空间细胞电融合关键技术的地基研究——烟草细胞的电融合

本文针对建立空间细胞电融合技术存在的三个主要问题进行了研究。结果表明,用低温（４℃）、融合介质（０．５５ｍｏｌ／Ｌ甘露醇）并添加０．１％纤维素酶保存原生质体,７２ｈ内可以使约９４％细胞维持无壁状态,同时并未使细胞丧失再生能力,基本满足从地面制备亲本细胞到在微重力条件下进行电融合,对亲本细胞保持无壁状态的要求。为减少剪切力环境对亲本细胞造成的损伤,一方面用超速离心对亲本细胞之一去液泡,另一方面用电泳     

香菇和侧耳属间原生质体的电融合研究

从培养在液体培养基中的香菇、美味侧耳和平菇的单核菌丝用酶法分离了原生质体。施加0.5MHz、500PV/cm的正弦波和μs、6000PV/cm方形脉冲的电场诱导下使其电融合。电融合后的融合子和原生质体在固体培养基上植板培养成菌落。在显微镜下检查融合子菌株菌丝的锁状联合选出从融合子长成的菌株。香菇和美味侧耳的融合菌株产生频率为61.53%,香菇和平菇的融合菌株产生频率为32.58%。根据融合菌株与亲本的拮抗作用和他们的过氧化物同工酶和酯酶同工酶的电泳酶谱与其亲本酶谱的不同,证实这些融合菌株是从融合的异核体生长成的。同时讨论了电融合方法和结果。     

普通番茄叶肉原生质体和多毛番茄茎尖原生质体的电融合

普通番茄叶肉原生质体和多毛番茄茎尖原生质体在一交变电场中(正弦波;1mHz,200v/cm)可发生双向电泳而随机排列成串。再附加单个直流方波脉冲,可诱导相邻原生质体的融合,适宜的融合脉宽为40μs,电压幅度为3000v/cm。最高融合率可达57%。培养经电融合处理的原生质体,观察到了少数原生质体的第1次分裂。     

利用微秒和微纳秒脉冲电场诱导细胞融合

[目的]以小鼠骨髓瘤(SP2/0)细胞作为实验材料,比较了SP2/0细胞在不同微秒(μs)脉冲和微纳秒(μs/ns)复合脉冲电融合的细胞存活率和融合率,并确定了最优的μs/ns复合脉冲电融合参数。[方法]将SP2/0细胞分别用Hoechst 33342和碘化丙啶(PI)进行染色,分别选取3组μs脉冲和3组μs/ns复合脉冲对染色后的SP2/0细胞进行电融合,通过荧光显微镜观察融合后细胞的存活率和融合率。[结果]对比不同μs和μs/ns复合脉冲电融合存活率和融合率结果得知,μs/ns复合脉冲比μs脉冲电融合效果更好,且电融合参数为2. 5 k V/cm、20μs、1次,10 k V/cm、200 ns、8次时存活率和融合效率相对最好,存活率和融合率分别为88. 5%±6. 2%和80. 1%±2. 6%。[结论]通过采用不同μs和μs/ns复合脉冲电融合比较了SP2/0细胞的存活率和融合效率,结果显示μs/ns复合脉冲电融合参数在2. 5 k V/cm、20μs、1次,10 k V/cm、200 ns、8次时,存活率比μs脉冲电融合提高6. 4%,融合率提高23. 3%,为利用μs/ns复合脉冲研究杂交瘤细胞电融合奠定了基础。     

基于微电极阵列的微生物电融合

利用自主研制的梳状交叉微电极阵列细胞电融合芯片系统,研究微生物电融合。在酶解浓度1．5％、酶解温度33℃、酶解时间3h、酶解pH值6．0、0．8mol／L山梨醇的渗透压条件下,获得生成率和再生率分别为95．2％和8．9％的微生物细胞原生质体。在脉冲峰值电压50V、持续时间80μs、8个脉冲、间隔1s的电融合条件下,该原生质体通过电融合获得一株菌株其乳化性能从62％提高到85％。     

