Nonviral gene administration by means of the Epstein-Barr virus (EBV)-based episomal vectors and it application to gene therapy and regenerative medicine

O. Mazda, T. Kishida, M. Matsui, H. Nakano, Koichiro Yoshimoto, Taketoshi Shimada, S. Nakai, Jiro Imanishr, Y. Hisa
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Abstract

Genetic transfection is a fundamental technology required for analysis and control of cells and tissues. The efficiency of gene transfection is drastically improved by using Epstein-Barr virus (EBV) nuclear antigen 1 (EBNA1) gene and oriP, which are derived from EBV genome, as components of plasmid vectors to be combined with various non-viral gene transfer vehicles. By means of the multiscale manipulation procedures, we analyzed intracellular distribution of EBNA1 and oriP sequence after transfected the EBNA1/oriP-bearing plasmid vectors (EBV-based episomal vectors) after transfected into mammalian cells, and estimated its implication to the high rate transfection of the EBV-based episomal vectors. Because the EBNA1 plays pleiotrophic roles in transfected cells, we also evaluated contribution of each function of the molecule to the transfection and expression efficiency of the vectors. Beside these studies on basic aspects of the EBNA1/oriP system, we assessed possible application of the EBV-based episomal vectors to regenerative medicine and gene therapy. For example, in vivo activities of various cytokines were tested in normal as well as diseased animals by transfecting them in vivo with the EBV-based episomal vectors carrying expression units for the cytokine genes. Thus, systemic administration of the interleukin-27 (IL-27) gene into the mice that had been transplanted with squamous cell carcinoma resulted in significant suppression of the growth of the tumor, which was mediated by the cooperation of the tumor-specific IgG antibody that was induced by IL-27 and the natural killer (NK) cells of which cytotoxic activity was also enhanced by the cytokine. IL-28 gene also suppressed the tumor in the similar experimental setting using the squamous cell carcinoma, but unlike the mechanism of IL-27-mediated anti-tumor effect, the tumor inhibition resulted from IL-28 gene transfer may be mediated by induction of the cytotoxic T lymphocytes, while coadministration of a chemotherapeutic agent significantly enhanced the IL-28-mediated tumor suppression. There findings may propose novel gene therapy and immunotherapy procedures to concur malignancies, while the highly efficient and long-term persistent exogenous gene expression accomplished by the EBV-based episomal vector may also provide a powerful means for stem cell study and regenerative medicine for human diseases.
eb病毒载体的非病毒基因给药及其在基因治疗和再生医学中的应用
基因转染是分析和控制细胞和组织所需的一项基本技术。利用eb病毒(EBV)核抗原1 (EBNA1)基因和来源于EBV基因组的oriP作为质粒载体,与各种非病毒基因转移载体结合,大大提高了基因转染效率。采用多尺度操作方法,分析了携带EBNA1/oriP的质粒载体(ebv - episomal载体)转染到哺乳动物细胞后,EBNA1和oriP序列在细胞内的分布,并估计了其与ebv - episomal载体高转染率的关系。由于EBNA1在转染细胞中发挥多营养作用,我们还评估了该分子的每种功能对载体转染和表达效率的贡献。除了对EBNA1/oriP系统的基本方面进行研究外,我们还评估了基于ebv的episal载体在再生医学和基因治疗中的可能应用。例如,用携带细胞因子基因表达单位的基于ebv的episomal载体在体内转染正常动物和患病动物,测试了各种细胞因子的体内活性。因此,将白细胞介素-27 (IL-27)基因系统注入鳞状细胞癌移植小鼠体内,可显著抑制肿瘤的生长,这是由IL-27诱导的肿瘤特异性IgG抗体与自然杀伤细胞(NK细胞)共同介导的,NK细胞的细胞毒活性也被细胞因子增强。在类似的实验环境下,IL-28基因对鳞状细胞癌也有抑制作用,但与il -27介导的抗肿瘤作用机制不同,IL-28基因转移对肿瘤的抑制可能是通过诱导细胞毒性T淋巴细胞介导的,而联合化疗药物可显著增强IL-28介导的肿瘤抑制作用。这些发现可能为治疗恶性肿瘤提供新的基因治疗和免疫治疗方法,而基于ebv的episomal载体实现的高效和长期持续的外源基因表达也可能为干细胞研究和人类疾病的再生医学提供有力的手段。
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