磁性纳米颗粒介导基因转染的研究进展

介绍了磁性纳米颗粒介导基因转染的最新研究进展,面临的主要问题以及将来的发展方向。     

Effect of chitosan‐alginate nanoparticles and ultrasound on the efficiency of gene transfection of human cancer cells

Background

Gene therapy has been used to treat a variety of health problems, but transfection inefficiency and the lack of safe vectors have limited clinical progress. Fabrication of a vector that is safe and has high transfection efficiency is crucial for the development of successful gene therapy. The present study aimed to synthesize chitosan‐alginate nanoparticles that can be used as carriers of the pAcGFP1‐C1 plasmid and to use these nanoparticles with an ultrasound protocol to achieve high efficiency gene transfection.

Methods

Chitosan was complexed with alginate and the pAcGFP1‐C1 plasmid at different charge ratios to create chitosan‐alginate‐DNA nanoparticles (CADNs). The average particle size and loading efficiency were measured. Plasmid DNA retardation and integrity were analysed on 1% agarose gels. The effect of CADNs and ultrasound on the efficiency of transfection of cells and subcutaneous tumors was evaluated.

Results

In the CADNs, the average size of incorporated plasmid DNA was 600–650 nm and the loading efficiency was greater than 90%. On the basis of the results of the plasmid DNA protection test, CADNs could protect the transgene from DNase I degradation. The transgene product expression could be enhanced efficiently if cells or tumor tissues were first given CADNs and then treated with ultrasound.

Conclusions

The use of CADNs combined with an ultrasound regimen is a promising method for safe and effective gene therapy. Copyright © 2009 John Wiley & Sons, Ltd.

     

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.     

无机纳米粒子作为基因载体的研究进展

转染是将具生物功能的核酸转移、运送到细胞内,并使其在细胞内维持生物功能的过程。作为现代生物化学和分子生物学中的一种主要技术手段,转染对于基因治疗有重要的意义。无机纳米粒子作为基因载体受到人们日益广泛的关注,其具有易于制备,可进行多样化的表面修饰等多种优势。本文将概述无机纳米粒子作为基因载体的现状及其对基因表达的影响。     

Ag-SiO_2核壳型纳米粒的制备及其抗菌作用

利用抗坏血酸对AgNO3进行还原,生成银纳米粒核心,并通过正硅酸四乙酯的水解与聚合反应获得SiO2介孔外壳,制备平均粒径约为92.9 nm的Ag-SiO2核-壳型纳米粒。Ag-SiO2纳米粒可以显著地抑制香石竹镰刀菌的生长,最小抑菌质量浓度为4μg/mL,并可抑制香石竹镰刀菌菌丝生长和孢子分生。Ag-SiO2纳米粒处理2~4 h后,菌丝体的过氧化氢酶、总超氧化物歧化酶、过氧化物酶活力增强,提示Ag-SiO2纳米粒抗菌机制和活性氧诱导相关。     

Delivery of DNA into mammalian cells by receptor-mediated endocytosis and gene therapy

The correction of genetically based disorders by the introduction of a therapeutic genetic construct into the appropriate cell type (“gene therapy”), has become a distinct possibility in recent years. In order for gene therapy to be a practical alternative to more conventional pharmaceutical approaches to treatment, it must be administrable in vivo. This demands that a system be developed that can specifically target the DNA to the desired cell type once introduced into the patient. Among the procedures that are currently being pursued, the delivery of DNA to cells by receptor mediated endocytosis (RME), comes closest to fulfilling this crucial requirement. The natural physiological process of RME can be exploited to deliver genetic material to cells. An antibody or ligand to a cell surface receptor that is known to undergo endocytosis, is complexed with DNA through a covalently linked polycationic adjunct (e.g., polylysine, protamines). Such complexes retain their binding specificity to the cell surface and are taken up into the cell where they enter the endosomal compartment via normal endocytotic processes. In addition, steps must be taken to avoid degradation of the DNA within the endosome-lysosome. Cells can be treated with the lysosomatropic agent chloroquine during the transfection procedure. Alternatively, the components of viruses that enter cells by endocysis and possess an endosomal “break out” capacity can be used. Replication defective adenovirus coupled to the ligand-DNA complex gives transfection efficiencies of virtually 100% on tissue culture cells in vitro. Synthetic peptides that mimic the membrane fusing region of influenza virus hemagglutinin, have also been successfully used as part of the ligand-DNA complex to bring about endosomal escape. Preliminary studies have demonstrated the potential of this method to specifically target DNA to the cell type of choice in vivo. Delivery of genes by receptor-mediated endocytosis offers the greatest hope that gene therapy can be an inexpensive, easily applicable, widespread technology.     

