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。     

非病毒载体的研究现状

非病毒载体在基因表达质粒,反义寡核苷酸或反义表达质粒直核细胞的靶向转移中,有着病毒载体不可替代的作用,对这方面的研究人们投入了很大的精力,以期在基因治疗方面有所突破。本文综述了近年来非病毒载体的研究现状,分别阐明了质粒DNA肌肉注射,脂质体载体、多聚阳离子载体、多肽导向载体以及嵌合载体,指出了非病毒载体亟需发展这外以及病毒载体与非病毒载体联合发展的必要性。     

非病毒型基因载体研究进展

非病毒载体以其安全性、低毒性、低免疫反应、靶向性及易于组装等优点被寄予厚望 ,对非病毒载体的研究人们投入了很大的精力 ,以期在基因治疗方面有所突破。综述了近年来非病毒载体的研究现状 ,分别总结阐述了阳离子脂质体载体、多聚阳离子载体、壳聚糖载体、树状高分子载体以及无机壳类SiO2 纳米粒子载体。提出非病毒载体今后的发展方向及发展的必要性。     

钠米颗粒介导质粒DNA转染体外真核细胞

DNA传递是基因表达与功能研究及其医学应用的重要技术,安全高效的DNA传递一直是研究者期待的目标。利用一种新的阳离子多聚物脱乙酰甲壳胺16介导重组质粒pcDNA3vp1转染COS7细胞,RTPCR可检测到目的基因vp1在mRNA水平的表达,实时定量PCR结果表明其转染效率介于脂质体与磷酸钙法之间,同时还对转染条件进行了探讨。DNA结合分析发现脱乙酰甲壳胺16能够与DNA形成核酸纳米颗粒,提高DNA稳定性,促进真核细胞转染效率的提高。这些结果表明脱乙酰甲壳胺16确能做为一种新型的非病毒纳米DNA传递载体,并将可能在基因表达与功能研究及基因治疗等领域发挥重要作用 。     

基因治疗的输送屏障及输送载体的研究

基因治疗是将可具有治疗性的基因导入病变细胞以达到治疗遗传性疾病或获得性功能缺损疾病的治疗手段,是一种极具潜力的新型治疗方法。然而基因治疗面临着一系列一陆床应用障碍,其中缺乏理想的基因输送载体是首要问题。绝大多数基因治疗方案受困缺乏安全有效的基因输送手段,载体要达到目的地发挥作用,需要克服一系列复杂的体内生物屏障,包括细胞外屏障和细胞内屏障。目前基因输送载体主要分为病毒载体和非病毒载体,其中病毒载体天然进化至可进入宿主细胞,具有输送效率高,靶向性好的特点,但存在长期安全性的缺点。非病毒载体主要包括阳离子脂质体和阳离子聚合物,由于易于制备和无免疫原性、安全性好,被认为是更有潜力的输送载体,是目前研究的重点。本文结合基因治疗输送屏障的理论基础及临床研究,对基因输送载体系统的现状进行了综述。     

新型非病毒三元复合DNA载体的研究

基因治疗是未来临床医学最具潜力的治疗方式,目前阻碍临床基因治疗发展的主要因素是缺乏安全和高效的基因载体,因此研究理想的非病毒转基因载体具有重要的意义.构建了由质粒DNA(D)-抗DNA抗体(A)-阳离子脂质体(C)组成的三元复合纳米基因载体(DAC),研究表明,三组分在磷酸缓冲液中可通过分子组装形成复合纳米胶束,DAC在细胞培养中表现出显著高效的基因表达,DAC在血管平滑肌细胞中的基因转染效率比不含抗DNA抗体的二元组合(DC)高4倍,比不含阳离子脂质体的二元组合(DA)约高11倍.激光共聚焦荧光显微观察证明,DAC细胞摄取量和DNA进入细胞核的量均明显高于对照组,而DC二元组合(不含抗DNA抗体)的DNA很少进入细胞核,细胞在DAC存在下生长正常.未发现细胞毒性.研究结果提示,DAC的作用机理主要是三元复合胶束中DNA的装载量比二元载体大得多,抗DNA抗体与阳离子脂质体的协同作用明显有利于DNA被细胞摄取和胞吞,从而提高了基因的转染和表达.     

