血清饥饿、汇合培养及放线菌酮对奶牛成纤维细胞周期的影响

在动物克隆研究中,研究者普遍认为位于细胞周期的G0+G1期的二倍体细胞对于核移植中供核细胞的重新程序化是必需的。本文探讨了血清饥饿、汇合培养及放线菌酮（CHX）处理对不同传代次数的体外培养奶牛成纤维细胞周期分布的影响。流式细胞仪分析结果显示：第3代和第13代细胞经血清饥饿处理72h后,细胞周期分布与对照差异显著(P<0.05);汇合培养可以显著增加奶牛成纤维细胞处于G0+G1期细胞数。CHX处理第3代细胞经CHX处理后处于G0+G1期的细胞数差异不显著,而第13代细胞处理后差异显著。结果表明体外培养奶牛成纤维细胞高代对血清饥饿、汇合培养及CHX处理更敏感。     

体细胞来源及培养代数对核移植重构胚发育的影响

为探讨体细胞来源及培养代数对核移植重构胚发育的影响,实验采用电融合法将小鼠2—细胞胚胎卵裂球、胚胎干细胞(ES)、胎儿成纤维细胞、耳成纤维细胞、尾尖成纤维细胞、睾丸支持细胞和精原细胞以及不同培养代次的胎儿成纤维细胞进行了核移植。结果显示：2—细胞胚胎卵裂球供核重构胚发育最好,囊胚率为7．4％;ES细胞重构胚虽然发育率低,但仍有囊胚出现,比例为0．7％;胎儿成纤维细胞重构胚最高发育阶段为桑椹胚,比例为0．2％;精原细胞重构胚只能发育到8-细胞阶段,比例为0．3％;其他几类细胞重构胚则仅能发育至4-细胞阶段。不同培养代数的胎儿成纤维细胞重构胚除第3代外都可发育到8-细胞阶段,且发育率差异不显著,但第一代细胞重构胚2-细胞发育率(40．7％)显著低于2、3和4代细胞重构胚。结果表明：不同分化程度的细胞核移植后,重新编程的难易程度是不一样的,分化程度越高则重新编程越难;未调整细胞周期的ES细胞由于多数处于S期,所以重构胚发育率很低;体外培养传代有利于体细胞核移植后重新编程。     

不同方法处理供核细胞对细胞周期和重构胚发育的影响

利用流式细胞仪和细胞染色体核型分析技术,比较奶牛的转基因体细胞和正常细胞经血清饥饿、抑制培养周期同步化处理后的G0/G1期细胞比例;并将同步化处理的核供体细胞进行核移植,然后统计囊胚发育率.结果表明,血清饥饿和抑制培养均能获得较高比例的G0/G1期细胞,两组间差异不显著(P>0.05),但均显著高于未处理对照组(P<0.05);血清饥饿组的囊胚率显著高于抑制培养组和非处理对照组(P<0.05);但细胞同步化处理6 d后细胞染色体核型异常率增加.因此,要获得正常核型的G0/G1核移植供体细胞和较高的囊胚率,同步化处理时间以不超过4 d为宜.     

西伯利亚狍成纤维细胞建系及其生物学特性分析北大核心CSCD

本研究以内蒙古大青山获得野生雄性和雌性西伯利亚狍(Capreolus pygargus)为实验材料,利用组织块贴壁培养法进行气管、肺和耳3种组织成纤维细胞原代建系,研究不同组织来源的细胞贴壁率、冷冻前及复苏后存活率、生长曲线,进一步绘制狍成纤维细胞核型图并分析其G带特征。实验结果显示,气管、肺和耳3种组织成纤维细胞增殖经历潜伏期、对数生长期、平台期三个阶段,细胞形态为梭形、三角形或不规则形,是典型成纤维细胞形态;成纤维细胞呈漩涡状生长,其中气管、耳成纤维细胞生长增殖能力最强、肺成纤维细胞增殖能力较弱,气管和耳组织来源成纤维细胞呈典型“S”型细胞生长特征。染色体核型及G带分析结果显示,雄性狍成纤维细胞染色体条数为2n=70,其中,有34对常染色体,形态类型为12条近端着丝粒染色体(st),22条亚中着丝粒染色体(sm),1对性染色体,X染色体为中着丝粒染色体(m),Y染色体为近端着丝粒染色体(st),5条超数染色体(B);雌性狍成纤维细胞染色体条数为2n=70,其中,有34对常染色体,其形态类型为29条亚中着丝粒染色体(sm),5条近端着丝粒染色体(st),1对为性染色体,X染色体为亚中着丝粒染色体(sm),8条超数染色体(B)。本研究成功建立了雄性和雌性西伯利亚狍气管、肺和耳3种组织来源的成纤维细胞系,在体外培养时生长状态良好且维持了细胞的遗传信息稳定性,绘制了西伯利亚狍雄性和雌性染色体核型及G带图谱,为将来更深入开展相关研究提供材料与基本技术支撑。     

