京尼平交联低聚乙烯亚胺智能基因载体的制备与表征

使用京尼平与分子量为1800的超支化低聚乙烯亚胺在70％的乙醇溶液中反应,合成了具有荧光的交联型聚合物.利用核磁、凝胶渗透色谱、粒度仪、zeta电位仪和凝胶阻滞电泳对聚合物载体及其与DNA复合物颗粒进行了表征.研究表明,聚合物载体与DNA复合物颗粒粒径为120 ～150 nm,zeta电位为+20～25 mV,聚合物/...     

MicroRNA Delivery by Graphene-Based Complexes into Glioblastoma Cells

Glioblastoma (GBM) is the most common primary and aggressive tumour in brain cancer. Novel therapies, despite achievements in chemotherapy, radiation and surgical techniques, are needed to improve the treatment of GBM tumours and extend patients’ survival. Gene delivery therapy mostly uses the viral vector, which causes serious adverse events in gene therapy. Graphene-based complexes can reduce the potential side effect of viral carries, with high efficiency of microRNA (miRNA) or antisense miRNA delivery to GBM cells. The objective of this study was to use graphene-based complexes to induce deregulation of miRNA level in GBM cancer cells and to regulate the selected gene expression involved in apoptosis. The complexes were characterised by Fourier transform infrared spectroscopy (FTIR), scanning transmission electron microscopy and zeta potential. The efficiency of miRNA delivery to the cancer cells was analysed by flow cytometry. The effect of the anticancer activity of graphene-based complexes functionalised by the miRNA sequence was analysed using 2,3-bis-(2-methoxy-4-nitro-5-sulfophenyl)-2H-tetrazolium-5-carboxyanilide salt (XTT) assays at the gene expression level. The results partly explain the mechanisms of miRNA deregulation stress, which is affected by graphene-based complexes together with the forced transport of mimic miR-124, miR-137 and antisense miR-21, -221 and -222 as an anticancer supportive therapy.     

含氟高分子基因载体

阳离子高分子被广泛应用为非病毒类基因载体,但这类高分子材料的转染效率与细胞毒性之间通常存在"恶性"关联,即获得高转染效率时往往会伴随严重的细胞毒性.如何制备兼具高效、低毒特点的高分子载体是成功实施基因治疗的关键.含氟高分子是一类具有独特理化性质的高分子,能够在低电荷密度条件下与核酸形成稳定的复合物,从而实现高效、低毒的基因转染.含氟功能基团可帮助阳离子高分子改善复合物稳定性、细胞内吞、内涵体逃逸、胞内核酸释放等多个环节,从而赋予了含氟高分子在基因递送过程中的氟效应.该专论系统地总结了含氟高分子基因载体的研究,介绍了含氟高分子的基因递送性能、作用机理以及在基因治疗、基因编辑中的应用,并对含氟高分子载体的未来发展进行了展望.     

Light-Induced Self-Escape of Spherical Nucleic Acid from Endo/Lysosome for Efficient Non-Cationic Gene Delivery

Developing non-cationic gene carriers and achieving efficient endo/lysosome escape of functional nucleic acids in cytosol are two major challenges faced by the field of gene delivery. Herein, we demonstrate the concept of self-escape spherical nucleic acid (SNA) to achieve light controlled non-cationic gene delivery with sufficient endo/lysosome escape capacity. In this system, Bcl-2 antisense oligonucleotides (OSAs) were conjugated onto the surface of aggregation-induced emission (AIE) photosensitizer (PS) nanoparticles to form core–shell SNA. Once the SNAs were taken up by tumor cells, and upon light irradiation, the accumulative ¹O₂ produced by the AIE PSs ruptured the lysosome structure to promote OSA escape. Prominent in vitro and in vivo results revealed that the AIE-based core–shell SNA could downregulate the anti-apoptosis protein (Bcl-2) and induce tumor cell apoptosis without any transfection reagent.     

