基因治疗心肌缺血的载体应用新进展

近年来,随着基因治疗技术的不断进步,为心肌缺血的治疗开辟了一条全新的途径,并取得了一些令人鼓舞的进展。基因治疗主要包括治疗基因、基因转移载体以及基因导入途径三个方面。基因转移载体又在治疗基因和基因表达之间起着桥梁作用,因此,发展安全、高效的基因转移系统是基因治疗的关键之一。目前用于基因治疗心肌缺血基因转移的载体主要有病毒载体和非病毒载体。下面将就不同载体在心肌缺血的基因治疗中的应用进展进行简要的总结。     

病毒载体与造血干细胞基因治疗

多种获得性和遗传性疾病累及造血细胞。造血干细胞是人类基因治疗的重要靶细胞。成功的造血干细胞基因治疗不仅需要高效基因转移,还需要治疗基因的长期、高水平表达。反转录病毒载体是造血干细胞基因治疗的常用载体,结合优化的造血干细胞转导条件,其介导的腺苷脱氨酶缺陷引起的严重联合免疫缺陷和X染色体连锁的严重联合免疫缺陷的基因治疗已经获得初步成功;其他整合型病毒载体如慢病毒和腺相关病毒载体,也在临床前造血干细胞基因治疗研究中得到广泛应用。从病毒载体、基因转移和基因表达等几个方面综述了造血干细胞基因治疗的临床前和临床研究的重要进展。     

当前肿瘤基因治疗中存在的主要问题及其解决途径

本文概述了当前肿瘤基因治疗研究中存在的一些主要问题,如绝大多数治疗方案中目的基因只有一个,肿瘤基因治疗缺乏靶向性,基因转移载体的效率、安全性及容量等问题。讨论了解决这些问题的主要途径,即肿瘤多基因联合治疗、直接体内途径基因治疗与靶向基因治疗、基因转移载体的改造。     

当前肿瘤基因治疗中存在的主要问题及其解决途径

本文概述了当前肿瘤基因治疗研究中存在的一些主要问题,如绝大多数治疗方案中目的基因只有一个,肿瘤基因治疗缺乏靶向性,基因转移载体的效率、安全性及容量等问题。讨论了解决这些问题的主要途径,即肿瘤多基因联合治疗、直接体内途径治疗与靶向基因治疗、基因转移载体的改造。     

基因治疗中的动物病毒载体

动物病毒载体在基因转移和治疗中有着重要意义。逆转录病毒载体是目前用子基因治疗最为成功的,已用于多种病例的临床研究;腺病毒载体成功地对多种基因进行了转移,并用于囊性纤维病的基因治疗临床研究;腺病毒相关病毒载体和单纯疤疾病毒载体介导的基因转移在体外培养细胞和动物实验中都取得成功,在某些疾病的基因治疗中显示出特殊的应用价值。     

人类基因治疗研究的进展

人类基因治疗研究的进展陈诗书（上海第二医科大学生化教研室分子生物学实验室）人类基因治疗研究中心一、基因治疗的概念基因治疗能够在比较短的时间从理论设想变为现实,主要是对疾病分子生物学的研究已取得了重大的进展,同时发展了许多有关的新技术新方法。特别是７０年代对ＲＮＡ或ＤＮＡ肿瘤病毒转化细胞的研究中所发现的病毒的遗传物质可以转移至宿主细胞基因组中的证据,揭示这些病毒可以作为基因转移的媒介。重组DNA 技术的迅速发展使人们可以在实验室构建各种病毒载体。     

用“乒乓效应”提高包装细胞培养上清中逆转录病毒滴度的方法

逆转录病毒是基因治疗研究中最为主要的基因转移载体,目前批准的基因治疗试验方案中绝大多数采用逆转录病毒作为载体。逆转录病毒具有稳定、安全、高效的优点,但仍存在病毒滴度低的问题。目前多从质粒结构和病毒包装两方面来提高病毒滴度。 将HyTK基因替换逆转录病毒载体GlNa     

基因治疗载体及其基因转移技术的关键问题与研究现状

目前使用的基因治疗载体及其基因转移技术中还没有一种能用于临床并永久有效的基因转移技术 .该文分析了直接体内转移、间接体内转移及其非载体法、病毒载体法、非病毒性生物载体法等基因治疗转移技术存在的一些关键问题 ,并探讨了各问题的解决办法或研究策略以及基因治疗载体研究的发展方向     

Duchenne肌营养不良基因缺陷及基因治疗

Duchenne肌营养不良(DMD)是常见的神经肌肉遗传病之一,由于骨胳肌肌膜上的抗肌萎缩蛋白(dys—trophin)完全或部分缺失引起。本文介绍了dystrophin的结构和功能,对DMD基因治疗的目的基因。基因治疗方式(包括病毒载体和非病毒载体)。基因转染途径作了较为全面的介绍,指出腺相关病毒载体介导的基因治疗及干细胞移植是有希望的治疗方向。经全身途径使目的基因广泛转染骨胳肌并实现心肌和膈肌的转染,是基因治疗研究的难点。     

慢病毒载体的设计及应用进展

慢病毒载体是一类重组逆转录病毒载体,由于其结构和功能的特点作为一种重要的基因转移工具被应用于基因治疗和细胞分子生物学研究领域。目前,为进一步完善慢病毒载体的功能,研究者们从提高载体的生物安全性及增强外源基因的表达调控能力等方面对慢病毒载体进行了改建。本文对慢病毒载体的设计进展及应用进行了简要综述,展望了今后的研究前景。     

Gene therapy: progress and challenges.

