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。     

茎用芥菜细胞质雄性不育系子叶原生质体培养和高效植株再生

利用茎用芥菜细胞质雄性不育系原生质体培养获得了再生植株,并研究了影响原生质体培养的因素.结果表明,子叶是茎用芥菜原生质体培养最佳的外植体,10 d苗龄的子叶原生质体在改良MS培养基上培养3 d后发生第1次细胞分裂,6 d后发生第2次分裂,3周后形成细胞团,5周后形成肉眼可见的小愈伤.培养基中缺少NAA或2,4-D都会降低愈伤组织的再生能力.在含一定浓度的NAA(0.25 mg/L)和2,4-D(0.25 mg/L)培养基上诱导的愈伤组织质地致密且有光泽,芽的分化能力高;在MS+BA l mg/L+NAA 0.2 mg/L的培养基上芽的分化频率高达近29%,再生芽在1/2MS+NAA0.1 mg/L培养基上生根,形成完整植株.     

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。     

茎用芥菜细胞质雄性不育系子叶原生质体培养和高效植株再生（英文）

利用茎用芥菜细胞质雄性不育系原生质体培养获得了再生植株,并研究了影响原生质体培养的因素.结果表明,子叶是茎用芥菜原生质体培养最佳的外植体,10 d苗龄的子叶原生质体在改良MS培养基上培养3 d后发生第1次细胞分裂,6 d后发生第2次分裂,3周后形成细胞团,5周后形成肉眼可见的小愈伤.培养基中缺少NAA或2,4-D都会降低愈伤组织的再生能力.在含一定浓度的NAA(0.25 mg/L)和2,4-D(0.25 mg/L)培养基上诱导的愈伤组织质地致密且有光泽,芽的分化能力高;在MS+BA l mg/L+NAA 0.2 mg/L的培养基上芽的分化频率高达近29%,再生芽在1/2MS+NAA0.1 mg/L培养基上生根,形成完整植株.     

茎用芥菜细胞质雄性不育系子叶原生质体培养和高效植株再生

利用茎用芥工细胞质雄性不育系原生质体培养获得了再生植株,并研究了影响原生质体培养的因素。结果表明,子叶是茎用芥菜原生质体培养最佳的外植体,10d苗龄的子叶原生质体在改良MS培养基上培养3d后发生第1次细胞分裂,6d后发生第2次分裂,3周后形成细胞团,5周后形成肉眼可见的小愈伤,培养基中减少NAA或2,4－D都会降低愈伤组织的再生能力,在含一定浓度的NAA（0．25mg/L)和2,4－D（0．25mg/L)培养基上诱导的愈伤组织地致密且有光泽,芽的分化能力高;在MS＋BA 1mg/L NAA0.2mg/L的培养基上芽分化频率高达近29％,再生芽1／2MS＋NAA0．1mg/L培养基上生根,形成完整植株。     

诸葛菜叶柄原生质体培养再生植株

本文首次报道用诸葛菜(Orychophragmus violaceus)试管苗叶牺为材料分离原生质体,经培养再生了植株。用于原生质体培养的基本培养基为Nitsch培养基,附加1OOmg／L丝氨酸,800mg／L谷氨酰胺和13％的蔗糖,激素成分为0.5mg／L BA,0．5mg／L NAA和lmg／L2,4一D(或0．5mg／L BA和2mg／L 2,4-D)。原生质体的培养密度为2×10⁵／ml。培葬7天的原生质体分裂频率约为40％。在附加O．05mg／L NAA和3mg／L BA的MS分化培养基上,愈伤组织可分化出大量的芽和苗,分化频率为100％。     

霸王的原生质体培养的研究

目的：为利用原生质体融合技术转移霸王抗旱基因。方法：采用酶解法分离霸王原生质体,比较了霸王子叶和愈伤组织游离原生质体的产量和活力,不同渗透压和起始密度对原生质体分裂频率的影响。结果：愈伤组织游离的原生质体产量和活力均高于子叶,原生质体产率可达2.4×106个/g.FW,活力达89%。采用液体浅层培养,在附加2,4-D（2mg/L）、6-BA（1.0mg/L）、2%蔗糖和甘露醇（0.4mol/L）的DPD培养基中,原生质体分裂频率最高,达68.6%。转移到附加2-iP（3mg/L）、KT（1.0mg/L）、6-BA（1.0mg/L）的分化培养基上,获得2个再生苗。结论：采用酶解法游离霸王愈伤组织,可获得高活力和高分裂频率的霸王原生质体。     

