Lectin functionalized nanocarriers for gene delivery

Gene therapy has emerged as one of the most promising therapeutic methods to treat various diseases. However, inadequate gene transfection efficacy during gene therapy demands further development of more efficient gene delivery strategies. Targeting genetic material to specific sites of action endows numerous advantages over non-targeted delivery. An ample variety of non-viral gene delivery vectors have been developed in recent years owing to the safety issues raised by viral vectors. Non-viral gene delivery vectors containing specific targeting ligands on their surfaces have been reported to enhance the gene transfection efficiency via receptor-mediated endocytosis for gene delivery. Among various targeting moieties investigated, carbohydrates and lectins (carbohydrate-binding proteins) played an essential role in gene delivery via either direct or reverse lectin targeting strategies. Lectins have a specific carbohydrate binding domain that can bind specifically to the carbohydrates. This review sheds light on various gene delivery nanovectors conjugated with either lectins or carbohydrates for enhanced gene transfection.     

阳离子聚合物在非病毒基因转染中的研究进展

基因治疗为治疗先天性遗传疾病和严重后天获得性疾病提供了一条新途径.目前,基因载体分为两类:病毒载体和非病毒载体.病毒载体转染效率高,但由于某些病毒载体存在免疫原性、致癌性、宿主DNA插入整合等缺点,从而限制了它们的应用.非病毒载体具有价格低、制备简单、安全有效、无免疫原性等优点,成为基因载体研究的热点.阳离子多聚物是非病毒载体的典型代表.文中综述近年来阳离子多聚物作为基因载体的研究现状和进展,重点介绍了阳离子多聚物基因载体的分类和与DNA的相互作用和传递机制.     

Design,preparation and application of nucleic acid delivery carriers

Gene delivery vectors must deliver their cargoes into the cytosol or the nucleus, where DNA or siRNA functions in vivo. Therefore it is crucial for the rational design of the nucleic acid delivery carriers. Compared with viral vectors, non-viral vectors have overcome some fatal defections in gene therapy. Whereas the most important issue for the non-viral vectors is the low transfection efficiency, which hinders the progress of non-viral carriers. Sparked by the structures of the virus and understanding of the process of virus infection, various biomimic structures of non-viral carriers were designed and prepared to improve the transfection issues in vitro and in vivo. However, less impressive results are achieved. In this review, we will investigate the evolution of the virus-mimicking carriers of nucleic acids for gene therapy, especially in cancer therapy; explore and discuss the relationship between the structures, materials and functions of the carriers, to provide guidance for establishing safe and highly efficient non-viral carriers for gene therapy.     

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.     

Acid‐activated nonviral peptide vector for gene delivery

Nonviral vector–based gene therapy is a promising strategy for treating a myriad of diseases. Cell‐penetrating peptides are gaining increasing attention as vectors for nucleic acid delivery. However, most studies have focused more on the transfection efficiency of these vectors than on their specificity and toxicity. To obtain ideal vectors with high efficiency and safety, we constructed the vector stearyl‐TH by attaching a stearyl moiety to the N‐terminus of the acid‐activated cell penetrating peptide TH in this study. Under acidic conditions, stearyl‐TH could bind to and condense plasmids into nanoparticle complexes, which displayed significantly enhanced cellular uptake and transfection efficiencies. In contrast, stearyl‐TH lost the capacities of DNA binding and transfection at physiological pH. More importantly, stearyl‐TH and the complexes formed by stearyl‐TH and plasmids displayed no obvious toxicity at physiological pH. Consequently, the high transfection efficiency under acidic conditions and low toxicity make stearyl‐TH a potential nucleic acid delivery vector for gene therapy.     