非病毒型载体介导基因转染

基因载体是制约基因转移技术发展的关键。近年来,非病毒载体由于其安全、低毒、低免疫原性等特点而备受青睐。文章以脂质体和聚乙烯亚胺为代表,介绍了非病毒载体的性质、介导转染的机制。随着人们对细胞转染机制了解的深入以及生物材料科学的迅速发展,非病毒型载体将有望实现高效、低毒、靶向特异等特点,从而成为基因治疗中的理想载体。     

5个HIV基因修饰可明显提高其在不同系统中的表达

目的:确定HIV-1疫苗中有效的交叉保护性细胞免疫抗原,提高各个基因在相应疫苗载体中的表达水平,为研究不同抗原在DNA载体和痘苗病毒载体中的免疫原性奠定实验基础。方法:选择HIV B′/C亚型5个以细胞免疫为主的抗原(Gag、Pol、Rev、Tat和Nef),进行基因序列优化及表达结构改造,并分别构建以质粒DNA和重组痘苗病毒为载体的两大类HIV-1疫苗。结果:优化前后5个目的基因均能够在这2种载体中有效表达;虽然采用相同的基因修饰策略,但与痘苗病毒载体相比,在DNA载体中各基因表达水平的提高均较为明显;含有抑制性序列(INS)的gag、pol基因经密码子优化后,Gag、Pol蛋白的表达均明显提高,其中Pol蛋白的提高更为明显,单独pol基因比gagpol天然结构表达水平要高,而gag基因却变化不大;对于rev、tat、nef基因而言,优化后的单独基因结构要略高于优化后的融合结构(hRTN),且二者均高于未优化的融合结构(RTN)。结论:为进一步确定HIV-1疫苗中有效的交叉保护性细胞免疫抗原、研究不同抗原在DNA载体和痘苗病毒载体中的免疫原性奠定了实验基础,为进一步研究DNA疫苗和重组痘苗病毒疫苗联合免疫提供了实验依据。     

鸡白细胞介素2增强传染性法氏囊病病毒多聚蛋白DNA疫苗免疫原性的研究

鸡白细胞介素 2(IL-2)基因是新近被确定的非哺乳类IL-2基因。将鸡白细胞介素2(IL-2)基因和传染性法氏囊病病毒 (IBDV)多聚蛋白基因 (VP2/VP4/VP3)分别插入真核表达载体pCI的CMV启动子下游 ,制备DNA疫苗 ,免疫 14日龄SPF鸡 ,14d后二免 ,二免后 3d攻击标准强毒株。结果表明共注射鸡IL 2质粒能明显增强DNA疫苗对强毒攻击 ,保护率达 80 % ;能增强DNA疫苗诱导的中和抗体效价 (P<0.05 ) ;能显著促进鸡胸腺、脾脏和外周血液T淋巴细胞及法氏囊B淋巴细胞增殖反应(P<0.05)。这些结果提示鸡IL 2能明显增强IBDV多聚蛋白DNA疫苗的免疫原性 ,是一种优良的禽类DNA疫苗佐剂。     

纳米颗粒作为基因载体的应用

随着纳米技术的发展,纳米颗粒因具有较高的转染效率、良好的靶向性及有效的基因保护作用而被用作基因载体。简要介绍了磁性纳米颗粒、硅纳米颗粒及阳离子多聚物颗粒等的研究进展。     

Polymer‐coated viral vectors: hybrid nanosystems for gene therapy

The advantages and critical aspects of nanodimensional polymer‐coated viral vector systems potentially applicable for gene delivery are reviewed. Various viral and nonviral vectors have been explored for gene therapy. Viral gene transfer methods, although highly efficient, are limited by their immunogenicity. Nonviral vectors have a lower transfection efficiency as a result of their inability to escape from the endosome. To overcome these drawbacks, novel nanotechnology‐mediated interventions that involve the coating or modification of virus using polymers have emerged as a new paradigm in gene therapy. These alterations not only modify the tropism of the virus, but also reduce their undesirable interactions with the biological system. Also, co‐encapsulation of other therapeutic agents in the polymeric coating may serve to augment the treatment efficacy. The viral particles can aid endosomal escape, as well as nuclear targeting, thereby enhancing the transfection efficiency. The integration of the desirable properties of both viral and nonviral vectors has been found beneficial for gene therapy by enhancing the transduction efficiency and minimizing the immune response. However, it is essential to ensure that these attempts should not compromise on the inherent ability of viruses to target and internalize into the cells and escape the endosomes.     