In vivo gene expression: combining hydrodynamics-based transfection and electrotransfer

Clinical development of gene therapy is hampered by the lack of an efficient and safe method for in vivo gene transfer. New methodologies for plasmid transfer are being developed. Recently, significant expression of a reporter gene was achieved in liver cells by coupling intravenous injection and stimulation of the tissue with electric pulses. This combination of hydrodynamics-based transfection and electrotransfer could provide the basis for many promising clinical applications.     

新型纳米转染试剂转染PNP自杀基因体外杀伤实验

将壳聚糖纳米粒包裹的报告基因pEGFP-N1质粒转染至HEK293细胞,并在HEK293细胞中成功表达荧光蛋白的基础上,进一步将本室自行构建的PNP基因的真核高效表达载体质粒pcDNA3-PNP转染至HEK293细胞。转染72h后,对转染的HEK293细胞给予前体药6-MPDR至终浓度40μg/ml,一天后,采用MTT比色法测定药物对细胞增值的影响,并进行统计学处理。实验结果表明采用壳聚糖纳米粒转染试剂转染并给予前体药6-MPDR的实验组活细胞数,与用壳聚糖转染但不给前体药6-MPDR的对照组活细胞数相比,有显著差异(P<0.05),说明新筛选出的壳聚糖纳米粒转染试剂可以将PNP自杀基因递送至靶细胞中,并在细胞中进行表达,从而使PNP/6-MPDR自杀基因系统发挥杀伤细胞的作用。分别采用相同工作浓度的脂质体与壳聚糖纳米粒转染试剂转染相同浓度的基因质粒,壳聚糖纳米粒对靶细胞生长数量影响很小,说明的壳聚糖纳米粒细胞毒性大大低于阳离子脂质体的细胞毒性。     

Drug and gene delivery using gold nanoparticles

Monolayer-functionalized gold nanoparticles provide attractive vehicles for pharmaceutical delivery applications as a result of their size and the unique properties and release mechanisms imparted by their monolayer. This review provides examples of recent advances in the field of drug and gene delivery using gold nanoparticles.     

Novel two-stage screening procedure leads to the identification of a new class of transfection enhancers

BACKGROUND: Non-viral gene transfer efficiency is low as compared to viral vector systems. Here we describe the discovery of new drugs that are capable of enhancing non-viral gene transfer into mammalian cells using a novel two-stage screening procedure. METHODS: First, potential candidates are preselected from a molecular library at various concentrations by a semi-automated yeast transfection screen (YTS). The maximal transfection efficiency of every positive drug is subsequently determined in independent experiments at the optimal concentration and compared to the inhibitory effect of the drug on cell growth (IC50). In a subsequent mammalian cell transfection screen (MTS), the maximal transfection efficiency and the IC50 are determined for all preselected drugs using a human cell line and a luciferase reporter gene construct. RESULTS: Employing our novel system we have been able to identify a new class of transfection enhancers, the tricyclic antidepressants (i.e. doxepin, maprotiline, desipramine and amoxapine). All positive drugs enhanced gene transfer in both yeast and human cell lines, but lower concentrations were sufficient for mammalian cells. With a triple combination of doxepin, amoxapine and chloroquine we obtained a transfection efficiency that exceeded that of chloroquine, one of the best-known transfection enhancers of mammalian cells, by nearly one order of magnitude. CONCLUSIONS: Non-viral gene transfer efficiency can be increased significantly using new transfection enhancers that are identified by a novel, semi-automated two-stage screening system employing yeast cells in the first and specific human target cells in the second round.     