Multifunctional nanocomplexes for gene transfer and gene therapy

DNA formulated into aggregates with polycationic reagents are referred to by a variety of terms including non-viral vectors, synthetic vectors, lipoplexes, polyplexes and more recently nanoparticles. The capacity for delivery of multiple genes, genomic-sized constructs and siRNA delivery, with a diversity of possible formulations, as well as the possibilities of improved efficiency of in vivo gene deliveries, means that nanoparticles, or nanocomplexes to reflect self-assembling systems, will be investigated with increasing vigour in the coming years. This review briefly outlines the applications and challenges for nanoparticle technologies in the field of gene therapy then focuses on the development of a specific kind of formulation, receptor-targeted nanocomplex (RTN), that we have found to be particularly useful in our gene therapy research. An overriding guiding concept that has emerged in the development of synthetic nanodelivery systems is the idea to develop formulations and structures that mimic viruses, whilst retaining the safety elements of synthetic, non-viral systems. RTNs have been optimised and developed for airway epithelial transfection, leading towards gene therapy for cystic fibrosis and for vascular transfection in vein grafts used in bypass surgery. The modular design of the RTN platform further allows for the testing of specific hypotheses relating to the structure and functional role of components in the formation of stable particles and in the transfection pathway, leading to their ultimate disassembly in the nucleus.     

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.     

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。     

Biosurfactants of MEL-A increase gene transfection mediated by cationic liposomes.

Many microorganisms growing on water-insoluble substrates have been known to produce surface-active compounds called biosurfactants. Although biosurfactants have received increasing attention due to their special properties, there has been no information available until now of a role for them with regard to gene transfection. Thus, we studied here the effects of biosurfactants on gene transfection by cationic liposomes with a cationic cholesterol derivative. Our results showed clearly that a biosurfactant of mannosylerythritol lipid A (MEL-A) increased dramatically the efficiency of gene transfection mediated by cationic liposomes with a cationic cholesterol derivative. Among them, the liposomes with a cationic cholesterol derivative, cholesteryl-3 beta-carboxyamindoethylene-N-hydroxyethylamine (I), were much more effective for gene transfection than the liposomes with DC-Chol (cholesteryl-3 beta-oxycarboxyamidoethylenedimethylamine) or liposomes without MEL-A in various cultured cells. This demonstrates that this new finding has great potential in the experiment of gene transfection and gene therapy mediated by nonviral vectors such as cationic liposomes.     

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.     

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。     

Biodegradable,endosome disruptive,and cationic network-type polymer as a highly efficient and nontoxic gene delivery carrier

The success of gene therapy is largely dependent on the delivery vector system. Efficient transfection and nontoxicity are two of the most important requirements of an ideal gene delivery vector. To generate both an efficient and nontoxic vector, we rationally constructed polymeric vectors to have simultaneous multiple functions, i.e., controlled degradation, an endosome disruptive function, and positive charges. Remarkably, the transfection efficiency of network poly(amino ester) (n-PAE) synthesized in this manner was comparable to that of polyethylenimine (PEI), one of the most efficient polymeric gene delivery vectors reported to date. However, there was a marked difference in cytotoxicity between the polymers. The majority of PEI-transfected cells were granulated and dead, whereas most of the cells transfected with n-PAE were viable and healthy. Successive events of efficient endosome escape of n-PAE/DNA polyplex and n-PAE biodegradation should result in high transfection efficiency and favorable cell viability response. The n-PAE-mediated transfection was also very efficient in the presence of serum. These data show that the approach we applied is a very appropriate way of making an ideal gene delivery carrier.     

Comparison of cis and trans tat gene expression in HIV LTR-based amplifier vectors

The long terminal repeat (LTR) of the human immunodeficiency virus (HIV) drives highly efficient gene expression in the presence of the transactivator, Tat. Thus, tat-containing vectors may be very useful tools in gene therapy. However information about the optimal way of delivering the tat gene is limited. In this study, we compared the effects of cis and trans expressions of the tat gene and its effects on HIV LTR-driven gene expression in different cell lines using non-viral vectors. The human interleukin-2 (IL-2) gene was used as a reporter gene under the control of the HIV2 LTR (pHIV2-IL-2). The tat gene, driven by a cytomegalovirus (CMV) promoter, was either co-transfected separately (pCMV-Tat) or inserted downstream of the IL-2 gene (pHIV2-IL-2-neo-C-Tat). Our results showed that HIV2 LTR-Tat-based vectors were much more potent than CMV promoter-based vectors in transient expression. The co-transfection of both plasmids was comparable to a single transfection of pHIV-IL-2-neo-C-Tat in both high and low transfection efficiency cells. In conclusion, the co-placement of HIV2 LTR and tat genes on a single plasmid allows for gene expression as efficiently as a two-plasmid system, suggesting that HIV2 LTR-Tat-based vectors may be attractive tools for gene therapy.     

