绵羊胎儿成纤维细胞体外培养及转基因研究

目的用增强型绿色荧光蛋白(EGFP)基因转染体外培养绵羊胎儿成纤维细胞,探讨绿色荧光蛋白对绵羊胎儿成纤维细胞生物学特性的影响.方法体外分离培养绵羊胎儿成纤维细胞,经脂质体介导EGFP基因转染第一代成纤维细胞,G418筛选10～12*!d,挑选转基因单克隆细胞,传代培养,进行细胞形态观察、生长曲线以及染色体核型分析,并进行了培养细胞性别鉴定.结果整合有EGFP基因的绵羊胎儿成纤维细胞生物学行为与未转染外源基因的细胞无明显差别,根据荧光强度可直接反应外源基因的表达量.结论 EGFP基因作为体内报告基因可用于转基因细胞的研究,并将整合有EGFP基因的转基因细胞为克隆动物提供核供体奠定了基础.     

东方田鼠胚胎成纤维细胞永生化细胞系的建立

目的建立东方田鼠胚胎成纤维永生化细胞系,为全面研究东方田鼠抗日本血吸虫机制以及开展不同动物成纤维细胞间比较研究奠定基础和提供细胞实验材料。方法运用脂质体介导的基因转染法将pSV3neo质粒导入第3代东方田鼠胚胎成纤维细胞,经G418筛选抗性克隆并扩大培养,建立永生化细胞系;用PCR检测细胞株中SV40T基因的整合,RT-PCR鉴定SV40T基因在转染细胞中的表达;绘制东方田鼠胚胎成纤维永生化细胞生长曲线。结果阳性细胞克隆已扩大培养并稳定传代50代,经鉴定SV40T抗原已整合到东方田鼠胚胎成纤维细胞中且稳定表达。结论成功建立东方田鼠胚胎成纤维永生化细胞系。     

小鼠KGF基因毛囊特异性表达载体的构建及mESC脂质体悬浮转染条件的优化

旨在构建小鼠角质细胞生长因子(KGF)真核表达载体pCDsR-UKA,通过脂质体转染法转染小鼠胚胎干细胞( mESC),并进一步优化其转染条件,最终获得可以正常生长并稳定表达红色荧光蛋白的转KGF基因的ES细胞.利用RTPCR技术扩增小鼠KGF基因cDNA并构建表达载体pCDsR-UKA (6.6 kb),经鉴定正确的重组质粒DNA用脂质体包裹后转染mESC.从小鼠成纤维细胞cDNA扩增出891 bp的KGF基因片段与UHS启动子和BGH polyA序列成功重组到pCDsRed2载体中.经酶切和DNA测序验证,插入载体的DNA片段为KGF基因且方向正确.采用脂质体法优化转染条件,mESC最高转染效率达到(34.4±4.1)％.经G418筛选的转基因ES细胞通过PCR鉴定证实外源基因已整合在ES细胞基因组中.成功获得了小鼠KGF基因片段,以及真核表达载体pCDsR-UKA,经优化的脂质体悬浮法转染条件,在六孔板中当DNA与脂质体比例为3:10时,可获得最佳转染效率且不改变ES细胞的生长状态,经筛选获得了转基因ES细胞克隆.为下一步通过四倍体补偿技术获得ES小鼠提供了转基因ES细胞.     

