苗龄与红光对向日葵原生质体分离和培养的影响

用1.0—1.5%(W/V)纤维素酶(Onozuka R-10)和0.3—0.5%(W/V)果胶酶[Pectinasc (Serva)]配合分离到大量有活力的向日葵下胚轴原生质体,经液体浅层培养或琼脂糖小块培养7—10天后,均能持续分裂到细胞团或体细胞胚,至14—21天形成大量肉眼可见的小愈伤组织(直径0.5—2.0mm)。比较试验表明:(1)影响向日葵下胚轴原生质体分裂生长的首要因素是起始材料无菌苗的生理状态。用红光照射无菌苗,能明显地促使下胚轴原生质体在较低密度(1×10~4/ml)培养时,也能持续分裂,再生小愈伤组织;(2)在MS培养基上添加5mmol/L谷氨酰胺或以7.5mmol/L谷氨酰胺代替原培养基中的无机氮,能促使原生质体高频率(44.4%左右)分裂,再生愈伤组织。     

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。     

小偃麦原生质体培养及植株再生

硬粒小麦(Triticum durum Desf.AABB)和中间偃麦革[Elytrigia intermedium(Host)Nevski BBEEFF]的杂种 F_1——小偃麦的幼穗诱导的胚性愈伤组织继代培养近两年后,转入修改的 MS 液体培养基建成胚性细胞悬浮系。从此悬浮系分离的原生质体在修改的 KM_(8p)培养基中培养48小时后出现第一次分裂。15天后,在液体浅层培养条件下的细胞分裂频率为2%;而用1.2%琼脂糖固化进行固体平板培养时,细胞的分裂频率则为12.14%。20—30天后,添加渗透压降低的原生质体培养液。当从原生质体再生的愈伤组织长至2—4mm 大小时,逐步转至生长及分化培养基上再生出完整植株。     

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。     

埃塞俄比亚芥的原生质体培养及植株再生

以埃塞俄比亚芥“84A165”为材料,从3—5日龄无菌苗的子叶、下胚轴或温室生长的三叶期苗的第一真叶游离原生质体,悬浮于 P-B 液体培养基中,用0.15—0.3%低融点琼脂糖固化,薄层漂浮,暗培养。原生质体密度为5×10~3—1×10~4/ml。下胚轴原生质体在培养后48小时出现一次分裂,3天后分裂频率达21%,6天后达34%。子叶和真叶原生质体起始分裂稍晚(第5天),分裂频率也较低。培养1周后,加入稀释培养基 DPDK_3,并转至光下,以后每隔一周加液一次。一个月后获得肉眼可见的小愈伤组织。植板率为2—3%。小愈伤组织在固体增殖培养基上继代长大。子叶和真叶原生质体来源的愈伤组织在转至补加 NAA0.1、BA3mg/1的分化培养基上后获得芽分化,把这些芽切离,转至 IAA0.2mg/l 的生根培养基上,再生出完整植株。     

沙打旺原生质体培养再生植株

用1%半纤维素酶,0.4%纤维素酶,0.1%果胶离析酶,CPW9M酶液分离沙打旺无菌苗下胚轴和子叶原生质体。K8P原生质体培养基悬滴培养。下胚轴原生质体形成小细胞团后用琼脂糖包埋培养,形成小块愈伤组织后转入增殖培养基M1、M2(改良MS培养基)上形成大块愈伤组织。经过两次诱导分化,在分化培养基M3(MS 0.7mg/L BA 0.2mg/L NAA),M4(MS 0.5mg/L BA 0.5mg/L KT 0.5mg/L ZT 0.2mg/L NAA)和M6(MS 3mg/L ZT 0.2mg/L IAA)上分化出苗,再生植株。由子叶分离的原生质体未能形成愈伤组织。     

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。     

甘蓝下胚轴原生质体再生植株

经纯化后,甘蓝下胚轴原生质体的产量为1．5×10⁶g^-1(Fw),采用液体浅层培养的方法进行培养。2～3d后,发生第一次分裂,第10天,统计分裂频率为6l％,5周内形成大量的细胞团和小愈伤组织,统计植板率为1．1％,把小愈伤组织转到与原生质体培养基相同激素的MS固体培养基上增殖。当愈伤组织长到3～5mm大小时,接到分化培养基上,芽分化率为46.7％．分化出来的芽长到3～4cm长时,从基部切下,插入生根培养基,两星期左右即可长成完整植株。     

