Role of polarity in de novo shoot bud initiation from stem disc explants of <Emphasis Type="Italic">Curculigo orchioides</Emphasis> Gaertn. and its encapsulation and storability

The occurrence of strong polarity towards shoot bud induction and the effect of cytokinin(s) on each segment of stem axis, encapsulation and storability of de novo Shoot buds of Curculigo orchioides Gaertn. (Hypoxidaceae) have been documented in the present communication. Maximum number of shoot buds arising de novo from the stem discs (cross section) explanted from proximal end on MS medium fortified with BAP and KIN 1 mg/L each. Stem discs from distal end were less efficient in shoot bud induction. A combination of two cytokinins (BAP and KIN) as a synergistic effect on shoot buds induction from each segment of stem axis. Stem discs in inverted position produced shoot buds from the lower surface, showing strong polarity within the explant. Further, storability and shoot development of sodium alginate encapsulated shoot buds of Curculigo orchioides were tested on half-strength Murashige and Skoog (MS) basal medium fortified with coconut water (10% v/v). The frequency of regeneration from encapsulated shoot buds was affected significantly by concentration of sodium alginate and the duration of exposure to calcium chloride. Shoot buds encapsulated with 2.5% sodium alginate dissolved in MS basal salts solution recorded significantly higher shoot development than other treatments. A relatively short (5 min) incubation with calcium chloride solution provided uniform encapsulation of shoot buds that gave the highest percentage (68%) of shoot development. Encapsulated shoot buds could be stored at 4°C for 50 days without reduction in viability as oppose to non-encapsulated shoot buds, which showed 9.5% viability after 20 days at 4°C. Encapsulated shoot bud developed into normal shoots. Based on the present observations an improved protocol may be developed for the rapid multiplication and conservation of the endangered species—C. orchioides.     

Propagation of Morus indica L. (Mulberry) by encapsulated shoot buds

Axillary buds of mulberry (Morus indica L) were encapsulated in alginate and agar to produce individual beads. The beads could be stored at 4°C for 45 days without loss of viability. Amongst the encapsulating agents tested, sodium alginate was found to be a better matrix. Encapsulated buds regenerated complete plantlets on an appropriate medium. This technique would provide an easy and novel propagation system for the elite as well as difficult-to-root species of mulberry.Abbreviations BAP benzylaminopurine - MS Murashige and Skoog (1962).     

Precocious Growth and Effect of ABA : Encapsulated Buds of Kalanchoe tubiflora

Under artificial seed technology development programme the epiphyllous buds of Kalanchoe tubiflora were used for encapsulation using various concentrations of sodium-alginate. Buds were treated with different concentrations of ABA either prior to encapsulation or even in the alginate matrix to inhibit the precocious growth. The germination behaviour of the encapsulated buds was also studied.     

Encapsulation of micropropagated buds of six woody species

Regrowth after encapsulation in a sodium alginate matrix of micropropagated buds from six different in vitro proliferated woody species was evaluated. Actinidia deliciosa Liang & Ferguson (kiwifruit), Betula pendula Roth (birch), Crataegus oxyacantha L. (hawthorn), Malus spp. (apple), Rubus spp. (blackberry) and Rubus idaeus L. (raspberry) propagated in vitro were used as bud sources. Encapsulation with sodium alginate and subsequent regrowth on nutrient rich medium was compared to encapsulation with nutrient-enriched alginate capsules followed by regrowth on nutrientless medium. Apical and sub-apical buds of Malus (rootstock M. 27 and cultivar Starkspur Red) were also compared for encapsulation and regrowth ability. All species showed a regrowth after encapsulation, but only if cultured on enriched media. M.27 apical and sub-apical buds showed different regrowth ability after encapsulation with sodium alginate. Applicability of encapsulation of single micropropagated tree buds is discussed.     

Production of disease-free encapsulated buds of Zingiber officinale Rosc.

Shoot buds of ginger were successfully encapsulated in 4% sodium alginate gel. Encapsulated buds were germinated in vitro to form roots and shoots. In vitro germination (emergence of sprouts) of encapsulated buds ranged from 16.7% to 81.8% on different media after 5 weeks of incubation. Normal plantlets with an average shoot length of 2.3 cm and 1.7 cm root length were successfully transplanted into unsterilized soil without any hardening process. These plantlets showed no symptoms of ginger yellows disease and the causal fungal pathogen failed to grow out on culture media (used as a diagnostic test).     

