Spatiotemporal modeling and analysis of transient gene delivery

A quantitative and mechanistic understanding of intracellular transport processes in eukaryotic cells during transient transfection is an important prerequisite for the systematic and specific optimization of transient gene expression procedures for pharmaceutic and industrial protein production. There is evidence that intracellular transport processes during gene delivery and their regulation may have significant influence on the transfection efficiency. This contribution describes a compartmented, spatiotemporally resolved and stochastic modeling approach that describes intracellular transport processes responsible for gene delivery during transient transfection. It enables a detailed prediction and analysis and identification of potential bottlenecks. This model is currently being adapted to a model cell line, HEK293s. The simulated results are compared with experimental quantitative polymerase chain reaction (qPCR) data and confocal imaging data obtained with transfected and stained HEK293 cells. Global parameter estimation is performed to qPCR data based on two different novel plasmid constructs in order to identify candidates for plasmid-specific transport parameter variations. The influence of the specific property of HEK293 cells to grow in clusters is investigated and the impact of active microtubule transport depending on cell morphology and clustering is examined. A general sensitivity analysis allows for the identification of the sensitive parameters.     

Coexpression of acidic fibroblast growth factor enhances specific productivity and antibody titers in transiently transfected HEK293 cells

Recombinant proteins are of great commercial and scientific interest. However, most current production methods using mammalian cells involve the time- and labor-intensive step of creating stable cell lines. Although production methods based on transient gene expression could offer a significant improvement, transient transfection is currently still limited by low titers and low specific productivity compared to stable cell lines. To overcome these bottlenecks, we have explored the use of various growth factors to enhance specific productivity and titers in the context of transient gene expression. For that purpose, several growth factors were cloned and screened for their effect on transient gene expression in HEK293E and CHO-DG44 cells. In particular, acidic fibroblast growth factor (aFGF) was able to increase specific productivity by 60% and recombinant protein titers by 80% in HEK293E cells, while FGF9 increased titers by 250% in CHO-DG44 cells.     

人P2X7真核表达载体的构建及稳定转染细胞株的建立

目的：构建人P2X7基因的真核表达载体,并通过转染获得稳定表达P2X7分子的HEK293细胞株。方法：以人脑组织P2X7cDNA为模板扩增出P2X7基因,插入到真核表达载体pEGFP-N1中,构建重组质粒pEGFP-N1/P2X7。用X-fect试剂盒将重组质粒转染HEK293细胞,通过G418辅助荧光筛选建立稳定表达P2X7-EGFP细胞株。经流式细胞仪、Western blot和激光共聚焦显微镜检测,了解人P2X7在HEK293细胞中的表达水平及细胞内定位。结果：重组质粒pEGFP-N1/P2X7构建正确,建立了稳定表达人P2X7的HEK293细胞系。Western blot和流式细胞仪检测证实,P2X7在HEK293细胞系中成功表达,激光共聚焦显微镜检测显示P2X7-EGFP定位在细胞膜上。结论：重组载体pEGFP-N1/P2X7构建成功并建立了稳定表达人P2X7的HEK293细胞系,为进一步研究P2X7离子通道结构和功能奠定基础。     

Prohibitin特异性MiRRNAi表达载体构建及其干扰效果测定

目的：构建携带prohibitin（PHB-1）基因的MiRRNAi真核表达载体pcDNA^TM 6．2-GW／EmGFP-MiR,并观察其转染HEK293细胞株前后PHB-1的表达变化。方法：根据GenBank中prohibifin的序列,设计特异的两条互补的单链寡核苷酸退火后形成双链,克隆至pcDNA^TM6．2-GW／EmGFP-MiR质粒缺口末端,连接在质粒上生成含MiRRNAipcDNA^TM6．2．GW／EmGFP-MiR-PHB载体,测序鉴定后,用脂质体将重组子转染至HEK293细胞中,用Westernblotting检测干扰后HEK293细胞内PHB-1表达的变化。结果：将目的序列成功连接到载体上,并经测序分析证实载体构建成功。Westernblotting检测结果证实构建的PHB-1 MiR RNA表达重组体可显著抑制HEK293细胞内PHB-1的表达。结论：成功构建了携带PHB-1基因的MiR RNAi真核表达载体。     