小麦成熟胚愈伤组织诱导及分化研究

以2个小麦品种成熟胚为外植体进行离体培养,研究了不同预处理、不同2,4-D浓度及与KT组合、不同蔗糖浓度等因素对愈伤组织诱导及分化的影响。结果表明:4℃低温预处理可提高愈伤组织的出愈率及再生苗率,2个材料的出愈率及再生苗率均达到90%和30%以上;在不同预处理条件下,2,4-D浓度对出愈率及再生苗率的影响与基因型有关,2,4-D浓度为1~2 mg/L更有利于愈伤组织诱导及分化;附加KT能缓解高浓度2,4-D对再生苗率的抑制作用,而对于在1、2 mg/L 2,4-D的培养基中附加KT则不表现这种作用;蔗糖浓度则在30 g/L条件下更有利于愈伤组织诱导。因此通过4℃低温预处理,在MS基本培养基中附加1~2mg/L 2,4-D及30 g/L蔗糖亦可促进小麦成熟胚愈伤组织的诱导和分化。     

改良MS培养基对水稻成熟胚培养的影响及其细胞组织学观察(简报)

含 5 mg/L Vit B_1,附加 2 mg/L 2,4-D,5mg/L ABA和 300 mg/L LH的MS培养基对水稻成熟胚离体培养的效果明显优于含5mg/L Vit B_1,附加2mg/L 2,4—D和1mg/LKT的MS培养基。从后者诱导产生的愈伤组织多呈白色不透明状,并通过器官(芽)发生途径再生绿苗,而前者培养基上产生的愈伤组织绝大多数为乳白色,表面呈疣状突起,常形成胚状体继而再生绿苗。     

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。     

水稻原生质体培养再生植株程序化的初步研究

从12个品种水稻成熟种子诱发愈伤组织并继代培养,通过MS培养基中2,4-D浓度的变换,研究了2,4-D对水稻愈伤组织生长的影响。用AA培养基建立适合原生质体培养的胚性细胞悬浮系仅需3个月。由悬浮细胞系游离的原生质体在改良的KPR培养基中进行液体浅层培养,有10个品种获得高植板率的细胞团。变换使用不同的分化培养基,从7个品种得到再生植株。实验重复性达到80%,初步实现了水稻原生质体培养的程序化。     

Plant regeneration from callus protoplasts of the forage legume Astragalus adsurgens Pall.

A reproducible release of viable protoplasts was obtained from friable calli of Astragalus adsurgens. Protoplasts underwent sustained divisions and formed cell colonies when cultured in either liquid or agarose-solidified Kao and Michayluk (1975) protoplast medium (KM8P) supplemented with 1.5 mg/l 2,4-D, 0.5 mg/l BA and 0.5 M glucose. Compared to liquid culture, agarose bead culture improved division frequency effectively, the two culture systems showing a plating efficiency of 0.8±0.5% and 6.5±0.7%, respectively. Upon transfer to Murashige and Skoog (1962) medium (MS) with 1–2 mg/l BA, alone or in combination with NAA or 2,4-D at 0.1 mg/l, the protoplast-derived calli produced complete plantlets through somatic embryogenesis. The maximum percentage of calli producing somatic embryos (52.5± 2.2%) occurred on MS medium containing 0.1 mg/l NAA and 1 mg/l BA, whereas the maximum number of calli regenerating plantlets (64.7±6.2) was obtained on MS medium with 0.1 mg/l NAA and 2 mg/l BA. Received: 25 April 1997 / Revision received: August 1997 / Accepted: 2 September 1997     

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.     

Plant Regeneration from Callus Protoplasts of Codonopsis pilosula

Embryogenic cell line was established from hypocotyl segments of Codonopsis pilosula (Franch.)Nannf. 4--8 day old embryogenic callus was used to isolate protoplasts in an enzyme solution containing 1.5 % cellulase Onozuka R-10 and 3 % pectinase. Protoplasts were cultured in MS,C81V,DPD and KMSp basal medium supplemented with 1.2 mg/L 2,4-D, 0.2 mg/L NAA, 0. 2 mg/L BAP, 0. 1 mg/L ZT,and different combinations of glucose and mannitol . Protoplast-derived cells underwent sustained divisions in KM8p medium. As an osmoticum, glucose was more beneficial to protoplast division. A combination of 0. 30 mol/L glucose with 0.10 mol/L mannitol gave the best result. Under proper conditions , protoplasts underwent the first division on the 3rd day of culture,formed colonies within 30 days , and developed into microcalli in 6 weeks. Plantlets were regenerated from protoplast-derived calli through somatic embryogenesis. 0.2 % activated charcoal promoted embryoid formation and root development.     

