谷氨酰胺和天冬酰胺对CHO细胞生长、代谢及抗体表达的影响

以离心换液的批培养为例,通过设计谷氨酰胺和天冬酰胺不同的添加方式来考察两者对CHO细胞生长,代谢及产物表达的影响。结果表明：基础培养基中谷氨酰胺和天冬酰胺不能简单地相互替换,缺失谷氨酰胺或天冬酰胺的基础培养基均不能支持dhfr-CHO细胞的正常生长和产物表达,仅谷氨酰胺和天冬酰胺的浓度同时达到4mmol/L,才能满足细胞生长所需。另外,代谢副产物氨的生成仅与谷氨酰胺和天冬酰胺的加和线性相关,与两者添加比例无关。但适当提高天冬酰胺与谷氨酰胺的比例可提高抗体表达水平,同时减少乳酸的生成。因此,为培养基开发与优化过程中谷氨酰胺和天冬酰胺的添加策略提供了依据,为建立高效的流加培养过程奠定了基础。     

运用氨基酸分析法和DOE法优化抗PD-1单克隆抗体生产用培养基

本研究采用氨基酸分析法结合DOE设计法优化并获得高表达抗PD-1单克隆抗体生产用基础和补料培养基。通过对市售多种基础和补料培养基进行筛选,获得细胞生长状况较优的基础培养基和抗体表达较高的补料培养基,利用氨基酸分析法检测较优基础培养基和补料培养基中氨基酸消耗情况,确定影响细胞生长和抗体表达的关键氨基酸种类,利用DOE分析软件设计分别在较优基础和补料培养基中添加不同浓度的氨基酸种类及浓度,根据细胞生长及抗体表达,优化得到抗PD-1单克隆抗体的基础和补料培养基组合。最终优化后基础培养基配方为:Hycell CHO培养基中添加1.04 mmol/L L-天冬酰胺和0.76 mmol/L L-谷氨酰胺。最终优化后补料培养基配方为:OPM CHOCD Feed1补料培养基中添加38.7 mmol/L L-组氨酸,75.0 mmol/L L-酪氨酸,64.0 mmol/L L-丝氨酸,49.2 mmol/L L-谷氨酰胺和18.7 mmol/L L-半胱氨酸。经过3 L反应器培养验证,优化后的培养基比未优化时,最大活细胞密度(PVCD)提高了62.7%,抗PD-1单克隆抗体表达量提高了71.5%,且活性无明显差异。     

天冬酰胺酶介导的分枝杆菌酸适应机制

[目的]结核分枝杆菌可以在宿主细胞内的酸性环境中长期存活.为了探明天冬酰胺酶(AnsA)代谢通道介导的分枝杆菌在酸性环境中的适应机制,分别通过体内和体外实验,对AnsA的活性、突变体性质进行了分析.[方法]以无致病性的卡介苗分枝杆菌(M.bovis BCG)为模式菌,扩增天冬酰胺酶编码基因ansA并在大肠杆菌中进行表达和纯化,对AnsA的酶学活性进行了分析.在卡介苗分枝杆菌中将ansA敲除,对其抗酸、产氨等特性进行了研究.[结果]纯化的重组AnsA在体外可以将天冬酰胺分解并产生氨.在酸性培养基中,分枝杆菌利用天冬酰胺产生的氨,可以释放到培养基中,将酸性培养基中和.敲除ansA后,卡介苗分枝杆菌在酸性环境中的生长滞后10天左右.为了更好的理解天冬酰胺介导的抗酸机制,绘制了天冬酰胺代谢、氨产生和转运示意图.[结论]结核分枝杆菌的抗酸特性之一是通过分泌氨将周围的酸性环境中和来实现的.氨来源于分枝杆菌AnsA对底物天冬酰胺的分解.这为揭示结核分枝杆菌在宿主巨噬细胞内酸性环境中的生存机制提供了线索.     