癌基因EJ－ras在小鼠胚胎干细胞（ES－5）中的表达及其对ES－5细胞一些特征的影响

转基因动物在研究基因的功能、医药、畜牧业等方面有重要的应用。利用胚胎干细胞（ＥＳ）制作转基因动物,比传统的显微注射法有无可比拟的优点。但是,目前、只在小鼠中建立起了ＥＳ细胞系,在其它哺乳动物（包括家畜）中尚未建成。近来,人们开始探索：改变胚胎细胞的遗传物质（如：把外源基因导入胚胎细胞）是否有利于获得ＥＳ细胞系．在各种外源基因中,癌基因是值得尝试的基因。因为：（１）ＥＳ细胞的建系是使胚胎的ＩＣＭ细胞永生化的过程;（２）在体外利用癌基因转染可使许多原代培养细胞永生化;（３）ＥＳ细胞高表达一些原癌基因。我们用癌基因ＥＪ－ｒａｓ转染小鼠ＥＳ细胞,观察其对ＥＳ－５细胞一些特性（增殖、嵌合能力）的影响,以便选择合适的癌基因用于家畜ＥＳ细胞的建系。ＥＳ－５细胞通常培养在丝裂霉素处理的小鼠胚胎成纤维细胞（ＭＥＦ）上（Ｆｉｇ．Ａ）。转染用ＥＳ－５细胞培养在无饲养层细胞的、含有大鼠肝细胞（ＢＲＬ）的条件培养液ＤＭＥＭ中。ＥＪ－ｒａｓ基因克隆在真核表达载体ＰＳＶ２ｎｅｏ的ＢａｍＨＩ位点上、使用磷酸钙法转染ＥＳ－５细胞,Ｇ－４１８法筛选阳性克隆,得到的抗性克隆仍以集落形式生长（Ｆｉｇ．Ｂ）,选取５个较好的克隆（ＥＳ－ｒａｓ１,２,     

外源基因转染山羊体细胞的整合效率研究

为了探讨影响山羊体细胞中外源基因整合效率的因素,采集胎羊和小羊皮肤并制备成纤维细胞,采用"Lipofectamine LTX"脂质体转染试剂包埋外源基因,分别导入上述细胞中,比较同一种外源基因载体(人凝血因子Ⅸ)转染至不同个体和类型的羊细胞,以及不同载体(人凝血因子Ⅸ、人转铁蛋白和牛催乳素)转染至同一个体羊细胞的整合效率的差异.通过药物筛选得到单细胞簇,经定量PCR计算外源基因的整合效率.同一种外源目的基因载体转染小羊成纤维细胞的整合效率显著高于胎羊成纤维细胞(P<0.05);而不同目的基因载体转染同一个体羊细胞,其细胞的整合效率与转染载体的片段大小有关.由此可知,小羊成纤维细胞外源基因整合频率优于胎羊细胞,且载体片段的大小影响外源基因转染的整合频率.     

长江江豚脐带永生化成纤维细胞系建立及细胞生长特性研究

取长江江豚(Neophocaena phocaenoids asiaeorientalis)产后胎盘脐静脉, 经组织块培养, 差异贴壁法纯化, 构建长江江豚的原代细胞系; 经外源癌基因SV40 T antigens（猿猴病毒T抗原）转染构建稳定脐带细胞系, 并对长江江豚的永生化后的成纤维细胞的细胞形态、转染效率、生长曲线和活率等进行探究。结果表明: (1)原代脐静脉细胞大约14d从组织边缘分离, 20d形成单层, 细胞呈现典型的成纤维细胞状, 梭形、不规则星行或多边形。原代细胞传代14代后出现老化和凋亡。(2)通过SV40 T antigens转染构建的细胞系可传代40—50次, 证实转染SV40 T antigens后可增加细胞的增殖能力。(3)不同世代永生化的成纤维细胞复苏前后细胞活性并无明显差异, 复苏细胞活性在90%以上, 表明永生化后的细胞可以稳定保存。利用CCK-8法测得细胞的生长曲线呈现“S”型。(4)对永生化的细胞系进行后续基因表达尝试, 通过转染外源基因绿色和红色荧光蛋白, 转染外来质粒效率约为15%, 说明外源基因可以表达, 并能被成功检测。研究构建长江江豚的脐静脉来源的永生化后细胞系, 为江豚的其他组织细胞系建立以及江豚细胞库的建立提供基础, 成功对永生化后的细胞系进行外源基因的转染, 为以后深入长江江豚相关基因和分子机制研究打下基础。     

