酿酒酵母的同步培养方法及其应用

同步培养是指通过一定的化学或物理方法使培养的微生物或动植物细胞处于比较一致的生理状态,生长发育在同一阶段的培养方法。它不同于分批培养,在分批培养中,细胞处于不同的生长阶段,生理状态与代谢活动都不一样。显然,分批培养中的群体表现行为不能代表单个细胞的生理生化特性。而利用同步化技术,可以使同步生长群体与个体行为基本一致,这样就能用研究群体行为的方法来研究细胞水平的问题。需要指出,细胞的同步化既可以在自然条件下发生,又可以经人为处理得到。前者称为自然同步化,后者称为人工同步化,本文主要讨论人工同步化的…     

红豆杉细胞稳定生产紫杉醇中的同步化协同诱导作用

同步化协同诱导可以稳定提高曼地亚红豆杉细胞培养物中紫杉醇含量。细胞培养周期第8d的低温同步化处理可促使细胞达到最高同步化率（20.4%）,而茉莉酸甲酯（MJ）的协同诱导可提高紫杉醇产量,使紫杉醇产量最高值达到54.7mg·L^-1。在细胞生长周期第8d,未经低温同步化的红豆杉细胞中的关键酶基因DXR、HMGR、GGPPS和DBAT的表达量在MJ诱导24h后均迅速下降,但在低温同步化的细胞中紫杉醇表达量下降缓慢,60h后仍维持较高的水平。低温同步化和MJ协同诱导的红豆杉细胞中,紫杉醇合成关键酶基因高效稳定的表达可能是引起紫杉醇产量稳定提高的原因之一。     

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.     

肝癌细胞与内皮细胞的粘附力学特性研究

采用细胞同步技术和微管吸吮技术,从细胞周期的角度研究不同细胞周期肝癌细胞(hepatocellularcarcinoma cells,HCC)与脐静脉内皮细胞(HUVEC)的粘附力学特性。结果表明,未同步化肝癌细胞各周期时相的细胞百分比为:G_0/G_1期,53.51％;G_2/M期,11.01％;S期,35.48％。采用胸腺嘧啶脱氧核苷、秋水仙碱顺序阻断和胸腺嘧啶脱氧核苷双阻断后释放培养的方法可分别获得G_1期和S期的肝癌细胞,其平均同步率分别为69.02％和96.50％。G_1期肝癌细胞与人脐静脉内皮细胞的粘附力比S期相应值明显降低(P<0.01),与未同步化肝癌细胞组比较也得到同样结果,而S期与未同步化肝癌细胞组的粘附力值无明显差别。肝癌细胞与脐静脉内皮细胞的粘附力随着粘附时间的变化而变化,在30～60min内迅速增长,60min之后维持在较稳定的水平,即300×10~(10)N左右。提示:在肝癌细胞与内皮细胞的粘附过程中,S期细胞可能起的作用更大;肝癌细胞和内皮细胞上粘附分子表达呈现时间效应,从而体现出粘附和去粘附的行为特征。     

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。     

体外培养的牛耳成纤维细胞的细胞周期研究

通过细胞体外培养,对牛耳成纤维细胞的周期分布进行了研究。不同代数的细胞在生长至70-85％汇合和血清饥饿72h两种状态的细胞周期分布无显著差异。对于体外培养的第8代细胞,生长至50-60％、70-85％和完全汇合时,细胞周期分布存在显著差异;而培养时间对血清饥饿培养和正常培养至充分汇合时的细胞周期分布无显著影响。结果表明,体外培养代数及培养方法不会明显影响细胞周期的分布,但同代细胞因处于不同生长阶段细胞周期分布会存在显著差异。     

