Biofilms are considered to be highly resistant to antimicrobial agents. Several mechanisms have been proposed to explain this high resistance of biofilms, including restricted penetration of antimicrobial agents into biofilms, slow growth owing to nutrient limitation, expression of genes involved in the general stress response, and emergence of a biofilm-specific phenotype. However, since combinations of these factors are involved in most biofilm studies, it is still difficult to fully understand the mechanisms of biofilm resistance to antibiotics. In this study, the antibiotic susceptibility of Escherichia coli cells in biofilms was investigated with exclusion of the effects of the restricted penetration of antimicrobial agents into biofilms and the slow growth owing to nutrient limitation. Three different antibiotics, ampicillin (100 g/ml), kanamycin (25 g/ml), and ofloxacin (10 g/ml), were applied directly to cells in the deeper layers of mature biofilms that developed in flow cells after removal of the surface layers of the biofilms. The results of the antibiotic treatment analyses revealed that ofloxacin and kanamycin were effective against biofilm cells, whereas ampicillin did not kill the cells, resulting in regrowth of the biofilm after the ampicillin treatment was discontinued. LIVE/DEAD staining revealed that a small fraction of resistant cells emerged in the deeper layers of the mature biofilms and that these cells were still alive even after 24 h of ampicillin treatment. Furthermore, to determine which genes in the biofilm cells are induced, allowing increased resistance to ampicillin, global gene expression was analyzed at different stages of biofilm formation, the attachment, colony formation, and maturation stages. The results showed that significant changes in gene expression occurred during biofilm formation, which were partly induced by rpoS expression. Based on the experimental data, it is likely that the observed resistance of biofilms can be attributed to formation of ampicillin-resistant subpopulations in the deeper layers of mature biofilms but not in young colony biofilms and that the production and resistance of the subpopulations were aided by biofilm-specific phenotypes, like slow growth and induction of rpoS-mediated stress responses.Reduced susceptibility of biofilm bacteria to antimicrobial agents is a crucial problem for treatment of chronic infections (11,29,48). It has been estimated that 65% of microbial infections are associated with biofilms (11,29,37), and biofilm cells are 100 to 1,000 times more resistant to antimicrobial agents than planktonic bacterial cells (11,29,32).The molecular nature of this apparent resistance has not been elucidated well, and a number of mechanisms have been proposed to explain the reduced susceptibility, such as restricted antibiotic penetration (47), decreased growth rates and metabolism (7, 52), quorum sensing and induction of a biofilmspecific phenotype (8,29,35,39,49), stress response activation (7,52), and an increase in expression of efflux...
Bacteria show remarkable adaptability under several stressful conditions by shifting themselves into a dormant state. Less is known, however, about the mechanism underlying the cell transition to dormancy. Here, we report that the transition to dormant states is mediated by one of the major toxin-antitoxin systems, RelEB, in a cell density-dependent manner in Escherichia coli K-12 MG1655. We constructed a strain, IKA121, which expresses the toxin RelE in the presence of rhamnose and lacks chromosomal relBE and rhaBAD. With this strain, we demonstrated that RelE-mediated dormancy is enhanced at high cell densities compared to that at low cell densities. The initiation of expression of the antitoxin RelB from a plasmid, pCA24N, reversed RelEmediated dormancy in bacterial cultures. The activation of RelE increased the appearance of persister cells against -lactams, quinolones, and aminoglycosides, and more persister cells appeared at high cell densities than at low cell densities. Further analysis indicated that amino acid starvation and an uncharacterized extracellular heat-labile substance promote RelE-mediated dormancy. This is a first report on the induction of RelE-mediated dormancy by high cell density. This work establishes a population-based dormancy mechanism to help explain E. coli survival in stressful environments. Dormancy is an adaptive response to environmental stress, and this strategy is observed with both eukaryotic organisms and bacteria. Bacteria can enter into dormant conditions as spores or persister cells and in viable but nonculturable (VBNC) states (30,34). Dormant bacteria do not proliferate but are