水牛皮肤成纤维细胞的分离与体外培养

探讨水牛成纤维细胞的分离与传代培养方法。组织块培养法培养的成纤维细胞原代生长较慢,需12天左右方可汇合形成单层,而酶消化法培养的成纤维细胞原代生长相对生长快,仅需8天便可汇合形成单层。两种方法传代细胞的生长速度相似,仅需4-5天就可汇合形成单层。通过体细胞的核型分析发现,成纤维细胞在传代培养过程中的核型变化不大,66．67％～81．67％的细胞具有正常的二倍体核型,各代之间无显著差异。结果表明,水牛成纤维细胞均能稳定地进行传代培养。     

表皮生长因子和胰岛素对大熊猫体外培养皮肤成纤维细胞生物学特性的影响

用DME:Ham's F12(1∶1)培养液,添加3个水平的表皮生长因子和2个水平的胰岛素,组合成6种 培养体系(CS)分别培养大熊猫皮肤成纤维细胞。通过对细胞生长速度和染色体数目变异率进行测定,测得在 添加10μg／mL的胰岛素和40 ng／mL的表皮生长因子的培养体系(CS-5)中:以(1．673±0．185)×105／mL密 度接种细胞,经3．5 d,密度达到6．890×105／mL,其生长速度最快;染色体数目为二倍体细胞的比率75．77％; 核型分析显示,培养的细胞是大熊猫体细胞。综合衡量,CS-5更适合大熊猫皮肤成纤维细胞的培养。     

家兔供体细胞的发育周期与重构胚发育的关系

采用血清饥饿法处理体外培养的兔子胎儿成纤维细胞,并将其作为供体细胞移入去核卵母细胞内构建重构胚胎。检查供体细胞的细胞周期对重构胚的融合率、分裂率和着床率的影响。实验结果表明：培养基中血清含量在0．5％的情况下,G0／G1期的细胞比例由正常培养条件下(培乔液中含有10％FCS)的73．2％明显地增加到86％以上。饥饿1～3天的细胞作为供体细胞构建重构胚时,可明显提高重构胚的融合率,但是不同的饥饿时间其融合率并无显著的差异。饥饿处理可明显增加重构胚的分裂率,以饥饿处理3天为最佳。     

重组人gdnf乳腺特异表达载体转染牛胎儿成纤维细胞的研究

为了制备重组人GDNF牛乳腺生物反应器,采用组织块贴壁法分离培养雌性牛胎儿成纤维细胞,连续继代培养75d,进行形态观察和染色体分析,在此基础上,转染带有新霉素抗性和红色荧光蛋白双重筛选标记的重组人gdnf乳腺特异表达载体pNR-GDNF,G418筛选阳性抗性克隆,进行PCR法鉴定。结果表明,分离培养的牛胎儿成纤维细胞具有正常的形态、分裂增殖特性和染色体数目;目的基因已整合到转基因细胞的染色体上。     

野牦牛成纤维细胞分离培养与部分生物学特性观察

野牦牛是青藏高原珍稀牛种,国家一级保护动物。为了保存野牦牛遗传资源,采用组织块法建立了3株野牦牛成纤维细胞株。体外培养的野牦牛细胞呈现典型的成纤维细胞形态,增殖能力强,测定的细胞群体倍增时间为38．47h,平台期密度为2．08×10^6／mL。经免疫荧光染色,细胞表达FGFR5,经单克隆培养建立了FGFR5阳性细胞株。F7细胞染色体核型分析表明,二倍体正常核型率为84．33％,核型2n=60,常染色体均为近端着丝粒染色体,x、Y染色体为近端着丝粒染色体。所建立的野牦牛体细胞株为开展野牦牛克隆研究提供了材料。     

