Introduction of Plasmid to the Murine Gut via Consumption of an Escherichia coli Carrier and Examining the Impact of Bacterial Dosing and Antibiotics on Persistence

LeNaiya Kydd; Fawaz Alalhareth; Ana Mendez; Maryann Hohn; Ami Radunskaya; Hristo Kojouharov; Justyn Jaworski

doi:10.1007/s40883-022-00248-z

Introduction of Plasmid to the Murine Gut via Consumption of an Escherichia coli Carrier and Examining the Impact of Bacterial Dosing and Antibiotics on Persistence

Regen Eng Transl Med. 2022;8(3):489-497. doi: 10.1007/s40883-022-00248-z. Epub 2022 Apr 14.

Authors

LeNaiya Kydd¹, Fawaz Alalhareth², Ana Mendez², Maryann Hohn³, Ami Radunskaya³, Hristo Kojouharov², Justyn Jaworski¹

Affiliations

¹ Department of Bioengineering, The University of Texas at Arlington, Arlington, TX 76010 USA.
² Department of Mathematics, The University of Texas at Arlington, Arlington, TX 76010 USA.
³ Department of Mathematics, Pomona College, Claremont, CA 91711 USA.

Abstract

Purpose: We examine the impacts of dosing strategies of plasmids on bacterial communities in the murine gut by measuring the quantity of plasmids in mouse feces.

Methods: We fed mice carrier bacteria, E. coli, that contain plasmids with both a reporter gene and an antibiotic resistant gene. We varied the quantity of the plasmid-carrying bacteria and the length of time the mice consumed the bacteria. We also pretreated the gut with broad-spectrum antibiotics and used continuous antibiotic treatment to investigate selection pressure. We collected bacteria from fecal pellets to quantify the number of plasmid-carrying bacteria via plate assay.

Results: Dosing regimens with plasmid-carrying bacteria resulted in a significantly increased duration of persistence of the plasmid within the gut when supplemented continuously with kanamycin during as well as after completion of bacterial dosing. The carrier bacteria concentration influenced the short-term abundance of carrier bacteria.

Conclusion: We evaluated the persistence of plasmid-carrying bacteria in the murine gut over time using varying dosage strategies. In future work, we will study how bacterial diversity in the gut impacts the degree of plasmid transfer and the prevalence of plasmid-carrying bacteria over time.

Lay summary: Observing how plasmids persist within the gut can help us understand how newly introduced genes, including antibiotic resistance, are transmitted within the gut microbiome. In our experiments, mice were given bacteria containing a genetically engineered plasmid and were examined for the persistence of the plasmid in the gut. We found long-term persistence of the plasmid in the gut when administering antibiotics during and following dosing of the mice with bacteria carrying the plasmid. The use of higher concentrations of carrier bacteria influenced the short-term abundance of the plasmid-carrying bacteria in the gut.

Description of future works: Building on evidence from these initial studies that persistence of plasmids within the gut can be regulated by the dosage strategy, we will explore future studies and models of gene uptake in the context of spatial and taxonomic control and further determine if dosing strategies alter the compositional diversity of the gut microbiome.

Keywords: Antibiotic; Escherichia coli; Gene transfer; Microbiome.