Evidence of horizontal gene transfer and environmental selection impacting antibiotic resistance evolution in soil-dwelling Listeria

Goh, Ying-Xian; Anupoju, Sai Manohar Balu; Nguyen, Anthony; Zhang, Hailong; Ponder, Monica; Krometis, Leigh-Anne; Pruden, Amy; Liao, Jingqiu

Evidence of horizontal gene transfer and environmental selection impacting antibiotic resistance evolution in soil-dwelling Listeria

Ying-Xian Goh, Sai Manohar Balu Anupoju, Anthony Nguyen, Hailong Zhang, Monica Ponder, Leigh-Anne Krometis, Amy Pruden and Jingqiu Liao ()
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Ying-Xian Goh: Virginia Tech
Sai Manohar Balu Anupoju: Virginia Tech
Anthony Nguyen: Virginia Tech
Hailong Zhang: Virginia Tech
Monica Ponder: Virginia Tech
Leigh-Anne Krometis: Virginia Tech
Amy Pruden: Virginia Tech
Jingqiu Liao: Virginia Tech

Nature Communications, 2024, vol. 15, issue 1, 1-13

Abstract: Abstract Soil is an important reservoir of antibiotic resistance genes (ARGs) and understanding how corresponding environmental changes influence their emergence, evolution, and spread is crucial. The soil-dwelling bacterial genus Listeria, including L. monocytogenes, the causative agent of listeriosis, serves as a key model for establishing this understanding. Here, we characterize ARGs in 594 genomes representing 19 Listeria species that we previously isolated from soils in natural environments across the United States. Among the five putatively functional ARGs identified, lin, which confers resistance to lincomycin, is the most prevalent, followed by mprF, sul, fosX, and norB. ARGs are predominantly found in Listeria sensu stricto species, with those more closely related to L. monocytogenes tending to harbor more ARGs. Notably, phylogenetic and recombination analyses provide evidence of recent horizontal gene transfer (HGT) in all five ARGs within and/or across species, likely mediated by transformation rather than conjugation and transduction. In addition, the richness and genetic divergence of ARGs are associated with environmental conditions, particularly soil properties (e.g., aluminum and magnesium) and surrounding land use patterns (e.g., forest coverage). Collectively, our data suggest that recent HGT and environmental selection play a vital role in the acquisition and diversification of bacterial ARGs in natural environments.

Date: 2024
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DOI: 10.1038/s41467-024-54459-9

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