Abstract
ABSTRACTUnderstanding the interplay between antibiotic resistance and bacterial fitness and virulence is essential to guide individual treatments and improve global antibiotic policies. A paradigmatic example of a resistance mechanism is the intrinsic inducible chromosomal β-lactamase AmpC from multiple Gram-negative bacteria, including Pseudomonas aeruginosa, a major nosocomial pathogen. The regulation of ampC expression is intimately linked to peptidoglycan recycling, and AmpC-mediated β-lactam resistance is frequently mediated by inactivating mutations in ampD, encoding an N-acetyl-anhydromuramyl-l-alanine amidase, affecting the levels of ampC-activating muropeptides. Here we dissect the impact of the multiple pathways causing AmpC hyperproduction on P. aeruginosa fitness and virulence. Through a detailed analysis, we demonstrate that the lack of all three P. aeruginosa AmpD amidases causes a dramatic effect in fitness and pathogenicity, severely compromising growth rates, motility, and cytotoxicity; the latter effect is likely achieved by repressing key virulence factors, such as protease LasA, phospholipase C, or type III secretion system components. We also show that ampC overexpression is required but not sufficient to confer the growth-motility-cytotoxicity impaired phenotype and that alternative pathways leading to similar levels of ampC hyperexpression and resistance, such as those involving PBP4, had no fitness-virulence cost. Further analysis indicated that fitness-virulence impairment is caused by overexpressing ampC in the absence of cell wall recycling, as reproduced by expressing ampC from a plasmid in an AmpG (muropeptide permease)-deficient background. Thus, our findings represent a major step in the understanding of β-lactam resistance biology and its interplay with fitness and pathogenesis.
Highlights
Understanding the interplay between antibiotic resistance and bacterial fitness and virulence is essential to guide individual treatments and improve global antibiotic policies
Further studies showed that P. aeruginosa has, in addition to the cytoplasmic AmpD, two periplasmic N-acetyl-anhydromuramyl-L-alanine amidases (AmpDh2 and AmpDh3) and that their sequential inactivation leads to a stepwise upregulation of ampC, reaching full derepression with very high levels (Ͼ1,000-fold with respect to the wild-type level) of ampC expression and clinical -lactam resistance in the triple mutant [20]
Using the two reference P. aeruginosa strains PAO1 and PA14, we demonstrate that the lack of all three AmpD amidases has a major effect on fitness and pathogenicity, severely compromising growth rates, motility, and cytotoxicity, the latter being likely due to repression of key virulence factors
Summary
Understanding the interplay between antibiotic resistance and bacterial fitness and virulence is essential to guide individual treatments and improve global antibiotic policies. Further studies showed that P. aeruginosa has, in addition to the cytoplasmic AmpD, two periplasmic N-acetyl-anhydromuramyl-L-alanine amidases (AmpDh2 and AmpDh3) and that their sequential inactivation leads to a stepwise upregulation of ampC, reaching full derepression with very high levels (Ͼ1,000-fold with respect to the wild-type level) of ampC expression and clinical -lactam resistance in the triple mutant [20]. This full ampC derepression through inactivation of the three amidases has been associated with fitness and virulence impairment [21]
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