integrin β1在不同细胞周期肝癌细胞与内皮细胞粘附中的作用

探讨了integrin β1在不同细胞周期人肝癌细胞(SMMC-7721)上的表达和在肝癌细胞与人脐静脉内皮细胞粘附过程中的作用.未同步处理的肝癌细胞(对照组)各细胞周期时相百分比为G0/G1期53.51%、G2/M期11.01%、S期35.48%,采用胸腺嘧啶脱氧核苷、秋水仙碱顺序阻断和胸腺嘧啶脱氧核苷双阻断后释放培养的方法获得G1期和S期的肝癌细胞,其同步率分别为74.09%和98.29%.G1期肝癌细胞integrin β1表达的荧光强度较S期和对照组相应值明显降低.利用微管吸吮技术定量研究了肝癌细胞与内皮细胞之间的粘附力学特性,发现G1期肝癌细胞的粘附力值比S期相应值明显降低(P＜0.01),而S期的粘附力值与对照组比较无明显差别,integrin β1在肝癌细胞与内皮细胞粘附过程中的贡献约50%.结果提示胸腺嘧啶脱氧核苷和秋水仙碱能较好地将肝癌细胞同步于G1期和S期,integrin β1在SMMC-7721肝癌细胞上的表达水平呈现周期差异,在肝癌细胞与内皮细胞粘附过程中,S期细胞可能起的作用更大,integrin β1在这一粘附过程中起着重要作用.     

应用不同代次兔肾细胞培养风疹病毒松叶株的研究

目的为提高兔肾细胞产量用于增加风疹病毒生产。方法 SPF级家兔肾细胞经传代培养10代,对不同代次兔肾细胞进行遗传稳定性、外源因子及兔脑原虫检测后接种风疹病毒松叶株(Matsuba strain)的试验。结果兔肾细胞产量得到提高,由1对兔肾平均生产1瓶细胞增加为8瓶,细胞核型检查传至第10代的细胞染色体数目与初代细胞一致,细胞培养物均一性提高。第0～第3代细胞病毒培养物滴度间无显著性差异,χ2检验返回相关性的P值均大于0.95。结论第1～第3代细胞培养风疹病毒与第0代相比,可获得相同滴度的病毒培养物,p3代兔肾细胞应用于疫苗生产可显著提高细胞及病毒产量。     

南方红豆杉细胞双液相培养中强化紫杉醇生产的研究

研究了南主红豆杉(Taxuschinensisvar.maireiChengetFu)细胞双液相培养中前体饲喂和混合糖源作为生产培养基糖源对细胞生长和紫杉醇合成的影响。结果表明,前体饲喂(苯丙氨酸、苯甲酰胺和醋酸钠)或混合糖(麦芽糖和蔗糖)作为生产培养基糖源对南方红豆杉细胞单液相培养、更重要的是对其双液相培养的紫杉醇产量提高有显著促进作用,而且前体饲喂和混合糖源的协同作用对其双液相培养的紫杉醇产量提高有进一步的促进作用。与对照组(蔗糖作为糖源和无前体的单液相培养)相比,在南方红豆杉细胞双液相培养中,第10天加入前体,第11天加入混合糖源,紫杉醇产量提高4倍多     

人类主要Cyclins在MOLT-4细胞阻断动力学下的表达规律

细胞周期素与相应的细胞周期素依赖性蛋白激酶相结合,驱动着细胞通过细胞周期各时相,而细胞周期素时相性规律大多来自酵母研究或同步化细胞的分析。本研究着重于人类非同步化细胞的细胞周期素时相性规律的揭示。采用人类白血病细胞株MOLT-4,使其处于对数生长期,加以有丝分裂中期阻滞法,应用多参数流式细胞术分析人类主要细胞周期素B1、A和E。分析发现,细胞周期素B1峰值在M期,降解于M期后,细胞周期素A峰值在G2期,降解于M期,细胞周期素E峰值在G1晚期,降解于S期。以上结果,使我们首次在人类非同步化培养细胞展现了主要细胞周期素的时相性表达规律。     

Gene expression and its regulation during the cell cycle of higher plants in synchronous cell culture systems

Summary This review paper describes the importance of synchronous cell cultures as experimental systems for investigations of mechanisms of the cell cycle of higher plants, and various methods of synchronization are discussed. The efficient synchronization methods were double phosphate starvation in Catharanthus roseus cells and aphidicolin treatment in tobacco cells. Using these systems, cell cycle-dependent genes were isolated and characterized. One of them, cyc07, was investigated in detail and the possible function of cyc07 is discussed as an example of genes involved in the progression of the cell cycle of higher plants. Finally, a perspective of investigations of the cell cycle of higher plant cells is discussed.     

