Effect of cellulase fractionation on the viability of cultured barley (Hordeum vulgare) protoplasts

The age of the stock plants was important for the barley ( Hordeum vulgare L. cv. Perth) protoplast viability. Light conditions under which the stock plants were grown also affected the viability of the protoplasts. Greenhouse-grown plants yielded much higher number of protoplasts than dark-grown plants, but protoplast viability was better when protoplasts were isolated from etiolated plants. Light supplied during protoplast culture affected protoplast viability within the first 24 h of culture. Cellulase R-10 (Onozuka) was better than Cellulysin (Calbiochem) and Cellulase ⁺ Macerozyme R-10 (Onozuka) for barley mesophyll protoplast isolation. Cellulase R-10 (Onozuka) was fractionated on a G-75 Sephadex column. The eluted fractions were tested for their ability to release barley mesophyll protoplasts and for their toxicity towards the protoplasts. Only a small part of the Cellulase R-10 was necessary for protoplast isolation from barley leaves. When the fractionated cellulase was analysed by isoelectric focusing, this part of the cellolase appeared as a single band.     

Protoplast production fromPorphyra linearis using a simplified agarase procedure capable of commercial application

Abalone enzymes, Cellulase R-10, Macerozyme and agarase fromPseudomonas atlantica were tested for activity on agarose, cellulose, xylan, the cell wall matrix and porphyran isolated fromPorphyra linearis. Agarase, and to a lesser extent Macerozyme, digested both agarose and porphyran. Abalone enzymes and Cellulase R-10 reacted only weakly with porphyran. A simple standardized protocol for making protoplasts fromPorphyra linearis was developed using 0.025% agarase in seawater without added organic osmoticants. Protoplasts prepared with agarase remained viable for at least 24 h in the digestion medium. Regeneration of the protoplasts followed the normal pattern for this species. Agarase can be used to obtain large number of protoplasts which could substitute for conchospores in seeding nets for the aquaculture ofP. linearis Author for correspondenceIssued as NRCC no. 34897     

Optimization of Parameters for Isolation of Protoplasts from the Antarctic Sea Ice Alga Chlamydomonas Sp. ICE-L

The present study was initiated to provide a systematic protocol for producing protoplasts from the Antarctic sea ice alga Chlamydomonas sp. ICE-L suitable for physiological studies. The results showed that the mixtures of 3.0% Cellulase R-10 and 2.0% Macerozyme R-10 were most effective for isolating protoplasts from this alga. Optimum pH and temperature for hydrolytic enzyme reaction were pH 6.0 and 15^∘C, respectively. Mannitol and sorbitol were found to be the excellent osmotic stabilizers. Growth conditions of the algae prior to enzyme treatment also influenced the yield of protoplasts greatly. At the optimized condition, protoplast production was 47.8%, and the viability of isolated protoplasts was more than 97.6% as confirmed by Evan's blue staining.     

Efficient isolation, culture and regeneration of Lotus corniculatus protoplasts

This paper reports an improved protocol for isolation, culture and regeneration of Lotus corniculatus protoplasts. A range of parameters which influence the isolation of L. corniculatus protoplasts were investigated, i.e., enzyme combination, tissue type, incubation period and osmolarity level. Of three enzyme combinations tested, the highest yield of viable protoplasts was achieved with the combination of 2% Cellulase Onozuka RS, 1% Macerozyme R-10, 0.5% Driselase and 0.2% Pectolyase. The use of etiolated cotyledon tissue as a source for protoplast isolation proved vital in obtaining substantially higher protoplast yields than previously reported. Culture of the protoplasts on a nitrocellulose membrane with a Lolium perenne feeder-layer on the sequential series of PEL medium was highly successful in the formation of micro-colonies with plating efficiencies 3–10 times greater than previous studies. Shoot regeneration and intact plants were achieved from 46% of protoplast-derived cell colonies.     

Plant regeneration from protoplasts isolated from embryogenic calli of the forage legume<Emphasis Type="Italic"> Astragalus melilotoides</Emphasis> Pall.

