Newly isolated Drexlerviridae phage LAPAZ is physically robust and fosters eradication of Klebsiella pneumoniae in combination with meropenem

IF 2.5 4区 医学 Q3 VIROLOGY Virus research Pub Date : 2024-06-20 DOI:10.1016/j.virusres.2024.199417
Leonie Ziller , Patricia Christina Blum , Eva Miriam Buhl , Alex Krüttgen , Hans-Peter Horz , Thaysa Leite Tagliaferri
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Abstract

Due to the spread of multidrug resistance there is a renewed interest in using bacteriophages (briefly: phages) for controlling bacterial pathogens. The objective of this study was the characterization of a newly isolated phage (i.e. phage LAPAZ, vB_KpnD-LAPAZ), its antimicrobial activity against multidrug resistant Klebsiella pneumoniae and potential synergistic interactions with antibiotics. LAPAZ belongs to the family Drexlerviridae (genus: Webervirus) and lysed 30 % of tested strains, whereby four distinct capsular types can be infected. The genome consists of 51,689 bp and encodes 84 ORFs. The latent period is 30 min with an average burst size of 27 PFU/cell. Long-term storage experiments show that LAPAZ is significantly more stable in wastewater compared to laboratory media. A phage titre of 90 % persists up to 30 min at 50 ˚C and entire phage loss was seen only at temperatures > 66 ˚C. Besides stability against UV-C, antibacterial activity in liquid culture medium was consistent at pH values ranging from 4 to 10. Unlike exposure to phage or antibiotic alone, synergistic interactions and a complete bacterial eradication was achieved when combining LAPAZ with meropenem. In addition, synergism with the co-presence of ciprofloxacin was observed and phage resistance emergence could be delayed. Without co-addition of the antibiotic, phage resistant mutants readily emerged and showed a mixed pattern of drug sensitivity alterations. Around 88 % became less sensitive towards ceftazidime, meropenem and gentamicin. Conversely, around 44 % showed decreased resistance levels against ciprofloxacin. Whole genome analysis of a phage-resistant mutant with a 16-fold increased sensitivity towards ciprofloxacin revealed one de novo frameshift mutation leading to a gene fusion affecting two transport proteins belonging to the major facilitator-superfamily (MFS). Apparently, this mutation compromises ciprofloxacin efflux efficiency and further studies are warranted to understand how the non-mutated protein might be involved in phage-host adsorption.

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新分离的 Drexlerviridae 噬菌体 LAPAZ 具有强大的物理特性,与美罗培南联合使用可根除肺炎克雷伯氏菌。
由于多重耐药性的蔓延,人们对使用噬菌体(简称噬菌体)来控制细菌病原体重新产生了兴趣。本研究的目的是鉴定一种新分离出来的噬菌体(即噬菌体 LAPAZ,vB_KpnD-LAPAZ)的特性、其对耐多药肺炎克雷伯氏菌的抗菌活性以及与抗生素的潜在协同作用。LAPAZ 属于 Drexlerviridae 科(属:Webervirus),能溶解 30% 的受测菌株,可感染四种不同的囊膜类型。其基因组由 51,689 bp 组成,编码 84 个 ORF。潜伏期为 30 分钟,平均爆发大小为 27 PFU/细胞。长期储存实验表明,与实验室培养基相比,LAPAZ 在废水中的稳定性要高得多。在 50 ˚C 的条件下,噬菌体滴度的 90% 可维持 30 分钟,只有在温度大于 66 ˚C 时,噬菌体才会全部消失。除了对紫外线保持稳定外,噬菌体在液体培养基中的抗菌活性在 pH 值为 4 到 10 时也是一致的。与单独接触噬菌体或抗生素不同的是,当 LAPAZ 与美罗培南结合使用时,可产生协同作用并彻底消灭细菌。此外,在同时使用环丙沙星的情况下,还观察到了协同作用,噬菌体耐药性的出现可以被延缓。在不同时添加抗生素的情况下,噬菌体耐药突变体很容易出现,并表现出不同的药物敏感性改变模式。约 88% 的噬菌体对头孢他啶、美罗培南和庆大霉素的敏感性降低。相反,约 44% 的噬菌体对环丙沙星的耐药性降低。对噬菌体抗性突变体进行的全基因组分析显示,该突变体对环丙沙星的敏感性提高了 16 倍,其中一个新的换框突变导致基因融合,影响了属于主要促进剂超家族(MFS)的两个转运蛋白。显然,这种突变影响了环丙沙星的外排效率,因此有必要进行进一步研究,以了解未发生突变的蛋白可能如何参与噬菌体-宿主吸附。
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来源期刊
Virus research
Virus research 医学-病毒学
CiteScore
9.50
自引率
2.00%
发文量
239
审稿时长
43 days
期刊介绍: Virus Research provides a means of fast publication for original papers on fundamental research in virology. Contributions on new developments concerning virus structure, replication, pathogenesis and evolution are encouraged. These include reports describing virus morphology, the function and antigenic analysis of virus structural components, virus genome structure and expression, analysis on virus replication processes, virus evolution in connection with antiviral interventions, effects of viruses on their host cells, particularly on the immune system, and the pathogenesis of virus infections, including oncogene activation and transduction.
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