Dna-end binding activity of Ku in synchronized cells

Three different types of cells were synchronized by various methods and DNA-end binding (DEB) activities of Ku were compared with asynchronous controls. In CHO K1 cells synchronized in G1 phase by serum starvation and in S phase by serum refeeding, DEB activity was reduced in S cells but remained unchanged in G1 cells. However, the same type of cells synchronized in G1/S phase by double thymidine block and in S phase by releasing the blockage, have the same DEB activity as asynchronous controls. A similar result was found in RKO and HeLa cells synchronized by the latter method. Arresting cells in mitosis with nocodazole also generated different cell cycle effects. Ku activity was reduced in CHO K1 and RKO cells, but not in HeLa cells after treatment with nocodazole. In phase-enriched cells separated by centrifugal elutriation, DEB activities were similar at different stages of the cell cycle in all three types of cells. Thus, different synchronization procedures can give very different values of Ku activity in a cell type-dependent manner. Results from elutriated cells are consistent, and suggest DEB activity of Ku does not change with the cell cycle.     

Kinetics of taxol production, growth, and nutrient uptake in cell suspensions of Taxus cuspidata

Cell culture of Taxus cuspidata may represent an alternative to extraction of bark as a source of taxol and related taxanes. Cell suspensions of a cell line of T. cuspidata were grown for 44 days in shake flasks containing B5C2 medium. Throughout the growth cycle, fresh and dry weight accumulation, taxol yield on a dry weight basis, taxol accumulation in the medium, pH and pigmentation variation in the medium, as well as the uptake of sucrose, glucose, fructose, nitrate, and inorganic phosphate from the culture medium were examined. The results showed that the growth was relatively slow (doubling times of 17 and 20 days for fresh and dry weight, respectively), and taxol accumulation in the cells was non-growth related (higher in the stationary phase) and at relatively low levels (up to 4 mug/g of the extracted dry weight). Taxol concentration in the medium had two peaks: one during the early (0.4mug/mL) and another during the late (0.1-mug/mL) parts of the growth cycle. On a volumetric basis, the average total amount of taxol produced during the stationary phase (day 38) was 0.15 mug/mL, of which approximately 66% was in the medium and 34% was in the cells. Total carbohydrate uptake was closely associated with the increase in dry biomass. Sucrose was apparently extracellularly hydrolyzed after the first 6 days of culture; glucose was used before fructose. Nitrate was assimilated throughout the growth cycle, but phosphate was absorbed within the first week of culture. The pH variation showed an initial drop followed by a trend toward alkalinization for most of the growth period. Dark pigmentation in the medium increased progressively, particularly during the stationary phase. (c) 1994 John Wiley & Sons, Inc.     

Establishment and characterisation of a rapidly dividing diploid cell suspension culture of Arabidopsis thaliana suitable for cell cycle synchronisation

Polyploid plants often have altered gene expression, biochemistry, and metabolism compared to their diploid predecessors. Therefore cultured diploid cells have distinct benefits over cultured polyploid cells for the study of gene regulation and metabolism of the parent plant. Here we report methods for establishing and maintaining a rapidly dividing diploid Arabidopsis thaliana cell suspension culture, and subsequent cell cycle synchronisation. Rapid growth of homogeneous cell populations was achieved after 3 months of initiation of cultures from leaf calluses. The cells were grown in the dark on an orbital shaker (110 rpm, 50 mm orbit) at 24 °C. Continued maintenance of the culture required the use of late-exponential stage cells for subculture at weekly intervals using careful subculturing techniques to achieve accurate biomass transfer. Cell cycle synchronisation was achieved following sucrose starvation, phosphate starvation, hydroxyurea treatment, aphidicolin treatment, and a combination of phosphate starvation and aphidicolin treatment. Inhibition of the cell cycle and accumulation of cells in specific phases was monitored by microscopy to determine the metaphase/anaphase index, and by flow cytometry. The cell cycle was partially and reversibly blocked by sucrose or phosphate starvation and by hydroxyurea (2.5 mM) treatment. A complete block at G1/S interphase was achieved after aphidicolin treatment or phosphate starvation combined with aphidicolin treatment. Release from the aphidicolin block achieved ca. 78% cell cycle synchronisation in the cell population. Endoreduplication was evident after release from the block in all treatments but after one cycle (24 h) the cells returned to the diploid state. This diploid culture is currently being used in our laboratory for the genetic analysis of cell death.     