Nuclear localization signal peptide enhances transfection efficiency and decreases cytotoxicity of poly(agmatine/N,N′-cystamine-bis-acrylamide)/pDNA complexes

At present, nonviral gene vectors develop rapidly, especially cationic polymers. A series of bioreducible poly(amide amine) (PAA) polymers containing guanidino groups have been synthesized by our research team. These novel polymer vectors demonstrated significantly higher transfection efficiency and lower cytotoxicity than polyethylenimine (PEI)—25kDa. However, compared with viral gene vectors, relatively low transfection efficiency, and high cytotoxicity are still critical problems confronting these polymers. In this study, poly(agmatine/N,N′-cystamine-bis-acrylamide) p(AGM-CBA) was selected as a model polymer, nuclear localization signal (NLS) peptide PV7 (PKKKRKV) with good biocompatibility and nuclear localization effect was introduced to investigate its impact on transfection efficiency and cytotoxicity. NLS peptide-mediated in vitro transfection was performed in NIH 3T3 cells by directly incorporating NLS peptide with the complexes of p(AGM-CBA)/pDNA. Meanwhile, the transfection efficiency and cytotoxicity of these complexes were evaluated. The results showed that the transfection efficiency could be increased by 5.7 times under the appropriate proportion, and the cytotoxicity brought by the polymer vector could be significantly reduced.     

Recent patents in cationic lipid carriers for delivery of nucleic acids

Gene therapy is a medical technique intended for treatment of disorders caused by defective, missing, or overexpressing genes. Efficient delivery vectors are necessary in order to transport genetic material to the target cells. Such vectors include viral and non-viral carriers. Viral vectors transfect cells efficiently, however risks associated with their use have limited their clinical applications. Nonviral delivery systems are safer, easier to prepare, more versatile and cost effective. However, their transfection efficiency still falls behind that of the viral vectors. Considerable research into nonviral gene delivery has been conducted in the last two decades on synthetic soft materials such as cationic lipids, polymers, surfactants, and dendrimers as prospective nucleotide carriers for gene delivery. So far, cationic lipids are the most widely used constituents of nonviral gene carriers, with multiple strategies employed to improve their in vitro and in vivo transfection. Efforts in synthesizing new cationic lipids were not fully successful in closing the gap between the efficiency of the viral vectors and that of binary cationic lipid/DNA complexes. Current efforts for improving lipofection efficiency are focused on the development of multicomponent carriers including cationic lipids as key constituents. This review summarizes the recent patents on new cationic lipids as well as on multicomponent formulations enhancing their efficiency as nucleotide carriers.     

Functional and biodegradable dendritic macromolecules with controlled architectures as nontoxic and efficient nanoscale gene vectors

Gene therapy has provided great potential to revolutionize the treatment of many diseases. This therapy is strongly relied on whether a delivery vector efficiently and safely directs the therapeutic genes into the target tissue/cells. Nonviral gene delivery vectors have been emerging as a realistic alternative to the use of viral analogs with the potential of a clinically relevant output. Dendritic polymers were employed as nonviral vectors due to their branched and layered architectures, globular shape and multivalent groups on their surface, showing promise in gene delivery. In the present review, we try to bring out the recent trend of studies on functional and biodegradable dendritic polymers as nontoxic and efficient gene delivery vectors. By regulating dendritic polymer design and preparation, together with recent progress in the design of biodegradable polymers, it is possible to precisely manipulate their architectures, molecular weight and chemical composition, resulting in predictable tuning of their biocompatibility as well as gene transfection activities. The multifunctional and biodegradable dendritic polymers possessing the desirable characteristics are expected to overcome extra- and intracellular obstacles, and as efficient and nontoxic gene delivery vectors to move into the clinical arena.     