Construction of Bovine Serum Albumin/AIE‐Based Quaternary Complexes for Efficient Gene Transfection

High transfection efficiency and superior cell imaging are required for cationic polymers‐based gene delivery system to afford high therapeutic effect but its high toxicity and unstable cell imaging are easily ignored. In this study, cationic amino poly(glycerol methacrylate) derivative (PGMA‐EDA) is used to incorporate bovine serum albumin (BSA) and aggregation‐induced emission (AIE) molecular (tetraphenylethylene derivatives, TPE) as an efficient carrier for gene transfection and intracellular imaging. The obtained polymer/pDNA‐TPE/BSA (PDTB) quaternary nanoparticles (NPs) not only exhibit efficient gene transfection but also show excellent biocompatibility. After inclusion of TPE/BSA (TB) NPs, BSA promoted dissociation of the complexes upon being protonated and the lipophilic TPE‐reduced endosomal membrane stability, which enhanced endosomal escape of pDNA payload, finally resulting in an excellent gene transfection. On the other hand, less positive surface charge of PDTB NPs than that of the binary PD complexes, as well as the addition of biocompatible BSA, both factors contribute to the improved cell viability. Moreover, the AIE feature of TPE compared to aggregation‐caused quenching character of conventional fluorophores enables the complex with stably tracking the delivery of pDNA into cancer cells. Therefore, the newly developed PDTB complexes may be a promising candidate vector for traceable, safe, and effective gene delivery.     

CAGW and TAT‐NLS peptides functionalized multitargeting gene delivery system with high transfection efficiency

Gene therapy has attracted much attention in vascular tissue engineering. However, it is still challenging to develop a novel gene carrier with multifunction to overcome the barriers in gene delivery. Herein, the multitargeting gene complexes were developed based on methoxy‐poly(ethylene glycol)‐b‐poly‐(D,L‐lactide‐co‐glycolide) (mPEG‐b‐PLGA), poly(d ,l ‐lactide‐co‐glycolide)‐g‐polyethylenimine‐g‐CAGW (PLGA‐g‐PEI‐g‐CAGW), cell‐penetrating peptide YGRKKRRQRRR (TAT), nuclear localization signals (NLS), and pEGFP‐ZNF580 (pDNA) with the purpose of enhancing the transfection of endothelial cells (ECs). The low cytotoxic multitargeting gene complexes could be easily prepared by adjusting the weight ratio of mPEG‐b‐PLGA and PLGA‐g‐PEI‐g‐CAGW. Meanwhile, CAGW peptide with selectively ECs‐targeting ability and TAT‐NLS peptide sequence with both cell‐penetrating ability and nuclear targeting capacity were simultaneously introduced into gene complexes in order to enable them with the multitargeting function so as to improve their gene delivery capacity. The pDNA loading capacity of these gene complexes was confirmed by agarose gel electrophoresis assay. MTT results demonstrated that the relatively cell viability of the multitargeting gene complexes was higher than those of other groups. These multitargeting gene complexes showed higher internalization and transfection efficiencies than other groups. These results revealed that CAGW and TAT‐NLS peptide sequences benefited for efficient gene delivery. Furthermore, the wound healing assay demonstrated that the multitargeting gene complexes could promote the proliferation and migration of ECs. These results collectively demonstrated that CAGW and TAT‐NLS peptides functionalized gene delivery system could effectively enhance the transfection of ECs, which has great potential in vascular tissue engineering.     

