将睡美人转位应用于细胞治疗:胜利与挑战。
Translating Sleeping Beauty transposition into cellular therapies: victories and challenges.
机构信息
Max-Delbrück Center for Molecular Medicine (MDC), Berlin, Germany.
出版信息
Bioessays. 2010 Sep;32(9):756-67. doi: 10.1002/bies.201000027.
Abstract
Recent results confirm that long-term expression of therapeutic transgenes can be achieved by using a transposon-based system in primary stem cells and in vivo. Transposable elements are natural DNA transfer vehicles that are capable of efficient genomic insertion. The latest generation, Sleeping Beauty transposon-based hyperactive vector (SB100X), is able to address the basic problem of non-viral approaches - that is, low efficiency of stable gene transfer. The combination of transposon-based non-viral gene transfer with the latest improvements of non-viral delivery techniques could provide a long-term therapeutic effect without compromising biosafety. The new challenges of pre-clinical research will focus on further refinement of the technology in large animal models and improving the safety profile of SB vectors by target-selected transgene integration into genomic "safe harbors." The first clinical application of the SB system will help to validate the safety of this approach.
摘要
最近的研究结果证实,通过在原代干细胞和体内使用转座子为基础的系统,可以实现治疗性转基因的长期表达。转座元件是天然的 DNA 转移载体,能够有效地进行基因组插入。最新一代的 Sleeping Beauty 转座子超活跃载体 (SB100X) 能够解决非病毒方法的基本问题,即稳定基因转移的效率低。转座子为基础的非病毒基因转移与非病毒递送技术的最新改进相结合,在不影响生物安全性的情况下,可以提供长期的治疗效果。临床前研究的新挑战将集中在进一步完善大型动物模型中的技术,并通过靶向选择的转基因整合到基因组“安全港”中来提高 SB 载体的安全性。SB 系统的首次临床应用将有助于验证该方法的安全性。
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