Serum starvation induced cell cycle synchronization facilitates human somatic cells reprogramming

Human induced pluripotent stem cells (iPSCs) provide a valuable model for regenerative medicine and human disease research. To date, however, the reprogramming efficiency of human adult cells is still low. Recent studies have revealed that cell cycle is a key parameter driving epigenetic reprogramming to pluripotency. As is well known, retroviruses such as the Moloney murine leukemia virus (MoMLV) require cell division to integrate into the host genome and replicate, whereas the target primary cells for reprogramming are a mixture of several cell types with different cell cycle rhythms. Whether cell cycle synchronization has potential effect on retrovirus induced reprogramming has not been detailed. In this study, utilizing transient serum starvation induced synchronization, we demonstrated that starvation generated a reversible cell cycle arrest and synchronously progressed through G2/M phase after release, substantially improving retroviral infection efficiency. Interestingly, synchronized human dermal fibroblasts (HDF) and adipose stem cells (ASC) exhibited more homogenous epithelial morphology than normal FBS control after infection, and the expression of epithelial markers such as E-cadherin and Epcam were strongly activated. Futhermore, synchronization treatment ultimately improved Nanog positive clones, achieved a 15-20 fold increase. These results suggested that cell cycle synchronization promotes the mesenchymal to epithelial transition (MET) and facilitates retrovirus mediated reprogramming. Our study, utilization of serum starvation rather than additional chemicals, provide a new insight into cell cycle regulation and induced reprogramming of human cells.     

Different culture conditions used for arresting the G0/G1 phase of the cell cycle in goldfish (Carassius auratus) caudal fin-derived fibroblasts

One of the most important factors determining the success of the development of cloned embryos is the cell cycle stage of the donor cells. We investigated the effects of serum starvation, culturing to confluence and roscovitine treatment on the cell cycle synchronization of goldfish caudal fin-derived fibroblasts by flow cytometric analysis. The results show that culturing the cells to confluence (85.5%) and roscovitine treatment (82.71%) yield a significantly higher percentage of cells arrested in the G0/G1 (P < 0.05) phase than serum starvation (62.85%). Different concentrations of roscovitine (5, 10, or 15 μM) induce cell cycle arrest at the G0/G1 phase.     

Synchrony induced by double phosphate starvation in a suspension culture of Catharanthus roseus

A synchronous cell division system was established using the double phosphate starvation method, based on the observation that one of the limiting factors in the growth of a suspension culture of Catharanthus roseus (L.) G. Don cells in the medium of Murashige and Skoog was phosphate. In the system, an increase in cell number took place in a short period of only 4 h, while the cell number remained almost constant during other periods of the cell cycle. The synchrony of the culture was confirmed by changes in mitotic index, which increased sharply prior to the increase in cell number. The S phase was determined by measuring incorporation of [³H]-thymidine into the DNA fraction during the cell cycle and synchrony of DNA synthesis was verified likewise. Synchronization by phosphate starvation is discussed in relation to the function of phosphate as a nutrient. The synchronous system thus established will be useful in biochemical studies of the cell cycle in higher plants.     

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.     

Synthesis of protein and mRNA is necessary for transition of suspension-cultured Catharanthus roseus cells from the G1 to the S phase of the cell cycle

The effects of inhibition of the synthesis of protein, mRNA or rRNA on the progression of the cell cycle have been analyzed in cultures of Catharanthus roseus in which cells were induced to divide in synchrony by the double phosphate starvation method. The partial inhibition of protein synthesis at the G₁ phase by anisoniycio or cycloheximide caused the arrest of cells in the G₁ phase or delayed the entry of cells into the S phase. When protein synthesis was partially inhibited at the S phase, cell division occurred to about the same extent as in the control. When asynchronously dividing cells were treated with cycloheximide, cells accumulated in the G₁ phase, as shown by flow-cytometric analysis. The partial inhibition of mRNA synthesis by α-amanitin at the G₁ phase caused the arrest of cells in the G₁ phase, although partial inhibition of mRNA synthesis at the S phase had little effect on cell division. In the case of inhibition of synthesis of rRNA by actinomycin D at the G₁ phase, initiation of DNA synthesis was observed, but no subsequent DNA synthesis or the division of cells occurred. However, the addition of actinomycin D during the S phase had no effect on cell division. These results suggest that specific protein(s), required for the progression of the cell cycle, are synthesized in the G₁ phase, and that the mRNA(s) that encode these proteins are also synthesized at the G₁ phase.