南蛇藤原生质体培养及植株再生

以4℃低温暗处理24 h的南蛇藤胚性愈伤组织为分离原生质体的原材料,用MS培养基进行液体浅层静置、固液双层以及琼脂糖包埋培养原生质体,获得再生愈伤组织并分化成苗,建立了原生质体培养体系。结果表明,低温暗处理利于高产率高质量原生质体的获得;0.5%纤维素酶+0.5%果胶酶+5 mmol.L-1MES为酶的最佳配方;12 h为最佳酶解时间;13%为甘露醇最佳浓度;静置12 h+振荡0.5 h为最佳酶解方式;液体浅层静置培养取得了较好的原生质体培养效果;MS+6-BA2.0 mg.L-1+IBA 0.1 mg.L-1为愈伤组织最佳分化培养基;1/2MS+NAA0.1 mg.L-1为最佳生根培养基。     

葡萄原生质体分离及瞬时转化体系的建立

为了建立葡萄原生质体进行遗传转化的技术,该研究以葡萄品种‘黑香蕉’的叶片和愈伤组织为材料,分析纤维素酶和离析酶的浓度与配比、渗透压和酶解时间等主要因素对葡萄原生质体分离的影响,探讨建立稳定、高效的葡萄原生质体分离与瞬时转化体系,为鉴定目标基因的功能奠定基础。结果表明:(1)葡萄叶片原生质体的分离以3.0%纤维素酶和0.75%离析酶的酶组合,在0.6mol/L甘露醇溶液中,酶解14h为宜,每克游离产量为4.09×106个原生质体,活力为83.12%。(2)葡萄愈伤组织原生质体的分离以2.0%纤维素酶和0.5%离析酶的酶组合,在0.5mol/L甘露醇溶液中,酶解14h为宜,每克游离产量为6.05×106个原生质体,活力为84.13%。(3)利用该方法得到的葡萄原生质体为受体,采用40%PEG-4000介导转化质粒载体pEZS-NL,目标基因瞬时表达产物检测表明,GFP蛋白表达稳定、清晰。该研究建立的葡萄原生质体制备和转化体系,可以用较少量的质粒DNA获得外源基因在原生质体内的表达,为葡萄功能基因的研究提供技术支持。     

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。     

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。     

北美鹅掌楸原生质体的分离与培养

以鹅掌楸属植物北美鹅掌楸的悬浮细胞和组培苗叶片为材料,对北美鹅掌楸原生质体分离、纯化与培养条件进行研究.结果表明:叶片和悬浮细胞用含有0.1％2-吗啉乙磺酸(MES)和0.6 mol/L甘露醇的Cell ProtoplastWash(60M-CPW)溶液25℃预处理lh效果最好;悬浮细胞最佳酶解液为60M-CPW+ 1％纤维素酶+1％半纤维素酶+0.2％果胶酶Y-23+0.1％ MES,每克材料25℃酶解6h有效原生质体产量可以达到3×106个;叶片最佳酶解液为60M-CPW+2％纤维素酶+1％半纤维素酶+0.2％果胶酶Y-23+0.1％ MES,每克材料25℃酶解10 h有效原生质体产量可以达到11×106个;悬浮细胞原生质体易于培养,在KM8p+1.0 mg/L 2,4-D+0.5 mg/L 6-BA培养基中培养25 d可形成肉眼可见的愈伤组织.     

新疆杨愈伤组织原生质体的游离与纯化

目的:以愈伤组织为材料,研究新疆杨原生质体的游离、纯化。方法:以新疆杨愈伤组织为材料,采用简单试验设计和方差分析方法,对新疆杨原生质体游离的影响因素进行研究,并利用二乙酸荧光素染色法观察原生质体活力。结果:适宜新疆杨愈伤组织原生质体游离的较适宜条件是:CPW+2.0%纤维素酶R-10+1.0%离析酶R-10+1.0%果胶酶Y-23+0.6 mol/L甘露醇,酶解温度27℃,酶解时间8 h。在此条件下,原生质体产量达8.5×106个/(g.FW),活力达83.6%。原生质体纯化可采用蔗糖等密度离心法,较适蔗糖浓度为30%。结论:研究筛选出的酶解因素组合与等密度离心条件较适宜新疆杨愈伤组织原生质体的游离和纯化。     

