New Paper: Multidrug-resistant E. coli encoding high genetic diversity in carbohydrate metabolism genes displace commensal E. coli from the intestinal tract

Congratulations to our Education & Mentorship Co-Lead Dr. Braedon McDonald on this recent publication!

Abstract

Extra-intestinal pathogenic Escherichia coli (ExPEC) can cause a variety of infections outside of the intestine and are a major causative agent of urinary tract infections. Treatment of these infections is increasingly frustrated by antimicrobial resistance (AMR) diminishing the number of effective therapies available to clinicians. Incidence of multidrug resistance (MDR) is not uniform across the phylogenetic spectrum of Ecoli. Instead, AMR is concentrated in select lineages, such as ST131, which are MDR pandemic clones that have spread AMR globally. Using a gnotobiotic mouse model, we demonstrate that an MDR Ecoli ST131 is capable of out-competing and displacing non-MDR Ecoli from the gut in vivo. This is achieved in the absence of antibiotic treatment mediating a selective advantage. In mice colonised with non-MDR Ecoli strains, challenge with MDR Ecoli either by oral gavage or co-housing with MDR Ecoli colonised mice results in displacement and dominant intestinal colonisation by MDR Ecoli ST131. To investigate the genetic basis of this superior gut colonisation ability by MDR Ecoli, we assayed the metabolic capabilities of our strains using a Biolog phenotypic microarray revealing altered carbon metabolism. Functional pangenomic analysis of 19,571 Ecoli genomes revealed that carriage of AMR genes is associated with increased diversity in carbohydrate metabolism genes. The data presented here demonstrate that independent of antibiotic selective pressures, MDR Ecoli display a competitive advantage to colonise the mammalian gut and points to a vital role of metabolism in the evolution and success of MDR lineages of Ecoli via carriage and spread.

Publication: Multidrug-resistant Ecoli encoding high genetic diversity in carbohydrate metabolism genes displace commensal Ecoli from the intestinal tract. Connor CH, Zucoloto AZ, Munnoch JT, Yu IL, Corander J, Hoskisson PA, McDonald B, McNally A. PLOS Biology. 17 Oct 2023.

Share This Post

Twitter
LinkedIn
Email

Recent Posts