水稻原生质体电融合时的参数选择（简报）

水稻（0862和台北309）原生质体电融合最佳条件是交流电场强度250V／cm,频率600kHz;高压直流脉冲幅值1．65kV／cm,脉冲持续时间50μs,脉冲间隔时间3．0S。融合率最高可达275％．在上述条件下,电场处理基本不影响原生质体的活力。     

小麦与多年生黑麦草原生质体的电融合及杂种愈伤组织的形成

多年生黑麦草(Lolium perenne L.)悬浮培养细胞来源的原生质体和小麦(Triticumaestivum L.)含叶绿体的悬浮培养细胞来源的原生质体间,用直流方波脉冲进行电融合,获得了体细胞杂种愈伤组织。小麦的原生质体经过碘乙酰胺失活。愈伤组织的形态和颜色被用作识别预期杂种的标记。为了对杂种愈伤组织进行同工酶分析,观察了亲本的9种同工酶谱,其中3种在亲本间表现出差异(ADH、GOT 和 SDH)。酒精脱氢酶(ADH)的分析结果表明,有6个细胞系表现出杂种带。这些细胞系经过其他两种同工酶分析和 rDNA 探针杂交试验表明,一个细胞系表现出基本完全的亲本基因组间的组合,其余5个细胞系是部分杂种。     

空间电融合的烟草原生质体再生植株分析

报告了在"神舟四号"飞船中通过电融合获得的烟草融合细胞,经地面培养获得再生植株。空间飞行样品再生愈伤组织的频率为地面对照的3倍多,而植株再生频率却比地面对照约低20%,约有32%的再生植株可能具有杂种性状。选取叶形状变化最为明显的H23号植株与黄花品种进行回交,回交一代的叶比原始材料宽,花的颜色与亲本黄花品种相同,表明空间微重力环境中融合的烟草原生质体能够再生植株,获得有繁殖能力的杂种。     

蚕豆叶肉原生质体电融合的研究

本文研究了蚕豆叶肉原生质体经透明质酸酶、核糖核酸酶、神经氨酸酶、碱性磷酸酶、胰蛋白酶、脂肪酶六种水解酶和SDS、Triton X-100、CTMAB三种表面活性剂以及秋水仙素、细胞松驰素B处理后的电融合过程。结果表明:胰蛋白酶处理后的原生质体融合率明显下降;碱性磷酸酶、脂肪酶以及核糖核酸酶、透明质酸酶、神经氨酸酶处理的原生质体电融合率均有不同程度的上升。Triton X-100和CTMAB促进原生质体的电融合,但较高浓度(0.01%)的SDS起抑制作用。秋水仙素和细胞松驰素B处理的原生质体其电融合率有较大幅度的增高。     

细胞电融合技术及最新进展

细胞电融合（cell electrofusion）是一种发展迅速的细胞工程技术,在细胞融合研究领域得到了最广泛的应用。细胞电融合利用细胞在相对电极之间的介电电泳,诱导细胞按特定方向排列,通过电极间产生的较高场强的电脉冲使相互接触的细胞发生电穿孔,进而发生电融合。融合后的细胞得到了不同细胞的遗传物质,具有新的遗传或生物特性。目前,细胞电融合技术对生物医学、农业等相关领域的研究具有非常重要的意义。本文介绍了细胞电融合技术及其最新研究动态,并简单介绍了本实验室在该领域的研究进展。     

Facilitated electrofusion of vacuolated x evacuolated oat mesophyll protoplasts in hypo-osmolar media after alignment with an alternating field of modulated strength