EphA3基因稳定表达细胞模型的建立与分析

目的：建立稳定表达外源EphA3基因的小鼠成纤维细胞株模型,初步探讨EphA3基因表达对肿瘤发生、发展的影响。方法：通过脂质体介导的方法,将真核表达载体pcDNA3.1（-）/myc-his-EphA3转染NIH3T3细胞,用Western印迹确定外源EphA3基因表达;通过MTT实验、软琼脂集落形成实验,观察EphA3基因表达对NIH3T3细胞生物学特性的影响。结果：建立了稳定转染EphA3基因的NIH3T3细胞株;EphA3基因表达的小鼠成纤维NIH3T3细胞生长速度没有明显变化,但在软琼脂上锚着非依赖生长的能力加强。结论：建立了稳定表达外源EphA3基因的NIH3T3细胞株,EphA3基因稳定表达具有诱导正常NIH3T3细胞发生恶性转化的重要生物功能。     

西藏小型猪胚胎成纤维细胞的分离培养及性别鉴定

目的探索和建立西藏小型猪胚胎成纤维细胞体外分离培养及性别鉴定的技术方法。方法取35d的西藏小型猪胚胎分离胚胎成纤维细胞,进行体外原代培养及传代培养,观察细胞成纤维细胞的形态和生长状况。根据猪Y染色体上性别决定基因SRY设计引物进行性别鉴定,同时以β珠蛋白作为内参基因,建立PCR反应体系鉴别胚胎的性别。结果西藏小型猪胚胎成纤维体外分离后,呈贴壁生长,快速增殖。PCR性别鉴定结果表明雄性胚胎细胞可扩增出一特异性SRY基因条带,而雌性则没有。该法可快速鉴定胚胎的性别,可用于体细胞克隆动物早期性别鉴定。结论研究结果表明利用胶原酶消化法所获得的西藏小型猪胚胎成纤维细胞可在体外稳定培养并传代,利用PCR鉴定猪胎儿性别具有简单、快速、准确的特点,可应用于克隆猪研究中体细胞系的早期性别鉴定。     

借助慢病毒将EGFP基因导入西藏小型猪胎儿成纤维细胞

目的借助慢病毒将EGFP基因导入西藏小型猪胎儿成纤维细胞（porcine embryonic fibroblasts,PEFs）,以基于PEFs建立慢病毒介导的外源基因体外投递系统。方法取35d西藏小型猪胚胎,酶消化法分离培养西藏小型猪的PEFs;按Invitrogen公司推荐的标准程序进行慢病毒（携带EGFP基因）包装（脂质体介导的瞬时转染）,随后用病毒上清感染PEFs,24～48h后荧光显微镜下观察是否见绿色荧光以证实慢病毒是否成功生产和成功感染PEFs。结果成功分离培养西藏小型猪的PEFs,按标准程序生产的携带EGFP基因慢病毒高效率感染西藏小型猪的PEFs。结论针对西藏小型猪的PEFs建立了相应的慢病毒介导的外源基因体外投递系统,为相关后续研究打下了良好基础。     

构建LEF1基因毛囊特异表达载体并稳定转染胎儿成纤维细胞

旨在构建内蒙古白绒山羊(Capra hircus)淋巴样增强因子-1(Lymphoid enhancer factor,LEF1)基因真核表达载体并转染胎儿成纤维细胞,获得稳定表达红色荧光蛋白及毛囊特异性表达LEF1的转基因细胞克隆。以pCDsRed2载体为基本骨架将LEF1基因亚克隆到KAP6-1启动子下游,连接红色荧光蛋白表达元件,构建LEF1基因毛囊特异表达载体pCDsRed-KL。外源表达载体以lipofectamineTM2000介导转染胎儿成纤维细胞,通过G418筛选获得稳定转染的细胞克隆。PCR鉴定外源基因在细胞基因组中的整合。测序显示构建的表达载体pCDsRed-KL序列中,LEF1基因正确连接在KAP6-1启动子下游,顺序连接CMV启动子和红色荧光蛋白基因,载体构建正确。脂质体介导的稳定转染效率约为14.0%,经G418筛选得到高效表达红色荧光蛋白转基因细胞克隆。PCR检测显示外源KAP6-1启动子和LEF1基因整合到胎儿成纤维细胞基因组中。     

