Storability and germination of sodium alginate encapsulated somatic embryos derived from the vegetative shoot apices of mature <Emphasis Type="Italic">Pinus patula</Emphasis> trees

Storability and germination of sodium alginate encapsulated somatic embryos derived from vegetative shoot apices of mature Pinus patula trees were tested on half strength DCR basal medium without growth regulators. The germination percentage of encapsulated somatic embryos was affected significantly by the concentration of sodium alginate and the duration of exposure to calcium chloride. Somatic embryos encapsulated with 2.5 sodium alginate dissolved in DCR basal salts gave significantly higher germination (89) than other treatments. Short (5 min) incubation of the alginate encapsulated embryos in calcium chloride solution proved to be the best encapsulation procedure and the embryos subsequently gave the highest germination (89). Synthetic seeds could be stored at 2 °C for 120 days without a reduction in germination as opposed to non-encapsulated somatic embryos which showed only 9 germination after 20 days at 2 °C. Germinated synthetic seeds produced normal plantlets. This study reports for the first time the storability of encapsulated somatic embryos generated from vegetative shoot apices of mature Pinus patula trees. This has potential for application in forestry.     

Synthetic seed technology for short term conservation of medicinal orchid Dendrobium densiflorum Lindl. Ex Wall and assessment of genetic fidelity of regenerants

Artificial seeds were obtained through encapsulation of protocorm-like bodies (PLBs) of Dendrobium densiflorum in calcium alginate beads. This paper demonstrates the alginate-encapsulation and conversion (complete plantlet regeneration) from PLBs, the effect of storage conditions (at different temperature; 4, 8, 16 °C, RT and duration; 15, 30, 45, 60, 75, 90 days) on viability of encapsulated plant materials as well as the assessment of genetic fidelity of the regenerants. Individual PLBs were encapsulated in calcium alginate beads for mass propagation, short-term storage and germplasm sharing. The superior gel matrix for encapsulation was obtained using 3 % sodium alginate and 100 mM calcium chloride (CaCl₂·2H₂O). The highest percentage of conversion (100 %) of encapsulated PLBs (capsules) was obtained on MS2 medium (MS medium + 2 mg/l BAP). Capsules were successfully stored till 60 days at 8 °C with conversion frequency of 95.5 %. Plantlets regenerated from encapsulated beads were acclimatized successfully with 95 % survival rate. A total of 40 primers were screened, out of which 10 primers successfully generated 39 scorable bands, ranging from 0.2 to 1.3 kb amplicons. The uniform RAPD banding profile among the plantlets derived from encapsulated PLBs following 60 days of storage confirmed genetic fidelity.     

Large Scale Production and Storability of Encapsulated Somatic Embryos of Mothbean (Vigna aconitifolia Jacq)

Storability and germination of sodium alginate encapsulated somatic embryos of Vigna aconitifolia (Jacq.) cv. BMB-43 were tested on half strength Murashige and Skoog (MS) basal medium fortified with coconut water (10% v/v). The frequency of regeneration from encapsulatd embryos was affected significantly by concentration of sodium alginate and the duration of exposure to calcium chloride. Embryos encapsulated with 2.5 % sodium alginate dissolved in MS basal salts solution recorded significantly higher germination than other treatments. A relatively short (5 min) incubation with calcium chloride solution provided uniform encapsulation of embryos that gave the highest percentage (65%) of germination. Synthetic seeds could be stored at 4üC for 50 days without reduction in viability as opposed to non - encapsulated somatic embryos which showed 6% viability after 20 days at 4°C. Germinated synthetic seeds produced normal plantlets.     

