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。     

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。     

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。     

腺病毒相关病毒载体的研究进展

实现基因治疗的关键在于目的基因的高效转移并适度表达,这将直接影响其治疗的效率和安全性。因此,探寻理想的基因转移载体显得尤为重要。腺病毒相关病毒（adeno-associated virus,AAV）是一种缺陷型的单链DNA病毒,既可以转染分裂细胞又可以转染非分裂细胞。AAV在宿主体内以定向整合的方式存在,AAV重组体在细胞内能长期稳定地表达,且在体内不引起明显的病理变化,表明AAV作为基因治疗的载体是安全、有效和可行的。     

目的基因表达调控研究进展

载体技术的发展使基因治疗中的安全性问题及外源基因的转移效率等技术难题已部分解决,越来越多的研究显示目的基因体内表达的可控性是决定基因治疗成功的关键,组织特异性启动子,诱导性调控元件,增强子,静息子及反式作用因子作用机制的阐明为改造,增强基因治疗载体表达特性,实现人类基因治疗目的基因表达的可控性,靶向性目标,为基因治疗真正进入临床奠定了基础。     

基因治疗及其临床应用研究进展

基因治疗可定义为在某一个体的细胞中引入新的遗传物质,从而使该个体的疾病得到治疗的方法．基因治疗主要研究免疫治疗、细胞素／药物传递基因、药物敏感基因、药物抗性基因和选择性抗性基因治疗等．基因治疗尚仅限于体细胞,生殖细胞的基因治疗由于技术难度更大,且涉及伦理学与社会学的问题．还不在考虑之列．目前基因治疗的对象主要以恶性肿瘤为重点,同时兼顾心血管及少数遗传病。基因治疗的基本内容包括;引起疾病的缺陷基因定位（基因诊断）;选择适当的载体及载体的加工、修饰与包装（基因载体）;外源基因导入人体靶细胞（基因转移）的临床研究．体外基因转移已广泛应用于各类基因病的临床治疗研究;而体内基因转移目前尚未走出实验室．继美国之后,世界上许多国家都已开始实施各自的基因治疗研究计划．人类的基因病有４０００多种,基因治疗前景广阔．     

基因治疗研究中脂质体介导的基因转移技术

对于脂质体的深入研究特别是阳离子脂质体的研制使其逐步成为重要的基因转移载体之一,并且初步应用于基因治疗研究,同时多种靶向脂质体的研制也为体内靶向基因转移和表达奠定了基础。本文就脂质体的结构、功能、在基因治疗研究中的应用以及各种靶向脂质体的研制进行了介绍。     

基于四环素调控系统的病毒载体在基因治疗中的应用

基因治疗已经发展成为处理各种疾病的理想治疗模式.病毒载体是将基因递送到体内或体外的分裂和非分裂细胞的有效工具.病毒载体基因治疗在临床环境成功应用的一个重要问题是严谨和持续地调控基因表达.目前,已经报道的无毒且严谨的调控转基因表达系统中,四环素转录调控系统是在体内和体外研究最好而且高效的调控系统.Tet调控系统已经被编码在慢病毒属、腺病毒属、腺相关病毒属和逆转录病毒属,而且可以有效地对基因进行调控.将主要讨论已经在Tet调控系统调控下递送基因的主要载体系统及其在基因治疗上的应用.     

腺病毒载体的细胞导向性基因转移

腺病毒（ａｄｅｎｏｖｉｒｕｓ,Ａｄ）载体广泛应用于基因治疗,其主要特征之一是能高效地进行各种组织如肺上皮、肝、肌肉、胰岛、胆囊等的体内（ｉｎｖｉｖｏ）基因转移。然而,因其混杂的向性而引起的全身体内基因转导后治疗基因不受组织限制的表达,限制了它在基因治疗中的应用,因此希望改变腺病毒的天然向性,而使治疗基因导向转移到选择的细胞类型中。目前腺病毒载体细胞导向性的基因转移可通过（１）修饰腺病毒载体的细胞表面识别成分,限制腺病毒导向性感染选择的细胞类型;（２）腺病毒载体中导入组织特异性启动子,控制治疗基因…     

