草木樨状黄芪叶肉原生质体的植株再生

分别从草木樨状黄芪胚轴再生苗的上部和下部叶片分离原生质体。来自上部叶片的原生质体培养在P_2培养基(含2,4-D 1.0mg/L)中获得了较高的分裂频率(48.9%)和愈伤组织再生频率(321块/m1),过高和过低的2,4-D对于愈伤组织的再生都是不利的。来自下部叶片的原生质体分裂频率很低,不能形成愈伤组织。小愈伤组织转入固体或液体增殖培养基中均能快速生长。愈伤组织转入分化培养基或继续在液体培养基中振荡培养均能分化出芽,频率达100%。目前已获得了大量的再生植株,部分已移栽成活。     

洋葱叶肉原生质体培养再生小植株

用纤维素酶(EA 3-867)和离析酶(Macerozyme R-10)酶解洋葱叶肉细胞,游离获得大量具有活力的原生质体。在MS培养基上(附加2,4-D 2,6-BA 0.5 mg/l,原生质体能再生细胞壁,生长,分裂,形成类似球形的愈伤组织;将它们分别移入分化培养基MS_1,MS_2,MS_3,得到再生的小植株。     

埃斯基红豆草下胚轴愈伤组织原生质体的培养与植株再生

埃斯基红豆幼苗的下胚轴切段在附加２,４－Ｄ０．５ｍｇ／Ｌ,ＫＴ１ｍｇ／Ｌ的ＭＳ中形成胚性愈伤组织。来自１１－１３个月龄、继代６－１５天的愈伤组织的原生质体,在改良的Ｖ－ＫＭ液体培养基中可持续分裂形成细胞团,培养１０天时的分裂率和克隆率分别为６５．８８％和５３．３８％周后就可将将原生质体形成的小愈伤组织转于培养基上。原生质体在改良的Ｂ５液体培养基也可以分裂形成小愈伤组织,但分裂率低于Ｖ－ＫＭ。来自原     

硬粒小麦单倍体原生质体培养及植株再生

由硬粒小麦（Ｔｒｉｔｉｃｕｍ ｄｕｒｕｍ Ｄｅｓｆ．）×玉米（Ｚｅａ ｍａｙｓＬ．）建立的单倍性胚性愈伤组织,在继代培养４ 个月后置于含２．０ ｍ ｇ／Ｌ２,４－Ｄ、３％ 蔗糖、２００ ｍ ｇ／Ｌ水解酪蛋白、１４６ ｍ ｇ／Ｌ谷氨酰胺和３００ ｍ ｇ／Ｌ天冬氨酸的ＭＳ液体培养基中进行悬浮培养,４ 个月后形成了生长迅速、由大小不同（０．５ ～５ ｍ ｍ ）的愈伤组织块组成的愈伤组织悬浮系。酶解试验表明,２．０％ 纤维素酶ＲＳ和０．５％ 的离析酶效果最好,而液体悬浮培养物和固体培养的愈伤组织（在酶解时用锋利的解剖刀片切成１ ｍ ｍ 左右的小块）都能释放出大量原生质体,但悬浮培养物释放出的原生质体状态较好,胞质更浓厚,用ＫＭ８ｐ 培养基以琼脂糖包埋培养方式培养时分裂频率可达５％ 左右。由原生质体再生的小愈伤组织经增殖、筛选后可获得胚性愈伤组织,将其转移至分化培养基Ⅰ（０．２ ｍ ｇ／Ｌ ２,４－Ｄ、１．０ ｍ ｇ／Ｌ ＢＡＰ、０．１ ｍ ｇ／ＬＮＡＡ、３％ 蔗糖、２００ ｍ ｇ／Ｌ 水解酪蛋白、１４６ ｍ ｇ／Ｌ谷氨酰胺和３００ ｍ ｇ／Ｌ天冬氨酸的ＭＳ固体培养基）和Ⅱ（不含２,４－Ｄ,其它成分同Ⅰ）上进行分步分化培养可再生出完整植株,分化频率约为２０％     

