CRISPR-Cas inhibits plasmid transfer and immunizes bacteria against antibiotic resistance acquisition in manure.

IF 3.9 2区 生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Applied and Environmental Microbiology Pub Date : 2024-09-18 Epub Date: 2024-08-19 DOI:10.1128/aem.00876-24
Chahat Upreti, Pranav Kumar, Lisa M Durso, Kelli L Palmer
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引用次数: 0

Abstract

The horizontal transfer of antibiotic resistance genes among bacteria is a pressing global issue. The bacterial defense system clustered regularly interspaced short palindromic repeats (CRISPR)-Cas acts as a barrier to the spread of antibiotic resistance plasmids, and CRISPR-Cas-based antimicrobials can be effective to selectively deplete antibiotic-resistant bacteria. While significant surveillance efforts monitor the spread of antibiotic-resistant bacteria in the clinical context, a major, often overlooked aspect of the issue is resistance emergence in agriculture. Farm animals are commonly treated with antibiotics, and antibiotic resistance in agriculture is on the rise. Yet, CRISPR-Cas efficacy has not been investigated in this setting. Here, we evaluate the prevalence of CRISPR-Cas in agricultural Enterococcus faecalis strains and its antiplasmid efficacy in an agricultural niche: manure. Analyzing 1,986 E. faecalis genomes from human and animal hosts, we show that the prevalence of CRISPR-Cas subtypes is similar between clinical and agricultural E. faecalis strains. Using plasmid conjugation assays, we found that CRISPR-Cas is a significant barrier against resistance plasmid transfer in manure. Finally, we used a CRISPR-based antimicrobial approach to cure resistant E. faecalis of erythromycin resistance, but this was limited by delivery efficiency of the CRISPR antimicrobial in manure. However, immunization of bacteria against resistance gene acquisition in manure was highly effective. Together, our results show that E. faecalis CRISPR-Cas is prevalent and effective in an agricultural setting and has the potential to be utilized for depleting antibiotic-resistant populations. Our work has broad implications for tackling antibiotic resistance in the increasingly relevant agricultural setting, in line with a One Health approach.IMPORTANCEAntibiotic resistance is a growing global health crisis in human and veterinary medicine. Previous work has shown technologies based on CRISPR-Cas-a bacterial defense system-to be effective in tackling antibiotic resistance. Here we test if CRISPR-Cas is present and effective in agricultural niches, specifically in the ubiquitously present bacterium, Enterococcus faecalis. We show that CRISPR-Cas is both prevalent and functional in manure and has the potential to be used to specifically kill bacteria carrying antibiotic resistance genes. This study demonstrates the utility of CRISPR-Cas-based strategies for control of antibiotic resistance in agricultural settings.

CRISPR-Cas 可抑制质粒转移,使细菌免受粪便中抗生素耐药性的侵袭。
细菌间抗生素耐药性基因的水平转移是一个紧迫的全球性问题。细菌防御系统簇状有规律间隔短回文重复序列(CRISPR)-Cas 是抗生素耐药质粒传播的屏障,基于 CRISPR-Cas 的抗菌药物可以有效地选择性清除抗生素耐药细菌。虽然大量的监测工作是为了监控抗生素耐药细菌在临床环境中的传播,但这一问题的一个重要方面却常常被忽视,那就是农业中出现的耐药性。农场动物通常使用抗生素治疗,农业中的抗生素耐药性正在上升。然而,CRISPR-Cas 在这种情况下的功效尚未得到研究。在这里,我们评估了 CRISPR-Cas 在农业粪肠球菌菌株中的流行情况及其在农业生态位(粪便)中的抗质粒功效。通过分析来自人类和动物宿主的 1,986 个粪肠球菌基因组,我们发现 CRISPR-Cas 亚型在临床和农业粪肠球菌菌株中的流行程度相似。通过质粒共轭试验,我们发现 CRISPR-Cas 是阻止粪便中抗性质粒转移的重要障碍。最后,我们利用基于CRISPR的抗菌方法治愈了耐药性粪肠球菌对红霉素的耐药性,但这受到了粪便中CRISPR抗菌剂传递效率的限制。然而,针对粪便中耐药基因的获得对细菌进行免疫则非常有效。总之,我们的研究结果表明,粪肠球菌的 CRISPR-Cas 在农业环境中普遍存在且有效,有可能被用来消灭抗生素耐药菌群。我们的工作对于在日益相关的农业环境中解决抗生素耐药性问题具有广泛的意义,符合 "一个健康"(One Health)方法。以往的研究表明,基于 CRISPR-Cas 细菌防御系统的技术能有效解决抗生素耐药性问题。在这里,我们测试了 CRISPR-Cas 是否存在于农业壁龛中并有效,特别是在普遍存在的粪肠球菌中。我们的研究表明,CRISPR-Cas 在粪便中既普遍又有效,有可能被用来专门杀死携带抗生素耐药基因的细菌。这项研究表明,基于 CRISPR-Cas 的策略可用于控制农业环境中的抗生素耐药性。
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
Applied and Environmental Microbiology
Applied and Environmental Microbiology 生物-生物工程与应用微生物
CiteScore
7.70
自引率
2.30%
发文量
730
审稿时长
1.9 months
期刊介绍: Applied and Environmental Microbiology (AEM) publishes papers that make significant contributions to (a) applied microbiology, including biotechnology, protein engineering, bioremediation, and food microbiology, (b) microbial ecology, including environmental, organismic, and genomic microbiology, and (c) interdisciplinary microbiology, including invertebrate microbiology, plant microbiology, aquatic microbiology, and geomicrobiology.
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