鹰嘴紫云英甲硫氨酸抗性系原生质体培养及植株再生

本研究建立了鹰嘴紫云英(AstragaluscicerL.)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,通过酶法游离出大量有活力的原生质体。原生质体经培养持续细胞分裂形成了愈伤组织,并分化出再生苗。比较了不同培养基、培养密度对原生质体形成细胞分裂和再生的影响。结果表明,原生质体以2×105个/ml的植板密度,在附加2.0mg/L2,4-二氯苯氧乙酸(2,4-D)、0.2mg/L6-苄氨基嘌呤(6-BA)、200mg/L水解酪蛋白、2%蔗糖和0.3mol/L甘露醇DPD培养基中培养后,其分裂频率达38.3%。原生质体培养形成的愈伤组织仍具有对甲硫氨酸的抗性。转移到附加10mg/LKT、0.5mg/LNAA的MS分化培养基上,获得大量的再生苗。     

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。     

枸杞原生质体培养及高效成株体系的建立

由枸杞髓部组织诱导出胚性愈伤组织,并由此愈伤组织建立起稳定的细胞悬浮系,从悬浮细胞游离的原生质体在改良KM培养基（1．5mg/L 6-BA,0.5mg/L NAA和0．5mg/L2,4-D)中进行液体浅层培养,3－4d后出现第一次分裂,第7d统计分裂频率为50．3％,15d左右可形成细胞团,3－4周后形成肉眼可见的愈伤组织,愈伤组织植板率为1．25％,将细胞团转移到液体分化培养基（MS＋6－BA 1．5mg/L 2,4-D 0.2mg/L)8-10d可形成大量胚状体,及时将胚性愈伤组织块转移到固体分化培养基上（MS 6-BA 0.2mg/L)可形成大量绿芽,分化率54．17％。绿芽在生根培养基（MS＋NAA 0．2mg/L)可形成完整植株,移栽后成活良好。     

沙葱叶基愈伤组织原生质体再生体系的建立

沙葱是一种具有抗旱抗寒、抗病性和适应性强等生理特性的荒漠植物.为开发利用其固有的遗传资源,本研究利用细胞工程技术建立了沙葱(Allium mongolicum Regel)叶基愈伤组织原生质体的分离、培养和植株再生实验体系.研究结果表明,酶法分离原生质体的产率和分裂频率明显取决于用于制各原生质体的愈伤组织的状态.转代培养7～10d的松软愈伤组织可分离出大量有活性的.在附加2.0mg/L2,4-D、0.2mg/L激动素、500 mg/L水解乳蛋白、0.4 mol/L甘露醇和2%蔗糖的MS培养基中进行液体浅层培养,4～5 d后出现第一次原生质体分裂;7～10d出现第二次分裂.结果显示原生质体的分裂频率大约为5%;4周后,可见到小愈伤组织.当将原生质体分裂形成的愈伤组织转移到附加2.0mg/L6-苄氨基嘌呤(或激动素)和0.4mg/L萘乙酸(NAA)的MS固体培养基上,并在低光照条件下培养后,从愈伤组织上分化出了不定芽,进而发展成小植株,并移栽成活.本研究对沙葱抗逆遗传品质用于经济植物遗传改良的研究奠定了可行的实验基础.     

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。     

甜菜原生质体培养直接产生体细胞胚

甜菜(Beta vulgaris L.)是重要的经济植物,是制糖的重要原料。近10年来已相继有人开展了甜菜原生质体的培养,但到目前为止,在国内外还未有关于甜菜原生质体培养中体细胞胚发生的报道,尤其是从原生质体直接的发生。本研究从甜菜未授粉的胚珠诱导产生的愈伤组织制备原生质体,分裂后直接产生体细胞胚,现报道于下。用于分离原生质体的愈伤组织是从甜菜(Beta vulgaris L.)品系1804/6未授粉胚珠诱导产生的。将该愈伤组织在 MS 培养基附加1.0mg/L 2,4-D 0.5mg/L 6-BA 中     

枸杞原生质体培养及高效成株体系的建立

由枸杞髓部组织诱导出胚性愈伤组织,并由此愈伤组织建立起稳定的细胞悬浮系。从悬浮细胞游离的原生质体在改良KM培养基(1.5 mg/L 6_BA,0.5 mg/L NAA和0.5 mg/L 2,4_D)中进行液体浅层培养,3～4 d后出现第一次分裂,第7 d统计分裂频率为50.3%,15 d左右可形成细胞团,3～4周后形成肉眼可见的愈伤组织,愈伤组织植板率为1.25%。将细胞团转移到液体分化培养基(MS+6_BA 1.5 mg/L+2,4_D 0.2 mg/L) 8～10 d可形成大量胚状体,及时将胚性愈伤组织块转移到固体分化培养基上(MS+6_BA 0.2 mg/L),可形成大量绿芽,分化率54.17%。绿芽在生根培养基（MS+NAA 0.2 mg/L）可形成完整植株,移栽后成活良好。     