An efficient and reproducible protocol is described for the regeneration of Astragalus melilotoides protoplasts isolated from hypocotyl-derived embryogenic calli. Maximum protoplast yield (11.74±0.6×10⁵/g FW) and viability (87.07±2.8%) were achieved using a mixture of 2% (w/v) Cellulase Onozuka R10, 0.5% (w/v) Cellulase Onozuka RS, 0.5% (w/v) Macerozyme R10, 0.5% (w/v) Hemicellulase, and 1% (w/v) Pectinase, all dissolved in a cell protoplast wash (CPW) salt solution with 13% (w/v) sorbitol. First divisions occurred 3–7 days following culture initiation. The highest division frequency (9.86±0.68%) and plating efficiency (1.68±0.05%) were obtained in solid-liquid medium (KM8P) supplemented with 1.0 mg/l 2,4-dichlorophenoxyacetic acid, 0.5 mg/l 6-benzylaminopurine (BA), 0.2 mg/l kinetin, 0.2 M glucose, 0.3 M mannitol and 500 mg/l casein hydrolysate. Upon transfer to MS medium with 0.5 mg/l -naphthaleneacetic acid and 1-2 mg/l BA, the protoplast-derived calli produced plantlets via somatic embryogenesis (56.3±4.1%) and organogenesis (21.6±0.6%). Somatic embryos or adventitious shoots developed into well-rooted plantlets on MS medium without any plant growth regulators or supplemented with 3.0 mg/l indole-3-butyric acid, respectively. About 81% of the regenerants survived in soil, and all were normal with respect to morphology and growth characters.Abbreviations BA: 6-Benzylaminopurine - CH: Casein hydrolysate - CPW: Cell protoplast wash - 2,4-D: 2,4-Dichlorophenoxyacetic acid - FDA: Fluorescein diacetate - IBA: Indole-3-butyric acid - KIN: Kinetin - MES: 2-(N-morpholino) Ethanesulphonic acid - NAA: -Naphthaleneacetic acidCommunicated by A. Altman     

玉米、小麦、水稻原生质体制备条件优化

玉米Zea mays L.、小麦Triticum aestivum L.、水稻Oryza sativaL.是三大重要粮食作物,对其原生质体制备条件的优化具有重要意义.以玉米(综3)、小麦(中国春)、水稻(日本晴)10日龄幼苗为材料,研究了叶肉细胞原生质体分离过程中的酶浓度、酶解时间和离心力大小等因素对产量和活力的影响.结果表明:酶浓度和酶解时间对原生质体产量影响显著,随着酶解液浓度和酶解时间的提高,原生质体产量增加,但细胞碎片同时增多.水稻经真空处理后,原生质体产量大幅度提高.通过正交实验设计得出如下结果:玉米叶肉细胞原生质体分离的最佳条件为:纤维素酶1.5％,离析酶0.5％,50 r/min酶解7h,100×g离心2 min收集,原生质体产量为7×106/g FW;小麦叶肉细胞原生质体分离的最佳条件为:纤维素酶1.5％,离析酶0.5％,50 r/min酶解5h,100×g离心2 min收集,原生质体产量为6×106/g FW;水稻叶肉细胞原生质体分离的最佳条件为:纤维素酶2.0％,离析酶0.7％,50 r/min酶解7h,1 000×g离心2 min收集,得到的原生质体产量为6×106/g FW.通过二乙酸荧光素染色发现原生质体活力均在90％以上.用PEG-Ca2+介导法将含有绿色荧光蛋白的质粒转化入原生质体,转化率可达50％ ～80％.     

A simple method for mass isolation of protoplasts from species of Monostroma, Enteromorpha and Ulva (Chlorophyta, Ulvales)

A simple enzyme mixture containing 2% Cellulase Onozuka R–10 and1% Macerozyme R–10 prepared in deionised water supplemented with 3% NaCland 1 mM CaCl₂ was developed for isolating rapidlyprotoplasts from different species of Monostroma,Enteromorpha and Ulva. The yield fordifferent species of Monostroma ranged from 9.6 ×10⁶ to 10.2 × 10⁶ cells g^–1f. wt thallus, and forEnteromorpha from 3.48 × 10⁶ to 11.7× 10⁶ cells g^–1 f. wt and forUlva from 4.58 × 10⁶ to 26.8 ×10⁶ cells g^–1 f. wt. The overallregeneration rate of the protoplasts isolated was usually > 90% and showednormal morphogenesis. The method yields rapid mass production of viableprotoplasts with high regeneration rates.     