SCG10基因重组质粒的构建及蛋白表达和定位

目的构建SCG10真核表达载体并证实融合蛋白在细胞内表达及定位。方法以人胎脑cDNA文库为模板,PCR扩增SCG10全长编码基因,亚克隆至pEGFP-C1表达载体中。将构建的重组质粒测序并转染到人胚肾HEK293中,提取细胞蛋白进行Western blot检测。利用共聚焦激光扫描显微镜观察pEGFP-SCG10在HEK293细胞内定位。结果 SCG10全长基因序列克隆到了真核表达载体pEGFP-C1中,酶切鉴定片段大小540bp。Western blot检测到了融合蛋白表达,分子量约为48kD。pEGFP-SCG10在细胞内定位以细胞浆为主,在细胞核少量表达。结论成功构建了SCG10全长基因真核表达载体,pEGFP-SCG10蛋白主要定位于HEK293细胞浆内。     

G418抗性HEK293细胞的培育

目的　培育具有G418抗性的HEK2 93细胞 ,用于建立猪内源性反转录病毒感染人HEK2 93细胞的模型。方法　通过脂质体转染的方法 ,将含有neo基因的质粒pIRESneo导入HEK2 93细胞中 ,利用G418的选择特性 ,对转染细胞进行压力筛选 ,并对其进行了PCR鉴定。结果　经 6 0 0 μg ml的G418压力筛选后 ,获得了抗性细胞克隆。抗性细胞的形态和生长速度与筛选前细胞没有差异 ,特异性核苷酸引物检测抗性细胞基因组DNA ,可以扩增出对应的核苷酸片段。结论　成功地培育了G418抗性HEK2 93细胞 ,为建立猪内源性反转录病毒感染人HEK2 93细胞的模型奠定了基础。     

肿瘤内皮标志物8同型物Ⅰ基因真核表达载体的构建及其在HEK293F细胞中的表达

目的:构建肿瘤内皮标志物8(TEM8)基因真核表达载体,实现TEM8在HEK293F细胞中的外源表达。方法:用PCR技术扩增TEM8基因,经限制性酶切、连接、转化,插入pcDNA3.1(+)-EGFP真核表达载体,并通过脂质体将TEM8表达质粒转染至HEK293F细胞中,Western印迹检测TEM8的表达。结果:PCR扩增得到TEM8基因,构建了真核表达载体pcDNA3.1(+)-TEM8-EGFP并转染HEK293F细胞,经G418加压筛选及有限稀释法得到生长性状良好、表达效率高的单克隆细胞系TEM8-EGFP/HEK293F;Western印迹证明过表达细胞系TEM8-EGFP/HEK293F显著表达TEM8蛋白。结论:构建了表达TEM8的重组HEK293F工程细胞系TEM8-EGFP/HEK293F,为进一步研究TEM8的生理功能奠定了基础。     

Transient gene expression in mammalian cells grown in serum-free suspension culture

In order to establish a simple and scaleable transfection system we have used the cationic polymer polyethylenimine (PEI) to study transient transfection in HEK293 and 293(EBNA) cells grown in serum-free suspension culture. The transfection complexes were made directly within the cell culture by consecutively adding plasmid and PEI (direct method). Alternatively, the DNA-PEI transfection complexes were prepared in fresh medium (1/10 culture volume) and then added to the cells (indirect method). The results of this study clearly show that the ratio of PEI nitrogen to DNA phosphate is very important for high expression levels. The precise ratio is dependent on the DNA concentration. For example, using 1 μg/ml DNA by the indirect method, the ratio of optimal PEI:DNA was about 10–13:1. However, the ratio increases to 33:1 for 0.1–0.2 μg/ml DNA. By testing several different molecular weights of the polycationic polymer we could show that the highest transfection efficiency was obtained with the PEI 25 kDa. Using PEI 25 kDa the indirect method is superior to the direct addition because significantly lower DNA concentrations are needed. The expression levels of the soluble human TNF receptor p55 are even higher at low DNA compared to 1 μg/ml plasmid. The EBV-based pREP vectors gave better transient gene expression when used in 293(EBNA) cells compared to HEK293 cells in suspension culture. No differences in expression levels in the two cell lines were observed when the pC1 (CMV)-TNFR was used. In conclusion, PEI is a low-toxic transfection agent which provides high levels of transient gene expression in 293(EBNA) cells grown in serum-free suspension culture. This system allows highly reproducible, cost-effective production of milligram amounts of recombinant proteins in 2–5 l spinner culture scale within 3–5 days. Fermentor scale experiments, however, are less efficient because the PEI-mediated transient tranfection is inhibited by conditioned medium. This revised version was published online in July 2006 with corrections to the Cover Date.     

