Analysis of a novel phage as a promising biological agent targeting multidrug resistant Klebsiella pneumoniae.

IF 3.5 3区生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

AMB Express Pub Date : 2025-03-05 DOI:10.1186/s13568-025-01846-0

Mahmoud A Abdel-Razek, Shaimaa I Nazeih, Nehal Yousef, Momen Askoura

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引用次数: 0

Abstract

The rise of deaths by resistant bacteria is a global threat to public health systems. Klebsiella pneumoniae is a virulent pathogen that causes serious nosocomial infections. The major obstacle to bacterial treatment is antibiotic resistance, which necessitates the introducing of alternative therapies. Phage therapy has been regarded as a promising avenue to fight multidrug-resistant (MDR) pathogens. In the current study, a novel phage vB_KpnP_KP17 was isolated from sewage, and its lytic potential was investigated against K. pneumoniae. The isolated phage vB_KpnP_kP17 was lytic to 17.5% of tested K. pneumoniae isolates. One step growth curve indicated a virulent phage with a short latent period (20 min) and large burst size (331 PFU/cell). Additionally, vB_KpnP_kP17 maintained its activity against planktonic cells over a wide range of pH, temperature and UV irradiation intervals. The potential of vB_KpnP_KP17 as antibiofilm agent was revealed by the biofilm inhibition assay. The isolated phage vB_KpnP_KP17 at multiplicity of infection (MOI) of 10 inhibited more than 50% of attached biofilms of tested K. pneumoniae isolates. The genome of vB_KpnP_kP17 was characterized and found to be a linear dsDNA of 39,936 bp in length and GC content of 52.85%. Additionally, the absence of toxicity, virulence and antibiotic resistance genes further confirms the safety of vB_KpnP_KP17 for clinical applications. These characteristics make vB_KpnP_KP17 of a potential therapeutic value to manage MDR K. pneumoniae infections. Additionally, the formulation of vB_KpnP_KP17 in a cocktail with other lytic phages or with antibiotics could be applied to further limit biofilm-producing K. pneumoniae infections.

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耐药细菌致死率的上升是对公共卫生系统的全球性威胁。肺炎克雷伯氏菌是一种烈性病原体，可导致严重的医院内感染。细菌治疗的主要障碍是抗生素耐药性，因此有必要引入替代疗法。噬菌体疗法被认为是对抗耐多药（MDR）病原体的一种有前途的途径。本研究从污水中分离出一种新型噬菌体 vB_KpnP_KP17，并研究了它对肺炎双球菌的溶菌潜力。分离出的噬菌体 vB_KpnP_kP17 可溶解 17.5% 的肺炎双球菌分离株。一步生长曲线显示，这种毒力噬菌体潜伏期短（20 分钟），迸发量大（331 PFU/细胞）。此外，vB_KpnP_kP17 在很宽的 pH 值、温度和紫外线照射间隔范围内都能保持对浮游细胞的活性。生物膜抑制试验揭示了 vB_KpnP_KP17 作为抗生物膜剂的潜力。分离出的噬菌体 vB_KpnP_KP17 在感染倍率（MOI）为 10 的情况下，可抑制 50%以上受测肺炎双球菌分离物附着的生物膜。对 vB_KpnP_kP17 的基因组进行了鉴定，发现它是一个长度为 39,936 bp 的线性 dsDNA，GC 含量为 52.85%。此外，vB_KpnP_KP17 不含毒性、毒力和抗生素耐药性基因，这进一步证实了其临床应用的安全性。这些特性使 vB_KpnP_KP17 在控制 MDR 肺炎 K.感染方面具有潜在的治疗价值。此外，将 vB_KpnP_KP17 与其他溶菌噬菌体或抗生素配制成鸡尾酒，可进一步限制产生生物膜的肺炎克菌感染。

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来源期刊

AMB Express BIOTECHNOLOGY & APPLIED MICROBIOLOGY-

CiteScore

7.20

自引率

2.70%

发文量

141

审稿时长

13 weeks

期刊介绍： AMB Express is a high quality journal that brings together research in the area of Applied and Industrial Microbiology with a particular interest in ''White Biotechnology'' and ''Red Biotechnology''. The emphasis is on processes employing microorganisms, eukaryotic cell cultures or enzymes for the biosynthesis, transformation and degradation of compounds. This includes fine and bulk chemicals, polymeric compounds and enzymes or other proteins. Downstream processes are also considered. Integrated processes combining biochemical and chemical processes are also published.