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。     

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。     

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。     

虎仗原生质体分离纯化及电融合初步研究

以野生虎杖根状茎芽为外植体诱导虎杖愈伤组织,选取生长状况良好的愈伤组织作为原生质体分离材料,通过L16(44)正交试验对虎杖原生质体分离条件进行优化.结果表明:1.4%纤维素酶R-10,0.1%果胶酶,17%甘露醇的酶液,酶解时间7h,虎杖原生质体分离效果最好.在80r/min振荡分离后虎杖原生质体得率为46.2%.以800r/min的离心速度纯化,纯化的原生质体得率为43.8%,其中原生质体的成活率为75%.通过对虎杖原生质体进行融合,原生质体的融合率为20.2%.     

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.     

The isolation and culture of protoplasts from an embryogenic cell suspension culture of Picea glauca (moench) voss

Conditions were standardized for the isolation and culture of protoplasts from an embryogenic cell suspension culture of Picea glauca. A combination of 0.5% Cellulase R-10, 0.25% Macerozyme, 0.25% Driselase, 0.25% Rhozyme HP-150 with 0.5M mannitol and 5 mM CaCl₂.2H₂O produced an average of 4.5 × 10⁶ protoplasts per gram fresh weight of cells. Of the several protoplast culture media tested, von Arnold and Eriksson and Kao and Michayluk (KM8P) media best supported mitotic divisions of protoplasts. A density of 10⁵ protoplasts per ml and the addition of 5 mM glutamine to the culture medium was necessary to induce sustained divisions and microcallus formation. Microcalli grew into subculturable callus using a nurse culture technique.Abbreviations BAP benzylaminopurine - 2,4-D 2,4-dichlorophenoxy-acetic acid - FDA fluorescein diacetate NRCC No. 27937     

胚乳和蔗糖对大麦成熟胚无菌苗生长和叶片切段愈伤组织诱导及分化的影响

大麦无菌苗的苗高。苗干重和单位长度、叶片切段的干重均依胚培养时所带胚乳的增多而递增。但叶片切段培养时的愈伤组织诱导率和再分化率并不与胚乳多少正相关。成熟胚培养时蔗糖的供应明显影响叶片切段培养时的愈伤组织诱导率。培养带1/2胚乳的胚,用萌发率高的新鲜种子培养无菌苗时,以不供给蔗糖的有较高的叶段愈伤组织诱导率,用萌发率显著降低的陈种子时,则以育苗时供给6％蔗糖为好。     

Isolation of protoplasts,and culture and regeneration into plants in <Emphasis Type="Italic">Alstroemeria</Emphasis>

Summary An efficient system for the regeneration of plants from protoplasts was developed in Alstroemeria. Friable embryogenic callus (FEC) proved to be the best source for protoplast isolation and culture when compared with leaf tissue and compact embryogenic callus. Protoplast isolation was most efficient when FEC was cultured under vacuum for 5 min in an enzyme solution consisting of 4% cellulase, 0.5% Driselase and 0.2% Macerozyme, followed by culture for 12–16h in the dark at 24°C. Cell wall formation and colony formation were better in a liquid medium than on a semi-solid agarose medium. Micro-calluses were formed after 4 wk of culture. Ninety percent of the micro-calluses developed into FEC after 12wk of culture on proliferation medium. FEC cultures produced somatic embryos on a regeneration medium and half of these somatic embryos developed shoots. Protoplast-derived plants showed more somaclonal variation than vegetatively propagated control plants.     