半乳糖流加对CHO细胞生长代谢及其表达的Fc融合蛋白糖基化的影响

旨在深入认识补料分批培养过程中,以半乳糖替代葡萄糖作为碳源,对CHO细胞生长、代谢和产物表达的影响。通过将补料培养基中的葡萄糖用等摩尔的半乳糖进行替换,综合考察了不同比例替换条件下CHO细胞的生长代谢和Fc融合蛋白的产物合成特性。结果显示:摇瓶的数据表明60%比例以上半乳糖的替代对细胞的生长造成了不利影响,培养后期的pH出现了大幅上升。同时随着半乳糖替代比例的增加,虽然代谢副产物乳酸的浓度有明显下降,但氨的生成却显著增多;此外,培养过程中谷氨酸和丙氨酸的浓度也随着替代比例的增加而增加。产物表达方面,在较低替代比例内(0%-40%),Fc融合蛋白的表达量和总唾液酸含量都随着替代比例的增加而升高,而随着替代比例的进一步升高(60%-100%),两者都逐渐降低。最后,在反应器内通过对培养pH的稳定控制,40%半乳糖替代过程的产物表达量和总唾液酸含量分别提高了43%和37%。补料培养基中以半乳糖替代葡萄糖进行补料的方式,有效地提高了最终Fc融合蛋白的表达量和总唾液酸含量,有助于建立高产高质的CHO细胞培养过程。     

用于生产重组蛋白药物的抗凋亡CHO宿主细胞株的建立

哺乳动物工程细胞在大规模培养生产重组蛋白时很容易发生细胞凋亡,从而导致生产过程提前终止,造成生产成本高昂。细胞代谢产物氨已被证明可以促进细胞凋亡,而线粒体膜整合蛋白Bcl-2可以通过促进线粒体膜完整性而抑制细胞凋亡。本实验应用谷氨酰胺合成酶加压系统在CHO工程细胞中高效表达中国仓鼠Bcl-2蛋白,使细胞具有抗凋亡能力的同时,利用谷氨酸和氨合成谷氨酰胺而有效降低培养基中氨的含量,从而达到抑制细胞凋亡的目的。     

效应面法优化CHO细胞培养基中几种主要成分的含量

目的:考察培养基中葡萄糖、谷氨酰胺、血清、碳酸氢钠含量对CHO细胞生长繁殖的影响。方法:在CHO细胞培养基中添加不同成分的葡萄糖、谷氨酰胺、血清、碳酸氢钠,通过单因素实验结果结合Box-Behnken效应面法,根据二次回归模型的分析结果,以细胞表达蛋白体外活性为指标进行实验,考察培养基中葡萄糖、谷氨酰胺、血清、碳酸氢钠含量对细胞生长繁殖的影响。结果:根据回归方程分析结果,作出相应的曲面图和等高线图,优选出培养基中各组分的最佳配比为:葡萄糖2.54 g/L、谷氨酰胺0.59 g/L、血清8.3%,碳酸氢钠2.96 g/L。结论:Box-Behnken实验设计法用于细胞培养过程中考察培养基中各组分的优选是可行的,数学模型的预测值与实验观察值相符。通过对CHO细胞培养基成分的优化,使CHO细胞蛋白表达量高,有利于提高产品质量和降低生产成本。     

表达重组抗CD52单克隆抗体CHO细胞灌流培养基的筛选

目的筛选重组抗CD52单克隆抗体CHO细胞株培养和连续灌流表达用培养基,以提高抗体表达量。方法通过调整原有批培养用培养基中谷氨酰胺和植物水解蛋白,获得5种培养基配比。使用模拟灌注方式进行细胞培养,分析细胞密度、活细胞比率和目标蛋白表达,筛选连续灌流细胞培养和表达用培养基。最后在7 L反应器中采用灌注培养方式对筛选获得的培养基进行验证。结果使用50 mL细胞培养管进行模拟灌注培养时,活细胞比率较高,达到90%以上;CHO细胞在添加谷氨酰胺至4.0 mmol/L和植物水解蛋白至5.0 g/L的批培养用培养基中生长速度最快;在基础培养基中抗体表达量比优化前高15%。20 d培养周期内,优化的培养基在7 L反应器中可以维持CHO细胞密度在(2 727±253)万个/mL,活细胞比率在95%以上。结论通过模拟灌注培养,筛选获得了一种在7 L反应器灌流培养中适宜于重组抗CD52单克隆抗体CHO细胞表达的培养基。     

