medium Driver & Kuniyuki Walnut medium     

In vitro response of encapsulated somatic embryos of camellia

Plant regeneration via somatic embryogenesis was achieved in leafbase and leaf tip explants derived from 10-day-oldin vitro-grown seedlings ofEchinochloa colona. Somatic embryogenesis was induced in the callus on Murashige and Skoog (1962) medium supplemented with 4.44 μM 6-benzyladenine, 4.64 μM kinetin and 8.05 μM 1-naphthaleneacetic acid after 4 weeks of culture incubated for 14 days in continuous dark and subsequently under a 14-h photoperiod. The incidence of somatic embryogenesis was greater in leafbase- than in leaf tip-derived calluses. Histological observations revealed various stages of development of somatic embryogenesis. The embryos matured and germinated on fresh medium lacking growth regulators. The somatic embryo-derived plantlets were established in soil.     

Development and germination of Abies alba somatic embryos

Mature zygotic embryos of Abies alba mull were placed on a modified MCM medium (basal medium-BM) with 2.2 M benzyladenine and 2.3 M kinetin to induce embryogenic suspensor masses (ESM). These ESM proliferated on induction medium supplemented with 0.2 M 2,4-dichlorophenoxyacetic acid. From 61 ESM lines induced, 36 are still in culture after 2 years, of which 18 show embryogenic potential indicated by spontaneous formation of globular somatic embryos on the proliferation medium supplemented with 500–1000 mg l^-1 casein hydrolysate and 500 mg l^-1 l-glutamine. ESMs from cell line 2/56 were conditioned 1 week on BM with 58 mM sucrose and 10 g l^-1 activated charcoal for maturation of somatic embryos. Maturation was achieved on BM containing 20 M (±)cis-trans-abscisic acid in combination with 111 mM maltose. Organic nitrogen supplements improved the proliferation rate of cell line 2/56 as well as the maturation and vitality of the somatic embryos. Partial drying was necessary for subsequent root development. Plantlets with a root, primary needles and a terminal bud developed on BM when a combination of 30 mM sucrose and 50 mM maltose was provided as carbon source.Abbreviations BM basal medium - BA benzyladenine - ESM embryogenic suspensor mass - 2,4-d 2,4-dichlorophenoxyacetic acid - CH casein hydrolysate - l-gln l-glutamine - ABA (±) cis-trans-abscisic acid     

Development and germination of American chestnut somatic embryos

American chestnut (Castanea dentata (Marsh.) Borkh.) plants were regenerated from developing ovules through somatic embryogenesis. On an initiation medium containing 18.18 μM 2,4-dichlorophenoxyacetic acid and 1.11 μM 6-benzyladenine (BA), 25 out of 1,576 ovules were induced to form proembryogenic masses (PEMs). These PEMs were cultivated on a development medium for 4 weeks. Individual somatic embryos were then grown on a maturation medium for at least one month, until shoot meristems and radicles were developed. Both development and maturation media consisted of Gamborg's B-5 basal medium, 0.5 μM BA, and 0.5 μM α-naphthaleneacetic acid, but the former contained 20 g l⁻¹ sucrose and the later contained 60 g l⁻¹ sucrose. A range of 86 to 586 embryos per gram PEMs was observed beyond the cotyledonary stage. These embryos then germinated, resulting in plantlets with a 3.3% conversion rate. An additional 6.3% of the mature embryos produced shoots, which could also result in plantlets by rooting of microcuttings. Proembryogenic masses that were established in continuous culture and maintained on initiation medium for 17 months retained regenerability, though the embryo yield decreased over time. Twenty plantlets were acclimatized and grown in potting mix in a greenhouse. The largest 6 were transplanted, along with seedling controls, into a nursery bed in 1997. As of July, 1999, 4 out of the 6 were surviving. This revised version was published online in June 2006 with corrections to the Cover Date.     