黄山药愈伤组织的诱导与分化

以黄山药的叶片、茎段和叶柄作外植体,以MS为基本培养基,试验了不同激素组合对愈伤组织诱导的影响,采用正交试验法研究了愈伤组织的分化效果。结果表明,以MS+2,4-D1~2mg/L+6-BA2mg/L培养基对叶片的愈伤组织诱导效果最好,接种12d后初见愈伤组织,20d后可形成大量的愈伤组织,而茎段和叶柄的诱导效果较差。分化试验结果表明,生根率最高可达85.3%,而出芽率最高仅达29.6%。     

Study on Tissue and Protoplast Culture of Wild Cotton (Gossypium davidsonii)

This paper deals with the study on the condition of callus formation, embryogenesis, organogenesis, plant regeneration and protoplast culture of wild cotton (G. davidsonii) Callus cultures derived from several organs such as root, stem, leaf, cotyledon and hypocotyl. The results obtained in these cultures showed that the modified MS medium containing 2,4-D 1.0+KT 0.1; 2,4-D 0.1+KT 0.01; NAA (IAA) 2.0+KT 0.1 and NAA (IAA) 1.0+KT 0.1 mg/L were favorable to callus formation. Modified MS medium containing 2,4-D was suitable for initiated callus of G. davidsonii Besides, suspension cultures from callus of G. davidsonii were saccessfully initiated. Optimum concentration of 6BA (or ZT, or 2ip) and NAA (IAA) was for shooting, somatic embryo or leaf formation. Plantlets regenerated from somatic embryo at lower concentration of 6BA, or ZT, or 2ip. As to protoplast culture of this species, the age and physiological condition of callus or suspension cells and concentration of enzymes used for protoplast isolation affected the yield and survival of protoplasts. Protoplast of this species cultured in modified MS medium containing 2,4-D 0.5+NAA 0.5+ZT 0.1–0.2 mg/L. and divied after 3–4 days. The rate of division was 3--4% and cell cluster formed after 14 days, then these cells died.     

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.     

mRNAs newly synthesized by tobacco mesophyll protoplasts are wound-inducible

We have used 2-dimensional (2D) non-equilibrium pH gradient gel electrophoresis (NEPHGE) of in vitro synthesized proteins and northern hybridization with labelled cDNAs coding for three pathogenesis related (P.R.) proteins, to analyze the shift in mRNA content induced by the isolation and culture of tobacco mesophyll protoplasts. The in vitro protein pattern of mRNAs from freshly isolated protoplasts is characterized by the absence of most leaf spots and the appearance of 19 new spots. After 6 hours of culture, the mRNAs coding for the P.R. proteins become detectable and after 12 hours the protoplasts contain an mRNA population almost typical of callus cells.The different steps involved in the isolation and culture of protoplasts were analysed. Cutting off the leaf and sterilization do not change the mRNA set. In contrast, the mechanical injury applied to the leaf in order to facilitate the penetration of the enzymatic mixture induces a modification of the mRNA content identical to that resulting from protoplast isolation. Wounding is the essential event inducing dedifferentiation. Varying the culture medium and conditions leads to only limited modifications of the mRNA pattern. These results are discussed on the basis of present knowledge of the reaction of the plant to wounding and we suggest that wound healing callus and in vitro callus correspond to the same differentiation state.     

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.     

Differences in oxidative stress, antioxidant systems, and microscopic analysis between regenerating callus-derived protoplasts and recalcitrant leaf mesophyll-derived protoplasts of Citrus reticulata Blanco

It is known that protoplasts derived from either leaves or suspension cultures of a citrus genotype vary greatly in their regeneration capacities; however, the underlying physiological mechanisms are not well known. In this study, oxidative stress and antioxidant systems during in vitro culture of callus-derived protoplasts and leaf mesophyll-derived protoplasts of Ponkan (Citrus reticulata Blanco) were analyzed to gain insights into observed physiological differences. Morphological observations using light microscopy and scanning microscopy have shown that new cell wall materials appeared within 2–3 days, and the integrate cell walls were regenerated approximately after 6 days of culture of the callus protoplasts, whereas no cell wall formation was observed in the mesophyll protoplasts after culture. During the culture, higher levels of H₂O₂ and malondialdehyde were detected in the mesophyll protoplasts as compared with the callus ones. On the contrary, the callus protoplasts possessed higher activities of antioxidant enzymes (SOD, POD and CAT) and larger amount of glutathione and ascorbic acid (at one time point) than the mesophyll protoplasts during the culture process. The current data indicate that the mesophyll and callus protoplasts displayed remarkable difference in the degree of oxidative stress and the antioxidant systems, suggesting that high levels of antioxidant activities might play an important role in the regeneration of protoplasts.