PEI-g-MPEG/白细胞介素-10基因传递系统转染背根神经节细胞的体外性能研究

探索非病毒基因载体聚乙二醇-聚乙烯亚胺共聚物(PEI-g-MPEG)介导白细胞介素-10(Interleukin-10,IL-10)体外转染原代培养背根神经节细胞(dorsal root ganglion cells,DRGs)的效果.采用本实验室设计合成的PEI-g-MPEG,与同时携带增强型绿色荧光蛋白报告基因及IL-10基因的真核表达质粒DNA(pDC316-EGFP/IL-10)形成复合物,以脂质体(lipofectamine)复合体系Lipo/pDNA为对照,通过溴乙啶(ethidiumbromide,EB)排斥实验、凝胶阻滞电泳实验、粒径与电位的测定及扫描电镜等实验方法观察PEI-g-MPEG/pDNA的复合效果.并且检测了复合物对DRGs的毒性、转染效果及IL-10的蛋白表达情况.结果表明,PEI-g-MPEG在N/P(PEI-g-MPEG所含的氮原子和质粒DNA中磷原子的摩尔比)为5时可完全复合pDNA;随着N/P的增大,PEI-g-MPEG/pDNA复合物的粒径逐渐减小,而表面电位逐渐增大;在N/P为15时报告基因转染效果和IL-10蛋白表达情况较好,复合物的形貌呈大小均一的球形.PEI-g-MPEG/IL-10基因传递系统对于神经病理性疼痛的基因治疗具有潜在应用价值.     

Novel cationic 6-lauroxyhexyl lysinate modified poly(lactic acid)-poly(ethylene glycol) nanoparticles enhance gene transfection

The leading principle of non-viral delivery systems for gene therapy is to mediate high levels of gene expression with low cytotoxicity. Nowadays, biodegradable nanoparticles formulated with poly(lactic acid)-poly(ethylene glycol) (PLA-PEG) were wildly developed. However, the relative lower gene transfection efficiency and higher cytotoxicity still remained critical problems. To address these limitations, PLA-PEG nanoparticles have been composited with other components in their formulation. Here, a novel cationic lipid, 6-lauroxyhexyl lysinate (LHLN), was fabricated onto PLA-PEG nanoparticles as a charge modifier to improve the transfection efficiency and cytotoxicity. The obtained cationic LHLN modified PLA-PEG nanoparticles (LHLN-PLA-PEG NPs) could condense pDNA thoroughly via electrostatic force, leading to the formation of the LHLN-PLA-PEG NPs/pDNA complexes (NPs/DNA complexes). The nanoparticles obtained have been characterized in relation to their physicochemical and biological properties, and the results are extremely promising in terms of low cell toxicity and high transfection efficiency. These results indicated that the novel cationic LHLN modified PLA-PEG nanoparticles could enhance gene transfection in vitro and hold the potential to be a promising non-viral nanodevice.     

Polyphosphonium polymers for siRNA delivery: an efficient and nontoxic alternative to polyammonium carriers

A water-soluble polyphosphonium polymer was synthesized and directly compared with its ammonium analog in terms of siRNA delivery. The triethylphosphonium polymer shows transfection efficiency up to 65% with 100% cell viability, whereas the best result obtained for the ammonium analog reaches only 25% transfection with 85% cell viability. Moreover, the nature of the alkyl substituents on the phosphonium cations is shown to have an important influence on the transfection efficiency and toxicity of the polyplexes. The present results show that the use of positively charged phosphonium groups is a worthy choice to achieve a good balance between toxicity and transfection efficiency in gene delivery systems.     

Improved GFP gene transfection mediated by polyamidoamine dendrimer-functionalized multi-walled carbon nanotubes with high biocompatibility

The multi-walled carbon nanotubes (MWCNTs)-polyamidoamine (PAMAM) hybrid was prepared by covalent linkage approach, and characterized by transmission electron microscopy, Fourier transform infrared spectroscopy and ultraviolet-visible spectrometry. The PAMAM dendrimers were present on the surface of MWCNTs in high density, and the MWCNT-PAMAM hybrid exhibited good dispersibility and stability in aqueous solution. The interaction between MWCNT-PAMAM with plasmid DNA of enhanced green fluorescence protein (pEGFP-N1), intracellular trafficking of the hybrid, transfection performance and cytotoxicity to HeLa cells were evaluated in detail. We found that the MWCNT-PAMAM hybrid possessed good pEGFP-N1 immobilization ability and could efficiently delivery GFP gene into cultured HeLa cells. The surface modification of MWCNTs with PAMAM improved the transfection efficiency 2.4 and 0.9 times, and simultaneously decreased cytotoxicity by about 38%, as compared with mixed acid-treated MWCNTs and pure PAMAM dendrimers. The MWCNT-PAMAM hybrid can be considered as a new carrier for the delivery of biomolecules into mammalian cells. Therefore, this novel system may have good potential applications in biology and therapy, including gene delivery systems.     

