新型阳离子基因传递载体PEI-PBLG的细胞转染研究

对新型阳离子聚合物PEI(10kD)-PBLG进行研究,重点考察其基因转染效率与细胞毒性,探讨其作为基因载体的可能性。通过粒径分析及扫描电镜(SEM)观察PEI(10kD)-PBLG与质粒pEGFP自组装形成的颗粒形态及粒径,预测其进入细胞的可能性。使用MTT比色法分析PEI(10kD)-PBLG、PEI(25kD)-PBLG、PEI(10kD)和PEI(25kD)的细胞毒性差异。选用表达增强型绿色荧光蛋白的质粒pEGFP作为报告基因模型,将其与PEI(10kD)-PBLG自组装后,分别转染真核细胞株Hela、COS-7、Vero-E6和ECV304,应用流式细胞术检测细胞转染效率,并比较了血清、缓冲液、细胞谱等多种因素对基因转染效率的影响。PEI(10kD)-PBLG可包裹质粒形成粒径100~120nm的纳米复合物,适合介导质粒进入细胞。该纳米粒复合物对转染缓冲液的敏感度较低,并能够在10%血清存在的条件下,转染全部实验用细胞株,尤其对Hela的转染效率最高,其次是COS-7、Vero-E6和ECV304;其中PEI-PBLG(10kD)/pEGFP复合物转染Hela细胞的比率为45.02%,高于PEI(10kD)/pEGFP的29.16%;PEI(10kD)-PBLG的细胞毒性作用显著低于PEI(25kD)、PEI(10kD)和PEI(25kD)-PBLG。新型阳离子多聚物PEI(10kD)-PBLG在提高PEI介导的基因转染效率的同时降低了其细胞毒性,提高了生物相容性,有望成为基因转移的有效载体。     

聚乙烯亚胺转基因影响因素的测定及其优化

聚乙烯亚胺 (PEI)为阳离子多聚物 ,可浓缩DNA形成纳米级颗粒 ,作为基因释放载体转染真核细胞 .选用Mr2 5 0 0 0 ,分枝状的聚乙烯亚胺转染质粒 ,比较多种转基因效率的影响因素 .通过MTT法测定PEI对COS 7细胞的细胞毒性 .利用电泳阻滞实验测定PEI与DNA形成复合物时所需的比例 .通过PEI转染增强型绿色荧光蛋白的pEGFP质粒、编码β 半乳糖苷酶的pSVβ质粒 ,探索氯喹、白蛋白、血清、盐离子浓度、质粒剂量、细胞数量等对聚乙烯亚胺转基因效率的影响 .实验发现 ,PEI对细胞的毒性作用与剂量相关 .PEI DNA的N P比在 3 0以上方可完全结合DNA .溶酶体抑制剂氯喹可增加转染效率 .培养液中的白蛋白、血清会降低转染效率 .生理盐溶液作为配制PEI DNA复合物的溶媒 ,转染效率高于 5 %葡萄糖作为溶媒 .随着转染质粒剂量的增加 ,转染效率呈剂量依赖正效应 .聚乙烯亚胺是有效的体外真核细胞转染剂 ,可用于合成更复杂的基因释放载体 .     

低分子量聚乙亚胺介导的基因转染系统及动物皮肤组织基因转染试验

将带有绿色荧光蛋白(GFP)报告基因的真核表达质粒与阳离子聚合物聚乙亚胺(PEI)结合,用肝癌细胞株CM7221实验,研究其转染效率及可能引起的细胞毒性;进一步用此PEI/DNA复合物转染小鼠皮肤组织,通过报告基因检测,研究转染基因的表达位置及持续表达时间。结果发现,低分子量PEI介导的细胞转染效率最高可达55%,转染效率与PEI结构无关,但是随着分子量的增加,转染活性略有下降。同时,随着分子量的增加,PEI对细胞的毒性也相应的加大;动物皮肤转染实验显示,转染24h后,GFP基因在皮肤组织的毛囊、汗腺、皮脂腺等处高效表达,表达可持续7天。表明低分子量PEI是低毒性、高转染效率的有用非病毒转染载体,能够在动物皮肤组织中进行基因转移,这对皮肤疾病的基因治疗具有潜在的应用价值。     