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。     

影响花椰菜下胚轴原生质体培养和植株再生的因素

从花椰菜的无菌苗下胚轴游离原生质体经纯化后的得率为1.5～2×10~6/g FW。通过液体浅层培养、平板固体培养、双层培养和gelrlte包埋培养方法的比较,发现gelrite包埋培养法,最有利于花椰菜下胚轴的原生质体培养。纯化的原生质体用MS-1培养基培养,再生细胞的分裂频率为24％。再生的愈伤组织转到分化培养基MS-5A或MS-5B上迅速分化出苗。共获得再生植株78株,移栽到盆中生长正常,结出正常的菜花。     

Plant Regeneration from Protoplasts of Savoy Cabbage(Brassica oleracea L. var. subauda)

Protoplasts of savoy cabbage (Brassica olleracea L. var. subauda), "SA61" (SV), were isolated from leaves and hypocotyls of seedlings grown in vitro, in enzyme mixture containing 2% cellulase (Onozuka R-10) and 0.8% macerozyme RI0. Good results of protoplast collection were obtained by using 18% and 17% sucrose solution floating leaf protoplasts and hypocotyl protoplasts respectively, and centrifugalizing with the rate of 500 r/min. All the collected protoplasts were cultured in 5 different liquid media from which the best results were observed on DPD1 medium for leaf protoplasts and on MS1 medium for hypocotyl protoplasts, with the highest cell division rate and planting efficiency. About 2 weeks of cultures, many cell clusters and a few embryo-like structures were visualized. The cell clusters developed into visible microcalli in 20-30 days and grew up to 1 mm or so in dimeter about 40 days of culture. For growth, the calli were transferred to 7 different agar media and from which two suitable media, MB2 and MB3, were selected. Cultured for 40-50 days, the calli grew up, and were transferred to 4 solid media for organ differentiation. Ideal results of shoot regeneration were obtained on MS, medium. About 2 weeks after rooted on the MS medium without any auxin, intact plants were regenerated.     

枸杞下胚轴原生质体培养再生植株(简报)

枸杞是我国常用的一种滋补中药,具有较高的经济价值。以枸杞茎尖、叶片、花药、胚乳为材料的组织培养均获得再生小植株。由愈伤组织分离出的原生质体培养形成了愈伤组织。最近,由叶肉原生质体培养获     

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     

Plant Regeneration from Sainfoin(Onobrychis viciaefolia)Protoplasts Derived from Cell Suspensions of Hypocotyl

The protoplasts were isolated from cell suspension cultures of hypocotyl (Onobrychis viciaefolia) cullured continuously for 3–4 months, and were cultured in modified Wguid Ⅴ- KM medium. The first division of the regenerated cell occurred after 24 h. culture. Small calli could be seen with naked eyes in 4 weeks. The calli which were propagated to 2–4 mm long in diameter in the (Ⅳ) medium were transferred onto differentiation medium and shoots appeared after 2–3 weeks. The differentiated shoots formed their roots on 1/2 MS supplamented with NAA 1.0mg/1 and grew into plantlets.     

High growth rate and regeneration capacity of hypocotyl protoplasts in some Brassicaceae

Protoplasts isolated from 4-day-old hypocotyls of various species of Brassica (Brassica napus, B. campestris and B. oleracea ) produced callus with high efficiency in media containing casein hydrolysate and high concentrations of the auxin 2,4-D (4.5 μM). Cell division began after 24 h and 60% of the cells had divided after 48 h. In contrast, protoplasts isolated from stem and mesophyll of plants grown in vitro or in the greenhouse began to divide after a delay of 3–5 days. In these cases 40–50% of the cells had divided after 5 days as compared to 70% for hypocotyl protoplasts. To obtain a high frequency of regeneration, rapidly growing calli were transferred to media having a high cytokinin:auxin ratio as early as possible, usually 3 weeks after protoplast isolation. The average regeneration frequency for calli obtained from mesophyll protoplasts was 50%, while as many as 70% of the calli derived from hypocotyl protoplasts of B. napus regenerated plantlets on a medium containing zeatin (9.1 μM) and IAA (0.6 μM). On the same medium regeneration of Brassica oleracea was obtained. A low percentage of calli (1%) from Brassica campestris formed shoots when cultured on a combination of zeatin (4.6 μM), BA (4.4 μM) and IAA (0.6 μM).     