反转录病毒载体介导的猪APOBEC3F在猪源细胞PK15中的表达

目的:利用反转录病毒载体构建猪载脂蛋白B mRNA编辑酶催化多肽样蛋白(APOBEC)3F重组质粒,并实现其在猪肾细胞PK15中的表达。方法:用RT-PCR方法扩增五指山猪来源的外周血淋巴细胞APOBEC3F基因,将其定点插入反转录病毒载体pMSCV neo中,同时于插入位点两侧分别添加FLAG和GFP标签,构建重组质粒pMSCV-FLAG-A3F-GFP,并进行酶切、测序鉴定;将鉴定正确的重组质粒与pVSV-G、pGag-Pol共转染包装细胞HEK293T,分别于转染后48~72 h收集细胞的培养上清以获得假型病毒粒子;用该假型病毒感染猪源细胞PK15,通过PCR、Western印迹检测目的基因的整合及表达。结果:PCR扩增到1254 bp的猪APOBEC3F基因,重组质粒pMSCV-FLAG-A3F-GFP经酶切、测序,结果无误;3质粒共转染HEK293T细胞包装出的假型病毒感染PK15细胞后观察到GFP表达;从感染假型病毒的PK15细胞基因组中扩增到1254 bp的猪APOBEC3F基因,Western印迹检测到78.1×103的猪APOBEC3F蛋白的表达。结论:实现了反转录病毒载体介导的猪APOBEC3F在猪源细胞PK15中的整合与表达,为深入研究该分子对猪内源性反转录病毒(PERV)的抑制作用奠定了基础。     

Expression and analysis of green fluorescent proteins in human embryonic kidney cells by capillary electrophoresis

The green fluorescent protein (GFP) has attracted much interest as a reporter for gene expression. In this paper, application of capillary electrophoresis with laser-induced fluorescent (CE-LIF) for quantitation of green fluorescence protein in cellular extracts and single cells is investigated. The S65T mutant form of GFP protein was successfully expressed in human embryonic kidney (HEK293) cells, and its production was confirmed by fluorescence microscopy and CE-LIF. The mass limit of detection for the mutant S65T was 5.3 x 10(-20) mol, which was better than that for the wild-type GFP by a factor of six. Detection of a small amount of GFP is difficult by conventional techniques such as fluorescent microscopy due to interference from cell autofluorescence at low GFP concentrations. The HEK293 cells were transfected with the GFP plasmid that produced S65T-GFP. Transient production of S65T protein was detected 2 h after the transfection and reached a maximum after 48 h. The protein concentration began to decrease significantly after 96 h. Single cell analysis of HEK293 cells after transfection with GFP plasmid indicate a nonuniform production of S65T-GFP protein among cells.     

Rational vector design and multi-pathway modulation of HEK 293E cells yield recombinant antibody titers exceeding 1 g/l by transient transfection under serum-free conditions

Transient transfection allows for fast production of recombinant proteins. However, the current bottlenecks in transient transfection are low titers and low specific productivity compared to stable cell lines. Here, we report an improved transient transfection protocol that yields titers exceeding 1 g/l in HEK293E cells. This was achieved by combining a new highly efficient polyethyleneimine (PEI)-based transfection protocol, optimized gene expression vectors, use of cell cycle regulators p18 and p21, acidic Fibroblast Growth Factor, exposure of cells to valproic acid and consequently the maintenance of cells at high cell densities (4 million cells/ml). This protocol was reproducibly scaled-up to a working volume of 2 l, thus delivering >1 g of purified protein just 2 weeks after transfection. This is the fastest approach to gram quantities of protein ever reported from cultivated mammalian cells and could initiate, upon further scale-up, a paradigm shift in industrial production of such proteins for any application in biotechnology.     