低分子量聚乙亚胺介导的基因转染系统及动物皮肤组织基因转染试验

将带有绿色荧光蛋白(GFP)报告基因的真核表达质粒与阳离子聚合物聚乙亚胺(PEI)结合,用肝癌细胞株CM7221实验,研究其转染效率及可能引起的细胞毒性;进一步用此PEI／DNA复合物转染小鼠皮肤组织,通过报告基因检测,研究转染基因的表达位置及持续表达时间。结果发现,低分子量PEI介导的细胞转染效率最高可达550%,转染效率与PEI结构无关,但是随着分子量的增加,转染活性略有下降。同时,随着分子量的增加,PEI对细胞的毒性也相应的加大;动物皮肤转染实验显示,转染24h后,GFP基因在皮肤组织的毛囊、汗腺、皮脂腺等处高效表达,表达可持续7天。表明低分子量PEI是低毒性、高转染效率的有用非病毒转染载体,能够在动物皮肤组织中进行基因转移,这对皮肤疾病的基因治疗具有潜在的应用价值。     

PEG修饰的聚阳离子基因载体PEG-Polycarbam-SP在COS-7细胞中转染和毒性的研究

目的：寻找一种转染效率高,细胞毒性低的非病毒基因载体,研究以人体内源性精胺为单体,以乙二醇二氯甲酸酯作为连接剂,以聚乙二醇（PEG）作为亲水基团连接剂合成亲水修饰聚阳离子载体PEG-Polycarbam-SP的基因担载效率,以及对非洲绿猴肾癌细胞COS-7的转染活性和细胞毒性的影响。方法：琼脂糖凝胶电泳方法考察复合物的基因担载效率,检测基因复合物的粒径和电位,以荧光素酶质粒为报告基因,研究PEG-Polycarbam-SP/DNA的复合物在COS-7细胞的转染活性,用MTT方法研究PEG-Polycarbam-SP对COS-7细胞的毒性。结果：聚合物与质粒在质量比5以后形成的复合物粒径稳定在50nm左右,Zate电位在20mV左右。COS-7细胞实验显示PEG-Polycarbam-SP具有低于PEI 25kDa的细胞毒性,同时也具有高效输送DNA的能力。结论：PEG-Polycarbam-SP是一种新型的高效、低毒,在基因治疗领域有潜在应用价值的非病毒基因输送载体。     

聚乙二醇修饰的壳聚糖包裹DNA的转染效果研究

目的:为探讨聚乙二醇(PEG,MW4000)修饰的壳聚糖用于包裹质粒DNA(Chi-DNA)是否能有效提高口服发送的外源基因在消化道中的表达量.方法:用PEG修饰的壳聚糖包裹不同剂量(10μg,50μg,100μg)的质粒(pCMVβ),形成壳聚糖纳米复合物,通过口服发送后经X-gal染色法检测pCMVβ在小鼠消化道内的表达效果.结果:胃酸消化实验及DNase Ⅰ消化实验均表明经PEG修饰的壳聚糖纳米粒能有效地保护DNA,使其免受胃酸及Dnase Ⅰ的降解.同时在小鼠消化道内的表达量较修饰前明显增加,随着所发送DNA剂量的增加,表达量也相应增加,且包裹10μg质粒的DNA纳米复合物的表达量相当于100μg未修饰复合物的表达水平.结论:经PEG修饰的Chi-DNA纳米复合物有较高的基因转染效果,有望作为基因治疔中高效非病毒口服发送系统的材料.     

阳离子脂质体转染人类骨骼肌原代细胞的初步研究

探讨不同脂质体介导基因转染人类骨骼肌原代细胞的转染效率和基因的表达.将含有β-半乳糖苷酶LacZ结构基因的质粒,用三种不同的阳离子脂质体导入人类骨骼肌原代细胞中,通过X-Gal染色观察不同的转染效率.结果发现,Fugene 6转染效率最高,蓝染细胞达10%,其脂质体与DNA的最佳比例为3∶ 2.Fugene 6可有效地将外源基因导入骨骼肌原代细胞,而且外源基因可以长效高效地表达,有望用来作为基因治疗的载体.     