A reactive oxygen species-responsive dendrimer with low cytotoxicity for efficient and targeted gene delivery

Nonviral vectors have been attracting more attention for several advantages in gene delivery and the development of nonviral gene ca rriers with high delivery efficiency and low cytotoxicity has long been a key project.Starburst polyamidoamine dendrimers are a class of synthetic polymers with unique structural and physical characteristics.However,when they are used as gene carrier,the gene transfection efficiency is not satisfactory.Herein,a novel thioketal-core polyamidoamine dendrimer(i.e.,ROS-PAMAM)was synthesized and characterized.Compared to ethylenediamine-core dendrimers or widely used cationic polymers of polyetherimide,ROS-PAMAM showed lower cytotoxicity.Moreover,ROS-PAMAM demonstrated reactive oxygen species responsive characteristics,which can facilitate the release of siRNA in the tumor microenvironment.In vitro gene transfection experiments based on A549 cells confirmed that siRNA/ROS-PAMAM exhibits high gene transfection efficiency.It is concluded that ROS-PAMAM shows great potential as a generalizable vehicle for gene therapy applications.     

胆固醇修饰的低分子量聚乙烯亚胺接枝化聚[L-天冬酰胺-co-L-赖氨酸]作为基因载体的性能研究

通过将低分子量的聚乙烯亚胺(PEI600)及其胆固醇衍生物与聚(L-天冬酰胺-co-L-赖氨酸)(PSL)进行开环反应, 合成了一类新型的肿瘤靶向基因载体, 研究了这类载体与DNA形成复合物的性质以及介导绿色荧光蛋白质粒pEGFP-C1转染不同细胞的性能. 结果表明, 在复合质量比大于5∶1时, 各载体均能与DNA形成结构稳定的复合物. 同时转染实验结果证明, 通过在侧链引入一定数目的胆固醇, 可以明显提高载体对于癌细胞HepG2和Hela的转染效率. 这类新型的载体具有良好的细胞相容性、较高的转染效率以及易于进行靶向修饰等特点, 在基因治疗研究领域中将具有较好的潜在应用价值.     

Polymers for DNA delivery

Nucleic acid delivery has many applications in basic science, biotechnology, agriculture, and medicine. One of the main applications is DNA or RNA delivery for gene therapy purposes. Gene therapy, an approach for treatment or prevention of diseases associated with defective gene expression, involves the insertion of a therapeutic gene into cells, followed by expression and production of the required proteins. This approach enables replacement of damaged genes or expression inhibition of undesired genes. Following two decades of research, there are two major methods for delivery of genes. The first method, considered the dominant approach, utilizes viral vectors and is generally an efficient tool of transfection. Attempts, however, to resolve drawbacks related with viral vectors (e.g., high risk of mutagenicity, immunogenicity, low production yield, limited gene size, etc.), led to the development of an alternative method, which makes use of non-viral vectors. This review describes non-viral gene delivery vectors, termed "self-assembled" systems, and are based on cationic molecules, which form spontaneous complexes with negatively charged nucleic acids. It introduces the most important cationic polymers used for gene delivery. A transition from in vitro to in vivo gene delivery is also presented, with an emphasis on the obstacles to achieve successful transfection in vivo.     