Characterization of a semi-replicative gene delivery system allowing propagation of complementary defective retroviral vectors

BACKGROUND: Recently, several cancer gene therapy studies have shown that replication-competent retroviral vectors represent a major improvement over replication-defective ones in terms of transgene propagation efficiency. However, this positive effect is somewhat spoiled by the increased risk of dissemination and oncogenesis that replication-competent retroviral vectors entail. To enhance both their integral safety and their transgene capacity, we developed a semi-replication-competent retroviral vector system. METHODS: The semi-replication-competent retroviral vector system is based on two transcomplementing replication-defective retroviral vectors termed gag-pol vector (GPv) and env vector (Ev). Vector propagation was monitored in vitro and in solid tumors in vivo, using different reporter transgenes for GPv and Ev. Systemic vector dissemination and leukemogenesis was assessed by direct intravenous vector injection and subsequent bone marrow transplantation, in MLV-sensitive mice. RESULTS: In vitro and in vivo the semi-replication-competent retroviral vectors propagate transgenes almost as efficiently as replication-competent ones. The semi-replication-competent retroviral vector system does not lead to detectable dissemination or leukemogenesis as does the replication-competent vector or the parental virus. Additionally, the vector duo allows co-propagation of different transgenes as well as mobilization of a third replication-defective vector. CONCLUSIONS: This study is an initial proof of principle for the use of complementary retroviral vectors to deliver and propagate transgenes in vitro and in solid tumors in vivo, but with reduced pathogenicity compared to its parental virus. In-between replication-defective and replication-competent retroviral vectors, this semi-replicative system offers good grounds for its application in in vitro studies and allows envisioning its further development for cancer gene therapy.     

Utility of intraperitoneal administration as a route of AAV serotype 5 vector-mediated neonatal gene transfer

BACKGROUND: Gene transfer into a fetus or neonate can be a fundamental approach for treating genetic diseases, particularly disorders that have irreversible manifestations in adulthood. Although the potential utility of this technique has been suggested, the advantages of neonatal gene transfer have not been widely investigated. Here, we tested the usefulness of neonatal gene transfer using adeno-associated virus (AAV) vectors by comparing the administration routes and vector doses. METHODS: To determine the optimal administration route, neonates were subjected to intravenous (i.v.) or intraperitoneal (i.p.) injections of AAV5-based vectors encoding the human coagulation factor IX (hfIX) gene, and the dose response was examined. To determine the distribution of transgene expression, vectors encoding lacZ or luciferase (luc) genes were used and assessed by X-gal staining and in vivo imaging, respectively. After the observation period, the vector distribution across tissues was quantified. RESULTS: The factor IX concentration was higher in i.p.-injected mice than in i.v.-injected mice. All transgenes administered by i.p. injection were more efficiently expressed in neonates than in adults. The expression was confined to the peritoneal tissue. Interestingly, a sex-related difference was observed in transgene expression in adults, whereas this difference was not apparent in neonates. CONCLUSIONS: AAV vector administration to neonates using the i.p. route was clearly advantageous in obtaining robust transgene expression. Vector genomes and transgene expression were observed mainly in the peritoneal tissue. These findings indicate the advantages of neonatal gene therapy and would help in designing strategies for gene therapy using AAV vectors.     

Gene delivery and gene therapy with herpes simplex virus-based vectors

The development of efficient means of delivery genes in vivo is essential both for testing gene function in the intact animal and for human gene therapy procedures. A number of viral and non-viral gene delivery methods have been developed for this purpose. Of those herpes simplex virus (HSV)-based vectors have particular advantages for gene delivery to the nervous system including their ability to infect non-dividing neurones and establish asymptomatic latent infections. Moreover, considerable progress has been made, firstly, in disabling HSV vectors so as to prevent the damaging effects of wild type virus and secondly, to ensure long-term expression of the inserted transgene(s). These vectors thus offer a valuable tool for testing gene function in neuronal cells in vivo and may ultimately be safe enough for use in human gene therapy procedures.     