效应面法优化CHO细胞培养基中几种丰要成分的含量

目的：考察培养基中葡萄糖、谷氨酰胺、血清、碳酸氢钠含量对CHO细胞生长繁殖的影响。方法：在CHO细胞培养基中添加不同成分的葡萄糖、谷氨酰胺、血清、碳酸氢钠,通过单因素实验结果结合Box-Behnken效应面法,根据二次回归模型的分析结果,以细胞表达蛋白体外活性为指标进行实验,考察培养基中葡萄糖、谷氨酰胺、血清、碳酸氢钠含量对细胞生长繁殖的影响。结果：根据回归方程分析结果,作出相应的曲面图和等高线图,优选出培养基中各组分的最佳配比为：葡萄糖2．54g／L、谷氨酰胺O．59g／L、血清8．3％,碳酸氢钠2．96g／L。结论：Box—Behnken实验设计法用于细胞培养过程中考察培养基中各组分的优选是可行的,数学模型的预测值与实验观察值相符。通过对CHO细胞培养基成分的优化,使CHO细胞蛋白表达量高,有利于提高产品质量和降低生产成本。     

氨浓度升高对CHO细胞维持期抗体融合蛋白的表达及N-糖基化的影响

为了深入理解在中国仓鼠卵巢(CHO)细胞流加培养过程中氨对抗体融合蛋白表达和N-糖基化的作用,认识氨影响N-糖基化加工的作用位点,考察了在细胞维持期(产物表达期)不同氨浓度条件与CHO细胞维持与代谢、抗体融合蛋白表达和N-糖链结构的关系。结果显示,氨浓度在5-12 mmol/L范围内对维持期的细胞生长曲线、葡萄糖和谷氨酰胺的消耗以及乳酸和氨的生成情况没有明显影响。但当氨浓度大于5 mmol/L时,随着氨浓度的升高,抗体融合蛋白的唾液酸化程度和半乳糖化程度均不断降低,而岩藻糖基化程度和高甘露糖糖型比例则没有变化。当氨浓度升高至大于9 mmol/L后,抗体融合蛋白的表达能力和最终表达量开始降低。因此,应在细胞培养工艺过程开发时控制氨的生成至小于5 mmol/L,以避免氨的累积导致产物的半乳糖化和唾液酸化程度降低以及产物表达量下降。     

大肠杆菌Nissle1917 L-天冬酰胺酶Ⅱ基因在大肠杆菌BL21中的表达与抗肿瘤活性

【目的】从大肠杆菌Nissle1917中获得L-天冬酰胺酶Ⅱ基因,并研究其抗肿瘤活性。【方法】以大肠杆菌Nissle1917基因组为模板PCR扩增L-天冬酰胺酶Ⅱ基因,克隆至可诱导表达载体pET28a上。将L-天冬酰胺酶Ⅱ表达载体pET28a-asp转化至大肠杆菌BL21(DE3)中并通过IPTG诱导表达,经聚丙烯酰胺凝胶电泳(SDS-PAGE)和液相色谱-质谱(LC-MS)对表达的L-天冬酰胺酶Ⅱ进行鉴定,并通过镍柱亲和层析纯化收集表达出的L-天冬酰胺酶Ⅱ。用纯化定量以后的L-天冬酰胺酶Ⅱ作用小鼠乳腺癌4T1细胞、人肝癌Hep-3B细胞和人脐静脉内皮细胞HUVEC。【结果】来自于大肠杆菌Nissle1917的L-天冬酰胺酶Ⅱ基因可在大肠杆菌BL21中高效表达并通过LC-MS得到鉴定,细胞毒性实验结果表明L-天冬酰胺酶Ⅱ对4T1细胞和Hep-3B细胞的生长具有较强的抑制作用,而对人脐静脉内皮细胞HUVEC的生长无明显抑制效果。【结论】来源于大肠杆菌Nissle1917的L-天冬酰胺酶Ⅱ能显著抑制4T1细胞和Hep-3肿瘤细胞的生长,而对人正常组织细胞的生长无明显抑制效果,为进一步研究L-天冬酰胺酶Ⅱ特异性抗肿瘤作用机制和对实体瘤的应用研究奠定了重要基础。     