Encapsulation of nodal cuttings and shoot tips for storage and exchange of cassava germplasm

We report the encapsulation of in vitro-derived nodal cuttings or shoot tips of cassava in 3% calcium alginate for storage and germplasm exchange purposes. Shoot regrowth was not significantly affected by the concentration of sucrose in the alginate matrix while root formation was. In contrast, increasing the sucrose concentration in the calcium chloride polymerisation medium significantly reduced regrowth from encapsulated nodal cuttings of accession TME 60444. Supplementing the alginate matrix with increased concentrations of 6-benzylaminopurine and alpha-naphthaleneacetic acid enhanced complete plant regrowth within 2 weeks. Furthermore, plant regrowth by encapsulated nodal cuttings and shoot tips was significantly affected by the duration of the storage period as shoot recovery decreased from almost 100% to 73.3% for encapsulated nodal cuttings and 94.4% to 60% for shoot tips after 28 days of storage. The high frequency of plant regrowth from alginate-coated micropropagules coupled with high viability percentage after 28 days of storage is highly encouraging for the exchange of cassava genetic resources. Such encapsulated micropropagules could be used as an alternative to synthetic seeds derived from somatic embryos.     

Plant regeneration from encapsulated nodal segments of Dalbergia sissoo Roxb., a timber-yielding leguminous tree species

One of the alternative methods adopted in recent years is to use biotechnological approaches for improving the tree species. The synthetic seeds offer several advantages, e.g., easy handling, storability, reduced size of propagules, and transportability. Germplasm can be effectively stored in the form of synthetic seeds. A protocol has been developed for plant regeneration from encapsulated nodal segments of Dalbergia sissoo Roxb. Nodal segments collected from basal sprouts of mature trees were encapsulated in calcium alginate beads. Inability of nodal segments entrapped in calcium alginate beads to form root was a major problem. To avoid this problem, an appropriate root induction treatment was given to nodal segments for 10 days, prior to encapsulation to allow formation of root primordia. For synthetic seeds production and subsequent conversion into plantlet, nodal segments with root primordia were encapsulated using sodium alginate and calcium chloride as gelling matrix. The best gel complexation was achieved using 3% sodium alginate and 75 mmol/L CaCl2 2H2O. Maximum percentage response (85%) for conversion of encapsulated nodal segments into plantlets was achieved on 1/2-MS medium without plant growth regulators, after 25 days of culture. The frequency of conversion of encapsulated nodal segments into plantlets affected by the concentration of sodium alginate, and the presence or absence of 1/2-MS nutrients in calcium alginate beads. Plantlets with well developed roots and shoots were transferred to pots containing autoclaved mixture of peat moss and soil (1:1). Plants were also established in pots. The conversion of encapsulated nodal segments into plantlets also occurred when calcium alginate beads having entrapped nodal segments were directly sown in autoclaved peat moss moistened with 1/2-MS0 medium. Out of 60 encapsulated nodal segments, in each experiments, stored at 4 degrees C for 30 days, 44 plants developed under in vitro conditions, and 27 on peat moss moistened with 1/2-MS0.     

A novel encapsulation technique for the production of artificial seeds

A novel technique for the encapsulation of plant material in calcium alginate hollow beads was tested. The technique involves suspending plant material (i.e. plant cells, tissues, organs, shoot tips, somatic embryos) in a solution containing carboxymethylcellulose and calcium chloride and then dripping it into a stirred sodium alginate solution. In initial experiments with Daucus carota (carrot), it was found that after 14 days of cultivation, 100 % of seeds encapsulated in calcium alginate hollow beads would germinate in the liquid core and that 13% would burst the capsules. Embryogenic calli developed inside hollow beads and formed somatic embryos while calli in conventional calcium alginate beads became detached from the beads early in development, and no somatic embryogenesis occurred. With Solanum tuberosum (potato), development of calli was observed in 50% of hollow beads. Eighty-one percent of shoot tips encapsulated in hollow beads sprouted and grew out of the capsules. Received: 28 October 1999 / Revision received: 11 February 2000 / Accepted: 22 February 2000     

Plant regeneration from alginate-encapsulated shoot tips of Phylianthus amarus schum and thonn, a medicinally important plant species