In vitro culture of Cucumis sativus L. XVIII. Plants from protoplasts through direct somatic embryogenesis

A procedure is described for the isolation and culture of protoplasts from embryogenic callus (gel-like callus — GLC) and embryogenic suspension cultures (ESC) of Cucumis sativus c.v. Borszczagowski. Maximal protoplast yields from GLC and ESC were 5×10⁶ and 1×10⁷ protoplasts/g tissue respectively. They were obtained following 14–16 h digestion with 1.2% Cellulase Onozuka R-10, 1.2% Macerozyme R-10 and 0.3% Driselase. At a plating density of 2×10⁵ / ml, first divisions occurred in 4–5 days and 7–8 days in ESC-and GLC-derived protoplasts respectively. The highest percentage of direct embryogenesis (over 80%) was observed with ESC. It was possible to obtain approximately 5000 embryo structures / g tissue. Some embryos converted into plants after 6 weeks, but most of them after 2 months of culture. ESC-derived plants, when transferred into the glasshouse, bloomed normally, and set seeds.Abbreviations CMS Murashige & Skoog (1962) medium for cucumber - GLC gel-like callus - ESC established embryogenic suspension culture - 2,4-d 2,4-dichlorophenoxyacetic acid     

Influence of pH and sucrose concentration on nonenzymatic and enzymatic isolation of protoplasts from mature pollen of Tulbaghia violacea

Studies on protoplast isolation were carried out with mature pollen grains of Tulbaghia violacea Harv. (Liliaceae). Pollen grains drifted from surface sterilized crushed anthers were incubated either in a nonenzymatic solution composed of Nitsch medium and sucrose, or in the same solution supplemented with 1% cellulase Onozuka R-10 and 1% Macerozyme R-10. The process of protoplast release was studied as a function of pH and sucrose concentration of nonenzymatic and enzymatic solutions. For nonenzymatic isolation, the tested range of pH and sucrose concentration was from 3.3 to 13.1 and from 0.015 to 1.12 M (final solution osmolality from 200 to 1,300 mOs kg^-1 H₂O), respectively. In the former case, the release of protoplasts occurred only at nonphysiological pH (12.2 to 13.1) and could be observed after several seconds to 120 min, depending on pH and sucrose concentration of medium. Under enzymatic incubation, viable protoplasts were released more rapidly (3 to 35 min) and in more physiological conditions, the optimum being pH 5.8 and final medium osmolality 652 mOs kg^-1 H₂O. Speed, manner of protoplast release, number and quality of protoplasts were dependent on interactions of pH and sucrose concentration.     

An Efficient Protocol for Ulmus minor Mill. Protoplast Isolation and Culture in Agarose Droplets

We describe here an efficient and reproducible protocol for isolation and culture of protoplasts from Ulmus minor. Different sources of donor tissues were tested for protoplast isolation: callus and juvenile leaves from in vitro and greenhouse plants. Several combinations and concentrations of hydrolytic enzymes were used. Comparative tests between Cellulase Onozuka R10 and Cellulase Onozuka RS were made and the last one proved to be more efficient. Both the pectinases used, Macerozyme Onozuka R10 and Pectinase (Sigma^®), were efficient in protoplast isolation and there was no need for a more active pectinase. In vitro leaves proved to be the best source for protoplast isolation and produced an average of 3.96 × 10⁷ protoplasts per gram of fresh weigh. Elm mesophyll protoplasts were cultured using the advantageous method of agarose droplets and a modification of the Kao and Michayluk culture medium, using two plating densities (1 × 10⁵ and 2 × 10⁵ protoplasts ml^?1). Protoplast division and evolution into colonies and microcalli was promoted in the agarose droplets plated at 2 × 10⁵ protoplasts ml^?1. Ten weeks after protoplast culture initiation a plating efficiency of 2.7% was attained and the bigger microcalli, with at least 0.5 mm diameter, were transferred to a solid medium previously used for the production of embryogenic callus.     

Protoplast isolation and regeneration from <Emphasis Type="Italic">Gracilaria changii</Emphasis> (Gracilariales,Rhodophyta)

The tropical agarophyte Gracilaria changii has been much researched and documented by the Algae Research Laboratory, University of Malaya, especially with regards to its potential as a seaweed bioreactor for valuable compounds. Protoplast regeneration of this seaweed was developed following the optimization of protoplast isolation protocol. Effect of the concentration and combination of isolating enzymes, incubation period, temperature, enzyme solution pH, tissue source on the protoplast yields were used to optimize the isolation protocol. The enzyme mixture with 4% w/v cellulase Onozuka R-10, 2% w/v macerozyme R-10 and 1 unit mL^-1 agarase was found to produce the highest yield of protoplast at 28°C and 3 h incubation period. Thallus tips gave higher yields of protoplasts than middle segments. Freshly isolated G. changii protoplasts were cultured in MES medium. Regeneration of protoplast cell walls after 24 h was confirmed by calcofluor white M2R staining under UV fluorescence microscopy. The protoplasts with regenerated cell walls then underwent a series of cell division to produce callus-like cell masses in MES medium. Following this, juvenile plants of G. changii were obtained.     