Successful long-term preservation of abscisic-acid-treated and desiccated carrot somatic embryos

We have previously reported that strong desiccation tolerance in carrot somatic embryos can be achieved by treatment with abscisic acid (ABA). In this study, we examined the possibility of long-term preservation of ABA-treated and desiccated somatic embryos. Somatic embryos that had been desiccated after treatment with ABA survived for at least 169 weeks at –25 °C. By contrast, somatic embryos that had not been desiccated after treatment with ABA survived for at least 24 weeks at +5 °C but died at –25 °C. Received: 11 July 1998 / Revision received: 20 October 1998 / Accepted: 20 November 1998     

Tissue-specific localization of mRNA for carrot homeobox genes, CHBs, in carrot somatic embryos

We examined spatial and temporal expression patterns of four carrot HD-Zip I homeobox genes in somatic embryos. The mRNAs for CHB3, CHB4 and CHB5 were accumulated preferentially in the innermost cortical cell layers of the embryo axis in the torpedo-shaped embryo. In contrast, the accumulation of CHB6 mRNA was restricted to procambial cells of the heart- and torpedo-shaped embryos. In the embryonic cotyledons and the hypocotyl of the seedlings, all of the mRNAs for the four genes were located in the vascular tissues. These findings indicate that different HD-Zip I homeobox genes may be involved in the differentiation of specific tissues during somatic embryogenesis.     

Morphology of carrot somatic embryos formed in medium with abscisic acid

Somatic embryogenesis was induced from embryogenie cells derived from cotyledon expiants cultured on MS medium supplemented with 1 mg/L 2,4-D. In order to clarify the effect of abscisic acid (ABA) on the morphology of somatic embryos, embryogénie cell clumps or developing somatic embryos were treated continuously, or briefly, with ABA during culture. When embryogenie cells in MS medium without 2,4-D were treated with 0.04 mg/L ABA for the first week, normal embryos with two cotyledons increased slightly and embryos with anomalous cotyledons decreased. However when cell clumps in 2,4-D-free medium were treated with ABA in the second week normal embryos with two cotyledons decreased prominently and this decrease of normal embryos also occurred in the continuous ABA treatment during culture. Thus the morphological abnormalities in somatic embryogenesis occurred by exogenous ABA treatment beyond globular stage or by continuous treatment. The length of somatic embryos with anomalous cotyledons was larger than that of normal embryos with two cotyledons in control but both the normal and anomalous somatic embryos treated with ABA were almost similar in length. Somatic embryos formed in medium with ABA were larger in size than those in control due mainly to enlarged cotyledons. The enlarged cotyledons were composed of a greater number of cells than those of control. Therefore the enlargement of cotyledon by exogenous ABA seems to be not due to the enlargement of cells in cotyledons.     

Possible involvement of abscisic acid in the induction of secondary somatic embryogenesis on seed-coat-derived carrot somatic embryos

When seed coats (pericarps) were picked from 14-day-old carrot (Daucus carota) seedlings and cultured on agar plates, embryogenic cell clusters were produced very rapidly at a high frequency on the open side edge. Embryo induction progressed without auxin treatment; indeed treatment caused the formation of non-embryogenic callus. The embryogenic tissues (primary embryos) developed normally until the torpedo stage; however, after this a number of secondary somatic embryos were produced in the hypocotyl and root regions. Tertiary embryos were formed on some of the secondary embryos, but many developed into normal plantlets. The primary embryos contained significantly higher levels of abscisic acid (ABA) than the hypocotyl-derived normal and seed-coat-derived secondary embryos. Fluridone inhibited the induction of secondary embryogenesis, while exogenously supplied ABA induced not only tertiary embryogenesis on the seed-coat-derived secondary embryos, but also secondary embryos on the hypocotyl-derived normal somatic embryos. These results indicate that ABA is one of the important endogenous factors for the induction of secondary embryogenesis on carrot somatic embryos. Higher levels of indole-3-acetic acid (IAA) in primary embryos also suggest the presence of some concerted effect of ABA and IAA on the induction of secondary embryogenesis in primary embryos.     

