疏水修饰聚阳离子高分子SP-Chol在COS-7细胞中转染和毒性的研究

目的：研究以精胺为单体,以乙二醇二氯甲酸酯作为连接剂,以胆固醇氯甲酸酯作为疏水基团连接剂合成的疏水修饰聚阳离子高分子SP-Chol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：以荧光素酶质粒为报告基因,研究SP-Chol与DNA的复合物在COS-7细胞的转染活性,用MTT方法研究SP-Chol对COS-7细胞的毒性。结果：COS-7细胞实验显示,SP-Chol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：SP-Chol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。     

疏水修饰聚阳离子高分子SP-Chol 在COS-7 细胞中转染和毒性的研究

目的:研究以精胺为单体,以乙二醇二氯甲酸酯作为连接剂,以胆固醇氯甲酸酯作为疏水基团连接剂合成的疏水修饰聚阳离子高分子SP-Chol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:以荧光素酶质粒为报告基因,研究SP-Chol与DNA的复合物在COS-7细胞的转染活性,用MTT方法研究SP-Chol对COS-7细胞的毒性。结果:COS-7细胞实验显示,SP-Chol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:SP-Chol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。     

新型聚乙烯亚胺衍生物在COS-7细胞中转染和毒性的研究

目的：研究以乙二醛为连接剂的聚乙烯亚胺（Polyethyleneimine,PEI）衍生物Polyimine-PEI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：以荧光素酶质粒为报告基因,研究高分子与DNA的复合物在COS-7细胞的转染活性,用MTT方法研究高分子对COS-7细胞的毒性。结果：COS-7细胞实验显示,Polyimine-PEI具有很低细胞毒性,其毒性显著低于PEI25kDa,同时也具有高效输送质粒的能力。结论：Polyimine-PEI是一种新型的高效,低毒在基因治疗领域有相当前景的非病毒载体。     

新型聚乙烯亚胺衍生物在COS-7 细胞中转染和毒性的研究

目的:研究以乙二醛为连接剂的聚乙烯亚胺(Polyethyleneimine,PEI)衍生物Polyimine-PEI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:以荧光素酶质粒为报告基因,研究高分子与DNA的复合物在COS-7细胞的转染活性,用MTT方法研究高分子对COS-7细胞的毒性。结果:COS-7细胞实验显示,Polyimine-PEI具有很低细胞毒性,其毒性显著低于PEI25kDa,同时也具有高效输送质粒的能力。结论:Polyimine-PEI是一种新型的高效,低毒在基因治疗领域有相当前景的非病毒载体。     

交联聚乙烯亚胺衍生物的构建及其转染COS-7 细胞的研究

目的:优化构建交联聚乙烯亚胺(Polyethylenemine,PEI)衍生物PEI-Bu,研究其对非洲绿猴肾成纤维细胞系(COS-7)的转染活性和细胞毒性。方法:以PEI 800Da为骨架,1,4-丁二醇二氯甲酸酯为连接剂制备聚合物PEI-Bu,琼脂糖凝胶电泳考察其复合质粒DNA的能力,MTT法检测PEI-Bu对COS-7的毒性,以荧光素酶质粒作为报告基因,测定PEI-Bu/DNA复合物在COS-7细胞的转染活性。结果:凝胶电泳表明PEI-Bu/DNA在质量比大于1时即具有复合DNA的能力,PEI-Bu的细胞毒性随浓度增大而增大,在同一浓度下PEI-Bu的细胞毒性小于PEI 25kDa,(P<0.05),PEI-Bu/DNA在质量比为5时达到最高转染活性,高于PEI 25kDa(P<0.01),并与Lipofectamine2000相当(P>0.05)。结论:PEI-Bu在COS-7细胞中是一种低细胞毒性、高转染活性的非病毒基因载体(与商业化的PEI 25kDa比较),其在基因治疗领域中具有潜在的应用前景。     