Callus culture as substrate for the production of specific cell wall degrading enzymes for derived protoplast isolation

Callus culture of spruce (Picea excelsa LINK) appears to be a suitable substrate for the fungusTrichoderma reesei to produce an efficient extracellular lytic system for protoplast isolation. In comparison with Onozuka R-10 cellulase, a yield of protoplasts from the spruce callus 2·5 higher was obtained. Another testea commercial cellulase DK was less efficient. The addition of Macerozyme R–10 significantly enhanced release of protoplasts within all tested enzyme preparations. No difference in the viability of protoplasts has been observed.     

三倍体‘银中杨’叶肉原生质体制备的优化

以三倍体杨树品种‘银中杨’（Populus alba×P.berolinensis Yinzhong）无菌苗叶片为材料,对其原生质体分离及纯化条件进行研究,为进一步通过细胞融合、基因工程等进行品种改良探索新的途径。结果表明：酶的种类及浓度、渗透压、酶解时间对‘银中杨’叶肉原生质体分离效果有显著影响,适宜的分离条件为CPW+3% Cellulase RS+0.5% Macerozyme R-10+0.3% Pectinse Y-23+0.6 mol/L甘露醇+0.6 g/L MES+1 g/L BAS,酶解时间为8 h,原生质体产量和活力分别为2.13×10⁷个/g和80.18%;‘银中杨’叶肉原生质体纯化最佳方法为上浮法蔗糖等密度离心,且蔗糖浓度为40%时原生质体产量最高（1.06×10⁷个/g）,可满足进一步的原生质体培养等技术的要求。     

Isolation of protoplasts from Fucus serratus and F. vesiculosus(Fucales, Phaeophyceae): factors affecting protoplast yield

Protoplasts were isolated enzymatically from meristematic tissues of the brown algae, Fucus serratus, using a combination of 2% cellulase R-10 Onozuka, 0.5% macerozyme and 1% crude extract of gland gut of Aplysia vaccaria. The main factors affecting protoplast yield were identified. Protoplasts were produced in large quantities from apical region of thallus and from plantlets compared to mature explants. Yields were greatly improved by the addition of sodium citrate and bovine serum albumin in the enzymatic solution and could reach 5.8 × 10⁶ protoplasts per gram of fresh wt. The applicability of these optimal parameters to other species Fucus vesiculosus was shown.     

Optimization of protoplast yields from the red algae <Emphasis Type="Italic">Gracilaria dura</Emphasis> (C. Agardh) J. Agardh and G. <Emphasis Type="Italic">verrucosa</Emphasis> (Huds.) Papenfuss

This study reports on the optimization of protoplast yield from two important tropical agarophytes Gracilaria dura and Gracilaria verrucosa using different cell-wall-degrading enzymes obtained from commercial sources. The conditions for achieving the highest protoplast yield was investigated by optimizing key parameters such as enzyme combinations and their concentrations, duration of enzyme treatment, enzyme pH, mannitol concentration, and temperature. The significance of each key parameter was also further validated using the statistical central composite design. The enzyme composition with 4% cellulase Onozuka R-10, 2% macerozyme R-10, 0.5% pectolyase, and 100 U agarase, 0.4 M mannitol in seawater (30‰) adjusted to pH 7.5 produced the highest protoplast yields of 3.7 ± 0.7 × 10⁶ cells g⁻¹ fresh wt for G. dura and 1.2 ± 0.78 × 10⁶ cells g⁻¹ fresh wt for G. verrucosa when incubated at 25°C for 4–6 h duration. The young growing tips maximally released the protoplasts having a size of 7–15 μm in G. dura and 15–25 μm in G. verrucosa, mostly from epidermal and upper cortical regions. A few large-size protoplasts of 25–35 μm, presumably from cortical region, were also observed in G. verrucosa.     