基于逆转录病毒载体的外源基因表达系统的评价和应用

逆转录病毒表达系统是基因治疗研究和RNA干扰技术广泛采用的外源基因表达系统。文中以增强型绿色荧光蛋白 (EGFP) 基因的表达水平和稳定性为指标,比较逆转录病毒表达载体pQCXIN和pcDNA3.1(+) 表达质粒介导的外源基因在HEK293细胞和CHO-K1细胞的表达效率。病毒感染HEK293细胞和CHO-K1细胞的相对荧光强度 (Relative fluorescence intensity,RFI) 均约为对应的质粒转染细胞的2倍。多轮反复感染逆转录病毒表达载体能有效提高HEK293细胞表达EGFP的效率。HEK293细胞经4轮病毒感染后的RFI值较1次病毒感染HEK293细胞的RFI值约提高2倍。此外,逆转录病毒表达载体介导的外源基因表达的稳定性优于质粒转染的外源基因表达。采用携带人重组活性蛋白C (Recombinant human activated protein C,rhAPC) 基因的pQCXIN和HEK293细胞进一步验证了逆转录病毒载体介导的外源基因表达效率,构建了rhAPC表达水平为10~15 mg/(106 cells·d) 的HEK293细胞系。研究结果表明,逆转录病毒表达系统是有应用价值的介导外源基因在哺乳动物细胞高效表达的技术途径。     

登革3型病毒prM-E基因重组质粒DNA的构建和真核表达

构建登革 3型病毒 prM E基因的真核表达重组质粒 ,并进行体外表达 ,为登革DNA疫苗的研究奠定基础。用RT -PCR法获得 prM -E基因片段 ,然后将其克隆到真核表达载体中。用电穿孔法将重组质粒DNA转入BHK细胞 ,通过免疫荧光法检测外源基因在真核细胞中的表达。结果 ,通过酶切和序列测定证实了构建的重组质粒DNA含序列正确的 prM- E基因。用免疫荧光法检测到转染了重组质粒DNA的BHK细胞的胞浆中有登革 3型病毒特异蛋白的表达。说明含有登革 3型病毒prM -E基因的真核表达重组质粒可以在BHK细胞中表达 ,该结果为观察该重组质粒的免疫原性奠定了基础。     

慢病毒重组同源盒基因HOXA4表达载体的构建及其感染人脐带间充质干细胞的实验性研究

目的 构建携带同源基因HOXA4的慢病毒表达载体,并测定其对人脐带间充质干细胞的感染效率.方法 使用酶切及PCR技术从含有HOXA4基因的质粒克隆模版HOXA4-MSCV逆转录载体中获取目的 基因HOXA4,并将HOXA4基因重组到慢病毒载体表达质粒上Lenti-GFP-CTB,通过酶切、测序验证HOXA4基因后,将Lenti-GFP-HOXA4质粒、和辅助包装质粒pRsv-REV、pMDlg-pRRE、PMD2G共同转染人胚胎肾上皮细胞系293T细胞,获得携带HOXA4基因的重组慢病毒Lentiviral-HOXA4;然后感染人脐带间充质干细胞,通过荧光显微镜及流式细胞术检测其感染效率.结果 成功构建携带HOXA4基因的慢病毒表达载体Lentiviral-HOXA4,并获得高纯度的慢病毒浓缩液.经检测病毒滴度达2.11×108 TU/ml.成功转染HOXA4基因的脐带间充质干细胞表达绿色荧光蛋白,当病毒感染复数（MOI）值为60时转染效率最高,达（95.4±4.3）%.结论 成功构建携带人HOXA4基因的慢病毒,并可以在体外有效转染人脐带间充质干细胞.     

