Abstract
Comparative genomics has greatly facilitated the identification of shared as well as unique features among individual cells or tissues, and thus offers the potential to find disease markers. While proteomics is recognized for its potential to generate quantitative maps of protein expression, comparative proteomics in bacteria has been largely restricted to the comparison of single cell lines or mutant strains. In this study, we used a data independent acquisition (DIA) technique, which enables global protein quantification of large sample cohorts, to record the proteome profiles of overall 27 whole genome sequenced and transcriptionally profiled clinical isolates of the opportunistic pathogen Pseudomonas aeruginosa. Analysis of the proteome profiles across the 27 clinical isolates grown under planktonic and biofilm growth conditions led to the identification of a core biofilm-associated protein profile. Furthermore, we found that protein-to-mRNA ratios between different P. aeruginosa strains are well correlated, indicating conserved patterns of post-transcriptional regulation. Uncovering core regulatory pathways, which drive biofilm formation and associated antibiotic tolerance in bacterial pathogens, promise to give clues to interactions between bacterial species and their environment and could provide useful targets for new clinical interventions to combat biofilm-associated infections.
Highlights
Bacteria either grow as free-swimming planktonic cells, or organized into biofilms [1,2]
Fractions were analyzed in triplicate by data dependent acquisition mass spectrometry, and the combined spectra were searched against the P. aeruginosa reference strain UCBPP-PA14 proteome
On the other hand we found a general down-regulation of environmental conditions were different from our study, we found an overlap with 48 proteins involved in translation processes in the biofilm-grown isolates
Summary
Bacteria either grow as free-swimming planktonic cells, or organized into biofilms [1,2]. Microbial biofilm communities are embedded in a thick, self-produced extracellular matrix and proliferate attached to abiotic or biotic surfaces [3,4,5]. Their formation represents a universal bacterial survival strategy, where the encapsulated bacteria are protected against a diverse array of environmental stressors [6,7]. Biofilms occur in natural environments, but there are biofilm-associated infections of the eukaryotic host, which are notoriously difficult to treat [8,9,10].
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