Pamela R. Tsoumbris, Russel M. Vincent, Paul R. Jaschke
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引用次数: 0
摘要
耐多药感染在全球范围内越来越普遍。噬菌体疗法是新兴的替代和辅助疗法之一。目前,绝大多数噬菌体疗法都使用天然分离的噬菌体。目前正在开发工程噬菌体,以提高噬菌体疗法的有效性,但对其潜在逃逸的担忧仍是一个突出问题。为了解决这个问题,我们设计了一种基于条件复制、使用琥珀色终止密码子抑制的生物噬菌体系统。这个系统可以很容易地安装在任何已知基因组序列的天然噬菌体上。为了测试该系统,我们分别将噬菌体 φX174 中三个重要帽状体基因的起始密码子突变为琥珀色终止密码子(UAG)。这些噬菌体能够有效地感染表达琥珀色启动子 tRNA 的宿主细胞,后者抑制琥珀色终止密码子,并在 TAG 终止密码子处启动翻译。琥珀噬菌体突变体也能成功感染宿主细胞,并减少其在固体琼脂和液体培养物上的数量,但在缺乏琥珀启动子 tRNA 或互补噬菌体基因的情况下,它们不能产生感染性颗粒。我们没有检测到噬菌体对已知缺乏φX174受体的大肠杆菌菌株有任何生长抑制作用,而且我们还发现工程噬菌体具有有限的逆转倾向。本文概述的方法可能有助于在实验室和临床中控制工程噬菌体的复制。
Designing a simple and efficient phage biocontainment system using the amber suppressor initiator tRNA
Multidrug-resistant infections are becoming increasingly prevalent worldwide. One of the fastest-emerging alternative and adjuvant therapies being proposed is phage therapy. Naturally isolated phages are used in the vast majority of phage therapy treatments today. Engineered phages are being developed to enhance the effectiveness of phage therapy, but concerns over their potential escape remain a salient issue. To address this problem, we designed a biocontained phage system based on conditional replication using amber stop codon suppression. This system can be easily installed on any natural phage with a known genome sequence. To test the system, we individually mutated the start codons of three essential capsid genes in phage φX174 to the amber stop codon (UAG). These phages were able to efficiently infect host cells expressing the amber initiator tRNA, which suppresses the amber stop codon and initiates translation at TAG stop codons. The amber phage mutants were also able to successfully infect host cells and reduce their population on solid agar and liquid culture but could not produce infectious particles in the absence of the amber initiator tRNA or complementing capsid gene. We did not detect any growth-inhibiting effects on E. coli strains known to lack a receptor for φX174 and we showed that engineered phages have a limited propensity for reversion. The approach outlined here may be useful to control engineered phage replication in both the lab and clinic.
期刊介绍:
Archives of Virology publishes original contributions from all branches of research on viruses, virus-like agents, and virus infections of humans, animals, plants, insects, and bacteria. Coverage spans a broad spectrum of topics, from descriptions of newly discovered viruses, to studies of virus structure, composition, and genetics, to studies of virus interactions with host cells, organisms and populations. Studies employ molecular biologic, molecular genetics, and current immunologic and epidemiologic approaches. Contents include studies on the molecular pathogenesis, pathophysiology, and genetics of virus infections in individual hosts, and studies on the molecular epidemiology of virus infections in populations. Also included are studies involving applied research such as diagnostic technology development, monoclonal antibody panel development, vaccine development, and antiviral drug development.Archives of Virology wishes to publish obituaries of recently deceased well-known virologists and leading figures in virology.
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