新型可降解PEI衍生物的表征及其在Brl-3A细胞中的毒性和转染研究

目的:对新型可降解高分子进行表征,研究其在Brl-3A细胞中的毒性和转染效率,以及连接剂比例对以上方面的影响。方法:通过化学方法合成不同比例PEI-Tr高分子,考察其包裹质粒DNA形成纳米颗粒的粒径和电位,以CCK-8方法考察Brl-3A细胞中的细胞毒性,以荧光素酶质粒为报告基因考察Brl-3A细胞中的转染效率。结果:PEI-Tr材料能形成200 nm以下带20 mV左右正电荷的纳米颗粒,具有较好的细胞内吞能力和溶液稳定性,细胞毒性实验证明,随着浓度增加PEI-Tr材料显示了远低于PEI-25kDa的细胞毒性,细胞转染实验表明其拥有高效输送质粒的能力。结论:PEI-Tr是一种高效低毒的可降解聚阳离子载体,在基因输送领域有很大的潜力;连接剂的比例在聚阳离子功能中起到重要作用。     

新型可降解PEI衍生物的体外表征及在HUVEC细胞中的毒性研究

目的:以分支状PEI 1800 Da为基本单元,以化学方法连接咪唑二醛,构建含有可降解亚胺键的新型聚乙烯亚胺衍生物基因载体。对合成的新型基因载体进行体外表征,测定其与p DNA形成的复合物的粒径和zeta电位,研究该复合物在HUVEC细胞中的细胞毒性。方法:通过有机合成方法合成新型聚乙烯亚胺衍生物,考察其与p DNA形成的复合物的粒径和zeta电位,并通过透射电镜考察复合物的形态特征,通过CCK-8方法测定复合物在HUVEC细胞中的毒性。结果:合成的新型基因载体能与p DNA复合形成200 nm左右带20 m V正电荷的纳米颗粒,有利于细胞内吞;形态特征研究表明新型基因载体能将p DNA压缩成类球形的纳米粒,大小与粒径检测结果基本一致。细胞毒性实验表明,合成的新型基因载体材料在相同质量比范围内显示出明显低于PEI25 KDa的细胞毒性。结论:合成的新型基因载体具有较低的细胞毒性,是一种具有良好应用潜力的基因输送载体。     

基于间苯二甲醛构建的IPEI在滑膜细胞中的转染与毒性研究

目的:研究以间苯二甲醛(Isophthalaldehyde)作为连接剂构建的新型聚乙烯亚胺(Polyethyleneimine,PEI)衍生物IPEI为非病毒基因载体在治疗类风湿性关节炎(RA)中的应用,主要对阳离子聚合物IPEI在SD大鼠滑膜细胞中进行体外生物学评价。方法:IPEI以不同质量比包裹绿色荧光蛋白(GFP)质粒和白细胞介素-1受体拮抗剂(IL-1Ra)质粒,研究复合物在滑膜细胞中的转染活性,同时用MTT方法研究聚合物对滑膜细胞的细胞毒性。结果:复合物在质量比为2到10范围内,转染效果比较理想,具有高效输送质粒的能力;同时IPEI的细胞毒性也很小,细胞存活率明显高于商业化转染试剂PEI 25 KDa对照组。结论:阳离子聚合物IPEI具有高转染效率和低毒性的特点,从体内水平上证实了IPEI是一种良好的治疗类风湿性关节炎的基因输送载体。     

新型PEI衍生物对基因沉默作用的研究

目的:构建出一种新型的高效的非病毒基因输送材料.方法:利用1,4-丁二醇二氯甲酸酯连接小分子PEI,合成新型的PEI衍生物(dPEI),通过体外COS-7和HSC细胞实验检测其对质粒和siRNA的输送情况.结果;COS-7细胞实验显示,dPEI具有高效输送质粒的能力,其转染效率是对照组PEI 25 kDa的10倍以上;同时,HSC细胞实验进一步证实dPEI包裹siRNA转染具有一定的基因沉默作用.结论:本研究合成的新型PEI衍生物既可以用于质粒基因的转染,也可用于siRNA的转染,是一种新型的高效的非毒基因输送材料.     

新型聚乙烯亚胺衍生物在Hep G2 细胞中转染和毒性的研究

目的:研究以对苯二甲醛( Terephthalaldehyde)为连接剂的聚乙烯亚胺(Polyethyleneimine,PEI)衍生物PEI-Tp对肝癌细胞Hep G2的转染活性和细胞毒性的影响.方法:以荧光素酶质粒作为报告基因,研究高分子和DNA的复合物在Hep G2细胞中的转染活性,用MTT的方法研究高分子对Hep G2细胞的毒性.结果:Hep G2细胞转染结果显示构建的聚乙烯亚胺衍生物PEI-Tp具有高效输送质粒的能力;细胞毒性结果显示PEI-Tp随着浓度的增加,其毒性显著低于PEI25 kDa.结论:Hep G2细胞实验数据显示PEI-Tp是一种高效、低毒,在基因治疗领域有相当前景的非病毒载体.     