Nonviral gene therapy targeting cardiovascular system

The goal of gene therapy is either to introduce a therapeutic gene into or replace a defective gene in an individual's cells and tissues. Gene therapy has been urged as a potential method to induce therapeutic angiogenesis in ischemic myocardium and peripheral tissues after extensive investigation in recent preclinical and clinical studies. A successful gene therapy mainly relies on the development of the gene delivery vector. Developments in viral and nonviral vector technology including cell-based gene transfer will further improve transgene delivery and expression efficiency. Nonviral approaches as alternative gene delivery vehicles to viral vectors have received significant attention. Recently, a simple and safe approach of gene delivery into target cells using naked DNA has been improved by combining several techniques. Among the physical approaches, ultrasonic microbubble gene delivery, with its high safety profile, low costs, and repeatable applicability, can increase the permeability of cell membrane to macromolecules such as plasmid DNA by its bioeffects and can provide as a feasible tool in gene delivery. On the other hand, among the promising areas for gene therapy in acquired diseases, ischemic cardiovascular diseases have been widely studied. As a result, gene therapy using advanced technology may play an important role in this regard. The aims of this review focus on understanding the cellular and in vivo barriers in gene transfer and provide an overview of currently used chemical vectors and physical tools that are applied in nonviral cardiovascular gene transfer.     

Biodegradable poly(vinyl alcohol)-polyethylenimine nanocomposites for enhanced gene expression in vitro and in vivo

Use of cationic polymers as nonviral gene vectors has several limitations such as low transfection efficiency, high toxicity, and inactivation by serum. In this study, varying amounts of low molecular weight branched polyethylenimine 1.8 kDa (bPEI 1.8) were introduced on to a neutral polymer, poly(vinyl alcohol) (PVA), to bring in cationic charge on the resulting PVA-PEI (PP) nanocomposites. We rationalized that by introducing bPEI 1.8, buffering and condensation properties of the proposed nanocomposites would result in improved gene transfer capability. A series of PVA-PEI (PP) nanocomposites was synthesized using well-established epoxide chemistry and characterized by IR and NMR. Particle size of the PP/DNA complexes ranged between 120 to 135 nm, as determined by dynamic light scattering (DLS), and DNA retardation assay revealed efficient binding capability of PP nanocomposites to negatively charged nucleic acids. In vitro transfection of PP/DNA complexes in HEK293, HeLa, and CHO cells revealed that the best working formulation in the synthesized series, PP-3/DNA complex, displayed ~2-50-fold higher transfection efficiency than bPEIs (1.8 and 25 kDa) and commercial transfection reagents. More importantly, the PP/DNA complexes were stable over a period of time, along with their superior transfection efficiency in the presence of serum compared to serum-free conditions, retaining the nontoxic property of low molecular weight bPEI. The in vivo administration of PP-3/DNA complex in Balb/c mice showed maximum gene expression in their spleen. The study demonstrates the potential of PP nanocomposites as promising nonviral gene vectors for in vivo applications.     

Nucleofection-based gene targeting in human pre-B cells

Electroporation is a powerful and convenient means for transfection of nonviral vectors into mammalian cells, providing an essential tool for numerous applications including gene targeting via homologous recombination. Recent evidence clearly suggests that high-efficiency gene transfer can be achieved in most cell lines by nucleofection, an electroporation-based transfection method that allows transfected vectors to directly enter the nucleus. In this paper, we analyze the effectiveness of nucleofection for gene targeting using human pre-B cells. For this, we tested 93 different transfection conditions, and found several conditions that gave high (~ 80%) transfection efficiency with low cytotoxicity (~ 70% survival rate). Remarkably, under the optimal nucleofection conditions, the gene-targeting efficiency was ~ 2-5-fold higher than that achieved with conventional electroporation methods. We also found that nucleofection conditions with high transfection efficiency and low cytotoxicity tend to provide high gene-targeting efficiency. Our results provide significant implications for gene targeting, and suggest that nucleofection-based nonviral gene transfer is useful for systematic generation of human gene-knockout cell lines.     

Comparison of nonviral transfection and adeno-associated viral transduction on cardiomyocytes

Cardiomyocytes are terminally differentiated cells that to date have been characterized as poor targets for nonviral gene transfer. This study was therefore designed to determine the optimal nonviral gene transfer parameters in cell cultures of neonatal rat cardiomyocytes and to compare them with the efficiency of gene transfer using adeno-associated viral vectors (AAV). Transfection efficiency was measured by quantitative chloramphenicol acetyltransferase type I (CAT)-enzyme-linked immunosorbent assay and β-galactosidase staining, based on overexpression of reporter genes (CAT and LacZ). The efficiency of CAT/LacZ overexpression was assessed using the following techniques: (1) liposomal reagents, such as: FuGENE 6, LipofectAMINE 2000, LipofectAMINE PLUS, GenePORTER, Metafectene, and LipoGen; (2) electroporation and nucleofector techniques; and (3) an AAV2 vector harboring a lacZ reporter gene. Toxicity was monitored by total protein measurement and by analyzing cell metabolism. On average, Lipofectamine 2000 was the most effective nonviral method examined yielding consistently high transfection rates (8.1% β-galactosidase-positive cells) combined with low toxicity. Electroporation also resulted in high transfection values (7.5%); however, cellular toxicity was higher than that of Lipofectamine 2000. Finally, transduction with AAV2 vectors provided the highest levels of transduction (88.1%) with no cellular toxicity. We conclude that although transduction with AAV is more efficient (88.1%), transfections with nonviral techniques, when optimized, may provide a useful alternative for overexpression of therapeutic genes in neonatal cardiomyocytes.     