Embryo rescue inVicia faba andVicia narbonensis

Embryo rescue in twoVicia faba L. cultivars (‘Polycarpe’ and ‘A-107’) and oneV. narbonensis L. population (A-202) was studied under a 22 ± 2°C/ 16 ± 1° day/night temperature regime. Very young ovules (1.0–1.8 mm long) cultured, in-ovule, on five liquid media remained green for a longer period of time on modified B5, modified Murashige and Skoog and modified Beasley and Ting media than on modified Phillips and Collins and modified Bourgin and Nitsch media. However, no embryo growth or embryo germination was observed. In-ovule culture of older ovules, 6 and 8 days forV. narbonensis and 10 and 14 days forV. faba, on modified B5 liquid medium allowed 6-day-oldV. narbonensis and 14-day-oldV. faba embryos to be rescued. Finally, culture of whole pods of the two species resulted in the rescue of even younger embryos. Thus, plantlets were obtained from as young as 4-day-oldV. narbonensis pods and 11-day-oldV. faba pods.     

二十世纪我国植物学家对植物组织培养的贡献

回顾了上一世纪我国植物组织培养的发展.1934年以来,我国的植物组织培养研究一直与国际发展同步进行.我国学者在离体器官发生、茎尖培养、花药培养、子房培养、胚乳培养、原生质体培养和细胞大量培养等分支领域都取得重要进展.本文在引证我国研究者发表的植物组织培养论文的基础上,着重评述了那些被国际同行公认的研究成果.此外,还介绍了植物组织培养在我国农业和工业上应用的情况.     

二十世纪我国植物学家对植物组织培养的贡献

回顾了上一世纪我国植物组织培养的发展。 1934年以来 ,我国的植物组织培养研究一直与国际发展同步进行。我国学者在离体器官发生、茎尖培养、花药培养、子房培养、胚乳培养、原生质体培养和细胞大量培养等分支领域都取得重要进展。本文在引证我国研究者发表的植物组织培养论文的基础上 ,着重评述了那些被国际同行公认的研究成果。此外 ,还介绍了植物组织培养在我国农业和工业上应用的情况     

猪苓、伴生菌及蜜环菌共培养的形态学研究

本文对猪苓、伴生菌及蜜环菌两两共培养及三者共培养进行了宏观形态观察及细胞学水平上的研究。结果表明,猪苓与伴生菌共培养时,在二者之间形成一致密拮抗线,猪苓菌落表面菌丝分化产生大量菌丝束;猪苓与蜜环菌共培养时,猪苓能阻止蜜环菌菌索对其自身的进一步侵袭,互作区中的双方菌丝及菌索均停止生长;蜜环菌与伴生菌共培养时,蜜环菌能穿透整个伴生菌菌落,在伴生菌菌落下方产生大量分枝;三者共培养后,猪苓对蜜环菌的防御能力有所下降,伴生菌对蜜环菌的耐受力有所提高,蜜环菌产生的新分枝均向伴生菌一侧生长,猪苓与伴生菌之间并不形成致密拮抗线,只可见双方菌丝的白色交融区。 猪苓与伴生菌均能在蜜环菌菌索皮层上形成侵入位点。     

荔枝生物技术研究进展（综述）

从荔枝的组织培养、花药培养和原生质体培养方面综述荔枝生物技术的研究概况,并提出该领域存在问题及发展方向。     

Tapping culture-an improved method for cell suspension culture

Summary A new culture vessel was designed for cell suspension culture. A silicone-convered magnet bar fixed by one end to the side wall of the bottle was held horizontally a short distance from the bottom. A standard type magnetic stirrer was used. In contrast to the conventional horizontal movement of “stirring” in cultures the bar moves vertically with a “tapping” motion. This improvement resulted in less cell injury, higher rate of cell proliferation and formation of fewer bubbles than in the conventional type. Nine cell types were simultaneously cultivated in tapping, stirring and stationary culture. All cell types proliferated more luxuriously in tapping cultures than in stirring cultures. Serial cultivation of cells in tapping cultures was also successful. This work was supported in part by the grants for Cancer Research from the Ministry of Education, Science and Culture, Japan.     