细叶黄芪叶肉原生质体植株再生

从细叶黄芪(Astragalus tenuis)外植体愈伤组织分化出的再生苗叶片分离原生质体。原生质体培养在改良 K8p 培养基中形成了愈伤组织。增殖后的愈伤组织转入分化培养基中分化出苗。幼苗在生根培养基中长出不定根,再生成为完整植株。再生苗叶肉原生质体在 AY培养基中,种子无菌苗叶肉原生质体在改良 K8p 或 AY 培养基中均不能形成愈伤组织。较低的2,4-D 浓度有利于原生质体愈伤组织的形成和分化,过高的2,4-D 浓度对愈伤组织的形成和分化有不利的影响。     

杨树新品种叶肉原生质体培养和植株再生

从１ 个月龄的ＮＬ－８０１０６ 杨（Ｐｏｐｕｌｕｓｄｅｌｔｏｉｄｅｓ×Ｐ． ｓｉｍ ｏｎｉｉ）无菌苗叶片分离得到大量原生质体,纯化后其原生质体产量为４×１０７／ｇ ｆｒ．ｗ ｔ． 纯化的原生质体在含２,４－Ｄ ２ ｍ ｇ／Ｌ、ＮＡＡ ０．５ ｍ ｇ／Ｌ和ＫＴ ０．５ ｍ ｇ／Ｌ的ＫＭ８ｐ 和ＭＳ培养基中进行高密度液体浅层培养,渗透势为０．４０ ｍ ｏｌ／Ｌ的ＫＭ８ｐ 培养基中原生质体分裂频率最高． 培养第５ 天观察到第一次细胞分裂,培养１０ ｄ 的分裂频率为４．５％ ,１２ 周内可形成大量的细胞团和小愈伤组织． ＮＬ－８０１０６杨叶肉原生质体在富含有机氮并以葡萄糖为碳源的培养基中具有较高的分裂频率和植板率．小愈伤组织在ｇｅｌｒｉｔｅ 固化的ＮＬＺ１ 培养基上增殖生长,３ 周后形成４—６ ｍ ｍ 结构紧密的鲜红色愈伤组织,转至ＮＬＦ分化培养基,分化成苗率为１００％ ． 待芽伸长到３ ｃｍ 时,从基部切下转至１／２ ＭＳ培养基上诱导生根,形成完整植株     

马铃薯无菌苗叶肉原生质体再生植株

商用马铃薯叶肉原生质体,在不同的液体培养基中浅层培养,耳生细胞分裂,并获得愈伤组织。将愈伤组织转到固体培养基上诱导分化,已从克新四号和68—62两个马铃薯品种的原生质体得到再生的完整植株。再生细胞的分裂频率受原生质体培养密度的影响。细胞团的生氏对液体培养基中的蔗糖浓度敏感。不同的原生质体培养基对愈伤组织的分化频率的影响非常显著。在分比培养基中加入3％的甘露醇,能提高愈伤组织的分化频率,并缩短分化期。     

甘蓝下胚轴原生质体高效成株系统的建立

本文采用萌发六天的甘蓝(Brassica oleracea)下胚轴材料游离原生质体,经纯化后的原生质体产量为1.45×10~6g~(-1)FW,于含有1.5mg/L BA,0.5mg/L NAA和0.5mg/L 2,4-D的KM 8p的培养基中进行液体浅层培养。原生质体培养3—4天后出现一次分裂,七天时统计分裂频率为50.3%,培养15天左右可形成细胞团,3—4周后即可形成肉眼可见的小愈伤组织,统计形成愈伤组织的植板率为1.25%。将愈伤组织转至含有1.5mg/L BA和0.2mg/L 2,4-D的MS固体扩增培养基上进行扩增,其后可在含有2mg/L BA和0.5mg/L ZT的MS分化培养基上分化出芽,其分化率为54.17%,分化芽可于生根培养基中生根形成完整植株,移栽后,在人工气候室中生长良好。在试验过程中,对取材的不同时间,酶解液的不同配比对原生质体产量的影响,以及不同培养基、不同培养密度、不同的激素配比和不同培养方法等方面对原生质体的再生和持续分裂的影响进行了讨论。     