Electrofusion of evacuolated and vacuolated oat leaf protoplasts is difficult because of the different size and density of these cells which results in separation of the two fusion partners during dielectrophoresis. The fusion yield of this cell system was considerably enhanced by electrofusion in hypo-osmolar media containing 0.4 M mannitol, 0.1 mM calcium acetate and 0.1% bovine serum albumin. This increase in yield was only achieved if the dielectrophoretically induced membrane contact between the two fusion partners was enhanced by an initial short 'burst' of higher field strength (500 V/cm, peak to peak, for 5 s followed by a reduction of to 90 V/cm, peak to peak, for 20 s, frequency 1 MHz). Due to the high field strength of the alternating field at the beginning of cell chain formation separation of fusion partners of different size and density was mainly avoided. Simultaneously, the short duration of this high field 'burst' avoided the generation of lethal effects in the cell membranes. The subsequent low field strength of the alternating field was sufficient to keep the aligned cells in position. Optimum fusion was induced by a single square pulse of 750 V/cm and 30 musec duration. The time required for rounding up of the heterologous fusion products decreased with decreasing osmolarity. Fusion resulted in a 5.7 +/- 1.2% yield of heterologous fusion products (compared to 0.7% using the conventional electrofusion protocol) as determined by flow cytometric assay. About 50% of the vacuolated oat protoplasts and 20-50% of the heterologous fusion products regenerated their cell walls within 5 days after hypo-osmolar treatment, but no cell divisions could be observed. Evacuolated oat protoplasts died after 2-3 days in culture without any detectable cell wall regeneration.     

Optimization of Electrofusion Parameters and Interspecific Somatic Hybrid Regeneration in Citrus

This study was primarily attempted to optimize the electrofusion parameters using protoplasts isolated from cell suspension cultures of "Page" tangelo ( Citrus reticulata Blanco x C. paradisi Macf) and mesophyll protoplasts of rough lemon ( Citrus jambhiri Lush) as fusion partners. It was shown that the binuclear heterokaryons frequency reached 15% with the following parameters: alternate current (AC) 125 V/cm, AC time 60 s, direct current (DC) 1 250 V/cm, DC pulse width 50 μs, DC pulse interval O. 5 s, No. of DC pulse 3. Considering the fact that different types of protoplasts have different specific weights, higher frequency of the binuclear heterokaryons was obtained by controlling the centrifugation time after fusion. The fusion products regenerated into plantlets after 3 to 4 months of culture. Chromosome counting of the root tips and morphological observation of the regenerants verified that 78% were tetraploids and the rest were diploids with the leaf morphology of mesophyll parent. Peroxidase (POX) isozyme and RAPD analysis indicated that interspecific somatic hybrids were obtained and an autotetraploid plant of mesophyll parent type was also verified.     

Quantitative studies on the viability of yeast protoplasts following dielectrophoresis

Abstract Protoplasts from Saccharomyces cerevisiae and Saccharomyces diastaticus were collected in a non-homogeneous alternating electric field. The dependence of the viability of the protoplasts on different conditions of collection was tested by determining the regeneration rates in each case. The parameters varied in collection were the field strength (0.33 kV/cm–6.67 kV/cm), the frequency of the alternating field (1–2 MHz) and the collection time (2–10 min). The introduction of a new type of fusion chamber (meander chamber) permitted, for the first time, quantitative exposure of protoplasts to the electric field as well as their complete transference into the regeneration medium. The regeneration rates of yeast protoplasts collected under those conditions employed for electrofusion did not differ from those of protoplasts which had been maintained under the same experimental conditions but were not subject to the influence of an alternating electric field. The two yeast strains were fused together (collection 1 kV/cm; pulse 15 kV/cm; duration of pulse 40 μs) and the fusion products were introduced into a selection medium for regeneration. The fusion rate was about 4.8 × 10⁻⁴; on average 272 colonies grew on the selection medium for each chamber filling.     

Modulation and direction of the electrofusion response in plant protoplasts

In experiments on electrofusion of protoplasts (from Solanum brevidens, S. tuberosum, Nicotiana plumbaginifolia) the presence of divalent cations (Ca²⁺) at 1 mM in the fusion medium was found to increase the yield of hybrids observed directly after fusion and decrease the duration of pulse needed for fusion. Pretreatment of protoplasts with the polyamine spermine also enhanced fusion yield, and when combined with 1 mM Ca²⁺ the effects were additive. The improvement in fusion yield (2–4 fold) was most marked for protoplast populations (e.g. from suspension cultured cells) that were least responsive to electrofusion in mannitol alone. Short term viability, judged from FDA fluorescence was found to be high at these increased fusion levels. Optimum fusion parameters for electrofusion thus may be determined from short term experiments. Attempts to direct to fusion response between populations of protoplasts of identical properties by pretreatment of one fusion partner with spermine were inconclusive.     