Gene therapy is the delivery of new genetic material into a patient's somatic cells for the treatment of disease and is made possible through the development of viral and non-viral gene transfer vectors. In the first five years of gene therapy, clinical studies failed to yield efficacy data with the vectors available at that time. The lack of consistent clinical benefit prompted the United States National Institute of Health Recombinant DNA Advisory Committee to evaluate gene therapy research and conclude that substantial improvements in gene transfer vectors were needed in the areas of vector safety and control of the level and duration of gene expression, and to increase the understanding of the biological interaction of gene transfer vectors with the host. We will describe the progress in development of gene delivery technology, focusing on improvements in vector safety, analysis of vector biodistribution and GMP manufacturing of viral and non-viral gene transfer systems over the last six years since the report. Whereas 5 years ago, investigators tested every vector for every potential disease indication, the accumulated database now enables investigators to select a single vector based upon it's known performance in a wide number of animal models and human clinical studies. We will also highlight several directions investigators have taken to improve the safety and efficacy of gene therapy vectors.     

Prospects for virus-based gene therapy for cystic fibrosis

Gene therapy for cystic fibrosis (CF) could potentially be accomplished with one of several recombinant virus vectors, including a murine retrovirus (MMuLV), adenovirus, or adeno-associated virus (AAV). All these vectors take advantage of their respective viruses' mechanisms for delivery of viral DNA to cells, evasion of lyosomal degradation, and optimization of the levels and duration of expression of viral (or vector) DNA. Each has its own unique life cycle, however. The differences among these viruses result in certain advantages and disadvantages, such as the requirement of retroviruses for active cell division, and the potential pathogenic effects from expression of certain adenovirus genes present in adenovectors. While no single vector may be optimal for CF gene therapy in humans, new techniques, such as receptor-mediated gene transfer, seek to take advantage of the desirable properties of one or more of the virus-based systems while avoiding certain potential hazards.     

直接转基因技术应用于神经系统基因治疗的研究进展

神经系统疾病的基因治疗是目前神经科学中发展比较迅速的一个领域,近年来研究发现,一此来源于单纯疱疹病毒,腺病毒和腺病毒相关病毒等的重组病毒表达载体能够将外源基因直接导入在体或离体培养的神经细胞。     

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。     

Gene therapy for Parkinson's disease

Gene therapy is a potentially powerful approach to the treatment of neurological diseases. The discovery of neurotrophic factors inhibiting neurodegenerative processes and neurotransmitter-synthesizing enzymes provides the basis for current gene therapy strategies for Parkinson's disease. Genes can be transferred by viral or nonviral vectors. Of the various possible vectors, recombinant retroviruses are the most efficient for genetic modification of cells in vitro that can thereafter be used for transplantation (ex vivo gene therapy approach). Recently, in vivo gene transfer to the brain has been developed using adenovirus vectors. One of the advantages of recombinant adenovirus is that it can transduced both quiescent and actively dividing cells, thereby allowing both direct in vivo gene transfer and ex vivo gene transfer to neural cells. Probably because the brain is partially protected from the immune system, the expression of adenoviral vectors persists for several months with little inflammation. Novel therapeutic tools, such as vectors for gene therapy have to be evaluated in terms of efficacy and safety for future clinical trials. These vectors still need to be improved to allow long-term and possibly regulatable expression of the transgene.     

The evolution of heart gene delivery vectors

Gene therapy holds promise for treating numerous heart diseases. A key premise for the success of cardiac gene therapy is the development of powerful gene transfer vehicles that can achieve highly efficient and persistent gene transfer specifically in the heart. Other features of an ideal vector include negligible toxicity, minimal immunogenicity and easy manufacturing. Rapid progress in the fields of molecular biology and virology has offered great opportunities to engineer various genetic materials for heart gene delivery. Several nonviral vectors (e.g. naked plasmids, plasmid lipid/polymer complexes and oligonucleotides) have been tested. Commonly used viral vectors include lentivirus, adenovirus and adeno-associated virus. Among these, adeno-associated virus has shown many attractive features for pre-clinical experimentation in animal models of heart diseases. We review the history and evolution of these vectors for heart gene transfer.     

Targeted vectors for gene therapy of cancer and retroviral infections

Gene therapy has developed to a technology which rapidly moved from the laboratory bench to the bedside in the clinic. This implies safe, efficient and targeted gene transfer systems for suitable application to the patient. Beside the development of such gene transfer vectors of viral or nonviral origin, improvement of cell type specific and inducible gene expression is pivotal for successful gene therapy leading to targeted gene action. Numerous gene therapy approaches for treatment of cancer and retroviral infections utilize cell type specific and/or regulatable promoter and enhancer sequences for the selective expression of therapeutic genes in the desired cell populations and tissues. In this article the recent developments and the potential of expression targeting are reviewed for gene therapy approaches of cancer and retroviral infections.     

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.