Background <p><i>Pseudomonas aeruginosa</i> accounts for 10–20% of hospital-acquired infections and is a major pathogen in immunocompromised patients. Combination therapies with beta-lactam antibiotics and beta-lactamase inhibitors, such as imipenem-relebactam have improved treatment options, yet resistant strains have already emerged, with mechanisms still not fully elucidated.</p> Results <p>We sequenced and analyzed 10 clinical <i>P. aeruginosa</i> isolates resistant to imipenem-relebactam (IMI/REL) and compared them with publicly available genomes of imipenem-resistant (IMI-R) and imipenem-susceptible (IMI-S) strains. Resistance genes were identified using the RGI CARD database, while amino acid variations in core-genome proteins were evaluated through Gene Ontology overrepresentation analysis (GO), followed by GWAS. In total, 15,758 ARGs were detected, 25.85% associated with carbapenem resistance, but only 568 classified as beta-lactamases. Among IMI/REL isolates, 36.36% carried Ambler class A and 54.54% class B beta-lactamases, contrasting with much lower frequencies in IMI-R (5.4% and 3.6%) and IMI-S (0% and 0.73%). Core-genome analysis revealed 1,106 proteins with resistance-associated variations. Comparative analyzes identified 1,618 proteins differing between IMI/REL and IMI-R genomes, and 1,015 differing between IMI/REL and all other strains. GWAS highlighted candidate genes with strong statistical associations, including those involved in metal ion transport (e.g., <i>tonB</i>, <i>foxA</i>, <i>phuR</i>, <i>pfeA</i>) and efflux pumps (e.g., <i>czcB</i>), as well as regulators such as <i>mexT</i> and biofilm-related proteins.</p> Conclusions <p>These findings suggest that, beyond classical beta-lactamases, resistance may be associated with multifactorial contributions from periplasmic and outer membrane proteins, metal ion homeostasis, efflux regulation, and biofilm-associated pathways. Our results expand current knowledge of <i>P. aeruginosa</i> resistome and highlight novel genomic signatures potentially driving resistance to imipenem-relebactam.</p>

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Molecular determinants associated with resistance to imipenem and imipenem–relebactam in clinical Pseudomonas aeruginosa isolates

  • André Bittencourt Lorusso,
  • Joyce de Souza,
  • Larissa Bail,
  • Carmen Antonia Sanches Ito,
  • João Antonio Carrara,
  • Felipe Francisco Bondan Tuon,
  • Helisson Faoro

摘要

Background

Pseudomonas aeruginosa accounts for 10–20% of hospital-acquired infections and is a major pathogen in immunocompromised patients. Combination therapies with beta-lactam antibiotics and beta-lactamase inhibitors, such as imipenem-relebactam have improved treatment options, yet resistant strains have already emerged, with mechanisms still not fully elucidated.

Results

We sequenced and analyzed 10 clinical P. aeruginosa isolates resistant to imipenem-relebactam (IMI/REL) and compared them with publicly available genomes of imipenem-resistant (IMI-R) and imipenem-susceptible (IMI-S) strains. Resistance genes were identified using the RGI CARD database, while amino acid variations in core-genome proteins were evaluated through Gene Ontology overrepresentation analysis (GO), followed by GWAS. In total, 15,758 ARGs were detected, 25.85% associated with carbapenem resistance, but only 568 classified as beta-lactamases. Among IMI/REL isolates, 36.36% carried Ambler class A and 54.54% class B beta-lactamases, contrasting with much lower frequencies in IMI-R (5.4% and 3.6%) and IMI-S (0% and 0.73%). Core-genome analysis revealed 1,106 proteins with resistance-associated variations. Comparative analyzes identified 1,618 proteins differing between IMI/REL and IMI-R genomes, and 1,015 differing between IMI/REL and all other strains. GWAS highlighted candidate genes with strong statistical associations, including those involved in metal ion transport (e.g., tonB, foxA, phuR, pfeA) and efflux pumps (e.g., czcB), as well as regulators such as mexT and biofilm-related proteins.

Conclusions

These findings suggest that, beyond classical beta-lactamases, resistance may be associated with multifactorial contributions from periplasmic and outer membrane proteins, metal ion homeostasis, efflux regulation, and biofilm-associated pathways. Our results expand current knowledge of P. aeruginosa resistome and highlight novel genomic signatures potentially driving resistance to imipenem-relebactam.