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经工程改造后能够展示外源肽的噬菌体可能成为短循环噬菌体。

Bacteriophages engineered to display foreign peptides may become short-circulating phages.

机构信息

Institute of Immunology and Experimental Therapy, Polish Academy of Sciences, Weigla 12, Wrocław, Poland.

出版信息

Microb Biotechnol. 2019 Jul;12(4):730-741. doi: 10.1111/1751-7915.13414. Epub 2019 Apr 29.

DOI:10.1111/1751-7915.13414
PMID:31037835
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6559017/
Abstract

Bacteriophages draw scientific attention in medicine and biotechnology, including phage engineering, widely used to shape biological properties of bacteriophages. We developed engineered T4-derived bacteriophages presenting seven types of tissue-homing peptides. We evaluated phage accumulation in targeted tissues, spleen, liver and phage circulation in blood (in mice). Contrary to expectations, accumulation of engineered bacteriophages in targeted organs was not observed, but instead, three engineered phages achieved tissue titres up to 2 orders of magnitude lower than unmodified T4. This correlated with impaired survival of these phages in the circulation. Thus, engineering of T4 phage resulted in the short-circulating phage phenotype. We found that the complement system inactivated engineered phages significantly more strongly than unmodified T4, while no significant differences in phages' susceptibility to phagocytosis or immunogenicity were found. The short-circulating phage phenotype of the engineered phages suggests that natural phages, at least those propagating on commensal bacteria of animals and humans, are naturally optimized to escape rapid neutralization by the immune system. In this way, phages remain active for longer when inside mammalian bodies, thus increasing their chance of propagating on commensal bacteria. The effect of phage engineering on phage pharmacokinetics should be considered in phage design for medical purposes.

摘要

噬菌体在医学和生物技术中引起了科学关注,包括噬菌体工程,广泛用于塑造噬菌体的生物特性。我们开发了呈现七种组织归巢肽的工程化 T4 衍生噬菌体。我们评估了噬菌体在靶向组织、脾脏、肝脏中的积累和在血液中的循环(在小鼠中)。出乎意料的是,没有观察到靶向器官中工程噬菌体的积累,而是三种工程噬菌体在靶向组织中的滴度比未经修饰的 T4 低 2 个数量级。这与这些噬菌体在循环中的生存能力受损有关。因此,T4 噬菌体的工程化导致了短循环噬菌体表型。我们发现补体系统比未修饰的 T4 更强烈地灭活工程噬菌体,而未修饰的 T4 对吞噬作用或免疫原性的敏感性没有显著差异。工程噬菌体的短循环噬菌体表型表明,天然噬菌体,至少那些在动物和人类共生菌上繁殖的噬菌体,自然优化以逃避免疫系统的快速中和。这样,噬菌体在哺乳动物体内保持更长时间的活性,从而增加了在共生菌上繁殖的机会。在噬菌体设计用于医学用途时,应该考虑噬菌体工程对噬菌体药代动力学的影响。

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Sci Rep. 2017 Aug 14;7(1):8004. doi: 10.1038/s41598-017-08336-9.
3
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Eur J Immunol. 2025 Mar;55(3):e202451543. doi: 10.1002/eji.202451543.
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5
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6
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