猪成纤维细胞细胞周期同期化对核移植胚胎发育的影响

供体细胞所处的细胞周期及细胞周期同期化的方法对于体细胞核移植（somatic cell nuclear transfer,SCNT）的成功非常重要,本研究对血清饥饿培养处理与培养至完全汇合后的猪成纤维细胞周期同期化水平进行了检测。利用不同方法对猪成纤维细胞同期化处理后,通过流式细胞仪对细胞的细胞周期分布比率进行了检测。将细胞进行血清饥饿24⁷2h,显著地增加了G₀/G₁期的细胞百分率（92.2%⁹3.7%vs.77.8%,P<0.05）。将细胞培养至完全汇合后再培养24⁴8h,G₀/G₁期的细胞比例类似于血清饥饿法（94.4%,89.6%）。血清饥饿24h后,置换为10%FBS能逆转至生长期。用这两种不同方法处理后的体细胞作为核移植的供体构建重构胚,分裂率与囊胚率差异不显著（P>0.05）。结果表明,猪成纤维细胞通过血清饥饿法或者培养至汇合完全均能有效地将细胞周期同期化至G₀/G₁期,且均可作为体细胞核移植的供体细胞。     

Culture,characteristics and chromosome complement of Siberian tiger fibroblasts for nuclear transfer

Tiger (Panthera tigris Linnaeus, 1758) is a characteristic species of Asia, which is in severe danger. Siberian tiger (Panthera tigris altaica) is the largest one of the five existent tiger subspecies. It is extremely endangered. One new way for tiger protection and rescue is to study interspecies cloning. But there is few research data about Siberian tiger. In this study, we cultured Siberian tiger fibroblasts in vitro, analyzed their biological characteristics, chromosomes, and cell cycles, to provide not only nuclear donors with good morphology, normal biological characteristics, and chromosome quantity for tiger interspecies cloning, but also reliable data for further studying Siberian tiger. The results indicated that Siberian tiger ear fibroblasts can be successfully obtained by tissue culture either with or without overnight cold digestion, the cultured cells were typical fibroblasts with normal morphology, growth curve, and chromosome quantity; G0/G1 percentage increased and S percentage decreased with the confluence of cells. G0/G1 and S stage rate was significantly different between 40–50% and 80–90%, 95–100% confluence; there is no distinct difference between 80–90% and 95–100% confluence. The cells at the same density (80–90% confluence) were treated with or without 0.5% serum starving, GO/G1 rate of the former was higher than the latter, but the difference was not significant. GO/G1 proportion of 95–100% confluence was slightly higher than serum starving (80–90% confluence), but no significant difference. Therefore, the Siberian tiger fibroblasts we cultured in vitro can be used as donor cells, and the donor cells do not need to be treated with normal serum starvation during nuclear transfer; if we will just consider the rate of the G0/G1 stage cells, serum starvation can be replaced by confluence inhibition when cultured cells were more than 80–90% confluence.     

Generation of cloned goats (Capra hircus) from transfected foetal fibroblast cells, the effect of donor cell cycle.