Transgene expression and differentiation of baculovirus-transduced human mesenchymal stem cells

BACKGROUND: Mesenchymal stem cells (MSCs) have drawn considerable attention as vehicles for cell- or gene-based therapies, yet various problems still exist for current gene delivery vectors. On the other hand, baculovirus has emerged as a novel gene therapy vector, but its transduction of stem cells has not been reported. METHODS: A recombinant baculovirus expressing the enhanced green fluorescent protein (EGFP) was constructed to transduce human MSCs derived from umbilical cord blood (uMSCs) or bone marrow (bMSCs). RESULTS: In this study, we demonstrated for the first time that human uMSCs or bMSCs could be transduced by baculovirus with high efficiencies (up to approximately 72.8% and 41.1%, respectively) and significantly elevated transgene (enhanced green fluorescent protein, EGFP) expression upon incubation with unconcentrated virus and phosphate-buffered saline for 4 h at 25 degrees C. The transduction efficiency into bMSCs could be further increased to approximately 72.2% by lowering the cell density. The improved transgene expression was partly attributed to the enhanced virus uptake upon transduction, as determined by quantitative real-time polymerase chain reaction (Q-PCR). MSC growth was not obstructed by baculovirus transduction itself, but was somewhat hampered by EGFP expression. Nonetheless, the baculovirus-transduced cells remained capable of differentiating into adipogenic lineage. The adipogenic progenitors appeared more permissive to baculovirus transduction than the undifferentiated bMSCs, thus allowing for the maintenance and enhancement of transgene expression by repeated transduction after subculture. CONCLUSIONS: These findings implicate the potential applications of baculovirus as an alternative vector to genetically modify MSCs for ex vivo gene therapy.     

Hybrid vector designs to control the delivery, fate and expression of transgenes

One of the greatest challenges to gene therapy is the targetting of gene delivery selectively to the sites of disease and regulation of transgene expression without adverse effects. Ultimately, the successful realization of these goals is dependent upon improvements in vector design. Over the years, viral vector design has progressed from various types of replication-defective viral mutants to replication-conditioned viruses and, more recently, to 'gutted' and hybrid vectors, which have, respectively, eliminated expression of non-relevant or toxic viral genes and incorporated desired elements of different viruses so as to increase the efficacy of gene delivery in vivo. This review will focus on the different viral and cellular elements which have been incorporated into virus vectors to: improve transduction efficiencies; alter the entry specificity of virions; control the fate of transgenes in the host cells; and regulate transgene expression.     

Conjugate-based targeting of recombinant adeno-associated virus type 2 vectors by using avidin-linked ligands

The development of targeted vectors, capable of tissue-specific transduction, remains one of the important aspects of vector modification for gene therapy applications. Recombinant adeno-associated virus type 2 (rAAV-2)-based vectors are nonpathogenic, have relatively low immunogenicity, and are capable of long-term transgene expression. AAV-2 vectors bind primarily to heparan sulfate proteoglycan (HSPG), a receptor that is present in many tissues and cell types. Because of the widespread expression of HSPG on many tissues, targeted transduction in vivo appears to be limited with AAV-2 vectors. Thus, development of strategies to achieve transductional targeting will have a profound benefit in the future application of these vectors. We report here a novel conjugate-based targeting method to enhance tissue-specific transduction of AAV-2-based vectors. The present report utilized a high-affinity biotin-avidin interaction as a molecular bridge to cross-link purified targeting ligands, produced genetically as fusion proteins to core-streptavidin, in a prokaryotic expression system. Conjugation of the bispecific targeting protein to the vector was achieved by biotinylating purified rAAV-2 without abolishing the capsid structure, internalization, and subsequent transgene expression. The tropism-modified vectors, targeted via epidermal growth factor receptor (EGFR) or fibroblast growth factor 1alpha receptor (FGFR1alpha), resulted in a significant increase in transduction efficiency of EGFR-positive SKOV3.ip1 cells and FGFR1alpha-positive M07e cells, respectively. Further optimization of this method of targeting should enhance the potential of AAV-2 vectors in ex vivo and in vivo gene therapy and may form the basis for developing targeting methods for other AAV serotype capsids.     