DIFFERENTIATION OF MESENCHYMAL LIMB BUD CELLS TO CHONDROCYTES IN ALGINATE BEADS

Manyin vitromodels of embryonic material used for the cultivation of chondrocytes yield mixed cultures consisting of chondrocytes and fibroblast-like cells. For the optimization of cartilage cell cultures, alginate, a semisolid medium, was employed to obtain pure chondrocyte cultures. Isolated mesenchymal cells from 12-day-old mouse limb buds were grown in alginate for up to 4 weeks. A sub-population of the cells differentiated to chondrocytes and exhibited a stable phenotype until the end of the culture period. After 3 to 4 days a cartilage-specific matrix started to develop. Fibroblast-like cells from this mixed culture did not survive; they became necrotic. When alginate was later on dissolved by chelating agents, only chondrocytes were isolated. During dissolution of alginate and centrifugation, chondrocytes did not lose their contact with their new matrix present on their surfaces. Cultivation of these chondrocytes or chondrones in mass culture yields a pure chondrocyte population. Immunoelectron microscopic investigations revealed collagen type II, fibronectin, decorin and chondroitin sulfate-proteoglycans in the chondrocyte capsules and in mass culture.     

马铃薯离体再生及人工种子研究

马铃薯３个品种虎头,克４和Ｆａｖｏｒｉｔａ的茎叶外植体在ＭＳ＋１ｍｇ／ＬＮＡＡ＋１ｍｇ／ＬＢＡ培养基上形成愈伤组织。在ＭＳ＋０２ｍｇ／ＬＮＡＡ＋１ｍｇ／ＬＢＡ培养基上,愈伤组织分化产生不定芽。在ＭＳ＋００５ｍｇ／ＬＮＡＡ培养基上,不定芽生根形成再生完整植株。０２～０３ｃｍ大小的不定芽反复继代可持续增殖。有３个以上叶片的不定芽在ＭＳ＋５ｍｇ／ＬＢＡ＋００５ｍｇ／ＬＩＢＡ培养基上和黑暗条件下,在侧芽或顶芽部位形成微型薯。用４％海藻酸钠和２％氯化钙溶液包裹０２～０３ｃｍ大小的不定芽或直径为０２～０３ｃｍ的微型薯制成微芽人工种子和微薯人工种子。在４℃下贮存２个月后,微芽人工种子和微薯人工种子在有菌腐殖土壤中播种２１ｄ的萌发率分别是１５７％和９６２％。     

In vitro storage of Eucalyptus grandis germplasm under minimal growth conditions

Slow growth-storage, for up to 10 months, has been achieved for Eucalyptus grandis shoot cultures by either the addition of 10 mg l⁻¹ abscisic acid to the growth medium or by the halving of nutrient supply (half MS) and removal of exogenous plant growth regulators. Reduction of light intensity or the addition of mannitol to the media were less effective in reducing growth rate. Isolated in vitro axillary buds encapsulated in calcium alginate and stored under low temperature and low light intensities survived for up to 3 months without loss in viability. Storage of such encapsulated fresh axillary buds at higher temperature resulted in a loss in viability. These methods have immediate applications to forestry breeding and clonal programs. This revised version was published online in June 2006 with corrections to the Cover Date.     

Alginate encapsulation of axillary buds of Ocimum americanum L. (hoary basil), O. Basilicum L. (sweet basil), O. Gratissimum L. (shrubby basil), and O. Sanctum. L. (sacred basil)

Summary Propagation and conservation of four pharmaceutically important herbs, Ocimum americanum L. syn. O. canum Sims. (hoary basil); O basilicum L. (swett basil); O. gratissimum L. (shrubby basil); and O. sanctum L. (sacred basil) was attempted using synthetic seed technology. Synthetic seeds were produced by encapsulating axillary vegetative buds harvested from garden-grown plants of these four Ocimum species in calcium alginate gel. The gel contained Murashige and Skoog (MS) nutrients and 1.1-4.4 μM benzyladenine (BA). Shoots emerged from the encapsulated buds on all six planting media tested. However, the highest frequency shoot emergence and maximum number of shoots per bud were recorded on media containing BA. Of the six planting media tested, both shoot and root emergence from the encapsulated buds in a single step was recorded on growth regulator-free MS medium as well as on vermi-compost moistened with halfstrength MS medium. Rooted shoots were retrieved from the encapsulated buds of O. americanum, O. basilicum, and O. sanctum on these two media, whereas shoots of O. gratissimum failed to root. The encapsulated buds could be stored for 60 d at 4°C. Plants retrieved from the encapsulated buds were hardened off and established in soil.     