PEI-Et输送特异性shRNA对大鼠肝细胞AGT基因表达的影响

目的:研究交联小分子量聚乙烯亚胺衍生物PEI-Et对大鼠肝细胞(BRL-3A)的细胞毒性、转染效率和携带高血压相关基因血管紧张素原(AGT)短发卡RNA(shRNA)沉默AGT表达的能力。方法:MTT法检测PEI-Et/shRNA复合物对BRL-3A细胞的毒性,流式细胞术检测PEI-Et/shRNA复合物对BRL-3A细胞的转染效率,RT-PCR和Western blot检测PEI-Et/shRNA对AGT的基因沉默效果。结果:在相同质量比(w/w)时PEI-Et/shRNA的细胞毒性小于PEI 25kDa/shRNA(P0.01),PEI-Et/shRNA在w/w为30时达到最高转染效率,高于PEI 25 kDa(P0.01),PEI-Et/shRNA能高效沉默BRL-3A细胞中AGT基因的表达。结论:PEI-Et在BRL-3A细胞中是一种低细胞毒性、高转染效率的非病毒基因载体(与商业化的PEI 25kDa比较),能携带AGT shRNA高效沉默BRL-3A细胞中AGT基因的表达,通过用PEI-Et/AGT shRNA来抑制AGT的表达将为高血压的基因治疗提供一种新的思路。     

Preparation, characterization and transfection efficiency of cationic PEGylated PLA nanoparticles as gene delivery systems

The cationic polylactic acid (PLA) nanoparticle has emerged as a promising non-viral vector for gene delivery because of its biocompatibility and biodegradability. However, they are not capable of prolonging gene transfer and high transfection efficiency. In order to achieve prolonged delivery of cationic PLA/DNA complexes and higher transfection efficiency, in this study, we used copolymer methoxypolyethyleneglycol-PLA (MePEG-PLA), PLA and chitosan (CS) to prepare MePEG-PLA-CS NPs and PLA-CS NPs by a diafiltration method and prepared NPs/DNA complexes through the complex coacervation of nanoparticles with the pDNA. The object of our work is to evaluate the characterization and transfection efficiency of MePEG-PLA-CS versus PLA-CS NPs. The MePEG-PLA-CS NPs have a zeta potential of 15.7 mV at pH 7.4 and size under 100 nm, while the zeta potential of PLA-CS NPs was only 4.5 mV at pH 7.4. Electrophoretic analysis suggested that both MePEG-PLA-CS NPs and PLA-CS NPs with positive charges could protect the DNA from nuclease degradation and cell viability assay showed MePEG-PLA-CS NPs exhibit a low cytotoxicity to normal human liver cells. The potential of PLA-CS NPs and MePEG-PLA-CS NPs as a non-viral gene delivery vector to transfer exogenous gene in vitro and in vivo were examined. The pDNA being carried by MePEG-PLA-CS NPs, PLA-CS NPs and lipofectamine could enter and express in COS7 cells. However, the transfection efficiency of MePEG-PLA-CS/DNA complexes was better than PLA-CS/DNA and lipofectamine/DNA complexes by inversion fluorescence microscope and flow cytometry. It was distinctively to find that the transfection activity of PEGylation of complexes was improved. The nanoparticles were also tested for their ability to transport across the gastrointestinal mucosa in vivo in mice. In vivo experiments showed obviously that MePEG-PLA-CS/DNA complexes mediated higher gene expression in stomach and intestine of BALB/C mice compared to PLA-CS/DNA and lipofectamine/DNA complexes. These results suggested that MePEG-PLA-CS NPs have favorable properties for non-viral gene delivery.     

