Comparative phenotypic and proteomic analysis of colistin-exposed Pseudomonas aeruginosa

Introduction: The emergence of colistin resistance threatens the treatment of Pseudomonas aeruginosa infections.

Methods: In this study, in vitro development of colistin resistance was investigated using comparative phenotypic and proteomic analysis of P. aeruginosa ATCC 9027, its 14-day colistin sub-MIC exposed strain (Col-E1), and 10-day antibiotic-free cultured Col-E1 strain (Col-E2). Antibiotic susceptibility, morphology, virulence factors, and proteomic changes were assessed using disc-diffusion, agar-based, spectrophotometry, SEM, and iTRAQ-LC-MS/MS methods.

Results: Colistin-exposed strains decreased susceptibility to colistin while remaining susceptible to other antibiotics. Col-E1 reduced the cell lengths by 17.67% and the colony size by 36.16% compared to the initial strain. The reduction remained in Col-E2. The pyocyanin production was reduced in Col-E1 (p=0.025, Tukey HSD) and increased again in Col-E2 (p=0.005, Tukey HSD). In contrast, no significant changes in elastase, protease, rhamnolipid, pyoverdine, and biofilm production were observed (p>0.05, Tukey HSD). In Col-E1, the proteome analysis showed 135 differentially expressed proteins (DEPs) of which 94 DEPs (69.23%) maintained their expression change in Col-E2. Among DEPs, 82 were involved in metabolism and protein synthesis. Some DEPs (6/135) played a role in stress response such as GrpE (fold change: 14.93) and Hmp (fold change: 12.08). In particular, membrane proteins like OprD, DdlB, and OprI showed significant colistin response with fold change of -8.47, 6.43 and 6.19, respectively.

Conclusions: In summary, colistin response in P. aeruginosa seemed to affect morphology, production of pyocyanin, and proteins of metabolism, protein synthesis, stress response and membrane.