骆驼刺发根农杆菌转化系的原生质体培养和植株再生

从发根农杆菌A4转化的荒漠植物—璐驼刺毛状根愈伤组织中分离的原生质体培养的结果表明,酶解新转代7～10d的淡黄色松软愈伤组织,可获得大量有活力的原生质体。原生质体在附加有1．5mg．L-1 2,4．D、0．2mg．L-1 6．BA、0．3m01．L-1甘露醇、2％（W/V）蔗糖和500mg·L-1水解酪蛋白的DPD培养基中进行液体浅层培养可持续分裂。培养基的最适渗透压为（450±3）mOsm·kg-1,原生质体的最适植板密度为4×10^5个．mL-1。制备原生质体的愈伤组织以低温（4℃）预处理后,原生质体的产率和分裂频率均提高,分裂频率最高可达50％。原生质体分裂形成的愈伤组织转移在附加1-2mg．L-1 6-BA（或KT）和0．2mg·L-1NAA的MS培养基上培养后,可以分化并获得再生植株。纸电泳检测表明,原生质体再生的愈伤组织和分化植株仍然含有毛状根转化系的特异产物——冠瘿碱。     

基因组对芸苔属作物原生质体培养及植株再生的影响

本文以包心菜、芜菁油菜、浙油６０１的无菌苗叶肉原生质体为材料,经不同液体培养基浅层培养,细胞分裂并形成愈伤组织。愈伤组织经增殖后,转到分化培养基上诱导分化,均获得了再生植株。本文着重研究了植物基因组对原生质体分裂频率及植株再生的影响。研究结果表明：（１）植物基因组对原生质体分裂频率的影响随原生质体培养基的不同而异;（２）植物基因组对原生质体再生植株影响显著,芜菁油菜的Ａ基因组不利于原生质体再生植株     

Plant Regeneration from Protoplasts of Talinum paniculatum

The protoplasts of Talinum paniculaturn (Jaeq.) Gaertn. were isolated from leaves and calli. The mesophyll protoplasts did not undergo normal division and lived one week at the longest in culture. However, the callus protoplasts, cultured in P4 medium (K8p+2, 4-D 0.2 mg/L, NAA 1.0 mg/L, ZT 0.5 mg/L, coconut milk 50 mL/L, glucose 0.5 mol/L), underwent first division after 3 d of culture. The division frequency was 36.7 % after 7 d of culture. The regeneration frequencies of callus were 0.31% in liquid culture and 0.34% in double-layer culture. Shoots differentiated on regeneration media and rooted on R3 and R7 media. Mature plants were obtained 2～3 months after transplanting the protoplast-derived plantlets into flower pot or successive subculturing in test tubes. The results also indicated that: (1) Too long a period of callus culture in liquid medium or in solid proliferation medium was unfavorable to differentiation. (2) Low concentration of 6-BA in medium was suitable for callus differentiation. (3) GA3 promoted development of young adventitious bud. (4) Multi-effect triazole significantly strengthened sprout and root development in test tube cultures.     

Isolation,culture and division of olive (Olea europaea L.) protoplasts

Protoplasts from Olea europaea L. have been compared in terms of their yield, viability, cell division and callus differentiation. Viable protoplasts were isolated from in vitro cultured leaves and cotyledons by an overnight incubation in an enzyme solution containing 1–1.5% driselase and 0.5M sucrose. This method allowed high yield of purified protoplasts, which floated and formed a dark green band at the meniscus, after centrifugation. Purified protoplasts were diluted to 3×10⁴ protoplasts·ml^–1 in culture medium. After cell wall regeneration, protoplasts gradually increased their volumes under appropriate conditions. The first divisions occurred during the second week in culture. Division efficiency ranged from 5.2 to 9.8% after 20 days in culture. Two weeks later visible microcolonies developed only from cotyledon protoplasts. After 6 weeks in culture, the microcalli were transferred to a solidified culture medium with 0.6% agarose, which induced active callus growth.Abbreviations OM olive proliferation medium, Rugini 1984 - Omg OM for the germination of olive embryos - OMr=OM for root induction - OMp=OM for protoplasts - OMc=OM for callus - BN Bourgin and Nitsch medium 1967 - IBA indol-3-butyric acid - NAA naphthalene acetic acid - 2,4-D dichlorophenoxyacetic acid.     