able to tolerate environmental stress and eventually recover under normal growing conditions.Persister cells, which are a small subpopulation of apparently nongrowing multidrug-tolerant cells, are observed in bacterial biofilms (21,24,43). Biofilms are formed when bacterial cells attach to a surface and grow into a mass encapsulated by an exopolymer matrix (11). In biofilms, bacterial cells are very dense, and bacteria exhibit social behavior through the use of extracellular signals, a mechanism called quorum sensing (40). This mechanism enables bacteria to coordinate the activation and deactivation of multiple genes in a cell density-dependent manner via the secretion and recognition of several different types of signals. Thus, the biofilm is prominently involved in bacterial dormancy and quorum sensing.It has been suggested that toxin-antitoxin (TA) modules are involved in the entry of Escherichia coli into dormant states (24, 31, 37). Several toxins, including HipA, RelE, YafQ, TisB, MqsR, CspD, and Hha, are associated with persister formation (13,18,24,25). RelEB is among the most studied TA systems in E. coli and encodes a cytotoxin, RelE, which cleaves mRNA on translating ribosomes, and an antitoxin, RelB, which antagonizes RelE by direct protein-protein interaction (10). Transcription of relBE is autoregulated by the antitoxin RelB via binding to the relBE promoter region, and RelE enha...
Although importance of the rpoS gene on biofilm formation by Escherichia coli has been suggested, there has not been any report showing where the rpoS is expressed during biofilm formation process. Since physiological state of the cells in the biofilms is considerably heterogeneous, the expression of the rpoS gene must be heterogeneous. In this study, in situ spatial expression of the rpoS gene during biofilm formation was investigated with an rpoS-gfp transcriptional fusion mutant strain. A ribosomal binding site and a gene encoding a green fluorescent protein were introduced into the downstream of the rpoS gene, which enabled us to observe the in situ spatial expression of the rpoS gene during biofilm formation processes without any disturbance of the rpoS expression. In the early stages of the biofilm formation process, the rpoS gene was expressed in the most of the cells. On the other hand, the rpoS expression was observed only at the outside of the biofilms during the late stages of the biofilm formation process. The in situ spatial expression of the rpoS gene in the biofilm was verified by quantifying the expression levels of the rpoS at the outside and the inside of the biofilms with the real time RT-PCR. In addition, global gene expression analysis was performed with DNA microarray to investigate physiological difference between the outside and the inside of the biofilms. This heterogeneous rpoS expression profile suggested that the cells at the outside of the biofilm need to express the rpoS to shift the physiological state to the stationary growth mode such as induction of various stress responses and suppression of the motility.
Quantitative PCR (qPCR) assays targeting the host-specific Bacteroides-Prevotella 16S rRNA genetic markers have been proposed as one of the promising approaches to identify the source of fecal contamination in environmental waters. One of the concerns of qPCR assays to environmental samples is the reliability of quantified values, since DNA extraction followed by qPCR assays are usually performed without appropriate sample process control (SPC) and internal amplification controls (IACs). To check the errors in sample processing and improve the reliability of qPCR results, it is essential to evaluate the DNA recovery efficiency and PCR amplification efficiency of the target genetic markers and correct the measurement results. In this study, we constructed a genetically-engineered Escherichia coli K12 strain (designated as strain MG1655 Δlac::kan) as sample process control and evaluated the applicability to environmental water samples. The recovery efficiency of the SPC strain MG1655 Δlac::kan was similar to that of Bacteroides fragilis JCM 11019, when DNA were extracted from water samples spiked with the two bacteria. Furthermore, the SPC was included in the qPCR assays with propidium monoazide (PMA) treatment, which can exclude the genetic markers from dead cells. No significant DNA loss was observed in the PMA treatment. The inclusion of both the SPC (strain MG1655 Δlac::kan) and IAC in qPCR assays with PMA treatment gave the assurance of reliable results of host-specific Bacteroides-Prevotella 16S rRNA genetic markers in environmental water samples.
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