Development of novel poly(ethylene glycol)-based vehicles for gene delivery

The purpose of this research was to develop and characterize a gene delivery vehicle with a poly(ethylene glycol) (PEG) backbone with the aim of overcoming limitations, such as cytotoxicity and rapid clearance, associated with current commonly used non-viral carriers. PEG was functionalized with DNA-binding peptides (DBPs) to make a vehicle (DBP-PEG) capable of condensing DNA. Complexes of plasmid DNA and DBP-PEG were formed and characterized by measuring particle size, zeta potential, and transfection efficiency as a function of N:P charge ratios (DBP-PEG amino groups:DNA phosphate). Dynamic light scattering showed that DBP-PEG was able to condense DNA efficiently resulting in a population of particles in the range of 250-300 nm. Neutral or slightly positive zeta potentials were measured for charge ratios of 3.5:1 and greater. DBP-PEG/DNA complexes, made with plasmids encoding the green fluorescent protein (GFP) and beta-Galactosidase (beta-Gal) genes, were used to transfect Chinese hamster ovary (CHO) cells. DBP-PEG/DNA was capable of transfecting cells and maximum transfection efficiency was observed for N:P ratios from 4:1 to 5:1, corresponding to zeta potentials from -4 to +1.6 mV. The effect of the DBP-PEG vehicle on cell viability was assayed. DBP-PEG was associated with a higher percentage of viable cells ( approximately 95%) than either polyethylenimine (PEI) or poly-L-lysine (PLL), and with transfection efficiency greater than PLL, but with somewhat lower than PEI. The results of this work demonstrate that PEG can be used as the backbone for gene delivery vehicles.     

程序组装多功能化纳米基因载体

基因治疗成功的关键之一是采用安全高效的载体递送基因。多功能化的非病毒基因载体可克服转染过程中的多种屏障,提高转染效率。通过科研实践和文献查阅,本文总结出实现载体多功能化的三种程序组装方式,即层层自组装、共聚物自组装和脂质掺入,并对近年来国内外通过程序组装构建多功能非病毒基因载体的研究进展做一简要综述。     

Chitosan-Graft-Polyethylenimine/DNA Nanoparticles as Novel Non-Viral Gene Delivery Vectors Targeting Osteoarthritis

The development of safe and efficient gene carriers is the key to the clinical success of gene therapy. The present study was designed to develop and evaluate the chitosan-graft-polyethylenimine (CP)/DNA nanoparticles as novel non-viral gene vectors for gene therapy of osteoarthritis. The CP/DNA nanoparticles were produced through a complex coacervation of the cationic polymers with pEGFP after grafting chitosan (CS) with a low molecular weight (Mw) PEI (Mw = 1.8 kDa). Particle size and zeta potential were related to the weight ratio of CP:DNA, where decreases in nanoparticle size and increases in surface charge were observed as CP content increased. The buffering capacity of CP was significantly greater than that of CS. The transfection efficiency of CP/DNA nanoparticles was similar with that of the Lipofectamine™ 2000, and significantly higher than that of CS/DNA and PEI (25 kDa)/DNA nanoparticles. The transfection efficiency of the CP/DNA nanoparticles was dependent on the weight ratio of CP:DNA (w/w). The average cell viability after the treatment with CP/DNA nanoparticles was over 90% in both chondrocytes and synoviocytes, which was much higher than that of PEI (25 kDa)/DNA nanoparticles. The CP copolymers efficiently carried the pDNA inside chondrocytes and synoviocytes, and the pDNA was detected entering into nucleus. These results suggest that CP/DNA nanoparticles with improved transfection efficiency and low cytotoxicity might be a safe and efficient non-viral vector for gene delivery to both chondrocytes and synoviocytes.     

Cardiac Usage of Reducible Poly(oligo-D-arginine) As a Gene Carrier for Vascular Endothelial Growth Factor Expression

Developments of non-viral carriers have headed toward reducing cytotoxicity, which results from the use of conventional gene carriers, and enhancing gene delivery efficiency. Cys-(d-R9)-Cys repeated reducible poly(oligo-D-arginine) (rPOA) is one of the most efficient non-viral carriers for gene therapy; however, while its efficiency has been verified in the lung and brain, it is necessary to confirm its activity in each organ or tissue since there are differences of gene carrier susceptibility to among tissue types. We therefore tested the compatibility of rPOA in cardiac tissue by in vitro or in vivo experiments and confirmed its high transfection efficiency and low cytotoxicity. Moreover, substantial regenerative effects were observed following transfection with rPOA/pVEGF expression vector complexes (79% decreased infarct size) compared to polyethyleneimine (PEI) (34% decreased infarct size) in a rat myocardial infarction (MI) model. These findings suggest that rPOA efficiently enables DNA transfection in cardiac tissue and can be used as a useful non-viral therapeutic gene carrier for gene therapy in ischemic heart disease.