Determination of physical membrane properties of plant cell protoplasts via the electrofusion technique: prediction of optimal fusion yields and protoplast viability

By variation of physical parameters (field strength, pulse duration) which result in electrofusion and electroporation, properties of the plasma membrane of different types of plant cell protoplasts were analyzed. The lower threshold for that field pulse intensity at which membrane breakdown occurred (recorded as fusion event) depended on pulse duration, protoplast size, and protoplast type (tobacco, oat; vacuolated, evacuolated). This fusion characteristic of plant protoplasts can also be taken as a measure of the charging process of the membrane and allows thus a non-invasive determination of the time constant and the specific membrane capacitance. Although the fusion yield was comparable at pulse duration/field strength couples of, e.g., 10 s/1.5 kV*cm^–1 and 200 s/0.5 kV*cm^–1, hybrid viability was not. Rates of cell wall regeneration and cell division of tobacco mesophyll protoplasts were not affected but may have been increased at short pulse duration/high field strength. Plating efficiency, in contrast, was significantly decreased with longer pulse duration at low field strengths.     

Fusion characteristics of plant protoplasts in electric fields

The electrical parameters important in the fusion of plant protoplasts aligned dielectrophoretically in high-frequency alternating electric fields have been established. Protoplasts were aligned in an alternating electric field between two relatively distant (1 mm) electrodes, by dielectrophoresis induced by field inhomogeneities caused by the protoplasts themselves. This arrangement allowed ease of manipulations, large throughput and low loss of protoplasts. In analytical experiments, sufficiently large samples could be used to study pulse duration-fusion response relations at different pulse voltages for protoplasts of different species, tissues and size (mesophyll protoplasts of Solanum brevidens, Triticum aestivum, Hordeum vulgare; suspension-culture protoplasts of Nicotiana sylvestris, N. rustica, Datura innoxia and S. brevidens; root-tip protoplasts of Vicia faba, hypocotyl protoplasts of Brassica napus). The percentage of aligned protoplasts that fused increased with increasing pulse parameters (pulse duration; voltage) above a threshold that was dependant on pulse voltage. The maximum fusion values obtained depended on a number of factors including protoplast origin, size and chain length. Leaf mesophyll protoplasts fused much more readily than suspension-culture protoplasts. For both types, there was a correlation of size with fusion yield: large protoplasts tended to fuse more readily than small protoplasts. In short chains (five protoplasts), fusion frequency was lower, but the proportion of one-to-one products was greater than in long chains (ten protoplasts). In formation by electrofusion of heterokaryons between mesophyll and suspension-culture protoplasts, the fusion-frequency response curves reflected those of homofusion of mesophyll protoplasts rather than suspension-culture protoplasts. There was no apparent limitation to the fusion of the smallest mesophyll protoplast with the largest suspension-culture protoplasts. Based on these observations, it is possible to direct fusion towards a higher frequency of one-to-one (mesophyll/suspension) products by incorporating low densities of mesophyll protoplasts in high densities of suspensionculture protoplasts and by using a short fusion pulse. The viability of fusion products, assessed by staining with fluorescein diacetate, was not impaired by standard fusion conditions. On a preparative scale, heterokaryons (S. brevidens mesophyll-N. sylvestris or D. innoxia suspension-culture) were produced by electrofusion and cultured in liquid or embedded in agar, and were capable of wall formation, division and growth. It is concluded that the electrode arrangement described is more suitable for carrying out directed fusions of plant protoplasts than that employing closer electrodes.     