Isolation of Allium pollen protoplasts

Studies on protoplasts isolation were carried out with mature pollen grains of 29 samples of species of Allium aflatunense, A. cepa, A. fistulosum, A. karataviense, A. longicuspis, A. nutans, A. odorum, A. sativum and A. schoenoprasum. Surface sterilized pollen grains drifted from crushed anthers were incubated in an enzyme solution containing 1% (w/v) cellulase Onozuka R-10, 1% (w/v) Macerozyme R-10, 0,5 mol l^-1 sucrose and the basal salts of Nitsch medium. Protoplasts were released within 3 to 120 min, either from the pollen grain, through a slightly disturbed germination pore (narrow aperture), or through a wider aperture, when the exine surrounding the germination pore was disturbed. For the first time, protoplasts were obtained from 13 genotypes of 6 Allium species, at a rate of 1 to 30% of the digested intact pollen grains, depending on the genotype.     

Production and regeneration of protoplasts from <Emphasis Type="Italic">Grateloupia turuturu</Emphasis> Yamada (Rhodophyta)

Protoplasts were isolated enzymatically from the carrageenophyte red alga Grateloupia turuturu (Halymeniales, Rhodophyta) that occurs along the coast of the French Channel in Normandy. Effects of the main factors on the protoplast yield were identified to improve the isolation protocol. The optimal enzyme composition for cell wall digestion and protoplast viability consisted of 2% cellulase Onozuka R-10, 0.5% macerozyme R-10, 2% crude extract from viscera of Haliotis tuberculata, 0.8 M mannitol, 20 mM sodium citrate, 0.3% bovine serum albumin at 25°C, and 4-h incubation period. The protoplasts were approximately 5–15 μm in diameter, liberated mainly from the surface cell layers. Maximum yield was 1.5 × 10⁷ protoplasts g^-1 fresh tissue. The protoplasts underwent initial division after 14 days with a high density level of 1 × 10⁶ cells mL^-1 in culture medium and developed into microthalli of a line of two to six cells.     

Isolation of protoplasts from edible seaweeds

Protoplasts were isolated enzymatically from three species of Chlorophyta (Enteromorpha linza, Monostroma zostericola andUlva pertusa) with high yield and viability. An enzyme solution appropriate for protoplast isolation from the marine green algae was the following: 2% Cellulase Onozuka R-10, 1.0.M mannitol, pH 6.0. Protoplasts could not be obtained from members of Phaeophyta or Rhodophyta.     

Production of bioflavor by regeneration from protoplasts of Ulva pertusa (Ulvales,Chlorophyta)

Protoplasts were isolated from thalli of Ulva pertusa using a mixed enzyme solution of 2.0% Cellulase Onozuka R-10, 2.0% Macerozyme R-10, and 2.0% Driselase. Isolated protoplasts regenerated cell walls, developed into thalli, and propagated in large numbers under aeration in the preparative scale-culture system. Typical bioflavor compounds produced from the regenerated plants, as well as from field-collected plants, were found to be long chain aldehydes, which gave a typical seaweed odor. The long chain aldehydes were formed enzymatically from unsaturated fatty acids and released into the culture fluid. A Percoll/mannitol discontinuous density gradient separation of the heterogeneous protoplasts led to a selection of cell lines with high production of bioflavor. The cells that regenerated from protoplasts were immobilized by polymer matrices such as alginate, -carrageenan, agarose, and agar. Living cells entrapped in alginate beads in aerated cultures survived best. However, the beads started to breakdown after two months. The immobilized cells demonstrated a higher bioflavor production than did the cultured cells.     

PROTOPLAST ISOLATION AND CELL DIVISION IN THE AGAR-PRODUCING SEAWEED GRACILARIA (RHODOPHYTA)1

Methods were developed for the isolation of large numbers of healthy protoplasts from two species of the agarophyte Gracilaria; G. tikvahiae McLachlan and G. lemaneiformis (Bory) Weber-van Bosse. This is the first report of protoplast isolation and cell division in a commercially important, phycocolloid-producing red seaweed, as well as for a member of the Florideophycidae. The optimal enzyme composition for cell wall digestion and protoplast viability consisted of 3% Onozuka R-10, 3% Macerozyme R-10, 1% agarase and 0.5% Pectolyase Y- 23 dissolved in a 60% seawater osmoticum containing 1.0 M mannitol. The complete removal of the cell wall was confirmed by several different methods, including electron microscopic examination, and the absence of Calcofluor White (for cellulose) and TBO (for sulfated polysaccharide) staining. Spontaneous protoplast fusion was observed on several occasions. Protoplast viability was dependent upon the strain and age of the parent material, as well as the mannitol concentration of the enzyme osmoticum. Cell wall regeneration generally occurred in 2-6 days; cell division in 5-10 days. Protoplast-produced cell masses up to the 16-32 cell stage have been grown in culture. However, efforts to regenerate whole plants have been unsuccessful to date.