Bacterial magnetic particles (BMPs)-PEI as a novel and efficient non-viral gene delivery system

BACKGROUND: Non-viral methods of gene delivery, especially using polyethylenimine (PEI), have been widely used in gene therapy or DNA vaccination. However, the PEI system has its own drawbacks, which limits its applications. METHODS: We have developed a novel non-viral delivery system based on PEI coated on the surface of bacterial magnetic nanoparticles (BMPs). The ability of BMPs-PEI complexes to bind DNA was determined by retardation of plasmid DNA in agarose gel electrophoresis. The transfection efficiency of BMPs-PEI/DNA complexes into eukaryotic cells was determined by flow cytometric analysis. The MTT assay was invited to investigate the cytotoxicity of BMPs-PEI/DNA complexes. The expression efficiency in vivo of BMPs-PEI bound to the plasmid pCMVbeta encoding beta-galactosidase was evaluated intramuscularly inoculated into mice. The immune responses of in vivo delivery of BMPs-PEI bound plasmid pcD-VP1 were determined by MTT assay for T cell proliferation and ELISA for detecting total IgG antibodies. RESULTS: BMPs-PEI complexes could bind DNA and provide protection from DNase degradation. The transfection efficiency of BMPs-PEI/DNA complexes was higher than that in PEI/DNA complexes. Interestingly, in contrast to PEI, the BMPs-PEI complex was less cytotoxic to cells in vitro. We further demonstrated that the BMPs-PEI system can deliver an exogenous gene to animals and allow it to be expressed in vivo. Such expression resulted in higher levels of humoral and cellular immune responses against the target antigen compared to controls. CONCLUSIONS: We have developed a novel BMPs-PEI gene delivery system with a high transfection efficiency and low toxicity, which presents an attractive strategy for gene therapy and DNA vaccination.     

A method to increase the bioactivity of plasmid DNA by heat treatment

A method to increase the bioactivity of plasmid DNA by heat treatment has been developed. The structure of the heat treated plasmid DNA was investigated by electrophoresis assay and atomic force microscope (AFM) observation. Electrophoresis assay showed that the heat treated DNA consisted of three components: the supercoiled DNA (component I), the open circular DNA (component II) and the heat denatured DNA component. The bioactivity of the heat treated plasmid DNA was investigated by both DNA condensation experiments and gene transfection experiment with mammal cells. DNA condensation experiments showed that the heat denatured DNA component owned higher sensitivity to spermidine and polyethylenimine (PEI) than component I and component II DNA. Gene transfection experiment with PEI indicated that the heat treated DNA had higher gene transfection efficiency than untreated DNA. Our experiment not only shows an effective approach to increase the bioactivity of plasmid DNA but also leads a way to improve the bioactivity of DNA by physically modifying their structure.     

Dilution of reporter gene with stuffer DNA does not alter the transfection efficiency of polyethylenimines

BACKGROUND: Polyethylenimines (PEIs) are among the most efficient non-viral gene transfer agents developed so far. However, transfections with these polymers were shown to require a very high copy number of plasmid DNA per cell to achieve gene expression. Here, we investigate whether it is possible to reduce the amount of plasmid DNA while keeping a high transfection efficiency. METHODS: Transfection experiments were performed under various conditions in order to study the interdependence between the amount of reporter DNA, the amine-to-phosphate ratio and the transfection efficiency. RESULTS: When suboptimal amounts of linear PEI 22 kDa/DNA complexes were used for transfection, a severe reduction in reporter gene expression was observed. On the other hand, for optimal amounts of PEI/DNA complexes more than half of the reporter gene can be replaced by carrier DNA or polyglutamic acid without substantially decreasing the transfection efficiency of the polymer both in cultured cells and after systemic administration in mice. When used under the same in vitro experimental conditions, the lipospermine DOGS, but not the monocationic lipid DOTAP, gave similar results. CONCLUSIONS: Taken together, our data suggest that the activity of compounds with endosome-buffering capacities, such as PEIs and lipospermines, requires a threshold amount of transfection agent. In addition, our results indicate that, in many gene transfer situations, it will be possible to lower the dose of active plasmid thus reducing costs and the risk of immune stimulation triggered by bacterial DNA.     