Proline and serine affect polarity and development of carrot somatic embryos

The time sequence of four different stages of development has been identified in carrot somatic embryos with an esterase staining technique as an early cytochemical marker of commitment to stelar differentiation. A progressive determination of development from cotyledonary traces to hypocotyl and root tip, in this order, has been confirmed through specific blocks induced by serine and proline.     

Synchronization of somatic embryogenesis from carrot cells at high frequency as a basis for the mass production of embryos

Synchronization of somatic embryogenesis at high frequency is a useful system for the mass production of embryos. Many attempts have been carried out, however, it was difficult to obtain the system in which most of the initial embryogenic cells or cell clusters synchronously differentiate to embryos. In carrot suspension cultures, high frequency, synchronous embryogenesis systems (following three systems) have been established.(1) Small spherical single cells from suspension cultures obtained by sieving and density gradient centrifugation in Percoll solutions differentiated to embryogenic cell clusters at high frequency when they were cultured in a medium containing 2,4-dichlorophenoxyacetic acid (0.05 micromolar), zeatin (1 micromolar) and mannitol (0.2 molar). (2) Embryogenic cell clusters from suspension cultures obtained by sieving, density gradient centrifugation in Ficoll solutions, and subsequent centrifugation at a low speed for a short time synchronously differentiated to embryos, especially globular embryos at high frequency, when they were cultured in a medium containing zeatin (0.1 micromolar) but no auxin. (3) Embryogenic cell clusters obtained by above method are cultured at cell densities of 2×10³ cell clusters ml^-1. Globular embryos which were sieved from embryos induced synchronously differentiated to torpedo-shaped embryos at high frequency when they were cultured at densities below 150 globular embryos ml^-1.Using these systems, the whole process of embryogenesis from single cells to whole plants could be synchronously induced at high frequency.Abbreviations ABA abscissic acid - 2,4-d 2,4-dichlorophenoxyacetic acid - GA₃ gibberellin A₃ - IAA indoleacetic acid - NAA naphthylacetic acid     

In vitro response of encapsulated somatic embryos of Lagerstroemia indica L

A method to produce encapsulatable units for synthetic seeds was developed in L. indica. Somatic embryos were harvested from leaf derived embryogenic callus on Murashige and Skoog's basal medium supplemented with 2, 4-dichlorophenoxy acetic acid (2, 4-D, 0.5 mg/l), 6-benzyl amino purine (BAP, 1 mg/l) and ascorbic acid (AA, 50 mg/l). The embryos were encapsulated in alginate beads and dehydrated. Germination ability of the artificial seeds were investigated. The frequency of regeneration from the encapsulated embryos was significantly affected by (i) the concentration of alginate (ii) the duration of storage, and (iii) the effect of different types of media. A 2% sodium alginate concentration on MS salts resulted in significantly higher germination frequencies than at other concentrations. L. indica showed maximum germination on MS medium (93.84%) after 6 weeks of culture. The germinated synthetic seeds with well developed roots and shoots were transferred successfully to green house. This is the first report on artificial seeds in Lagerstroemnia indica.     

Plantlet regeneration from encapsulated somatic embryos of hybrid Solanum melongena L

High frequency somatic embryogenesis was induced from leaf expiants of F1 hybrid Solanum melongena L. on Murashige and Skoog's medium supplemented with 8.0 mg/1 NAA and 0.1 mg/1 Kn. The somatic embryos were encapsulated in various concentrations (2–6%) of sodium alginate and complexed with calcium chloride (25–100mM): 3% sodium alginate and 75 mM calcium chloride were found to be optimal for encapsulation. The encapsulated somatic embryos were transferred to various conversion media in vitro and in vivo. The frequency of plantlet regeneration varied from 27.0–49.7% in vitro and 2.0–4.5% in vivo.Abbreviations IAA indole-3-acetic acid - IBA indole-3-butyric acid - Kn Kinetin - MS Murashige and Skoog (1962) - NAA naphthalene acetic acid