Facilitation of gene transfection with well-defined degradable comb-shaped poly(glycidyl methacrylate) derivative vectors

Recently, we reported that ethanolamine (EA)-functionalized poly(glycidyl methacrylate) (PGMA) vectors (PGEAs) can produce good transfection efficiency, while exhibiting very low toxicity. Further improvement in degradability and transfection efficiency of the PGEA vectors will facilitate their application in gene therapy. Comb-shaped cationic copolymers have been of interest and importance as nonviral gene carriers. Herein, the degradable high-molecular-weight comb-shaped PGEA vectors (c-PGEAs) composed of the low-molecular-weight PGEA backbone and side chains were prepared by a combination of atom transfer radical polymerization (ATRP) and ring-opening reactions. The PGEA side chains were linked with the PGEA backbones via hydrolyzable ester bonds. Such comb-shaped c-PGEA vectors possessed the degradability, good pDNA condensation ability, low cytotoxicity, and good buffering capacity. More importantly, the comb-shaped c-PGEA vectors could enhance the gene expression levels. Moreover, the PGEA side chains of c-PGEA could also be copolymerized with some poly(poly(ethylene glycol)ethyl ether methacrylate) species to further improve the gene delivery system.     

The role of surface chemistry-induced cell characteristics on nonviral gene delivery to mouse fibroblasts

ABSTRACT: BACKGROUND: Gene delivery approaches serve as a platform to modify gene expression of a cell population with applications including functional genomics, tissue engineering, and gene therapy. The delivery of exogenous genetic material via nonviral vectors has proven to be less toxic and to cause less of an immune response in comparison to viral vectors, but with decreased efficiency of gene transfer. Attempts have been made to improve nonviral gene transfer efficiency by modifying physicochemical properties of gene delivery vectors as well as developing new delivery techniques. In order to further improve and understand nonviral gene delivery, our approach focuses on the cell-material interface, since materials are known to modulate cell behavior, potentially rendering cells more responsive to nonviral gene transfer. In this study, self-assembled monolayers of alkanethiols on gold were employed as model biomaterial interfaces with varying surface chemistries. NIH/3T3 mouse fibroblasts were seeded on the modified surfaces and transfected using either lipid- or polymer- based complexing agents. RESULTS: Transfection was increased in cells on charged hydrophilic surfaces presenting carboxylic acid terminal functional groups, while cells on uncharged hydrophobic surfaces presenting methyl terminations demonstrated reduced transfection for both complexing agents. Surface--induced cellular characteristics that were hypothesized to affect nonviral gene transfer were subsequently investigated. Cells on charged hydrophilic surfaces presented higher cell densities, more cell spreading, more cells with ellipsoid morphologies, and increased quantities of focal adhesions and cytoskeleton features within cells, in contrast to cell on uncharged hydrophobic surfaces, and these cell behaviors were subsequently correlated to transfection characteristics. CONCLUSIONS: Extracellular influences on nonviral gene delivery were investigated by evaluating the upregulation and downregulation of transgene expression as a function of the cell behaviors induced by changes in the cells' microenvronments. This study demonstrates that simple surface modifications can lead to changes in the efficiency of nonviral gene delivery. In addition, statistically significant differences in various surface-induced cell characteristics were statistically correlated to transfection trends in fibroblasts using both lipid and polymer mediated DNA delivery approaches. The correlations between the evaluated complexing agents and cell behaviors (cell density, spreading, shape, cytoskeleton, focal adhesions, and viability) suggest that polymer-mediated transfection is correlated to cell morphological traits while lipid-mediated transfection correlates to proliferative characteristics.