Low molecular weight polyethylenimine for efficient transfection of human hematopoietic and umbilical cord blood-derived CD34+ cells

With the emerging role of hematopoietic stem cells as potential gene and cell therapy vehicles, there is an increasing need for safe and effective nonviral gene delivery systems. Here, we report that gene transfer and transfection efficiency in human hematopoietic and cord blood CD34+ cells can be enhanced by the use of low molecular weight polyethylenimine (PEI). PEIs of various molecular weights (800-750,000) were tested, and our results showed that the uptake of plasmid DNA by hematopoietic TF-1 cells depended on the molecular weights and the N/P ratios. Treatment with PEI 2K (m.w. 2000) at an N/P ratio of 80/1 was most effective, increasing the uptake of plasmid DNA in TF-1 cells by 23-fold relative to Lipofectamine 2000. PEI 2K-enhanced transfection was similarly observed in hematopoietic K562, murine Sca-1+, and human cord blood CD34+ cells. Notably, in human CD34+ cells, a model gene transferred with PEI 2K showed 21,043- and 513-fold higher mRNA expression levels relative to the same construct transfected without PEI or with PEI 25 K, respectively. Moreover, PEI 2K-treated TF-1 and human CD34+ cells retained good viability. Collectively, these results indicate that PEI 2K at the optimal N/P ratio might be used to safely enhance gene delivery and transfection of hematopoietic and human CD34+ stem cells.     

Enhanced gene transfer into brain capillary endothelial cells using Antp-modified DNA-loaded nanoparticles

Brain capillary endothelial cells (BCECs) have been considered as one of the primary targets for cerebral gene therapy. However, the cells, well-known for their poor function of endocytosis, are difficult to be transfected by general non-viral vectors. The aim of this study was to enhance the efficiency of transfection and expression in BCECs of DNA/polymer nanoparticles with the modification of membrane-penetrating peptide, Antennapedia peptide (Antp) polyethylenimine (PEI) and polyamidoamine (PAMAM) were chosen to prepare Antp-modified DNA-loaded nanoparticles with a complex coacervation technique. After a 20-min transfection, the efficiency, in terms of transfection and expression, of DNA/PEI NP or DNA/PAMAM NP was enhanced significantly with the modification of Antp. After a 3-h transfection of DNA/Antp/PEI NP, there was no difference in cellular uptake but an enhancement in gene expression, compared to DNA/PEI NP alone. However, both the transfection and expression efficiency of DNA/PAMAM NP were enhanced using Antp. These observations suggest that Antp can increase the membrane-penetrating ability of DNA-loaded nanoparticles, which can be employed as novel non-viral gene vectors.     

Synthesis and characterization of folate-PEG-grafted-hyperbranched-PEI for tumor-targeted gene delivery

A great challenge for gene therapy is to develop a high efficient gene delivery system with low toxicity. Nonviral vectors are still attractive although the current agents displayed some disadvantages (i.e., low transfection efficiency, high toxicity). To overcome the high toxicity of poly(ethylene imine) (PEI) and low transfection efficiency of PEGylated PEI (PEG-PEI), we linked a cell specific target molecule folate (FA) on poly(ethylene glycol) (PEG) and then grafted the FA-PEG onto hyperbranched PEI 25 kDa. The FA-PEG- grafted-hyperbranched-PEI (FA-PEG-PEI) effectively condensed plasmid DNA (pDNA) into nanoparticles with positive surface charge under a suitable N/P ratio. Tested in deferent cell lines (i.e., HEK 293T, glioma C6 and hepatoma HepG2 cells), no significant cytotoxicity of FA-PEG-PEI was added to PEG-PEI. More importantly, significant transfection efficiency was exhibited in FA-targeted cells. Reporter assay showed that FA-PEG-PEI/pDNA complexes had significantly higher transgene activity than that of PEI/pDNA in folate-receptor (FR) positive (HEK 293T and C6) cells but not FR-negative (HepG2) cells. These results indicated that FA-PEG-PEI might be a promising candidate for gene delivery with the characteristics of good biocompatibility, potential biodegradability, and relatively high gene transfection efficiency.     

