Presence of quorum-sensing systems associated with multidrug resistance and biofilm formation in Bacteroides fragilis.

Bacteroides fragilis constitutes 1-2% of the natural microbiota of the human digestive tract and is the predominant anaerobic opportunistic pathogen in gastrointestinal infections. Most bacteria use quorum sensing (QS) to monitor cell density in relation to other cells and their environment. In Gram-negative bacteria, the LuxRI system is common. The luxR gene encodes a transcriptional activator inducible by type I acyl-homoserine lactone autoinducers (e.g., N-[3-oxohexanoyl] homoserine lactone and hexanoyl homoserine lactone [C6-HSL]). This study investigated the presence of QS system(s) in B. fragilis. The genome of American-type culture collection strain no. ATCC25285 was searched for QS genes. The strain was grown to late exponential phase in the presence or absence of synthetic C6-HSL and C8-HSL or natural homoserine lactones from cell-free supernatants from spent growth cultures of other bacteria. Growth, susceptibility to antimicrobial agents, efflux pump gene (bmeB) expression, and biofilm formation were measured. Nine luxR and no luxI orthologues were found. C6-HSL and supernatants from Yersinia enterocolitica, Vibrio cholerae, and Pseudomonas aeruginosa caused a significant (1) reduction in cellular density and (2) increases in expression of four putative luxR genes, bmeB3, bmeB6, bmeB7, and bmeB10, resistance to various antibiotics, which was reduced by carbonyl cyanide-m-chlorophenyl hydrazone (CCCP, an uncoupler that dissipates the transmembrane proton gradient, which is also the driving force of resistance nodulation division efflux pumps) and (3) increase in biofilm formation. Susceptibility of ATCC25285 to C6-HSL was also reduced by CCCP. These data suggest that (1) B. fragilis contains putative luxR orthologues, which could respond to exogenous homoserine lactones and modulate biofilm formation, bmeB efflux pump expression, and susceptibility to antibiotics, and (2) BmeB efflux pumps could transport homoserine lactones.

Impact of anatomic site on growth, efflux-pump expression, cell structure, and stress responsiveness of Bacteroides fragilis.

This study investigated whether B. fragilis from various human sites acquired stable traits enabling it to express certain efflux pumps (EPs), adopt a particular cell structure, and tolerate certain stressors. Isolates from blood, abscess, and stool (n = 11 each) were investigated. Bacteria from various sites portrayed different ultrastructres and EP expression. Blood isolates were tolerant to nutrient limitation and stool isolates to NaCl and bile salt stress. Stressors significantly increased EP expression. These data demonstrate that (1) B. fragilis acquires stable traits from various in vivo microenvironments; (2) that EPs are involved in stress responsiveness; and (3) that EP expression is tightly controlled and site dependent.

Induction of multiple antibiotic resistance in Bacteroides fragilis by benzene and benzene-derived active compounds of commonly used analgesics, antiseptics and cleaning agents.

OBJECTIVES: To determine the potential of active compounds (ACs) present in commonly used analgesics/antiseptics and cleaning agents (detergents and disinfectants) to induce multiple antibiotic resistance (MAR) in Bacteroides fragilis. METHODS: B. fragilis ATCC 25285 untreated or pretreated with sublethal concentrations of ACs (n = 25) was grown for 12 h. Susceptibility of cells pre-treated with various ACs to antibiotics and expression of resistance nodulation division family (bmeB) efflux pumps and putative marA-like global activators (PGAs) were measured. RESULTS: Twelve aromatic ACs containing benzene or its activated derivatives (salicylate, acetaminophen, gingerol, benzoate, phenol, chlorhexidine gluconate, capsaicin, juglone, cinnamaldehyde, benzene, ibuprofen and Triton X-100) induced MAR, which was reduced by carbonyl cyanide m-chlorophenylhydrazone. There was a positive correlation between the predicted degree of benzene activation and the level of induction. Deactivated benzene or non-aromatic ACs were either poor inducers or non-inducers. Efflux pumps bmeB1, 3, 4, 7 and two PGAs bfrA1 and bfrA2 were overexpressed. Expression of bfrA1 or bfrA2 in Escherichia coli caused a >2-fold increase in the MAR and overexpression of acrB, suggesting that they were putative marA orthologues. CONCLUSIONS: These data demonstrate (i) the presence of an MarA-like system(s) in B. fragilis and (ii) the propensity of benzene or its activated derivatives present in pharmaceutical products to induce MAR.

Bile salts enhance bacterial co-aggregation, bacterial-intestinal epithelial cell adhesion, biofilm formation and antimicrobial resistance of Bacteroides fragilis.