防风悬浮细胞的原生质体再生植株

防风(Saposhnikovia divaricata(Turcz.)Schischk)试管苗的根尖,下胚轴或叶柄切段在含有1mg/l 2,4-D 的 MS 固体培养基上,形成含有胚性细胞团的愈伤组织。愈伤组织经液体振荡培养,形成含有大量胚性细胞团的悬浮培养物。用含有 Onozuka R-10 1.5%、Mace-rozyme R-10 0.3%、蜗牛酶0.5%、CaCl_2 5mmol/l 和甘露醇0.6 mol/l(pH=5.8)的酶液从胚性细胞团游离得到原生质体。原生质体在培养的第4天出现第一次分裂,50天左右形成的细胞团大小为1—2mm。这些细胞团在含有0.5 mg/l 2,4-D 的 MS 固体培养基上形成愈伤组织。在含有0.1 mg/l 6-BA 或0.1 mg/l 2,4-D+0.5mg/l 6-BA 的 MS 固体培养基上,原生质体再生的愈伤组织分化出胚状体。胚状体在不含任何生长调节剂的 MS 固体培养基上发育成完整的原生质体再生植株。     

甘蓝型油菜与芝麻菜体的细胞杂交

为拓宽油菜育种的基因资源库, 改良油菜品种, 以甘蓝型油菜(Brassica napus)花油3号下胚轴和芝麻菜(Eruca sativa)下胚轴为材料分离制备原生质体; 然后采用PEG-高Ca2+-高pH法进行原生质体融合, 当PEG浓度为35%, 原生质体融合密度为5×105个/mL时, 融合25 min时, 融合率可达18.2%。融合后在培养密度为1×105个/mL时, 以附加1.0 mg/L 2,4-D +0.5 mg/L 6-BA+0.5 mg/L NAA+ 200 mg/L肌醇+300 mg/L水解酪蛋白的改良的KM8p为融合体培养基, 以0.1 mol/L 蔗糖+0.2 mol/L葡萄糖+0.2 mol/L甘露醇作渗透稳定剂进行液体浅层培养, 效果较好, 愈伤组织再生率最高为6.8%。将融合体再生的小愈伤组织转移至培养基(B5无机盐+0.087 mol/L蔗糖+0.2 mg/L 2, 4-D+0.5 mg/L NAA+0.2 mg/L 6-BA+ 0.5% Agar, pH 5.8)上增殖培养, 待愈伤组织长至直径为3~5 mm时, 及时将其转至分化培养基(MS无机盐+0.087 mol/L 蔗糖+0.1 mg/L IAA+0.8 mg/L 6-BA+0.8% Agar, pH 5.8)中诱导不定芽再生, 芽分化率为35.7%。当不定芽长为2~3 cm时, 将其切下转入附加0.5 mg/L IBA+0.2 mg/L 6-BA的1/2MS生根培养基中诱导生根, 14 d左右即可形成再生植株, 生根率可达88%。同时, 以紫外线(60 μW/cm2)照射芝麻菜原生质体, 进行不对称融合, 照射2 min的获得了愈伤组织和再生植株, 照射4 min的只获得愈伤组织, 而照射5 min以上的没有获得愈伤组织, 但其愈伤组织再生、增殖及植株再生均不如对称融合。从细胞学鉴定的21块杂种愈伤组织上再生出16株杂种植株。     

水稻游离花粉培养的高频率再生植株

用二个水稻栽培品种(Oryza sativa L Sub.japonica.)中花11号和盐粳的花粉处于单核靠边期的花药,经低温处理10—20天,在无糖培养基中预培养2—4天后游离花粉进行培养。培养基为KM8P,附加1mg/L 2,4-D,100mg/L脯氨酸,500mg/L水解酪蛋白,9%蔗糖。培养5天,花粉进行一次分裂,10天后分裂频率为21.3%,21天可见小愈伤组织形成。随即将直径为0.5—1.0mm的愈伤组织移至分化培养基上,2—4星期后得到绿苗,频率为70%。并从许多花粉诱导的愈伤组织克隆中筛选出高频率再生绿苗的花粉细胞悬浮系。     