The neomycin-resistant gene (neo(r)) is probably the most commonly used selectable marker gene in gene targeting and gene transfection research. In this study, the neo(r) gene construct was introduced into in vitro cultured goat foetal fibroblast cells (IV-5), and the cells were selected with 900 microg/ml G418. The G418-resistant colonies were analysed by neo-specific PCR, karyotyping and anti-intermediate filament proteins antibody (anti-vimentin) staining. Cell cycle analysis of the neo(r) positive foetal fibroblast cell colony (IV-5.1) cultured in a variety of cell cycle-arresting medium indicated that 74.2% of cells cultured in serum-deprived medium for 3 days and 71.7% of cells grown to confluence were at G0/G1 stage of cell cycle, respectively, in comparison to 61.6% of cells in normal culture (cycling) medium. Nocodazole treatment for 17 hr in vitro culture could increase the number of cells at G2/M stage of cell cycle from 20.3% (in cycling medium) to 39.7%. In total, one early pregnancy was observed by B ultra-sound scanning in a surrogate transferred with cloned embryos from IV-5.1 cells at M stage (cells were cultured in nocodazole medium). Seven cloned goats, including two that miscarried at a late stage, were derived from the IV-5.1 cell clone cultured in starved medium (G0). Indeed, one surrogate receiving three blastocysts reconstituted from the starved donor cells, gave birth to three live cloned goats, all of which are healthy and doing well. PCR, Southern blot and G418 resistance in vitro of fibroblast cells from cloned goats confirmed that all cloned goats are positive for neo(r) transgene. This study demonstrates that a foreign gene, such as the neo-resistant gene, can be introduced into goat foetal fibroblast cells, and that the resulting transgenic cells are capable of being cloned to produce 100% transgenic animals.     

沙打旺悬浮培养细胞原生质体的体细胞胚胎发生再生植株(英文)

以继代培养5—24代的沙打旺(Astra-galus adsurgens Pall.)胚性悬浮系为材料,从生长4d的细胞培养物中可游离出大量有活力的原生质体。细胞预质壁分离或低温预处理对原生质体得率和活力没有影响,但可提高原生质体培养的植板率。预处理的原生质体培养在NH_4NO_3浓度降至2.5mmol/L,并附加0.5mg/L NAA、1.0mg/L 2,4-D、0.7mg/L BA和0.4mol/L葡萄糖的KM8P培养基中,经持续分裂形成细胞克隆,植板率高达16%—20%。细胞克隆在附加1.0mg/L 2,4-D和0.5mg/L BA的MS培养基中增殖后,转至含0.1mg/L NAA和1.0mg/L BA的MS分化培养基中可形成体细胞胚,平均体细胞胚发生频率约为40%,每个克隆产生20—40个体细胞胚。在无激素的1/2MS培养基中,体细胞胚发育成形态正常和染色体数稳定的小植株。     

Proliferation of human hematopoietic bone marrow cells in simulated microgravity

Expansion and/or maintenance of hematopoietic stem cell (HSC) potential following in vitro culture remains a major obstacle in stem cell biology and bone marrow (BM) transplantation. Several studies suggest that culture of mammalian cells in microgravity (micro-g) may reduce proliferation and differentiation of these cells. We investigated the application of these findings to the field of stem cell biology in the hopes of expanding HSC with minimal loss of hematopoietic function. To this end, BM CD34+ cells were cultured for 4-6 d in rotating wall vessels for simulation of micro-g, and assessed for expansion, cell cycle activation, apoptosis, and hematopoietic potential. While CD34+ cells cultured in normal gravity (1-g) proliferated up to threefold by day 4-6, cells cultured in micro-g did not increase in number. As a possible explanation for this, cells cultured in simulated micro-g were found to exit G0/G1 phase of cell cycle at a slower rate than 1-g controls. When assayed for primitive hematopoietic potential in secondary conventional 1-g long-term cultures, cells from initial micro-g cultures produced greater numbers of cells and progenitors, and for a longer period of time, than cultures initiated with 1-g control cells. Similar low levels of apoptosis and adhesion molecule phenotype in micro-g and 1-g-cultured cells suggested similar growth patterns in the two settings. These data begin to elucidate the effects of micro-g on proliferation of human hematopoietic cells and may be potentially beneficial to the fields of stem cell biology and somatic gene therapy.     

Effect of serum starvation and chemical inhibitors on cell cycle synchronization of canine dermal fibroblasts