Summary A method was developed for plant regeneration from alginate-encapsulated shoot tips of Phyllanthus amarus. Shoot tips excised from in vitro proliferated shoots were encapsulated in calcium alginate beads. The best gel complexation was achieved using 3% sodium alginate and 75 mM CaCl₂·2H₂O. Maximum percentage response for conversion of encapsulated shoot tips into plantlets was 90% after 5 wk of culture on Murashige and Skoog (MS) medium without plant growth regulator. The regrowth ability of encapsulated shoot tips was affected by the concentration of sodium alginate, storage duration, and the presence or absence of MS nutrients in calcium alginate beads. Plantlets with well-developed shoot and roots were transferred to pots containing an autoclaved mixture of soilrite and peat moss (1∶1). The conversion of encapsulated shoot tips into plantlets also occurred when calcium alginate beads were directly sown in autoclaved soilrite moistened with 1/4-MS salts. Encapsulation of vegetative propagules in calcium alginate beads can be used as an alternative to synthetic seeds derived from somatic embryos.     

Direct somatic embryogenesis and encapsulation of somatic embryos for in vitro conservation of Bacopa monnieri (L.) Wettst

Direct somatic embryogenesis and shoot organogenesis were achieved from leaf explants excised from microshoots of Bacopa monnieri cultured on Murashige and Skoog medium containing N6-benzyladenine (BA) and 2,4-dichlorophenoxyacetic acid (2,4-D). The maximum frequency of explants differentiated somatic embryos and shoot buds on MS medium supplemented with 12.5 µM BA and 1 µM 2,4-D. The frequency of explants differentiating somatic embryos decreased with increasing concentration of 2,4-D. Light and scanning electron microscopy revealed direct differentiation of somatic embryos and shoot buds from explants, and various developmental stages of the somatic embryos were observed. Somatic embryos and apical shoot tips were encapsulated in sodium alginate gel to produce synthetic seeds. The storage of synthetic seeds produced by encapsulation was studied at 4 and 25?°C (room temperature) for a period of 140 days. Encapsulated somatic embryos were found to retain viability after 140 days of storage at both temperatures, whereas encapsulated apical shoot buds failed to germinate even after 40 days when stored at 4?°C. The viability of synthetic seeds was higher when stored at 25?°C. All amplified markers scored by random amplified polymorphic DNA (RAPD) and inter-simple sequence repeats (ISSR) were monomorphic for all the plants produced from synthetic seeds following different periods of storage, thus establishing the clonal fidelity of propagated plantlets.     

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.     

Direct somatic embryogenesis and synthetic seed production from<Emphasis Type="Italic"> Paulownia elongata</Emphasis>

We have developed a reproducible system for efficient direct somatic embryogenesis from leaf and internodal explants of Paulownia elongata. The somatic embryos obtained were subsequently encapsulated as single embryos to produce synthetic seeds. Several plant growth regulators [6-benzylaminopurine, indole-3-acetic acid, -naphthaleneacetic acid, kinetin and thidiazuron (TDZ)] alone or in combination were tested for their capacity to induce somatic embryogenesis. The highest induction frequencies of somatic embryos were obtained on Murashige and Skoog (MS) medium supplemented with 3% sucrose, 0.6% Phytagel, 500 mg l^-1 casein hydrolysate and 10 mg l^-1 TDZ (medium MS10). Somatic embryos were induced from leaf (69.8%) and internode (58.5%) explants on MS10 medium after 7 days. Subsequent withdrawal of TDZ from the induction medium resulted in the maturation and growth of the embryos into plantlets on MS basal media. The maturation frequency of somatic embryos from leaf and internodal explants was 50.8% and 45.8%, respectively. Subculturing of mature embryos led to their germination on the same medium with a germination frequency of 50.1% and 29.8% from leaf and internode explants, respectively. Somatic embryos obtained directly on leaf explants were used for encapsulation in liquid MS medium containing different concentrations of sodium alginate with a 30-min exposure to 50 mM CaCl₂. A 3% sodium alginate concentration provided a uniform encapsulation of the embryos with survival and germination frequencies of 73.7% and 53.3%, respectively. Storage at 4°C for 30 days or 60 days significantly reduced the survival and complete germination frequencies of both encapsulated and non-encapsulated embryos relative to those of non-stored somatic embryos. However, the survival and germination rates of encapsulated embryos increased following storage at 4°C. After 30 days or 60 days of storage, the survival rates of encapsulated embryos were 67.8% and 53.5% and the germination frequencies were 43.2% and 32.4%, respectively. These systems could be useful for the rapid clonal propagation and dissemination of synthetic seed material of Paulownia elongata.Abbreviations BAP 6-Benzylaminopurine - IAA Indole-3-acetic acid - NAA -Naphthaleneacetic acid - TDZ ThidiazuronCommunicated by H. Lörz     