Isolation,Culture and Plant Regeneration of Protoplasts from an Embryogenic Callus Tissue of Gossypium hirsutum

Protoplasts were isolated and cultured from hypocotyl embryogenic callus tissue of Gossypium hirsutum L. cv. "Lumian 6". The highest yields of viable protoplasts were obtained from a vigorous embryogenic callus 7 to 9 d old subcultured on MS medium supplemented with 2 mg/L IAA and 1 mg/L KT using a solution of 1% cellulase Onozuka R-10, 1% pectinase, 0.7 mmol/L KH2PO4, 2.5 mmol/L Ca2+ , and 0.5 mol/L osmoticum (mannitol), at pH 5.8 and at a temperature of 30 ℃. After separation and purification (in 21% sucrose floatation medium), the protoplasts were laid up in a quiet liquid protoplast culture medium containing K3 salts, NT vitamins with 0.1 mg/L 2,4-D, 0.2 mg/L KT and 0.45 mol/L glucose for 10 to 15 min. The protoplasts were fractioned into an upper and a lower layer in the centrifugal tube. Most of the protoplasts in the lower layer were smaller, round and rich in cytoplasts in which contain many granular substances. When this kind of protoplasts were cultured in the thin liquid protoplast culture medium with a density of 1 x l0s to 5 x los protoplasts/mL, the division and the callus formation of the regenerated cells were easily observed. The first divisions occurred in 3 days and small cell clusters could be seen after 2 to 3 weeks in the culture. At this moment, the addition of the protoplast culture medium with decreased osmoticum once or twice is needed for the continuous protoplasts division to form calli. Regenerated calli, 3 to 5 mm in diameter, were transferred in succession on MS medium with 2 mg/L IAA and 1 mg/L KT for the initiation of embryogenesis. The embryoids germinated on the hormonefree MS medium and a number of plantlets were obtained. It seems that using vigorous embryogenic callus and decreasing osmoticum are the two critical factors for plant regeneration of cotton protoplasts.     

Callus formation from protoplasts of Artemisia sphaerocephala Krasch and some factors influencing protoplast division

Round wormwood (Artemisia sphaerocephala Krasch) seeds were germinated on Murashige & Skoog (1962) medium without plant growth regulators. The hypocotyls of seedlings were sliced and cultured on M1 medium with 2,4-dichlorophenoxyacetic acid (9.05 M) to induce callus. The induced calluses were subcultured on the same medium. Ten day old calluses were used to isolate protoplasts in an enzyme solution with 0.65 M mannitol. Protoplast yield strongly depended upon the state of callus cultures. Certain amount of hemicellulase could improve protoplast isolation. Purified protoplasts were cultured in modified Kao & Michayluk (1975) medium with 0.60 M mannitol as osmoticum, suggesting that protoplasts of A. sphaerocephala need a high initial osmolarity. Protoplasts generally divided evenly and the percentage of first division could reach 10%. Kinetin exhibited a positive effect on initial cell division. Furthermore, we studied the effect of protoplast density and vitamin C on sustained growth of protoplasts. After forty days, 1 mm calluses in diameter formed.Abbreviations CH casein hydrolysate - 2,4-D 2,4-dichlorophenoxyacetic acid - KM8P Kao & Michayluk (1975) protoplast medium - MS Murashige & Skoog (1962) medium - MES-2 (N-morpholino)ethanesulfonic acid     

小麦原生质体分离过程中生理状态的变化

酶解处理使小麦对肉原生质体膜流动性降低,膜脂过氧化产物丙二醛（ＭＤＡ）积累,说明脱璧过程对细胞有伤害作用,损伤位点可能发生在膜上。胚性愈伤组织的具有分裂能力的原生质体,不表现上述变化。酶解脱壁还使超氧化物歧化酶（ＳＯＤ）和过氧化氢酶（ＣＡＴ）活性上升;过氧化物酶（ＰＯＸ）在叶肉原生质体中活性下降,在胚性愈伤组织来源的原生质体中活性上升。以上结果表明：在原生质体分离过程中,细胞的生理特性发生了变化;膜损伤的发生可能与原生质体能否进入正常分裂状态有关。     

皱叶甘蓝的原生质体培养与植株再生

皱叶甘蓝(Brassica oleracea L. var. subauda)“SA61”(SV)的叶及下胚轴分离的原生质体在 MS_1(修改的MS)培养基上细胞壁再生和分裂启动较快。叶原生质体在 DPD_1(修改的 DPD)培养基上获得了最高的分裂率和植板率;下胚轴原生质体在MS_1上获得最佳的培养效果。叶原生质体培养3—4天后见到一次分裂;下胚轴原生质体在48小时左右即可发生一次分裂。原生质体培养 20—30天后形成肉眼可见的微愈伤颗粒,40天左右即可达1mm大小。在7种不同培养基上增殖微愈伤组织,MB_2、MB_3表现了优良的效果。在MS_2培养基上的芽分化效果最为理想。在不加任何激素的MS培养基上诱导生根,2周后得到再生植株。     

