Gordon A. McFeters scite author profile

SummaryQuorum sensing (QS) governs the production of virulence factors and the architecture and sodium dodecyl sulphate (SDS) resistance of bio®lm-grown Pseudomonas aeruginosa. P. aeruginosa QS requires two transcriptional activator proteins known as LasR and RhlR and their cognate autoinducers PAI-1 (N-(3-oxododecanoyl)-L-homoserine lactone) and PAI-2 (Nbutyryl-L-homoserine lactone) respectively. This study provides evidence of QS control of genes essential for relieving oxidative stress. Mutants devoid of one or both autoinducers were more sensitive to hydrogen peroxide and phenazine methosulphate, and some PAI mutant strains also demonstrated decreased expression of two superoxide dismutases (SODs), Mn-SOD and Fe-SOD, and the major catalase, KatA. The expression of sodA (encoding Mn-SOD) was particularly dependent on PAI-1, whereas the in¯uence of autoinducers on Fe-SOD and KatA levels was also apparent but not to the degree observed with Mn-SOD. b-Galactosidase reporter fusion results were in agreement with these ®ndings. Also, the addition of both PAIs to suspensions of the PAI-1/2-de®cient double mutant partially restored KatA activity, while the addition of PAI-1 only was suf®cient for full restoration of Mn-SOD activity. In bio®lm studies, catalase activity in wild-type bacteria was signi®cantly reduced relative to planktonic bacteria; catalase activity in the PAI mutants was reduced even further and consistent with relative differences observed between each strain grown planktonically. While wild-type and mutant bio®lms contained less catalase activity, they were more resistant to hydrogen peroxide treatment than their respective planktonic counterparts. Also, while catalase was implicated as an important factor in bio®lm resistance to hydrogen peroxide insult, other unknown factors seemed potentially important, as PAI mutant bio®lm sensitivity appeared not to be incrementally correlated to catalase levels.

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Biofilm resistance to antimicrobial agents

McFeters

Stewart

2000

281

192

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Spatial Physiological Heterogeneity in Pseudomonas aeruginosa Biofilm Is Determined by Oxygen Availability

Xu¹,

Stewart

Xia³

et al. 1998

Appl Environ Microbiol

442

193

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The role of oxygen availability in determining the local physiological activity of Pseudomonas aeruginosa growing in biofilms was investigated. Biofilms grown in an ambient-air environment expressed approximately 1/15th the alkaline phosphatase specific activity of planktonic bacteria subjected to the same phosphate limitation treatment. Biofilms grown in a gaseous environment of pure oxygen exhibited 1.9 times the amount of alkaline phosphatase specific activity of air-grown biofilms, whereas biofilms grown in an environment in which the air was replaced with pure nitrogen prior to the inducing treatment did not develop alkaline phosphatase activity. Frozen cross sections of biofilms stained for alkaline phosphatase activity with a fluorogenic stain demonstrated that alkaline phosphatase activity was concentrated in distinct bands adjacent to the gaseous interfaces. These bands were approximately 30 μm thick with biofilms grown in air, 2 μm thick with biofilms grown in pure nitrogen, and 46 μm thick with biofilms grown in pure oxygen. Overall biofilm thickness ranged from approximately 117 to approximately 151 μm. Measurements with an oxygen microelectrode indicated that oxygen was depleted locally within the biofilm and that the oxygen-replete zone was of a dimension similar to that of the biologically active zone, as indicated by alkaline phosphatase induction. These experiments revealed marked spatial physiological heterogeneity within P. aeruginosa biofilms in which active protein synthesis was restricted by oxygen availability to the upper 30 μm of the biofilm. Such physiological heterogeneity has implications for microbial ecology and for understanding the reduced susceptibilities of biofilms to antimicrobial agents.

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Spatial Variations in Growth Rate within Klebsiella pneumoniae Colonies and Biofilm

et al. 1996

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The use of acridine orange to visualize and quantify spatial variations in growth rate within Klebsiella pneumoniae colonies and biofilm was investigated. Bacterial colonies supported on polycarbonate filter membranes were grown on R2A agar plates. Some colonies were sampled for cell enumeration, while others were cryoembedded, sectioned, and stained with the fluorescent nucleic acid stain acridine orange. Spatial patterns of fluorescent color and intensity with depth in the colony were quantified using confocal microscopy and image analysis of stained cross sections. Colonies sampled in the midexponential phase were thin (20 microns), had high average specific growth rates (> 1 h-1), and had all the cells stained bright orange. Colonies sampled after more than 24 h of growth were thick (> 200 microns) and were growing slowly (mu < 0.15 h-1). These older colonies were characterized by distinct bands of orange at the colony edges and a dark green center. Stained biofilm cross sections displayed a similar orange band at the biofilm-bulk fluid interface and a green interior. Colony-average specific growth rates, determined by calculating the local slope of the cell accumulation versus time data, were correlated with colony-average fluorescence intensities. There was no correlation between average specific growth rate and orange or green intensity individually, but growth rate did correlate with the orange:green intensity ratio (r2 = 0.57). The resulting regression was used to predict specific growth rate profiles within colonies. These profiles indicated that bacteria were growing rapidly near the air and agar interfaces and more slowly in the center of the colonies when thicker than about 30 microns. The dimension of the orange bands ranged from 10 to 30 microns, which may indicate the thickness of growing regions. The inherent variability associated with this technique suggests that it is best applied in single species systems and that the results should be regarded as qualitative in nature.

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