Isolation and characterization of Proteus mirabilis bacteriophage T2 and its application

IF 3.5 3区医学 Q3 IMMUNOLOGY

Microbial pathogenesis Pub Date : 2025-09-08 DOI:10.1016/j.micpath.2025.108021

Chaoxiang Jia , Xinyan Yao , Ting Qin , Dai Peng , Linlin Huang , Yi Liu , Saiyu Zhang , Yingqian Han , Yang Liu , Yanbin Yang , Guoyu Yang , Hua Wu , Juan Geng , Yueying Wang , Heping Li

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引用次数: 0

Abstract

Public health problems caused by foodborne illnesses have become increasingly serious. Although it was usually regarded as an opportunistic pathogen causing urinary tract infections in humans, recent years have seen an increasing number of foodborne infections related to P. mirabilis. Therefore, it was crucial to develop effective strategies to control this bacterium. In this study, the bacteriophage T2 isolated from cattle dung formed numerous clear plaques with a diameter of approximately 3 mm on the bacterial lawn of P. mirabilis Y22 using a double-layer agar method. Electron microscopic and genomic DNA analyses suggested that phage T2 was a recently discovered virulent phage, classified under the genus Novosibovirus within the subfamily Slopekvirinae. Analyses of phylogeny and genomics indicated that there was a relatively close evolutionary relationship with Proteus phage. Notably, phage T2 exhibited excellent environmental adaptability and showed stable lytic activity across a wide range of pH values (4–10) and temperatures (20–50 °C), even in a 3 M NaCl solution. Phage T2 has the ability to inhibit and kill P. mirabilis Y22 in a dose-dependent manner in LB broth, and phage T2 was capable of significantly inhibiting biofilm formation and breaking down established biofilms. The growth of P. mirabilis Y22 in milk and sausage was successfully suppressed at an MOI of 100 (P < 0.01). Moreover, phage T2 can lyse and kill bacteria in G. mellonella, thereby increasing their survival rate. These results indicated that the lytic phage T2 could be a promising candidate for managing P. mirabilis contamination in food products.

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奇异变形杆菌噬菌体T2的分离鉴定及其应用。

食源性疾病引起的公共卫生问题日益严重。虽然它通常被认为是一种导致人类尿路感染的机会性病原体，但近年来，与奇异假单胞菌有关的食源性感染越来越多。因此，制定有效的策略来控制这种细菌至关重要。在本研究中，从牛粪中分离的噬菌体T2采用双层琼脂法在P. mirabilis Y22细菌草坪上形成了许多直径约为3 mm的透明斑块。电子显微镜和基因组DNA分析表明，T2噬菌体是最近发现的一种强毒噬菌体，属于Slopekvirinae亚科Novosibovirus属。系统发育和基因组学分析表明，它与变形杆菌噬菌体有较密切的进化关系。值得注意的是，噬菌体T2表现出优异的环境适应性，在广泛的pH值（4 ~ 10）和温度（20 ~ 50°C）范围内表现出稳定的裂解活性，即使在3m NaCl溶液中也是如此。噬菌体T2在LB肉汤中具有剂量依赖性的抑制和杀伤P. mirabilis Y22的能力，并且T2噬菌体能够显著抑制生物膜的形成和破坏已建立的生物膜。在MOI为100的条件下，成功抑制了牛奶和香肠中神奇P. Y22的生长（P < 0.01）。此外，T2噬菌体可以裂解和杀死葡萄球菌中的细菌，从而提高其存活率。这些结果表明，裂解噬菌体T2可能是控制食品中奇异假单胞菌污染的一个有希望的候选者。

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

Microbial pathogenesis 医学-免疫学

CiteScore

7.40

自引率

2.60%

发文量

472

审稿时长

56 days

期刊介绍： Microbial Pathogenesis publishes original contributions and reviews about the molecular and cellular mechanisms of infectious diseases. It covers microbiology, host-pathogen interaction and immunology related to infectious agents, including bacteria, fungi, viruses and protozoa. It also accepts papers in the field of clinical microbiology, with the exception of case reports. Research Areas Include: -Pathogenesis -Virulence factors -Host susceptibility or resistance -Immune mechanisms -Identification, cloning and sequencing of relevant genes -Genetic studies -Viruses, prokaryotic organisms and protozoa -Microbiota -Systems biology related to infectious diseases -Targets for vaccine design (pre-clinical studies)