Delivery of Survivin siRNA Using Cationic Diphenylalanine Vesicles

Small interfering RNA(siRNA) has been proved to be a powerful tool for silencing target gene in cells, raising the possibility that siRNA can be employed as a therapy for treating cancers and other genetic diseases. However, siRNA transfection has the limitation due to the difficulty in the delivery of siRNA to target cells and tissues. To explore an efficient biocompatible siRNA delivery system, cationic diphenylalanine vesicles(CDPVs) were constructed to transfer survivin siRNA to human ovarian cancer cells. The morphology of CDPVs was characterized by scanning electron microscopy(SEM) and the distribution of survivin siRNA was characterized by confocal laser scanning microscopy, which reveal that diphenylalanine and the survivin siRNA were successfully co-delivered. After co-incubation for 48 h, the CDPVs/siRNA exhibited enhanced tumor cell growth inhabitation and apoptosis inducted in human SK-OV-3 ovarian carcinoma cells. Overall, CDPVs is an efficient siRNA delivery system and has a promising prospect for cancer therapy.     

Bimodal Targeting Using Sulfonated,Mannosylated PEI for Combined Gene Delivery and Photodynamic Therapy

Photodynamic therapy (PDT) and gene delivery have both been used to target both cancer cells and tumor‐associated macrophages (TAMs). Given the complex nature of tumor tissue, there could be merit in combining these strategies simultaneously. In this study, we developed a bimodal targeting approach to both cancer cells and macrophages, employing materials conducive to both gene delivery and PDT. Polymers libraries were created that consisted of cationic polyethyleneimine (PEI) conjugated to the photosensitizer pyropheophorbide‐a, with sulfonation (to target selectin‐expressing cells) and mannosylation (to target TAMs). Polyplexes, consisting of these polymers electrostatically bound to DNA, were analyzed for transfection efficacy and cytotoxicity toward epithelial cells and macrophages to assess dual‐targeting. This study provides preliminary proof of principle for using modified PEI for targeted gene delivery and PDT.     

Self‐Assembled Fluorodendrimers Combine the Features of Lipid and Polymeric Vectors in Gene Delivery

An ideal vector in gene therapy should exhibit high serum stability, excellent biocompatibility, a desired transfection efficacy and permeability into targeted tissues. Here, we describe a class of low‐molecular‐weight fluorodendrimers for efficient gene delivery. These materials self‐assemble into uniform nanospheres and allow for efficient transfection at low charge ratios and very low DNA doses with minimal cytotoxicity. Our results demonstrate that these vectors combine the features of synthetic gene vectors such as liposomes and cationic polymers and present promising potential for clinical gene therapy.     

Therapeutic Potential of DNAzyme Loaded on Chitosan/Cyclodextrin Nanoparticle to Recovery of Chemosensitivity in the MCF-7 Cell Line

Commonly, acquired resistances to anticancer drug are mediated by overexpression of a membrane-associated protein that encode via multi-drug resistance gene-1 (MDR1). Herein, the mRNA-cleaving DNAzyme that targets the mRNA of MDR1 gene in doxorubicin-resistant breast cancer cell line (MCF-7/DR) loaded on the chitosan β-cyclodextrin complexes was used as a tropical agent. Chitosan/β-cyclodextrin complexes were used to deliver DNAzymes into cancer cells. Determination of the physicochemical characteristics of the particles was done by photon correlation spectroscopy and scanning electron microscopy. The encapsulation efficiency of the complexes was tested by using gel retardation assay. Positively charged nanoparticles interacted with DNAzyme that could perform as an efficient DNAzyme transfection system. The rationale usage of this platform is to sensitize MCF-7/DR to doxorubicin by downregulating the drug-resistance gene MDR1. Results demonstrated a downregulation of MDR1 mRNAs in MCF-7/DR/DNZ by real-time PCR, compared to the MCF-7/DR as control. WST1 assay showed the 22-fold decrease in drug resistance on treated cells 24 h after transfection. Results showed the intracellular accumulation of Rh123 increased in the treated cells with DNAzyme. Results suggested a potential platform in association with chemotherapy drug for cancer therapy and indicated extremely efficient at delivery of DNAzyme in restoring chemosensitivity.