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。     

草木樨状黄芪和木本霸王的科间体细胞杂交

在成功培养原生质体的基础上,用改进的PEG-高pH高钙法诱导草木樨状黄（Astragalus melilotoides）和木本霸王（Zygophyllum xanthoxylum）原生质体融合,得到了科间体细胞杂种融合细胞。采用罗丹明-6G预处理草木樨状黄芪原生质体以及UV-B辐照霸王原生质体,使双亲原生质体及其同源融合产物均不能持续分裂而死亡,融合后的杂种细胞由于生理互补可恢复持续分裂能力而被筛选出来。融合产物经培养分裂获得了2个杂种细胞系,其中1个分化出芽。染色体计数和分子鉴定证明了杂种的真实性。初步比较了杂种细胞系及亲本对盐分和水分胁迫的耐受性,结果表明杂种细胞系对盐分和水分胁迫的耐受性介于两个亲本之间。     

草木樨状黄芪和木本霸王的科间体细胞杂交

在成功培养原生质体的基础上, 用改进的PEG-高pH高钙法诱导草木樨状黄芪(Astragalus melilotoides)和木本霸王(Zygophyllum xanthoxylum)原生质体融合, 得到了科间体细胞杂种融合细胞。采用罗丹明-6G预处理草木樨状黄芪原生质体以及UV-B辐照霸王原生质体, 使双亲原生质体及其同源融合产物均不能持续分裂而死亡, 融合后的杂种细胞由于生理互补可恢复持续分裂能力而被筛选出来。融合产物经培养分裂获得了2个杂种细胞系, 其中1个分化出芽。染色体计数和分子鉴定证明了杂种的真实性。初步比较了杂种细胞系及亲本对盐分和水分胁迫的耐受性, 结果表明杂种细胞系对盐分和水分胁迫的耐受性介于两个亲本之间。     

Plant Regeneration from Protoplasts of Coriandrum sativum

Calli produced from stem segments of seedling of Coriandrum satwum which were cultured on MS agar medium containing NAA 1.0mg/L. The embryogenic cell colony suspension was estabilished on MS liquid medium containing NAA 1.0mg/L%2,4-D 0.2mg/L+BA 0.5 mg/L. The cell suspension culture was used for protoplast preparation. Protoplasts were obtained in the enzyme mixture containing 2.0% Onozuka R-10, 1.0% pectinase, 0.5% snailase, 0.5% dextran sulfate potassium Salt, 0.6mol/L mannital CPW solution at pH 5.8 and 25℃. Cultured in a KM8P liquid medium containing NAA 1.0mg/L+2,4-D 0.2mg/L+6-BA 0.5 mg/L, glucose 0.4mol/L and CM 20mi/L; the protoplasts entered the stage of derision after three days, cell clusters formed in 10 days and calli formed after about 50 days. When the calli were transferred to MS agar medium containing many growth substances, they differentiated into embryoids, and then developed into plantlet with many green leaves and roots on the 1/2 MS agar medium.     

Mesophyll Protoplast Culture and Plant Regeneration of Oriental Planetree (Platanus orientalis)

Large populations of mesophyll protoplasts were released from the leaves of 1.5–2 month old sterile seedlings, with a high protoplast yield (3.7× 10 6g-1FW) after protoplast purification. The purified protoplasts were cultured in a modified K8p liquid medium supplemented with 0.5 mg/L 2,4-D, 1 mg/L NAA and 0.5 mg/L BA. Higher density (1× 106/ml) in the initial culture of protoplasts is favourable to the division of cultured mesophyll protoplasts of this woody species among the densities tested. The protoplasts started to divide after 6 days of culture, and achieved 26.8% division frequency by 14 days. Sustained divisions resulted in mass production of cell colonies and small calli in 8 weeks. The calli further grew to 2–3mm on the gelrite-solidified K8 medium supplemented with 0.2 mg/L NAA aud 0.5 mg/L BA. Then, they were transferred onto the MSB proliferation medium with 0.1 mg/L NAA and 0.25 mg/L BA, where compact and cream-coloured calli were formed. Shoot formation was initiated on MSB differentiation medium coraming 0.5 mg/L IAA, 1 mg/L each of BA and ZT. It was observed that the frequency of shoot formation was about 28.7%. Whole plantlets were regenerated upon transferring 3 cm shoots to 1/2MS medium with 0.5mg/L IBA and 0.1mg/L BA, from which they were already transplanted into pots and grew well in the phytotron of Shanghai Institute of Plant Physiology.     

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.     

Plant regeneration from cultured protoplasts of a glutinous rice

Young embryos of rice (Oryza sativa L. subsp, japonicavar. Guo-xiang No. 1) were cultured on MS agar medium(2,4-D 2 mg/l). Calli were formed and subcultured on N6 agar medium (2,4-D 2 mg/l ). After selection, the small, grainy and pale yellowish cell clusters with dense cytoplasm were used in protoplast preparation. Isolated protoplasts were cultured in N6 medium (2,4-D 1 mg/l, 6-BA 0.2 mg/l)~1 with agarose block culture method. The protoplasts grew, divided and formed calli. After inducing differentiation, the regenerated mature plants were obtained.     

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.