Production and Characterization of Improved Adenovirus Vectors with the E1, E2b, and E3 Genes Deleted

Adenovirus (Ad)-based vectors have great potential for use in the gene therapy of multiple diseases, both genetic and nongenetic. While capable of transducing both dividing and quiescent cells efficiently, Ad vectors have been limited by a number of problems. Most Ad vectors are engineered such that a transgene replaces the Ad E1a, E1b, and E3 genes; subsequently the replication-defective vector can be propagated only in human 293 cells that supply the deleted E1 gene functions in trans. Unfortunately, the use of high titers of E1-deleted vectors has been repeatedly demonstrated to result in low-level expression of viral genes still resident in the vector. In addition, the generation of replication-competent Ad (RCA) by recombination events with the E1 sequences residing in 293 cells further limits the usefulness of E1-deleted Ad vectors. We addressed these problems by isolating new Ad vectors deleted for the E1, E3, and the E2b gene functions. The new vectors can be readily grown to high titers and have several improvements, including an increased carrying capacity and a theoretically decreased risk for generating RCA. We have also demonstrated that the further block to Ad vector replication afforded by the deletion of both the E1 and E2b genes significantly diminished Ad late gene expression in comparison to a conventional E1-deleted vector, without destabilization of the modified vector genome. The results suggested that these modified vectors may be very useful both for in vitro and in vivo gene therapy applications.     

Site-specific integration of a transgene mediated by a hybrid adenovirus/adeno-associated virus vector using the Cre/loxP-expression-switching system

As vectors, adenoviruses (Ads) have many attractive advantages for in vivo gene therapy. However, Ads do not usually integrate into the host genome and gene expression is, thus, transient. Adeno-associated virus (AAV) integrates into a specific locus (AAVS1) on the human host's chromosome 19, while conventional recombinant AAV (rAAV) vectors do not possess this property because such vectors lack the rep gene. AAV vectors carrying the rep gene do not have enough space for insertion of a transgene. We have constructed a hybrid adenovirus/adeno-associated virus (Ad/AAV) vector which has the advantages of both Ads and AAVs. Given that the rep gene products inhibit propagation of Ads, we used the Cre/loxP-expression-switching system to regulate the expression of the rep gene. The Ad/AAV vector easily propagates, can efficiently infect a broad range of cell types, and can integrate into a specific locus on host chromosomes.     

Ovine Adenovirus Vectors Overcome Preexisting Humoral Immunity against Human Adenoviruses In Vivo

Recombinant human adenoviruses (hAd) have become widely used as tools to achieve efficient gene transfer. However, successful application of hAd-derived vectors in clinical trials is limited due to immunological and potential safety problems inherent in their human origin. In this study, we describe a recombinant ovine adenovirus (OAV) as an alternative vector for gene transfer in vivo. In contrast to an hAd vector, the OAV vector was not neutralized by human sera. An OAV vector which contained the cDNA of the human alpha1-antitrypsin (hAAT) gene linked to the Rous sarcoma virus promoter was generated and administered systemically to mice. The level and duration of hAAT gene expression was similar to that achieved with an hAd counterpart in both immunocompetent and immunodeficient mice. However, the tissue distribution of the OAV vector differed from that observed for hAd vectors in that the liver was not the dominant target. Significantly, we demonstrated efficient gene transfer with the OAV vector into mice immunized with hAd vectors and vice versa. We also confirm that the immune response to a transgene product can prevent its functional expression following sequential application of a vector. Our results suggest a possible solution to endemic humoral immunity against currently used hAd vectors and should therefore have an impact on the design of improved gene therapy protocols utilizing adenovirus vectors.