Cryopreservation of encapsulated gentian axillary buds following 2 step-preculture with sucrose and desiccation

Alginate beads containing axillary buds of in vitro-grown gentian (Gentiana scabra Bunge var. buergeri Maxim.), were successfully cryopreserved following 2 step-preculture with sucrose and desiccation. The optimal preculture conditions were as follows: axillary buds were excised from in vitro-grown gentian plants and precultured on semi-solid Murashige and Skoog (MS) medium containing 0.1 M sucrose for 10 days (25 °C, 16-h photoperiod) (first step). This was followed by incubation on semi-solid MS media containing 0.4 M (1 day) and then 0.7 M sucrose (1 day) (second step). After preculture, the buds were encapsulated in alginate beads and desiccated aseptically on silica gel for 9 h to a water content of 10% (fresh weight basis), followed by immersion in liquid nitrogen (LN). With this protocol, 87% of the gentian buds survived exposure to LN and showed normal development of shoots and roots in vitro and in vivo. Depletion of NH₄NO₃ in the regeneration medium did not improve survival following desiccation and exposure to LN. The results show that 2 step-preculture with sucrose is effectively applicable in encapsulation–desiccation based cryopreservation of gentian axillary buds. This preculture can replace the conventionally used lengthy cold-hardening treatment and is useful for routine cryopreservation of gentian germplasm.     

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.     

Encapsulation of internode regenerated adventitious shoot buds of Indian Siris in alginate beads for temporary storage and twofold clonal plant production

This study for the first time demonstrates single bead alginate encapsulation and conversion (multiple shootlets rejuvenation) from adventitious shoot buds (AB) of Albizia lebbeck (L.) Benth. Internodal (IN) segments isolated from field grown 1-year-old plant of A. lebbeck were used for AB induction under in vitro conditions. IN segments incubated on MS medium augmented with 10.0 µM BA exhibited highest adventitious shoot bud induction frequencies (76 %) on all over the surface after 10 weeks of culture. Induced AB were detached from in vitro proliferating cultures and used for encapsulation as an explant to produce large number of synseeds (07–08) from a single IN explant. Four to five AB were encapsulated in a single calcium alginate bead to manage mass propagation, interim storage and germplasm sharing. The finer gel matrix for encapsulation was attained using 3.0 % sodium alginate and 100 mM calcium chloride. Highest percentage of shoot emergence and multiplication (75 %) from synseed was obtained on MS + 10.0 µM BA + 1.0 µM NAA (RM) after 10 weeks of culture. Encapsulated adventitious buds stored at 4 °C for 1–8 weeks (2 months) too showed thriving shoot emergence (68 %) and multiplication in encapsulated AB and development into complete plantlets when returned to RM. Hence, 4–5 encapsulated AB stored at 4 °C, when cultured back to RM also showed shoot induction resulting in up to 10 shoots per synseeds after 10 weeks of culture. Healthy root formation (½ MS + 2.0 µM IBA) and acclimatization were optimized by using previously standardized protocol (Perveen et al. in J For Res 22:47–52, 2011). Genetic stability of synseed-derived plantlets acclimatized under ex vitro was assessed and compared with mother plant using inter-simple sequence repeats (ISSR) analysis. The synthetic seeds have the achievability of being a substitute planting material for the forestry sector in future, especially for the multipurpose plant species.     

Morphogenic response of the alginate-encapsulated axillary buds from in vitro shoot cultures of six mulberries