尿激酶原测定方法的改进及对CL-11G工程细胞表达尿激酶原水平稳定性的观察

通过对不同浓度的尿激酶标准品经不同保温时间后溶解圈大小的观察,我们对原来的纤溶板法进行了一些改进,使测定结果更可靠、精确,并可节省成本。用该法对CL-11G工程细胞表达尿激酶原水平的稳定性观察表明,经104次连续传代,其表达量始终保持在每10~6细胞500IU/d左右,符合生产细胞的要求。     

High density and scale-up cultivation of recombinant CHO cell line and hybridomas with porous microcarrier Cytopore

Using porous microcarrier Cytopore and a low-serum medium supplement BIGBEF-3, we have successfully cultivated recombinant CHO cell line CL-11G producing prourokinase and hybridomas producing anti-prourokinase monoclonal antibody in Celligen 1.5 or 5 L bioreactor. The cell density obtained ranged from 1 to 2 × 107 cells mL-1. The yields of prourokinase and monoclonal antibody increased with increasing cell density. As the cells could spontaneously release from and reattach to porous microcarriers, it was very easy to scale-up the cultivation. Thus the bead to bead cell transfer method has been used to scale up the cultivation of CL-11G cells to a 20 L reactor-scale for the pilot production of prourokinase, and also to scale-up the culture of hybridomas for the production of monoclonal antibody for the purification of prourokinase. This revised version was published online in July 2006 with corrections to the Cover Date.     

产尿激酶原CHO工程细胞无血清培基的研究

在分析产尿激酶原CHO工程细胞对培基中氨基酸和糖利用的基础上,对DMEM：F12(1：1)进行初步优化。采用正交实验设计建立了无血清培基11G—SG—SFM和11G—SF—SFM。用11G—SG—SFM悬浮培养11G细胞,细胞增殖速率与含5％小牛血清DMEM: F12或CHO-s-SFM相当。用11G—SE—SFM培养11G细胞,细胞增殖缓慢,但有利于提高11G细胞表达pro—uK的水平,pm—UK的表达水平比含5％小牛血清的DMEM：F12培养提高80％左右。     

Growth behavior of Chinese hamster ovary cells in a compact loop bioreactor. 2. Effects of medium components and waste products.

Effects of biochemical factors, i.e., medium components and metabolic byproducts, on growth of Chinese hamster ovary (CHO) cells were investigated. Glucose and ammonia were found to inhibit the growth. Kinetic analysis gave the inhibition constants, 0.14 g l-1 for ammonia and 5.0 g l-1 for glucose. Since glutamine was unstable and was a main source of ammonia, precise studies on glutamine degradation and ammonia formation process were done. By evaluating the spontaneous reactions, net glutamine utilization and net ammonia production by the cells could be estimated. It became evident that asparagine could support the growth of CHO cells as a stable substitute for glutamine. Then, a glucose fed-batch culture was grown on a glutamine free and asparagine supplemented medium. Because of (1) low glucose concentration, but (2) no glucose limitation and (3) low ammonia accumulation, the maximum total cell concentration reached 3.4 x 10(6) ml-1, which was 1.8 times greater than that in the control experiment (initial 1.15 g l-1 glucose and 0.29 g l-1 glutamine, and no glucose feed).     

Effects of cysteine,asparagine, or glutamine limitations in Chinese hamster ovary cell batch and fed-batch cultures