Generation of stable cell line by using chitosan as gene delivery system

Establishing stable cell lines are useful tools to study the function of various genes and silence or induce the expression of a gene of interest. Nonviral gene transfer is generally preferred to generate stable cell lines in the manufacturing of recombinant proteins. In this study, we aimed to establish stable recombinant HEK-293 cell lines by transfection of chitosan complexes preparing with pDNA which contain LacZ and GFP genes. Chitosan which is a cationic polymer was used as gene delivery system. Stable HEK-293 cell lines were established by transfection of cells with complexes which were prepared with chitosan and pVitro-2 plasmid vector that contains neomycin drug resistance gene, beta gal and GFP genes. The transfection efficiency was shown with GFP expression in the cells using fluorescence microscopy. Beta gal protein expression in stable cells was examined by beta-galactosidase assay as enzymatically and X-gal staining method as histochemically. Full complexation was shown in the above of 1/1 ratio in the chitosan/pDNA complexes. The highest beta-galactosidase activity was obtained with transfection of chitosan complexes. Beta gal gene expression was 15.17 ng/ml in the stable cells generated by chitosan complexes. In addition, intensive blue color was observed depending on beta gal protein expression in the stable cell line with X-gal staining. We established a stable HEK-293 cell line that can be used for recombinant protein production or gene expression studies by transfecting the gene of interest.     

Gateway-compatible transposon vector to genetically modify human embryonic kidney and adipose-derived stromal cells

The Gateway technology cloning system and transposon technology represent state-of-the-art laboratory techniques. Combination of these molecular tools allows rapid cloning of target genes into expression vectors. Here, we describe a novel Gateway technology-compatible transposon plasmid that combines the advantages of Gateway recombination cloning with the Sleeping Beauty (SB) transposon-mediated transgene integrations. In our system the transposition is catalyzed by the novel hyperactive SB100x transposase, and provides highly efficient and precise transgene integrations into the host genome. A Gateway-compatible transposon plasmid was generated in which the potential target gene can be fused with a yellow fluorescent protein (YFP) tag at the N-terminal. The vector utilizes the CAGGS promoter to control fusion protein expression. The transposon expression vector encoding the YFP-interferon-β protein (IFNB1) fusion protein together with the hyperactive SB100x transposase was used to generate stable cell lines in human embryonic kidney (HEK293) and rat adipose-derived stromal cells (ASC). ASCs and HEK293 cells stably expressed and secreted the human IFNB1 for up to 4 weeks after transfection. The generated Gateway-compatible transposon plasmid can be utilized for numerous experimental approaches, such as gene therapy or high-throughput screening methods in primary cells, representing a valuable molecular tool for laboratory applications.     

腺病毒介导的人巨细胞病毒UL49基因小鼠模型的建立

建立表达HCMV UL49 基因的转基因小鼠,为抗病毒药物研究提供有效的实验动物模型。本实验将UL49-GFP基因插入腺病毒穿梭质粒pDC316中,构建重组质粒pDC316-UL49-GFP,与腺病毒骨架质粒pBHGloxΔE1,3Cre 通过脂质体介导共转染293 细胞,重组产生腺病毒Ad-UL49-GFP, 经PCR和Western Blot鉴定正确后,大量扩增、纯化,制备高滴度重组腺病毒。纯化腺病毒经尾静脉注射感染小鼠,通过荧光定量PCR 和Western blot 方法,检测UL49 基因在小鼠体内组织分布和表达时相。结果显示UL49基因在小鼠的心、肝、脾、肺、肾组织均有表达,并且表达量由高到低顺序依次是：肝、脾、肾、心、肺,在腺病毒感染第3天在各靶器官表达水平较高,此后逐渐下降,第14天时仅存在肝和脾中。表明表达UL49基因的小鼠模型构建成功。小鼠模型的成功建立为下一步筛选以UL49基因为靶的抗病毒药物奠定了基础。     