Axillary buds obtained from in vitro shoot cultures of six mulberries (Morus alba L., M. australis Poir., M. bombycis Koidz., M. cathyana Hemsl., M. latifolia Poir., and M. nigra L.) were encapsulated in calcium alginate hydrogel containing Murashige and Skoog (1962) nutrients (MS) and 4.4 μM benzyladenine (BA). Morphogenic response of encapsulated buds to various planting media such as MS medium + 4.4 μM BA, MS basal medium, soilrite mix + half-strength MS medium, garden soil + half-strength MS medium, soilrite mix + tap water and garden soil + tap water was evaluated. Encapsulated buds of M. alba, M. bombycis, M. latifolia and M. nigra exhibited shoot development in each of the six media tested whereas that of M. australis and M. cathyana responded only to the first four media. Analysis of variance revealed that the planting medium exhibited the greatest influence on shoot development. Of the six planting media evaluated, shoot development was highest in MS medium containing 4.4 μM BA and lowest in garden soil moistened with water. Of the six Morus species studied, one-step regeneration, i.e. both shoot and root formation, was recorded in M. alba, M. bombycis and M. latifolia. Rooted shoots were retrieved from encapsulated buds of these species on all planting media tested except the one that contained BA. Root development was significantly affected by the planting medium and the plant species with planting medium contributing the maximum amount (82%) of the total variation observed. Of the five planting media tested, the percentage of root development was highest in MS basal medium. Of the six Morus species studied, the best shoot and root development was observed in M. alba. Encapsulated buds of M. bombycis, M. latifolia and M. nigra stored for 90 days and those of M. alba, M. australis and M. cathyana for 60 days at 4 °C still regenerated shoots. Plants regenerated from the encapsulated buds were hardened off and transferred to soil. This revised version was published online in June 2006 with corrections to the Cover Date.     

Cryopreservation of embryogenic tissue of a range of genotypes of sweet potato (Ipomoea batatas [L] Lam.) using an encapsulation protocol

Embryogenic tissue of nine sweet potato [Ipomoea batatas (L.) Lam] genotypes from Asia, Africa and the Americas was established from in vitro axillary buds on Murashige and Skoog medium supplemented with 2,4-dichlorophenoxyacetic acid or 2,4,5-trichlorophenoxyacetic acid. Embryogenic aggregates, 1.0–2.0 mm in diameter, were encapsulated in alginate gel, precultured on medium containing elevated levels of sucrose and dehydrated prior to rapid freezing in liquid nitrogen. The maximum survival of embryogenic tissue ranged from 4% to 38%, depending on the genotype. With the incorporation of a slow-cooling step, survival was generally much higher than that obtained after rapid freezing alone. Five of eight genotypes tested with this protocol gave survival percentages in excess of 55%, and a further two in excess of 33%, all after evaporative dehydration. The most effective sucrose treatment(s), however, varied with the genotype. Received: 7 October 1996 / Revision received: 16 December 1996 / Accepted 27 January 1997     

Induction and identification of tetraploid <Emphasis Type="Italic">Hedychium coronarium</Emphasis> through thin cell layer culture

We describe an encapsulation–dehydration procedure with prefreezing steps for the cryopreservation of rhizome bud explants of Asparagus officinalis L. cv. Morado de Huétor. With this procedure, survival of Rhizome buds was at least 84 and 42% developed to complete plantlets at 8 weeks. Flow cytometry and EST-SSR molecular markers were used to assess genetic stability of the regenerated material. Effects of preculture time in a medium rich in sucrose and prefreezing treatments (0 °C or/and ??20 °C) on plant recovery were evaluated. Rhizome Buds of the “Morado de Huétor” landrace were incubated in preculture medium (MS?+?0.3 M sucrose) for 48 h, encapsulated in alginate beads and desiccated until a water content of 35%, prefrozen for one hour at 0 °C plus one hour at ? 20 °C, followed by cryopreservation in liquid nitrogen, and then were rewarmed and recovered in ARBM medium for 6 weeks and finally incubated in ARBM-0 for 4 weeks. Analyses of ploidy and molecular stability of plantlets recovered from cryopreserved rhizome buds of two selected genotypes showed no differences compared with the mother plants. Cryopreservation of RB explants of A. officinalis with this Encapsulation–Dehydration procedure will be useful in long-term preservation programs.     

Isolation of water-soluble alginate from brown algae

Summary Water-soluble alginate was obtained from an aqueous extract of Kjellmaniella crassifolia by precipitation with HCl, calcium acetate or 20% ethanol in the presence of 0.05 M MgCl₂ Of these precipitation procedures, MgCl₂-ethanol gave the purest alginate preparation as judged by electrophoresis. The thin-layer and gas-liquid chromatography of its acid hydrolysate, and the IR spectra analysis of the whole alginate, suggested that the water-soluble alginate is similar to ordinary water-insoluble and alkali-soluble alginate such as Kelco alginate.However, the alginate obtained in the present work contained a great excess of mannuronic acid residues, giving an M:G ratio of about 13. Its molecular weight distribution was rather broad as with Kelco alginate, but the molecular weight of its major component was estimated to be 500 000 amu, whereas that Kelco alginate measured on the same column under the same condition was 1 700 000 amu. This suggests that water-soluble alginate was far smaller in average molecular size than Kelco alginate.     