Amino acid availability is a key factor that can be controlled to optimize the productivity of fed-batch cultures. To study amino acid limitation effects, a serum-free chemically defined basal medium was formulated to exclude the amino acids that became depleted in batch culture. The effect of limiting glutamine, asparagine, and cysteine on the cell growth, metabolism, antibody productivity, and product glycosylation was investigated in three Chinese hamster ovary (CHO) cell lines (CHO-DXB11, CHO-K1SV, and CHO-S). Cysteine limitation was detrimental to both cell proliferation and productivity for all three CHO cell lines. Glutamine limitation reduced growth but not cell specific productivity, whereas asparagine limitation had no significant effect on either growth or cell specific productivity. Neither glutamine nor asparagine limitation significantly affected antibody glycosylation. Replenishing the CHO-DXB11 culture with cysteine after 1 day of cysteine limitation allowed the cells to partially recover their growth and productivity. This recovery was not observed after 2 days of cysteine limitation. Based on these findings, a fed-batch protocol was developed using single or mixed amino acid supplementation. Although cell density and antibody concentration were lower compared to a commercial feed, the feeds based on cysteine supplementation yielded comparable cell specific productivity. Overall, this study showed that different amino acid limitations have varied effects on the performance of CHO cell cultures and that maintaining cysteine availability is a critical process parameter for the three cell lines investigated.     

Effects of glutamine and asparagine on recombinant antibody production using CHO‐GS cell lines

A unique and nontraditional approach using glutamine and asparagine supplements for CHO‐glutamine synthetase (GS) cell lines was studied. In our experiments, we found that a decrease in pH and an increase in cell death occurred in production phase of a GS cell line, leading to reduced antibody expression and lower antibody yields. The experimental results and the statistical analysis (ANOVA) indicated that additions of glutamine and asparagine in the basal and feed media were effective to buffer the cell culture pH, reduce lactate generation, maintain a higher cell viability profile, and improve antibody productivity. In bench‐top bioreactors, glutamine and asparagine supplementation helped to prevent cell death, improve antibody yield, and reduce base usage. Glutamine is normally excluded from culture media for GS cell lines to prevent the bypass of selection pressure. In this study, however, the addition of glutamine did not affect cell population homogeneity, protein quality, or decrease antibody yield of two GS cell lines. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 30:1457–1468, 2014     

Improvement of Vero cell growth in glutamate-based culture by supplementing ammoniagenic compounds

Ammonia has been identified as one of the most inhibitory substances for mammalian cells. We have attempted to develop a less-ammoniagenic medium for the growth of Vero cells by substitution of glutamine with glutamate. In spite of reduced ammonia formation, Vero cells cultured in glutamate-based medium (DMEM-glu) could not grow normally as in glutamine-based medium (DMEM-gln). After Vero cells adapted to DMEM-glu, alanine was consumed instead of accumulated and both asparagine and glutamine were almost undetectable, indicating the lacking for aminonitrogen. By supplementing NH₄Cl, the growth was significantly improved and the cellular uptake of glutamate from medium was greatly increased. However the growth was still not restored to the level in DMEM-gln, likely due to ammonia toxicity. Asparagine was chosen to support the growth of Vero cells in DMEM-glu, formulating DMEM-glu-asn. This replacement reduced ammonia formation by 79% and increased cell yields by 34% compared with DMEM-gln. After Vero cells adapted to DMEM-glu-asn, glutamine synthetase (GS) activity was elevated by 3.8 folds compared with control in DMEM-gln. In DMEM-glu-asn Vero cell growth was arrested by the specific GS inhibitor, methionine sulphoximine. This arrest affirmed the essential role of GS in glutamine synthesis and disconfirmed the potential role of asparagine synthase (AS) in glutamine formulation (also asparagine utilization).     

Observations on the influence of glutamine,asparagine and peptone on growth and t-PA production of Chinese hamster ovary (CHO) cells

When a transfected CHO cell, that produces tissue-type Plasminogen Activator, t-PA, was transferred from a medium based on 5% Fetal Calf Serum, FCS, to a medium based on 0.8% casein peptone with variable glutamine and asparagine content, it was observed, that the growth of the cells changed from anchorage dependant to suspension culture giving more reproducible cultivations. In the FCS culture t-PA was unstable, observed as a decline in t-PA concentration after 250 h. This decline in t-PA concentration was not observed in the serum free culture, although there was a decline in productivity after 200 h. This change in production profile may be attributed to either no proteolytic attack from serum or by scavenging of proteolytic activities produced by the cells from the peptone peptides. Increasing amounts of glutamine/asparagine gave higher production of t-PA in synchrony with an increasing production of ammonia/ammonium ions. Ammonia inhibition does not seem to be a key factor for this cell line as seen with many others.