Plants regenerated from mesophyll protoplasts of white mulberry

INTRODUCTIONProtoplastcultureis0neofthen1ostrapidlydevel0pingareasinp1anttissueculture,becauseofitsimportancei11plantgeneticmanipulation.However,sofar,thereareonlyafewforesttreespeciesinwhichplantregenerationfr0mprotoplastshaJsbeensuccessful,namelyLiriode…     

An improved procedure for plant regeneration from indica and japonica rice protoplasts

Plant regeneration from protoplasts of two commercially cultivated Indian indica rice varieties, Pusa Basmati 1 and Java, has been accomplished by plating embryogenic cell suspension-derived protoplasts on the surface of filter membranes overlying agarose-embedded feeder cells of Lolium multltiflorum and Oryza ridleyi, combined with the use of a maltose-containing shoot regeneration medium. Embryogenic cell suspension cultures of Pusa Basmati 1 and Jaya were initiated from mature seed scutellum-derived calli in liquid R₂ medium modified by the addition of 560 mg l^–1 of proline and 1.0 % (w/v) maltose. In both varieties, protoplast plating efficiencies up to 0.4 % were obtained, depending on the nature of the feeder cells. L. multiflorum feeder cells induced a 6-fold higher plating efficiency than feeder cells of O. ridleyi. In combination, O. ridleyi and L. multiflorum feedercells further enhanced protoplast plating efficiency. Protoplast-derived cell colonies were not obtained from protoplasts of either indica varieties in the absence of feeder cells. MS-based medium containing kinetin (2.0 mg l^–1) and -naphthaleneacetic acid (0.5 mg 1^–1), together with sucrose and maltose both at 1.5 % (w/v), induced green shoot regeneration in 44 % of protoplast-derived tissues, depending on the feeder cells used for protoplast culture. In both varieties, tissues obtained using O. ridleyi feeder cells were more morphogenic than tissues obtained using L. multiflorum feeder cells, either alone or in combination with cells of O. ridleyi. In the japonica rice variety Taipei 309, this new procedure resulted in a 30-fold increase in plant regeneration from protoplasts compared to previous published procedures.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - FDA fluorescein diacetate - GPFs growth promoting factors - NAA -naphthaleneacetic acid On leave from Department of Genetics, Haryana Agricultural University, Hisar, IndiaOn leave from Biotechnology Centre, Punjab Agricultural University, Ludhiana, India     

Effect of sugar type on the efficiency of plant regeneration from protoplasts isolated from shoot tip-derived meristematic nodular cell clumps of Lilium x formolongi hort.

Summary Suspension cultures composed of meristematic nodular cell clumps of Lilium x formolongi hort were established from shoot tips placed on MS medium supplemented with 1 mg/l picloram and 30 g/l sucrose, glucose, fructose or sorbitol. Protoplasts isolated from these cultures were embedded in 1 g/l gellan gumsolidified 1/2MS medium with 1 mg/l picloram and the different kinds of sugars at 0.5 M, and cultured at 25 °C in the dark. The highest plating efficiency (13.7%) was obtained when the protoplasts were isolated from the cell clumps which had been subcultured in MS medium containing glucose and were likewise cultured in MS medium supplemented with 0.5 M glucose. Plants were regenerated from the protoplast-derived calli on 1/2MS medium containing 2.5–10 g/l sucrose or 5–10 g/l glucose. These results suggest that the kinds of sugar and concentration are important parameters affecting protoplast isolation, proliferation and plant regeneration in L. x formolomgi hort.Abbreviations FW fresh weight - MS Murashige and Skoog (1962) - 1/2MS medium MS medium containing half strength mineral salts - 1/2MS-0 1/2MS medium containing no growth regulators - NAA 1-naphthaleneacetic acid - p-calli protoplast-derived calli - PE plating efficiency - picloram 4-amino-3,5,6-trichloro-picolinic acid