Plant regeneration from alginate encapsulated somatic embryos of Asparagus cooperi baker

Somatic embryos of Asparagus cooperi were encapsulated as single embryos approximately 4–6 mm in diameter to produce individual synthetic seeds. The frequency of conversion of artificial seeds to plants was 34%. This frequency was affected by the concentration of calcium chloride, the commercial sources of sodium alginate, and the nutrient medium. The conversion frequency of artificial seeds to seedling plants was 8.3% after storage for 90 days at 2°C.Abbreviations NAA -Naphthaleneacetic acid - ABA Abscisic acid - GA₃ Gibberellic acid - Kn 6-Furfurylaminopurine - MS Murashige and Skoog (1962) medium - SH Schenk and Hildebrandt (1972) medium - WM White (1963) medium     

Plant regeneration from encapsulated somatic embryos of Carica papaya L.

Carica papaya L. (papaya) single somatic embryos (2.0 mm diameter) produced in a high-frequency liquid production system were encapsulated in two different synthetic encapsulation compounds. The frequency of regeneration from encapsulated embryos was significantly affected by (1) the concentration of sodium alginate, (2) the presence or absence of nutrient salts in the capsule, and (3) the duration of exposure to calcium chloride. A 2.5% sodium alginate concentration in a half-strength MS salts base resulted in significantly higher germination frequencies than other treatments. A relatively short (10 min) exposure to CaCl₂ provided uniform encapsulation of embryos and the highest frequencies of successful germination (77.5%). Germinated artificial seeds produced normal plantlets. Received: 12 March 1997 / Revision recieved: 24 June 1997 / Accepted: 18 July 1997     

Plant regeneration from alginate-encapsulated shoot tips of Spilanthes acmella (L.) Murr., a medicinally important and herbal pesticidal plant species

This article demonstrates the plantlet regeneration from alginate-encapsulated shoot tips of Spilanthes acmella. Shoot tip explants excised from in vitro proliferated shoots were encapsulated in calcium alginate beads. The best gel complexation for encapsulation of shoot tips was achieved using 3% sodium alginate and 100 mM calcium chloride. Maximum percent response for the conversion of encapsulated shoot tips into plantlets was obtained on growth regulator-free full-strength liquid MS (Murashige and Skoog, Physiol Plant 15:473–497, 1962) medium. The addition of MS nutrients in alginate matrix was found to have pronounced effect on shoot and root emergence from alginate beads. Encapsulated shoot tips could be stored at low temperature (4°C) up to 60 days. Plantlets regenerated from encapsulated shoot tips were acclimatized successfully. The present synthetic seed technology could be useful in large-scale propagation as well as short-term conservation and germplasm distribution and exchange of Spilanthes acmella. S. K. Singh and M. K. Rai contributed equally to this work.     