基因治疗微链载体的构建及表达分析

基因载体的转染、表达效率低和存在安全问题是基因治疗的难点。由于传统病毒及质粒载体含有大量外源基因, 其表达有可能引发较严重免疫副反应。本课题旨在新的设计思路上开发高效安全基因治疗载体。 微链载体利用设计好的Cap序列封闭基因表达框两端, 起到防止细胞内核酸外切酶降解的作用。从pEGFP-N3质粒中分离纯化得到GFP基因作为微链载体的报告基因。将微链载体与原质粒载体(pEGFP-N3质粒)分别转染入真核细胞, 利用荧光显微镜和流式细胞仪检测并比较其转染效率。结果显示微链载体在293、CNE2、3T3、B95-8等真核细胞中的转染、表达效率较高, 并具有较小的细胞毒性。初步证实了微链载体在真核细胞中转染、表达效率及安全性等方面具有一定的优越性。     

Evaluation of ADA Gene Expression and Transduction Efficiency in ADA/SCID Patients Undergoing Gene Therapy

A capillary electrophoresis (CE) method was developed for ADA/SCID diagnosis and monitoring of enzyme replacement therapy, as well as for exploring the transfection efficiency for different retroviral vectors in gene therapy.     

Evaluation of ADA gene expression and transduction efficiency in ADA/SCID patients undergoing gene therapy

A capillary electrophoresis (CE) method was developed for ADA/SCID diagnosis and monitoring of enzyme replacement therapy, as well as for exploring the transfection efficiency for different retroviral vectors in gene therapy.     

Non-viral and hybrid vectors in human gene therapy: an update

Non-viral DNA vectors have several advantages over viral vectors. For example, virus production is expensive and there are safety concerns regarding viral manipulations. In addition, the size of the delivered plasmid is limited by the size of the viral capsid, whereas this is not a problem with non-viral vectors. The major disadvantage of using non-viral DNA delivery vectors, compared with their viral counterparts, is the low transfection efficiency. This has resulted in low levels of usage in clinical trials. Consequently, the majority of research into non-viral gene therapy has been focused on developing more efficient vectors.     

Efficient Gene Delivery Using Anionic Liposome-Complexed Polyplexes (LPDII)

Synthetic gene transfer vectors based on polyplexes complexed to anionic liposomes (LPDII vectors) were characterized for their transfection efficiency in cultured mammalian cells. The effects of polycation to DNA ratio, lipid to DNA ratio, choice of polycation and lipid composition were systematically evaluated in human oral carcinoma KB cells, using a luciferase reporter gene. For LPDII formulations containing poly-L-lysine and dioeoylphosphatidylethanolamine/cholesteryl hemisuccinate (DOPE/CHEMS) anionic liposomes, at a constant lipid to DNA ratio, an increase in the polycation/DNA (N/P) ratio resulted in an increase in transfection activity. Meanwhile, the optimal lipid to DNA ratio for efficient gene delivery was influenced by the N/P ratio used, and was increased at higher N/P ratios. For the DNA condensing agent, poly-L-lysine could be replaced by polyethylenimine (PEI) as the DNA condensing agent in the formulations. For the lipidic components, CHEMS could be replaced by other anioniclipids including oleic acid, dicetylphosphate and phosphatidylserine, but DOPE, a fusogenic helper lipid, could not be replaced by dioleolyphosphatidylcholine. LPDII formulation showed significantly less cytotoxicity compared to the commonly used cationic lipsomes or PEI mediated transfection and several cell lines were transfected with high efficiency. LPDII vectors avoid the use of toxic cationic lipids and may have potential application in gene therapy.     

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.