The cell cycle stage of donor cells and the method of cell cycle synchronization are important factors influencing the success of somatic cell nuclear transfer. In this study, we examined the effects of serum starvation, culture to confluence, and treatment with chemical inhibitors (roscovitine, aphidicolin, and colchicine) on cell cycle characteristics of canine dermal fibroblast cells. The effect of the various methods of cell cycle synchronization was determined by flow cytometry. Short periods of serum starvation (24-72 h) increased (P<0.05) the proportion of cells at the G0/G1 phase (88.4-90.9%) as compared to the control group (73.6%). A similar increase in the percentage of G0/G1 (P<0.05) cells were obtained in the culture to confluency group (91.8%). Treatment with various concentrations of roscovitine did not increase the proportion of G0/G1 cells; conversely, at concentrations of 30 and 45 microM, it increased (P<0.05) the percentage of cells that underwent apoptosis. The use of aphidicolin led to increase percentages of cells at the S phase in a dose-dependent manner, without increasing apoptosis. Colchicine, at a concentration of 0.1 microg/mL, increased the proportion of cells at the G2/M phase (38.5%, P<0.05); conversely, it decreased the proportions of G0/G1 cells (51.4%, P<0.05). Concentrations of colchicines >0.1 microg/mL did not increase the percentage of G2/M phase cells. The effects of chemical inhibitors were fully reversible; their removal led to a rapid progression in the cell cycle. In conclusion, canine dermal fibroblasts were effectively synchronized at various stages of the cell cycle, which could have benefits for somatic cell nuclear transfer in this species.     

青扦胚性细胞悬浮培养中影响体细胞胚发生因素的研究

试验以青扦（Ｐｉｃｅａｗｉｌｓｏｎｉ）的胚性愈伤组织为材料,以改良５９基本成分附加２４－Ｄ１ｍｇ／Ｌ及ＫＴ１ｍｇ／Ｌ为培养介质,比较了液体悬浮与半固体二种培养方式对胚性愈伤组织增殖和体细胞发生的影响,研究了液体悬浮培养过程中影响体细胞胚发生的因素。结果表明：液体悬浮培养好于半固体培养,它的胚性愈伤组织的生长率为２６８％,是半固体培养的１２４倍;体细胞胚的分化率为９３％,是半固体培养的２２倍;悬浮培养较佳的培养条件为：初始细胞密度为２％（鲜重）,蔗糖浓度为２０ｇ／Ｌ,摇床转速为１００ｒ／ｍｉｎ,ｐＨ为５８。经过两个月悬浮培养,将培养物转至１／２改良５９附加ＡＢＡ１ｍｇ／Ｌ的分化培养基上,３个月后每ｇ培养物上可获得２８５个正常的子叶期体细胞胚。     

Viability and cell cycle analysis of equine fibroblasts cultured in vitro

This experiment aimed to study equine fibroblasts in culture analyzing and the cell cycle and viability of cells pre- and post-freezing. Skin fragments were obtained from 6 horses and cultured in DMEM high glucose + 10% FCS in 5% CO₂ until the beginning of confluence. Two passages were performed before freezing. Cells subjected to serum starvation (0.5% FCS) were analyzed for viability and cell cycle at 24, 48, 72, 96, 120, 144 and 168 h of culture. For the confluent groups, cells were analyzed at the moment they achieved confluence. Cellular viability was assisted with Hoescht 33342 and propidium iodide. The analysis of apoptosis/necrosis and cell cycle was performed using a flow cytometer (FACS Calibur BD^®) after staining the cells with annexin V and propidium iodide. Both optical microscopy and flow cytometry confirmed that cellular viability was similar for serum starvation and confluent groups (average 84%). Similarly, both methods were efficient to synchronize the cell cycle before freezing. However, after thawing, serum starvation, for more than 24 h, was superior to culture for synchronizing cells in G0/G1 (69% × 90%). The results of this experiment indicate that equine fibroblasts can be efficiently cultured after thawing.     

沙打旺悬浮培养细胞原生质体的体细胞胚胎发生再生植株

Protoplasts from 4-day-old embryogenic cell suspension cultures of Astragalus adsurgens, when cultured in KM8P medium which ammonium concentration was reduced to 2.5 mmol/L and supplemented with 0.5 mg/L NAA, 1.0 mg/L 2, 4-D, 0.7 mg/L BA and 0.4 mol/L glucose, underwent cell sustained divisions and formed cell colonies at a frequency of 16%-20%. Preplasmolysis or low temperature treatment of suspension cells prior to enzyme incubation enhanced colony formation. Following proliferation on MS medium containing 1.0 mg/L 2, 4-D and 0.5 mg/L BA, cell colonies were cultured on MS medium containing 0.1 mg/L NAA and 1.0 mg/L BA, where approximately 40% of colonies produced somatic embryos ranging in number from 20 to 40 per colony. No significant decrease was found in the potential of somatic embryogenesis when protoplast colonies were obtained from long-term cell suspensions. On hormone-free 1/2 MS medium, somatic embryos developed into intact plants, which showed normal morphology and stable chromosome number.     