Nutrient alginate encapsulation of nodal segments of Althaea officinalis L., for short-term conservation and germplasm exchange

Abstract

In the present study, an alternate method for germplasm storage in the form of artificial seeds was standardized via nodal explants excised from in vitro proliferated shoots. The explants were encapsulated using sodium alginate and calcium chloride as gelling matrix. For development of root along with shoot, excised nodal segments were pretreated with ½ MS medium along with 20 μM IBA for 24 h and encapsulation was carried thereafter. Combination of 3% sodium alginate augmented with 100 mM CaCl₂.2H₂O was found appropriate for the formation of clear and uniform beads and subsequent conversion of encapsulated nodal segments into plantlets. Maximum (66%) encapsulated nodal segments were converted into plantlets on MS medium supplemented with 7.5 μM BA and 0.5 μM NAA after eight weeks. Regeneration frequency of auxin-pretreated encapsulated and non-encapsulated nodal segments (stored at 4 ºC) was evaluated at different storage time (0 to 6 weeks). After four weeks of storage, encapsulated propagules exhibited highest conversion response on the optimized medium after eight weeks of culture. Plantlets were hardened and established with success in ex vitro conditions. Conversion of synthetic seeds into plantlets was observed when these were directly sown in autoclaved Soilrite^TM (Keltech Energies, Bangalore, India).     

Improving the Stability of Astaxanthin by Microencapsulation in Calcium Alginate Beads

There has been considerable interest in the biological functions of astaxanthin and its potential applications in the nutraceutical, cosmetics, food, and feed industries in recent years. However, the unstable structure of astaxanthin considerably limits its application. Therefore, this study reports the encapsulation of astaxanthin in calcium alginate beads using the extrusion method to improve its stability. This study also evaluates the stability of the encapsulated astaxanthin under different storage conditions. The evaluation of astaxanthin stability under various environmental factors reveals that temperature is the most influential environmental factor in astaxanthin degradation. Stability analysis shows that, regardless of the formulation used, the content of astaxanthin encapsulated in alginate beads remains above 90% of the original amount after 21 days of storage at 25°C. These results suggest that the proposed technique is a promising way to enhance the stability of other sensitive compounds.     

Effects of capsule hardness on germination frequency of encapsulated somatic embryos of carrot

Summary Somatic embryos of carrot were encapsulated in calcium alginate beads to provide artificial carrot seeds. Alginate capsules with a hardness of 0.2 to 0.5 kg/cm² were found to be suitable for germination of encapsulated somatic embryos. The germination frequencies were more than 95%, when grown aseptically on polyester fiber supports loaded with hormone-free Murashige-Skoog medium.     

Short-chain dehydrogenase/reductase,PsDeHase, from opium poppy: putative involvement in papaverine biosynthesis

Embryogenic synseeds were prepared in Albizia lebbeck by encapsulating cotyledon stage somatic embryos derived from in vitro maintained embryogenic cultures in different types of Ca-alginate beads. The germination rate of somatic embryos was affected significantly by the bead type, matrix composition and germination substrate. A matrix made of 3% Na₂-alginate complexed with 100 mM CaCl₂·2H₂O for a hardening period of 20 min provided uniform encapsulation of somatic embryo. Among different types of synseeds, type IIA, wherein somatic embryos encapsulated in a single layer of Ca-alginate matrix composed of MS medium supplemented with 2 g L^?1 activated charcoal and 1.0 µM gibberellic acid (GA₃) as reconstituted endosperm, was found to be the most efficient type having maximum germination rates (88.6?±?0.51%). Incorporation of GA₃ in the alginate beads stimulated greater germination of somatic embryos as against GA₃ supplementation in the germination substrate. Further, viability studies on short term cold (4 °C) storage of different types of embryogenic synseeds revealed that double layered synseeds (DLS) were found comparatively more robust to withstand longer storage durations than single layered synseeds as evident by greater germination rates of the former after 4–8 weeks of refrigerated storage. Also, the elevated levels of antioxidative enzymes (superoxide dismutase, catalase, ascorbate peroxidase and glutathione reductase) and leaf proline content in the plantlets derived from DLS reveals the possible role of alginate coatings in conferring alleviation to low temperature stress generated during different storage durations. Similar Inter simple sequence repeat profiles of embryogenic synseeds derived plantlets and mother tree nullifies the possible occurrence of somaclones, thereby establishing the efficacy of synseed technology for clonal propagation of A. lebbeck germplasm.

