Bacteriophage T4 genome packaging: mechanism and application.

Q1 Medicine

EcoSal Plus Pub Date : 2025-10-01 DOI:10.1128/ecosalplus.esp-0004-2025

Venigalla B Rao

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Abstract

It has been a 45-year journey studying genome packaging of a single virus, the tailed bacteriophage T4. T4, then and now, remains a powerful model for understanding viruses, particularly tailed phages, the most abundant and widely distributed organisms on Earth. The biochemistry, structure, and single-molecule dynamics of the T4 DNA packaging motor have been teased out. Packaging ~171 kb genomic DNA into a 120 × 86 nm prolate icosahedral head in a few minutes, the T4 packaging motor is the fastest and most powerful motor known. It is also the most promiscuous, allowing packaging of any double-stranded DNA regardless of sequence or length into various head (capsid) assemblies: unexpanded prohead, expanded prohead, or mature head. These studies established the basic architecture of an ATP-powered viral genome packaging machine consisting of a pentameric packaging motor attached to the dodecameric portal vertex of the capsid shell. Furthermore, it opened new avenues to engineer and repurpose the packaging machine for the delivery of genes, proteins, and protein-nucleic acid complexes into human cells. The biggest challenge now is to translate this knowledge into the design of future phage-vectored gene therapy platforms that allow engineered phages to interact with human cells and make appropriate genetic and metabolic corrections to alleviate disease. This possibility was unimaginable when we started but evolved through lessons learned by examining the intricate machinery of the phage T4 life cycle.

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噬菌体T4基因组包装：机制与应用。

对一种名为尾状噬菌体T4的病毒的基因组包装进行了长达45年的研究。无论是过去还是现在，T4仍然是了解病毒，特别是尾状噬菌体（地球上数量最多、分布最广泛的生物体）的有力模型。对T4 DNA包装马达的生物化学、结构和单分子动力学进行了梳理。在几分钟内将~171 kb的基因组DNA封装到一个120 × 86 nm长的二十面体头部，T4封装电机是目前已知的最快、最强大的电机。它也是最混杂的，允许包装任何双链DNA，不管序列或长度成各种头（衣壳）组装：未扩展的前导，扩展的前导，或成熟的头。这些研究建立了atp驱动的病毒基因组包装机的基本结构，该包装机由附着在衣壳壳十二聚体入口顶点的五聚体包装马达组成。此外，它还为设计和改造包装机器开辟了新的途径，用于将基因、蛋白质和蛋白质核酸复合物输送到人体细胞中。目前最大的挑战是将这些知识转化为未来噬菌体载体基因治疗平台的设计，使工程噬菌体能够与人类细胞相互作用，并进行适当的遗传和代谢纠正，以减轻疾病。当我们开始时，这种可能性是不可想象的，但通过研究噬菌体T4生命周期的复杂机制，我们得到了经验教训。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

EcoSal Plus Immunology and Microbiology-Microbiology

CiteScore

12.20

自引率

0.00%

发文量

期刊介绍： EcoSal Plus is the authoritative online review journal that publishes an ever-growing body of expert reviews covering virtually all aspects of E. coli, Salmonella, and other members of the family Enterobacteriaceae and their use as model microbes for biological explorations. This journal is intended primarily for the research community as a comprehensive and continuously updated archive of the entire corpus of knowledge about the enteric bacterial cell. Thoughtful reviews focus on physiology, metabolism, genetics, pathogenesis, ecology, genomics, systems biology, and history E. coli and its relatives. These provide the integrated background needed for most microbiology investigations and are essential reading for research scientists. Articles contain links to E. coli K12 genes on the EcoCyc database site and are available as downloadable PDF files. Images and tables are downloadable to PowerPoint files.