Quaternary complexes composed of plasmid DNA/protamine/fish sperm DNA/stearic acid grafted chitosan oligosaccharide micelles for gene delivery

Quaternary complexes with condensed core of plasmid DNA, protamine, fish sperm DNA and shell of stearic acid grafted chitosan oligosaccharide (CSO-SA), were prepared. The CSO-SA could self-assemble to form nano-sized micelles in aqueous solution and demonstrated excellent internalization ability of tumor cells. Dynamic light scattering (DLS) measurement and transmission electrostatic microscope (TEM) images showed that quaternary complexes had spherical shape with about 25 nm number average diameter, and the size of quaternary complexes was smaller than that of CSO-SA micelles and CSO-SA micelles/plasmid DNA binary complexes. The transfection efficiencies of quaternary complexes on HEK293 and MCF-7 cells increased with incubation time, and were significantly higher than that of CSO-SA micelles/plasmid DNA binary complexes. The optimal transfection efficiency of quaternary complexes on HEK293 and MCF-7 cells measured by flow cytometer after 96 h was 23.82% and 41.43%, respectively. Whereas, the transfection efficiency of Lipofectamine? 2000 on HEK293 and MCF-7 cells after 96 h was 32.45% and 33.23%, respectively. The data of luciferease activity measurement showed that the optimal ratio of plasmid DNA:fish sperm DNA:protamine:CSO-SA was 1:1:5:5. The results indicated that the present quaternary complexes were potential non-viral gene delivery system.     

Biodegradable cross-linked poly(amino alcohol esters) based on LMW PEI for gene delivery

Polyethylenimine (PEI, especially with M(w) of 25,000) has been known as an efficient gene carrier and a gold standard of gene transfection due to its high transfection efficiency (TE). However, high concomitant cytotoxicity limited the application of PEI. In this report, several cationic polymers derived from low molecular weight (LMW) PEI (M(w) 600) linked with diglycidyl adipate (DA-PEI) or its analogs (diglycidyl succinate, DS-PEI and diglycidyl oxalate, DO-PEI; D-PEIs for all 3 polymers) were prepared and characterized. GPC gave M(w)s of DA-PEI, DS-PEI and DO-PEI as 6861, 16,015 and 35,281, respectively. Moreover, degradation of the ester-containing DS-PEI was also confirmed by GPC. In addition, hydroxyls in these polymers could improve their water solubility. These polymers exhibited good ability to condense plasmid DNA into nanoparticles with the size of 120-250 nm. ζ-potentials of the polyplexes were found to be around +10-20 mV under weight ratios (polymer/DNA) from 0.5 to 32. Agarose gel retardation showed that DNA could be released from the polyplexes after being pre-incubated for 30 h. In vitro experiments were carried out and it was found that DS-PEI showed about 5 times of TE compared to that of the PEI/DNA polyplex under a weight ratio of 1 in A549 cells. Meanwhile, the cytotoxicity of D-PEIs assayed by MTT is lower than that of 25 kDa PEI in HEK293 cells. These results suggested that this series of PEI derivatives would be promising non-viral biodegradable vectors for gene delivery.     

DNA/PEI/Alginate polyplex as an efficient<Emphasis Type="Italic">in vivo</Emphasis> gene delivery system

A novel non-viral gene delivery system comprised of a DNA/PEI/Alginate (DPA) polyplex was prepared and assessedin vitro andin vivo. Coating the positively charged DNA/PEI (DP) complex with a polyanion resulted in a high level ofin vitro reporter gene transfection in the presence of 50 vol% serum due to the minimized cytotoxicity of PEI and the reduced nonspecific interactions with serum components. Among the tested anionic polymers, which included sodium alginate, poly(methacrylic acid) and poly(acrylic acid), the sodium alginate showed the highest gene transfection efficiency. The DPA polyplex also showed a reduced level of erythrocyte aggregation in target cells when compared with the DP complex. According toin vivo studies in which reporter genes encoding green fluorescent protein (GFP) and luciferase were used, injection of the DPA polyplex into tumor cells in six week old female C57/BL6 mice resulted in a much higher level of GFP expression and approximately 7 fold higher luciferase expression than treatment with the DP complex. Taken together, these results demonstrated that the anionic alginate coating of the DP complex contributed to efficient gene deliveryin vitro andin vivo.