     

High frequency somatic embryogenesis and synthetic seed production of the endangered species Swertia chirayita

An efficient protocol for plant regeneration through somatic embryogenesis was established from in vivo leaf explants of Swertia chirayita, a critically endangered medicinal herb. The highest frequency (76%) of embryogenic callus was induced on Murashige & Skoog (MS) medium supplemented with 0.5 mg/L 2,4-dichlorophenoxyacetic acid (2,4-D) and 0.5 mg/L kinetin (Kn) from in vivo leaf explants. Globular somatic embryos were induced and further matured from such embryogenic calli by subsequent culture on the same medium. The highest number of somatic embryos (48.83 ± 4.6) was recovered from embryogenic calli derived from leaf explants after 6 weeks of culture. Synthetic seeds were produced by encapsulating of torpedo stage embryos in sodium alginate (4% W/V) gel, dropped into 100 mM calcium chloride (CaCl₂ · 2H₂O) solution. The synthetic seeds were germinated on MS medium. The highest frequency of synthetic seed germination (84%) was observed on MS medium supplemented with 1.0 mg/L BA and 0.5 mg/L NAA. Regenerants were successfully acclimatized under ex vitro condition. This is the first report on synthetic seed production of S. chirayita. Application of these protocols would be helpful in reducing stress in natural habitat, and in long-term storage of elite genotypes through synthetic seed production.     

Insulin secretion dynamics of free and alginate-encapsulated insulinoma cells

This study investigates the effect of alginate/poly-l-lysine/alginate (APA) encapsulation on the insulin secretion dynamics exhibited by an encapsulated cell system. Experiments were performed with the aid of a home-built perfusion apparatus providing a 1 min temporal resolution. Insulin profiles were measured from: (i) murine insulinoma βTC3 cells encapsulated in calcium alginate/poly-l-lysine/alginate (APA) beads generated with high guluronic (G) or high mannuoric (M) content alginate, and (ii) murine insulinoma βTC-tet cells encapsulated in high M APA beads and propagated in the presence and absence of tetracycline. Results show that encapsulation in APA beads did not affect the insulin secretion profile shortly post-encapsulation. However, remodeling of the beads due to cell proliferation affected the insulin secretion profiles; and inhibiting remodeling by suppressing cell growth preserved the secretion profile. The implications of these findings regarding the in vivo function of encapsulated insulin secreting cells are discussed.     

Cryopreservation of Jiangxi Yanshan Red Bud Taro (Colocasia esculenta var. cormosus cv. Hongyayu) Embryogenic Calli by Encapsulation dehydration

Cryopreservation of Jiangxi Yanshan red bud taro (Colocasia esculenta var. cormosus cv. Hongyayu) embryogenic calli by encapsulation dehydration was studied. The results showed that the optimal preculture condition of cryopreservation by encapsulation dehydration was precultured on MS medium supplemented with 075mol·L-1 sucrose for 3 days. The optimal dehydration method was dehydration by sterile air in a laminar flow hood for 7h or sterile dry silica gel for 11h. the optimal thawing temperature was 37℃ (2min). The optimal culture condition after cryopreservation was first in the dark for 7d and then transferred to the photoperiod of 14h·d-1. The average survival rate of embryogenic calli after cryopreservation by encapsulation dehydration was about 45%. Cryopreservation time and whether the removal of encapsulated calcium alginate had no significant impact on the survival rate. Morphological and cytological study demonstrated that the regenerants were genetically and morphological stable.