
Control of Bacterial Persister Cells by Trp/Arg-Containing Antimicrobial Peptides
Author(s) -
Xi Chen,
Mi Zhang,
Chunhui Zhou,
Neville R. Kallenbach,
Dacheng Ren
Publication year - 2011
Publication title -
applied and environmental microbiology
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.552
H-Index - 324
eISSN - 1070-6291
pISSN - 0099-2240
DOI - 10.1128/aem.02440-10
Subject(s) - multidrug tolerance , biofilm , microbiology and biotechnology , escherichia coli , peptide , ofloxacin , bacteria , biology , antimicrobial , antimicrobial peptides , antibiotics , population , biochemistry , gene , medicine , genetics , environmental health , ciprofloxacin
Persister cells are dormant phenotypic variants inherent in a bacterial population. They play important roles in chronic infections and present great challenges to therapy due to extremely enhanced tolerance to antibiotics compared to that of normal cells of the same genotype. In this study, we report that cationic membrane-penetrating peptides containing various numbers of arginine and tryptophan repeats are effective in killing persister cells ofEscherichia coli HM22, a hyper-persister producer. The activities of three linear peptides [(RW)n -NH2 , wheren is 2, 3, or 4] and a dendrimeric peptide, (RW)4D , in killing bacterial persisters were compared. Although the dendrimeric peptide (RW)4D requires a lower threshold to kill planktonic persisters, octameric peptide (RW)4 -NH2 is the most effective against planktonic persister cells at high concentrations. For example, treatment with 80 μM (RW)4 -NH2 for 60 min led to a 99.7% reduction in the number of viable persister cells. The viability of persister cells residing in surface-attached biofilms was also significantly reduced by (RW)4 -NH2 and (RW)4D . These two peptides were also found to significantly enhance the susceptibility of biofilm cells to ofloxacin. The potency of (RW)4 -NH2 was further marked by its ability to disperse and kill preformed biofilms harboring high percentages of persister cells. Interestingly, approximately 70% of the dispersed cells were found to have lost their intrinsic tolerance and become susceptible to ampicillin if not killed directly by this peptide. These results are helpful for better understanding the activities of these peptides and may aid in future development of more effective therapies of chronic infections.