草木樨状黄芪甲硫氨酸抗性系的原生质体培养及植株再生

建立了草木樨状黄芪(Astragalus melilotoides Pall．)甲硫氨酸抗性系原生质体再生植株的实验体系。以茎切段诱导的松软愈伤组织为材料,通过酶法分离出大量有活力的原生质体。原生质体经培养持续分裂形成了愈伤组织,并高频率地分化出再生苗。比较了不同培养基、培养方法和培养密度对原生质体分裂和再生的影响。结果表明,原生质体以3×10⁵/mL的植板密度,采用琼脂糖岛法培养在附加1．0mg／L 2,4-二氯苯氧乙酸(2,4-D)、0．5mg／L 6-苄氨基嘌呤(6BA)、500mg／L水解酪蛋白、3％蔗糖、0．3mol／L甘露醇的KM_8p培养基中,可获得最佳效果,其细胞分裂频率达38％左右。原生质体培养后仍然保持对甲硫氨酸的抗性,同时对乙硫氨酸表现交叉抗性。     

抗氧化剂对苜蓿原生质体早期培养的影响

研究发现,分离原生质体的酶解脱壁处理可以诱导苜蓿细胞产生活性氧。培养基中添加抗氧化剂,有助于提高培养原生质体的分裂频率,缓解褐化现象的出现。经紫外照射处理的培养基不利于苜蓿原生质体的生长和分裂,添加抗氧化剂后,紫外辐射所引起的不良效应则被抵消。因而,通过抗氧化剂对活性氧的清除,有助于早期原生质体的培养。     

Callus production from photoautotrophic soybean cell culture protoplasts

Summary Protoplasts were prepared from a photoautotrophic (PA) cell line of Glycine max (soybean). A yield of 75 to 90% after two to three hours digestion in a mixture of 1% Cellulase R10, 0.2% Pectolyase Y23 and 2% Driselase was obtained. Cell division and colony formation occurred from approximately 18% of the plated protoplasts. The cultured protoplasts were as sensitive to the herbicide atrazine, a photosynthetic inhibitor, as the original PA cells under the same conditions. Protoplasts and cells of a heterotrophic (HT) soybean culture were not as sensitive to atrazine. The isolated protoplasts retained the PA characteristics of the parental culture in the callus and cell suspension cultures obtained from the protoplasts. The chromosome numbers in the parental cell line and in cells derived from the isolated protoplasts (both PA and HT) were found to be largely (99%) the normal diploid number of 40.Abbreviations BA Benzylaminopurine - 2,4-D 2,4-dichlorophenoxyacetic acid - HT Heterotrophic - MES 2-(morpholino) ethane sulfonic acid - NAA Naphthaleneacetic acid - PA Photoautotrophic - PCM Protoplast culture medium     

Differentiation in calli originated from isolated protoplasts of rice (Oryza sativa L.) through plating technique

Summary Protoplasts from mesophyll cells and callus cells of rice (Oryza sativa L.) have been isolated by enzyme treatment involving 2% pectinase followed by 3% cellulase at pH 5.4 in 0.45 M mannitol (viable protoplasts from mesophyll cells in 50–60% yield, 60–70% yield of viable protoplasts from callus cells through treatment with the mixture of the above mentioned enzymes at the same concentration). Our completely defined medium is the combination of three established media (Table 1). Culture conditions are: soft agar in petri dishes at 26° C, where they regenerated cell walls after 24 h. The first cell division was observed after 4 days in culture for callus protoplasts and after 5 days in culture for mesophyll protoplasts. Cell division continues thereafter, and after 4 weeks of culture small white calli were visible in the petri dishes. The type of plant material (whitish leaf sheaths) and cell density are important factors for the efficiency of colony formation (30% plating efficiency). Healthy root formation through transfer to suitable medium is up to now the morphogenetic reaction of the calli.Work carried out at Molecular Cytogenetics Research Unit, Deptt, of Genetics and Plant Breeding, Banaras Hindu University, Varanasi, India