Fungal protoplast fusion – a revisit

Protoplast fusion is a non-specific recombination technique used for transfer of cytosolic organelles including genetic material. The process involves cell wall breakdown, regeneration of protoplasts, chemofusion and electrofusion. This review article discusses all the stages involved in fusion of protoplasts and some of the applications of protoplast fusion technique in fungal systems.     

Factors affecting protoplast electrofusion efficiency

The electrofusion efficiency of protoplasts isolated from a carrot (Daucus carota) suspension culture was increased by treatment with 0.1 mg/ml lysolecithin, 2.5% dimethylsulfoxide (DMSO), or 0.5 mM Ca²⁺. The lysolecithin and DMSO treatments substantially increased protoplast lysis, whereas calcium treatment did not. The enzymes used for protoplast isolation were also found to have a dramatic effect on the efficiency of fusion. A mixture of Cellulysin and Driselase led to a two-fold enhancement of fusion as compared with Driselase alone. The stimulation by Cellulysin appears to be due to enzymatic modification of the cell surface. However, comparison of the time course for wall digestion with the development of susceptibility to electrofusion suggests that the effect of Cellulysin is not simply due to removal of the cell wall. Brief treatment of the cells with pronase or proteinase K also doubled the efficiency of fusion. Taken together, these results indicate that electrofusion efficiency can be enhanced by the method used for protoplast isolation; they also suggest that modification of membrane/cell-surface proteins during protoplast isolation may be particularly important in determining electrofusion efficiencies.Abbreviations a.c. alternating current - d.c. direct current - DMSO dimethylsulfoxide - NAA naphthaleneacetic acid - PEG polyethylene glycol     

Behavior and viability of tobacco protoplasts in response to electrofusion parameters

This investigation examines responses of protoplasts in a systematic and quantitative way to the various electrical treatments used to achieve electrofusion and their individual and cumulative effect on protoplast viability. Mesophyll and cell suspension protoplasts from two species of the same genera, Nicotiana tabacum and N. rustica var brasilia were used in these experiments. Optimal frequencies for alignment of tobacco protoplasts were between 500 kilohertz and 2 megahertz at 100 volts per centimeter. Variations in frequency and voltage of the alternating current (AC) field caused predictable movements of protoplasts within an electrofusion chamber. AC frequencies below 10 hertz or above 5 megahertz significantly decreased the viability of protoplasts in the fusion chamber as estimated by fluorescein diacetate staining 1 hour after treatment. Although the direct current (DC) pulse appeared to have a slight detrimental effect on protoplast viability, this effect was not significantly different from untreated control preparations.

Protoplasts from both leaf mesophyll cells and suspension cells were induced to fuse with one or more 10 to 30 microseconds DC square wave pulses of approximately 1 kilovolt per centimeter after the protoplasts had been closely appressed with an AC field.

     

Intensification of lipase biosynthesis as a result of electrofusion of Rhizopus cohnii protoplasts

Our objective was to obtain products of fusion of the filamentous fungus Rhizopus cohnii Rh.c./1 with an increased capacity for lipase biosynthesis in comparison with the original strain. Protoplasts of auxotrophic mutants of the parent strain Rh.c./1 obtained after UV irradiation of the spores were subjected to electrofusion. We found that the largest number of electrofusion products could be obtained with the use of the following process parameters: 1 or 2 impulses immediately following one another with a field intensity of 200 V/cm and an exposition time of 1000 ms at the stage of dielectrophoresis, 1 impulse with a field intensity of 500 V/cm and an exposition time of 10 ms or 20 ms at the stage of fusion, regulated temperature of 4 degrees C before and after the process, rounding time of ca 20 min. Electrofusion of protoplasts of auxotrophic mutants of the Rh.c./1 strain produced 19 fusion products whose lipase biosynthesis capacity in a liquid medium culture was higher than that of the parent strains. The fusion product labelled XIII-21 was selected as the best strain. Lipase activity obtained after its culture in the liquid medium was ca 3.5 times higher than that obtained after the culture of the original strain Rh.c./1.