Light requirement and photosynthetic cell cultivation – Development of processes for efficient light utilization in photobioreactors

Although the potential of photosyntheticmicroorganisms for production of various metabolitesand in environmental bioremediation is recognized,their practical application has been limited by thedifficulty in supplying light efficiently tophotobioreactors. Various types of photobioreactorwith high illumination to volume ratios have beenproposed, but most are limited by cost, mass transfer,contamination, scale-up or a combination of these.The problem of light supply to photobioreactorscan be solved by developing photosynthetic cellcultivation systems where light is either substitutedor supplemented. Many strains of photosynthetic cellsare capable of heterotrophic growth under darkconditions and their heterotrophic culture can be usedfor efficient production of biomass and somemetabolites. However, light is absolutely required forefficient production of some metabolites. In suchcases, there is a need to supplement the heterotrophicwith photoautotrophic metabolism. Inphotoheterotrophic (mixotrophic) culture, thephotoautotrophic and heterotrophic metabolisms can beexploited for efficient production of usefulmetabolites but it has many problems such as processoptimization in terms of making a balance between thephotoautotrophic and heterotrophic metabolism. Another promising system is the sequentialheterotrophic/ photoautotrophic cultivation system,where the cells are cultivated heterotrophically tohigh concentrations and then passed through aphotobioreactor for accumulation of the desiredmetabolite(s). Furthermore, cyclicphotoautotrophic/heterotrophic cultivation system canbe used to achieve continuous cell growth underday/night cycles. This involves cultivating thecells photoautotrophically using solar light duringthe day and then adding controlled amount of organiccarbon source during the night for heterotrophicgrowth. In this review, these various systems arediscussed with some specific examples.     

Technology for cell cycle research with unstressed steady-state cultures

A culture system for performing cell cycle analyses on cells in undisturbed steady-state populations was designed and tested. In this system, newborn cells are shed continuously from an immobilized, perfused culture rotating about the horizontal axis. As a result of this arrangement, the number of newborn cells released into the effluent medium each generation is identical to the number of cells residing in the immobilized population, indicating that one of the two new daughter cells is shed at each cell division. Thus, the immobilized cells constitute a continuous, steady-state culture because the concentrations, locations and microenvironments of the cells in the culture vessel do not vary with time. In tests with mouse L1210 lymphocytic leukemia cells, about 10⁸ newborn cells were produced per day. This new culture system enables a multiplicity of cell cycle analyses on large numbers of cells assured to be from populations in steady-state growth.

A simple device for planting replicate mammalian cell cultures

Summary The design and use of a unit for planting uniform inocula for replicate cultures are described. Its design permits continuous gassing of suspensions of mammalian cells with humidified CO₂, thus stabilizing the pH (±<0.05 pH unit) of culture media buffered with sodium bicarbonate. The unit can be readily modified to deliver different volumes; identical samples can be dispensed simply and rapidly, with minimal cell damage and chance of microbial contamination. Quantitative data regarding sample uniformity and growth subsequent to planting with this unit are presented.     

A simple device for planting replicate mammalian cell cultures

Summary The design and use of a unit for planting uniform inocula for replicate cultures are described. Its design permits continuous gassing of suspensions of mammalian cells with humidified CO₂, thus stabilizing the pH (±<0.05 pH unit) of culture media buffered with sodium bicarbonate. The unit can be readily modified to deliver different volumes; identical samples can be dispensed simply and rapidly, with minimal cell damage and chance of microbial contamination. Quantitative data regarding sample uniformity and growth subsequent to planting with this unit are presented.