     

Gene transfection using biodegradable nanospheres: results in tissue culture and a rat osteotomy model

In this paper, we have investigated sustained release biodegradable nanospheres for the delivery of plasmid DNA. The nanospheres were formulated using a proprietary co-polymer emulsion technique to encapsulate plasmid DNA. Gene transfection with nanospheres containing reporter genes (human placental alkaline phosphatase (AP) or Luciferase) was demonstrated in tissue culture (293T and COS-7 cells), and also in vivo in a nonunion femoral fracture (osteotomy) rat model. The bone gap was filled with nanospheres and gene expression in the implantation site was measured five weeks after the initial surgery. The nanospheres had a mean diameter of 230 nm, with a DNA loading of 0.7%w/w. These nanospheres demonstrated sustained release of the encapsulated DNA under in vitro physiologic conditions with an 82% cumulative DNA release over 17 days. The transfection efficiency of the nanospheres in tissue culture was two to five orders of magnitude greater than the gene expression with the same amount of plasmid DNA in solution. In the rat studies, the mean AP activity in the tissue retrieved from the osteotomy site in the experimental group was 291.8±52.5 cpm Versus 54.1±26.5 cpm (mean±S.E.M., P=0.03) in the sham control group. In conclusion, plasmid DNA nanospheres could be used as an effective nonviral method of gene delivery. In the future, nanospheres containing therapeutic genes, such as those encoding parathyroid hormone peptide, 1–34 amino acids (PTH-34) or Bone Morphogenic Protein-4 (BMP-4), could be used for the healing of nonunion bone fracture sites.     

Solid-phase synthesis of 89 polyamine-based cationic lipids for DNA delivery to mammalian cells

The ability of non-viral gene delivery systems to overcome extracellular and intracellular barriers is a critical issue for future clinical applications of gene therapy. In recent years much effort has been focused on the development of a variety of DNA carriers, and cationic liposomes have become the most common non-viral gene delivery system. Solid-phase synthesis was used to produce three libraries of polyamine-based cationic lipids with diverse hydrophobic tails. These were characterised, and structure-activity relationships were determined for DNA binding and transfection ability of these compounds when formulated as cationic liposomes. Two of the cationic lipids produced high-efficiency transfection of human cells. Surprisingly, these two compounds were from the library with two headgroups and one aliphatic tail, a compound class regarded as detergent-like and little investigated for transfection. These cationic lipids are promising reagents for gene delivery and illustrate the potential of solid-phase synthesis methods for lipoplex discovery.     

Hydrogen bonds in polycation improve the gene delivery efficiency in the serum-containing environment

Cationic polymers with high charge density could effectively condense the DNA and achieve gene transfection; however, it often brings non-negligible cytotoxicity. Notably, the high charge density gene vector fails in the serum environment, limiting further application in vivo. In this paper, an efficient and reliable non-viral gene vector of poly (amidoamine) (PAA) was designed by introducing diacryolyl-2,6-diaminopyridine (DADAP) onto the PAA backbone through Michael-addition polymerization, which provides high transfection efficiency in a serum-containing environment. Diacryolyl-2,6-diaminopyridine and cationic parts provided multiple interactions between gene vectors and DNA, including hydrogen bond and electrostatic interactions. The introduction of hydrogen bonding can effectively reduce the charge density of polyplexes without reducing the DNA condensing ability, incorporating the diaminopyridine group and cationic part in PAA chains successfully consolidated cellular uptake, endosome destabilization, and transfection efficiency for the PAA/DNA complexes with low cytotoxicity. The constructed vector with multiple interactions presented 6 times higher transfection efficiency in serum-free and 9 times in serum-containing environment than that of branched polyethyleneimine (PEI 25K) in 293T cells in vitro. Therefore, introducing the hydrogen band to form low charge density polyplexes with high transfection efficiency and low cytotoxicity has a great potential in gene delivery.