产双功能褐藻胶裂解酶菌株的筛选与初步研究

目的：双功能褐藻胶裂解酶既能降解聚β-D-甘露糖醛酸,又能降解聚α-L-古罗糖醛酸,可以用一种酶来制备不同结构的褐藻胶寡糖。本文的目的是筛选能产生双功能褐藻胶裂解酶的菌株,对其产酶曲线和降解产物作初步研究。方法：利用唯一碳源培养基筛选产生褐藻胶裂解酶的菌株,通过16SrDNA序列比对进行菌种鉴定,通过在凝胶上检测褐藻胶裂解酶活性来判断发酵上清液中褐藻胶裂解酶的数量及分子量,利用薄层层析确定降解褐藻胶的终产物组成。结果：从褐藻上筛选到一株海洋细菌QY107,鉴定为弧菌属细菌。发酵120h时褐藻胶裂解酶产量为12．32U／mL,其发酵液上清中只含有一种褐藻胶裂解酶,分子量在28kDa左右,并且对聚β—D-甘露糖醛酸和聚α-L-古罗糖醛酸都能降解,降解褐藻胶的终产物主要为三糖。结论：本文筛选到一株弧菌QY107,其发酵液上清中只有一种双功能褐藻胶裂解酶,可用于大量制备褐藻胶三糖。推测该酶具有特殊的催化腔结构,对其结构与功能相互关系的研究可能会发现新的底物结合与催化机制。酶解制备褐藻胶寡糖因其环保高效而越来越受到人们的重视,因此该菌株能促进海洋寡糖类生物制品的开发,在医药、食品、农业、生物燃料等领域具有广阔的应用前景。     

Effect of Sodium Alginate Addition on Physical Properties of Rennet Milk Gels

Effect of addition of sodium alginate (alginate) to milk on the storage modulus (G′), water holding capacity (WHC) and hardness of rennet gels was evaluated as a function of alginate (0–0.25 g/100 g) and fat (0.5–3.0 g/100 g) concentrations. There was a significant effect of alginate addition on ionic calcium in milk and whey (Ca²⁺), and particle size distribution in alginate added milk. Results showed a positive correlation of alginate with WHC; negative correlation of alginate and positive correlation of fat with G′; and negative correlation of interaction of fat and alginate with gel hardness of rennet gels. Hence, the rennet gels with lower fat content and higher added alginate tended to be softer due to the high water holding capacity of the alginate particles.     

海藻酸转化生物乙醇研究进展

作为第三代生物燃料,大型褐藻类生物质转化燃料乙醇的研究受到广泛的关注。但是,现有的乙醇工业菌株并不能利用褐藻中的主要成分海藻酸,这个问题是海藻生物乙醇实现工业化生产的主要技术难关。近几年随着对海藻酸裂解酶和海藻酸降解菌代谢途径的深入研究,科研人员构建了不同的海藻酸发酵菌株,为高效转化大型海藻生产生物乙醇提供了可行的技术基础。这篇文章对海藻酸资源概况和海藻酸转化生物乙醇存在的科学问题及其研究进展进行了综述。     

Some properties of alginate gels derived from algal sodium alginate

Alginic acid in soluble sodium alginate turns to insoluble gel after contact with divalent metal ions, such as calcium ions. The sodium alginate character has an effect on the alginate gel properties. In order to prepare a suitable calcium alginate gel for use in seawater, the effects of sodium alginate viscosity and M/G ratio (the ratio of D-mannuronate to L-guluronate) on the gel strength were investigated. The wet tensile strengths of gel fibers derived from high viscosity sodium alginate were higher than those from low viscosity sodium alginate. The tensile strength increased with diminishing sodium alginate M/G ratio. Among the gel fibers tested, the gel fiber obtained from a sodium alginate I-5G (1% aqueous solution viscosity = 520 mPa·s, M/G ratio = 0.6) had the highest wet tensile strength. After 13 days treatment in seawater, the wet tensile strength of the gel fiber retained 36% of the original untreated gel strength. For sodium alginates with similar viscosities, the seawater tolerance of low M/G ratio alginate was greater than that of the high M/G ratio one. This study enables us to determine a suitable calcium alginate gel for use in seawater.