PLoS Genetics (Jun 2023)

Genetic basis of I-complex plasmid stability and conjugation

  • Zheng Jie Lian,
  • Minh-Duy Phan,
  • Steven J. Hancock,
  • Nguyen Thi Khanh Nhu,
  • David L. Paterson,
  • Mark A. Schembri

Journal volume & issue
Vol. 19, no. 6

Abstract

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Plasmids are major drivers of increasing antibiotic resistance, necessitating an urgent need to understand their biology. Here we describe a detailed dissection of the molecular components controlling the genetics of I-complex plasmids, a group of antibiotic resistance plasmids found frequently in pathogenic Escherichia coli and other Enterobacteriaceae that cause significant human disease. We show these plasmids cluster into four distinct subgroups, with the prototype IncI1 plasmid R64 subgroup displaying low nucleotide sequence conservation to other I-complex plasmids. Using pMS7163B, an I-complex plasmid distantly related to R64, we performed a high-resolution transposon-based genetic screen and defined genes involved in replication, stability, and conjugative transfer. We identified the replicon and a partitioning system as essential for replication/stability. Genes required for conjugation included the type IV secretion system, relaxosome, and several uncharacterised genes located in the pMS7163B leading transfer region that exhibited an upstream strand-specific transposon insertion bias. The overexpression of these genes severely impacted host cell growth or reduced fitness during mixed competitive growth, demonstrating that their expression must be controlled to avoid deleterious impacts. These genes were present in >80% of all I-complex plasmids and broadly conserved across multiple plasmid incompatibility groups, implicating an important role in plasmid dissemination. Author summary Antimicrobial resistance is one of the greatest threats to human health. Left unchecked, we risk a rapid escalation of untreatable infections. Plasmids are one of the most important vehicles for resistance gene carriage and transmission between bacteria, and thus an understanding of plasmid biology is crucial to controlling the spread antimicrobial resistance. Here, we combine advanced bioinformatics and a state-of-the-art genetic screen to understand the molecular mechanisms involved in the maintenance and spread of a group of plasmids strongly associated with antibiotic resistance among bacteria that cause human infection. We characterised genes involved in the replication and maintenance of these plasmids, and experimentally demonstrated that plasmid spread is dependent on a well-conserved secretion system. Our genetic screen also discovered a set of broadly conserved, uncharacterised genes that adversely impact host fitness and plasmid spread under dysregulation. Taken together, these findings describe a molecular blueprint for the biology of a group of clinically relevant antibiotic resistance plasmids found frequently in Gram-negative bacterial pathogens.