Fast bacterial growth reduces antibiotic accumulation and efficacy.
Urszula ŁapińskaMargaritis VoliotisKa Kiu LeeAdrian CampeyM Rhia L StoneBrandon TuckWanida PhetsangBing ZhangKrasimira Tsaneva-AtanasovaMark A T BlaskovichStefano PagliaraPublished in: eLife (2022)
Phenotypic variations between individual microbial cells play a key role in the resistance of microbial pathogens to pharmacotherapies. Nevertheless, little is known about cell individuality in antibiotic accumulation. Here, we hypothesise that phenotypic diversification can be driven by fundamental cell-to-cell differences in drug transport rates. To test this hypothesis, we employed microfluidics-based single-cell microscopy, libraries of fluorescent antibiotic probes and mathematical modelling. This approach allowed us to rapidly identify phenotypic variants that avoid antibiotic accumulation within populations of Escherichia coli , Pseudomonas aeruginosa , Burkholderia cenocepacia, and Staphylococcus aureus . Crucially, we found that fast growing phenotypic variants avoid macrolide accumulation and survive treatment without genetic mutations. These findings are in contrast with the current consensus that cellular dormancy and slow metabolism underlie bacterial survival to antibiotics. Our results also show that fast growing variants display significantly higher expression of ribosomal promoters before drug treatment compared to slow growing variants. Drug-free active ribosomes facilitate essential cellular processes in these fast-growing variants, including efflux that can reduce macrolide accumulation. We used this new knowledge to eradicate variants that displayed low antibiotic accumulation through the chemical manipulation of their outer membrane inspiring new avenues to overcome current antibiotic treatment failures.
Keyphrases
- copy number
- single cell
- escherichia coli
- staphylococcus aureus
- pseudomonas aeruginosa
- cell therapy
- healthcare
- stem cells
- microbial community
- induced apoptosis
- poor prognosis
- biofilm formation
- mesenchymal stem cells
- magnetic resonance
- oxidative stress
- drug induced
- single molecule
- high resolution
- quantum dots
- emergency department
- combination therapy
- cystic fibrosis
- genome wide
- clinical practice
- cell proliferation
- mass spectrometry
- multidrug resistant
- long non coding rna
- bone marrow
- drug resistant
- high speed
- label free
- optical coherence tomography
- methicillin resistant staphylococcus aureus