An anti-apoptotic HEK293 cell line provides a robust and high titer platform for transient protein expression in bioreactors

ABSTRACT

HEK293 transient expression systems are used to quickly generate proteins for research and pre-clinical studies. With the aim of engineering a high-producing host that grows and transfects robustly in bioreactors, we deleted the pro-apoptotic genes Bax and Bak in an HEK293 cell line. The HEK293 Bax Bak double knock-out (HEK293 DKO) cell line exhibited resistance to apoptosis and shear stress. HEK293 DKO cells sourced from 2 L seed train bioreactors were most productive when a pH setpoint of 7.0, a narrow pH deadband of ±0.03, and a DO setpoint of 30% were used. HEK293 DKO seed train cells cultivated for up to 60 days in a 35 L bioreactor showed similar productivities to cells cultivated in shake flasks. To optimize HEK293 DKO transfection cultures, we first evaluated different pH and agitation parameters in ambr15 microbioreactors before scaling up to 10 L wavebag bioreactors. In ambr15 microbioreactors with a pH setpoint of 7.0, a wide pH deadband of ±0.3, and an agitation of 630 rpm, HEK293 DKO transient cultures yielded antibody titers up to 650 mg/L in 7 days. The optimal ambr15 conditions prompted us to operate the 10 L wavebag transfection without direct pH control to mimic the wide pH deadband ranges. The HEK293 DKO transfection process produces high titers at all scales tested. Combined, our optimized HEK293 DKO 35 L bioreactor seed train and 10 L high titer transient processes support efficient, large-scale recombinant protein production for research studies.     

裂解性复制诱导产生可视化重组Epstein Barr病毒

为了在病毒的整个基因组中研究基因的功能,分析基因与基因之间的相互作用,含有整个野生型EB病毒(EBV)基因组的BAC-EBV质粒(p2089),首先被转染EBV阴性的HEK293细胞,经潮霉素筛选建立了HEK293/p2089稳定细胞系.再构建pcDNA3.1( )/BZLF1和pcDNA3.1( )/BALF4真核表达质粒,共转染至HEK293/p2089细胞内,诱导EBV裂解性复制产生可视化的重组EBV颗粒.重组EBV颗粒感染Raji细胞,在倒置荧光显微镜下和流式细胞仪记数GFP阳性细胞,根据这些"绿色Raji单位"确定病毒的滴度.在国内首次建立这种以细菌人工染色体(BAC)为基础的EBV感染性克隆技术,将允许对EB病毒基因组中任何基因的任何遗传修饰,为在整个基因组中对EB病毒基因功能的研究奠定了基础,也为对EBV与其相关的肿瘤如鼻咽癌发生机理的研究建立了新的技术平台.     

Production of lentiviral vectors in suspension cells using low proportion of supercoiled circular plasmid DNA

The supercoiled circular (SC) topology form of plasmid DNA has been regarded to be advantageous over open circular or linearized analogue in transfection and expression efficiency, and therefore are largely demanded in the biopharmaceutical manufacturing. However, production of high-purity SC plasmid DNA would result in high manufacturing cost. The effect of SC proportion in plasmid DNA on the quality of packaged lentiviral vectors has never been reported. In this study, we established an efficient system for production of high-titer lentiviral vectors using suspension HEK293SF cells in serum-free media, and the lentiviral titer was not associated with the proportion of SC plasmid DNA. Plasmids DNA with different proportion of SC, open-circular, and linearized forms were prepared using the thermal denaturation method, and were transfected to adherent HEK293T or suspension HEK293SF cells for packaging of lentiviral vectors. The titer of lentiviral vectors from HEK293T cells, but not from HEK293SF cells, was significantly impaired when the proportion of SC plasmid DNA decreased from 60–80% to 30–40%. Further decrease of SC plasmid proportion to 3% led to a dramatic reduction of lentiviral titer no matter the packaging cell line was. However, lentiviral vectors from HEK293SF cells still showed a high titer even when the proportion of SC plasmid DNA was 3%. This study demonstrated that extremely high proportion of SC plasmid DNA was not required for packaging of high-titer lentiviral vector in HEK293SF cells, at least under our manufacturing process.