Plant Regeneration of Protoplasts of Trifolium lupinaster L. from Cell Suspension Cultures

paper deals with regeneration of protoplasts in cell suspension cultures of hypocothl from Trifolium lupinaster L. on the SL2 basal medium with BA 0.1 mg/L and picloram 0.06 mg/L for 3--4 month,s. The protopiasts were isolated from suspensions cells subcultured for 3 days and were recuhured in modified liguid medium 8p. The first division of the regenerated cell occurred 3 days after being cultured in medium Bp. Small calli could be seen with naked eyes by one month. The calli when grew up to 2 mm long, were transferred in succession differentiation medium A and B for organ differentiation. The differentiated shoots formed their roots on 1/2 MS supplamented with NAA 1.0mg/L and then grew into plantlets.     

Plant Regeneration from Protoplast of Trititrigia (Triticum sect. trititrigia Maekey)

Trititrigia is the intergeneric hybrid which is from the hybridization between Triticum durum Desf. and Elytrigia intermedium (Host) Nevski. Protoplasts of Trititrigia were isolated from the embryogenic cell suspension derived from immature inflorescence-induced calli of the hybrid F1. The first division occured 48 hr after plating in modified KM8p culture medium. The plating efficiency of protoplasts was 2% and 12.14% when they were cultured in liquid medium and agarose solidified medium, respectively. Clusters grew vigorously under these conditions. Fresh medium with decreased osmoticum was added 20–30 days after plating. When protoplast-derived calli, 2–4 mm in the size, were transferred step by step to different differentiation media, embryoids, green spots emerged and numerous plants regenerated eventually.     

Regeneration of whole plants from protoplasts isolated from tissue-cultured shoot primordia of garlic (Allium sativum L.)

Protoplasts derived from tissue-cultured shoot primordia of garlic (Allium sativum L.) initiated successive cell divisions within 4 days and formed small individual calli (0.2mm in diameter) after 5 weeks of culture on Gamborg's B5 medium supplemented with 0.1% casein hydrolysate, 1mg/1 1-naphthaleneacetic acid and 1mg/1 6-benzylaminopurine. Plating efficiency was roughly 5% at the density of 1x10⁴ protoplasts/ml of medium. Adventitious buds developed from the calli during subsequent subculture on Gamborg's B5 medium supplemented with 40mg/l adenine and 10% coconut milk. When transferred to the same medium without supplements, these buds grew into shoots and rooted. The regenerated garlic plantlets were successfully transferred to the greenhouse and grew into whole plants.     

Plant Regeneration from Protoplasts of Actinidia chinensis Planch.

Protoplasts isolated from cotyledon callus line of A14N7 of Actinidia Chinensis Planch. were cultured in the improved NN-69 medium. First division of regenerated cells occurred during 7–10 days of culture, and percentage of the cell division was about 10% at day 20. The best result of protoplast culture was achieved when protoplasts were cukured in liquid medium at a density of 5× 104/ml, About 4 months, procoplast-derived calli were transferred stepwisely onto differentiation media where they developed into green compact calli, from which the perfect plants were regenerated.     

A procedure for regenerating Japonica and Indica varieties of rice from protoplasts

Fertile rice plants have been regenerated from protoplasts of two japonica rice varieties (Radon and Baldo) using a protocol initially developed for plant regeneration from protoplasts of an indica rice. Embryogenic calli were developed from immature embryos of Radon and Baldo rice on a callus induction medium, and then used to establish cell suspensions. Protoplasts were isolated from the cell suspensions, and cultured on a Millipore filter placed on a Kao/agarose medium that contained cell clusters from suspensions of IR52 or IR45. The protoplasts grew vigorously on Kao medium and developed into embryogenic calli within two to three weeks. Somatic embryo development occurred during a subsequent transfer of the calli to an LS medium for two to three weeks. The calli were then transferred to MS or N6 plant regeneration medium, and within one to three weeks, plants regenerated from 21 to 32% of the Radon calli, and 33 to 35% of the Baldo calli. Based upon these results and the previous success in regenerating an indica variety from protoplasts, this procedure has great promise for regenerating a range of rice varieties, and probably for regeneration of other monocotyledonous plants from protoplasts