Bacteroides fragilis is the most common anaerobic bacterium isolated from human intestinal tract infections. Before B. fragilis interacts with the intestinal epithelial cells, it is exposed to bile salts at physiological concentrations of 0.1-1.3%. The aim of this study was to determine how pre-treatment with bile salts affected B. fragilis cells and their interaction with intestinal epithelial cells. B. fragilis NCTC9343 was treated with conjugated bile salts (BSC) or non-conjugated bile salts (BSM). Cellular ultrastructure was assessed by electron microscopy, gene expression was quantified by comparative quantitative real-time RT-PCR. Adhesion to the HT-29 human intestinal cell line and to PVC microtitre plates (biofilm formation) was determined. Exposure to 0.15% BSC or BSM resulted in overproduction of fimbria-like appendages and outer membrane vesicles, and increased expression of genes encoding RND-type efflux pumps and the major outer membrane protein, OmpA. Bile salt-treated bacteria had increased resistance to structurally unrelated antimicrobial agents and showed a significant increase in bacterial co-aggregation, adhesion to intestinal epithelial cells and biofilm formation. These data suggest that bile salts could enhance intestinal colonization by B. fragilis via several mechanisms, and could therefore be significant to host-pathogen interactions.

The Bacteroides fragilis cell envelope: quarterback, linebacker, coach-or all three?

Bacteroides fragilis is an anaerobic commensal constituting only 1-2% of the micro-flora of the human gastrointestinal tract, yet it is the predominant anaerobic isolate in cases of intraabdominal sepsis and bacteremia. B. fragilis can play two roles in the host: in its role as friendly commensal, it must be able to establish itself in the host intestinal mucosa, to utilize and process polysaccharides for use by the host, and to resist the noxious effects of bile salts. In its role as pathogen, it must be able to attach itself to the site of infection, evade killing mechanisms by host defense, withstand antimicrobial treatment and produce factors that damage host tissue. The cell envelope of B. fragilis, likewise, must be able to function in the roles of aggressor, defender and strategist in allowing the organism to establish itself in the host--whether as friend or foe. Recent studies of the genomes and proteomes of the genus Bacteroides suggest that these organisms have evolved strategies to survive and dominate in the overcrowded gastrointestinal neighborhood. Analysis of the proteomes of B. fragilis and Bacteroides thetaiotaomicron demonstrates both a tremendous capacity to use a wide range of dietary polysaccharides, and the capacity to create variable surface antigenicities by multiple DNA inversion systems. The latter characteristic is particularly pronounced in the species B. fragilis, which is more frequently found at the mucosal surface (i.e., often the site of attack by host defenses). The B. fragilis cell envelope undergoes major protein expression and ultrastructural changes in response to stressors such as bile or antimicrobial agents. These agents may also act as signals for attachment and colonization. Thus the bacterium manages its surface characteristics to enable it to bind to its target, to use the available nutrients, and to avoid or evade hostile forces (host-derived or external) in its multiple roles.

Capture of flowing human neutrophils by immobilised immunoglobulin: roles of Fc-receptors CD16 and CD32.

We investigated capture and activation of flowing human neutrophils through their Fc-receptors, FcRgammaIIIB (CD16) and FcRgammaIIA (CD32). Immobilised platelets bearing murine monoclonal antibody against glycoprotein IIbIIIA were able to capture and activate flowing neutrophils. The activation response was inhibited by antibody blockade of neutrophil CD32. However, capture only occurred efficiently at wall shear stress below 0.1 Pa if platelet P-selectin was blocked. If neutrophils were perfused over immobilised human IgG, many adhered at 0.025 or 0.05 Pa, but not at 0.1 Pa. Adhesion was reduced by blockade of CD16 or CD32, but blockade of CD16 had the greater effect. When neutrophils were perfused over a combination of purified P-selectin and IgG, blockade of CD16 and CD32 inhibited activation of captured cells. Immunoglobulin deposited in tissue could capture and activate slow-flowing neutrophils. It might also potentiate inflammatory responses at higher stress if presented along with selectins. The dominant FcR for capture of neutrophils was CD16, but with murine antibody, CD32 played a greater role.

Disturbed flow promotes deposition of leucocytes from flowing whole blood in a model of a damaged vessel wall.

Departure from simple laminar flow in arteries may promote the local attachment of leucocytes either to intact endothelium or platelet thrombi. We perfused blood through a chamber with a backward facing step, to observe whether adhesion from whole blood to P-selectin was indeed localized to a region of recirculating flow, and whether platelets binding to collagen in such a region could capture leucocytes. Blood flowing over the step established a stable vortex, a reattachment point where forward and backward flow separated, and a simple laminar flow with wall shear rate c. 400/s further downstream. Fluorescently labelled leucocytes were observed to attach to P-selectin immediately upstream or downstream of the reattachment point, and to roll back towards the step or away from it, respectively. There was negligible adhesion further downstream. When a P-selectin-Fc chimaera was used to coat the chamber, stable attachment occurred, again preferentially in the disturbed flow region. Numerous platelets adhered to a collagen coating throughout the chamber, although there were local maxima either side of the reattachment point. The adherent platelets captured flowing leucocytes in these regions alone. Leucocytes may adhere from flowing blood in vessels with high shear rate if the flow is disturbed. While platelets can adhere over a wider range of shear rates, their ability to capture leucocytes may be restricted to regions of disturbed flow.