Characterization of functionally active interleukin‐18/eGFP fusion protein expression during cell cycle phases in recombinant chicken DF1 Cells

The dependence of foreign gene expression on cell cycle phases in mammalian cells has been described. In this study, a DF1/chIL‐18a cell line that stably expresses the fusion protein chIL‐18 was constructed and the enhanced green fluorescence protein connected through a (G₄S)₃ linker sequence investigated the relationship between cell cycle phases and fusion protein production. DF1/chIL‐18a cells (1 × 10⁵) were inoculated in 60‐mm culture dishes containing 5 mL of media to achieve 50%–60% confluence and were cultured in the presence of the cycle‐specific inhibitors 10058‐F4, aphidicolin, and colchicine for 24 and 48 h. The percentage of cell density and mean fluorescence intensity in each cell cycle phase were assessed using flow cytometry. The inhibitors effectively arrested cell growth. The fusion protein production rate was higher in the S phase than in the G0/G1 and G2/M phases. When cell cycle progression was blocked in the G0/G1, S, and G2/M phases by the addition of 10058‐F4, aphidicolin, and colchicine, respectively, the aphidicolin‐induced single cells showed higher fusion protein levels than did the 10058‐F4‐ or colchicine‐induced phase cells and the uninduced control cells. Although the cells did not proliferate after the drug additions, the amount of total fusion protein accumulated in aphidicolin‐treated cells was similar to that in the untreated cultures. Fusion protein is biologically active because it induces IFN‐γ production in splenocyte cultures of chicken. © 2016 American Institute of Chemical Engineers Biotechnol. Prog., 32:581–591, 2016     

Effect of serum concentration, method of trypsinization and fusion/activation utilizing transfected fetal cells to generate transgenic dairy goats by somatic cell nuclear transfer

This work was performed within a commercial nuclear transfer program to investigate different methods for synchronizing donor cell cycle stage, for harvesting donor cells, and for fusion and activation of reconstructed caprine embryos. Primary fetal cells isolated from day 35 to day 40 fetuses were co-transfected with DNA fragments encoding both the heavy and light immunoglobulin chains of three different monoclonal antibodies and neomycin resistance. Four neomycin resistant cell lines for each antibody were selected, expanded, and aliquots were both cryopreserved for later use as karyoplast donors or used for further genetic characterization. Transfected fetal cells were cultured in 0.5% FBS to synchronize G0/G1 cell cycle stage cells, then re-fed with 10% FBS prior to use to allow donor cells to re-enter the cell cycle. Alternatively, transfected fetal cells were grown to confluence in 10% FBS to induce contact inhibition to synchronize G0/G1 cell cycle stage cells. Adherent monolayers of transfected fetal donor cells were harvested by either partial or complete trypsinization. Donor cells were simultaneously fused and activated with enulceated in vivo produced ovulated oocytes from superovulated does. Half of the fused couplets received an additional electrical activation pulse and non-fused couplets were re-fused. Four live offspring were produced from 587 embryos generated from cell lines cultured in 0.5% FBS, while one live offspring was produced from 315 embryos generated from cell lines cultured in 10% FBS (0.7% versus 0.3% embryos transferred, respectively, P > 0.05). Five offspring were produced from 633 embryos generated from cell lines harvested by partial trypsinization (0.8% embryos transferred), and no offspring were produced from 269 embryos generated from cell lines harvested by complete trypsinization. Four live offspring were produced from 447 embryos generated from re-fused couplets, and one live offspring was produced from 230 embryos generated from fused couplets that received an additional electrical activation pulse (0.9% versus 0.4% embryos transferred, respectively, P > 0.05). These results suggest that low-serum culture of transfected goat fetal cells and harvest by partial trypsinization may be more efficient methods for generating transgenic goats by somatic cell nuclear transfer. In addition, re-fusion of non-fused couplet or an additional activation step was successful for producing live offspring.