Magnetic nanoparticles for gene and drug delivery

Investigations of magnetic micro- and nanoparticles for targeted drug delivery began over 30 years ago. Since that time, major progress has been made in particle design and synthesis techniques, however, very few clinical trials have taken place. Here we review advances in magnetic nanoparticle design, in vitro and animal experiments with magnetic nanoparticle-based drug and gene delivery, and clinical trials of drug targeting.     

阳离子脂质体运载基因的跨膜机制

阳离子脂质体等非病毒载体以其制备简单、低毒性、低免疫原性、可生物降解等优点,成为近年来基因转运中的常用载体。理解阳离子脂质体运载基因的机制对阳离子脂质体的研究具有重要意义。从跨膜机制和信号调控的角度,介绍了脂质体/DNA复合体以特定构象避免细胞外基质中核酸酶的降解,跨越细胞膜进入细胞的过程;阐明了DNA在信号调控的作用下,逃离溶酶体并安全释放的机制;讨论了基因穿过核被膜进入到细胞核的方式,为进一步阐明阳离子脂质体运载基因的分子机制奠定基础。     

bcl-2基因转染对热应激心肌细胞保护作用的机制探讨

目的 :探讨bcl 2基因转染对热应激心肌细胞保护作用的机制。方法 :分离、培养乳鼠心肌细胞 ,用脂质体转染法将bcl 2基因转染入心肌细胞 ,进行热应激。用化学发光法测定bcl 2基因转染对热应激心肌细胞线粒体H ATPase合成活力的影响 ,用荧光分光光度法测定bcl 2基因转染对热应激心肌细胞Caspase3活性的影响。 结果 :bcl 2基因转染可以使 4 1℃和 4 3℃热应激心肌细胞线粒体H ATPase合成活力与转染前相比显著升高 (P <0 .0 1) ,可以使 4 1℃和 4 3℃热应激心肌细胞Caspase3活性与转染前相比显著降低 (P <0 .0 1)。结论 :bcl 2基因转染对热应激心肌细胞凋亡的保护作用可能与其保护心肌细胞线粒体H ATPase合成活力 ,并最终阻抑Caspase3活化有关     

In vitro and in vivo transfection and expression of plasmid-based non-viral vector for erythropoietin gene therapy

A non-viral gene therapy vector, pcDNA3-EPO, was constructed by subcloning erythropoietin (EPO) cDNA into plasmid pcDNA3. After liposome-mediated transfection of the NIH 3T3 cells in vitro, EPO expression in the culture medium was detected by ELISA and amounted to 1.25 ± 0.3 IU ml^–1. The biological activity of this EPO in the medium was detected after intramuscular injection of BALB/c mice. PCR of genomic DNA and RT-PCR of total RNA also confirmed that the plasmid pcDNA3-EPO had been transfected into the cells. A pool of pcDNA3-EPO transfectants, which stably expressed EPO, was obtained by G418 selection. When pcDNA3-EPO was combined into liposomes and intramuscularly injected into BALB/c mice, the reticulocyte ratio in the positive mice was three times higher than that in the control mice. In vivo expression was maintained in mice for at least one month.     

高表达人cyclin G2基因的SGC-7901细胞克隆筛选和鉴定

应用脂质体基因转染技术建立稳定表达cyclin G2基因的胃癌克隆细胞,为深入研究cyclin G2在胃癌细胞周期调控的作用和机制提供理想的生物学模型.构建以新霉素基因作为筛选标志基因的包含人cyclin G2基因真核重组表达载体pIRES-G2,大量扩增纯化后经限制性内切酶BamH I/BstXI双酶切鉴定;利用阳离子脂质体介导的基因转染法将其和对照空载体pIRESneo转染人胃癌细胞SGC-7901,经G418选择性培养基筛选后有限稀释法连续克隆化,免疫细胞化学染色检测cyclin G2蛋白表达情况.酶切结果表明cyclin G2cDNA已成功插入pIRESneo的多克隆位点内;经G418筛选后在转染pIRES-G2和转染pIRESneo组均见多个细胞克隆出现,细胞化学染色证实pIRES-G2转染组cyclin G2蛋白的表达水平明显高于pIRESneo转染组;经过多次有限稀释获得稳定高表达cyclin G2的细胞克隆.应用脂质体转基因技术成功建立高表达cyclin G2基因的人胃癌细胞克隆.