Non-thermal (low-temperature) physical plasma is under intensive study as an alternative approach to control superficial wound and skin infections when the effectiveness of chemical agents is weak due to natural pathogen or biofilm resistance. The purpose of this study was to test the individual susceptibility of pathogenic bacteria to non-thermal argon plasma and to measure the effectiveness of plasma treatments against bacteria in biofilms and on wound surfaces. Overall, Gram-negative bacteria were more susceptible to plasma treatment than Gram-positive bacteria. For the Gramnegative bacteria Pseudomonas aeruginosa, Burkholderia cenocepacia and Escherichia coli, there were no survivors among the initial 10 5 c.f.u. after a 5 min plasma treatment. The susceptibility of Gram-positive bacteria was species-and strain-specific. Streptococcus pyogenes was the most resistant with 17 % survival of the initial 10 5 c.f.u. after a 5 min plasma treatment. Staphylococcus aureus had a strain-dependent resistance with 0 and 10 % survival from 10 5 c.f.u. of the Sa 78 and ATCC 6538 strains, respectively. Staphylococcus epidermidis and Enterococcus faecium had medium resistance. Non-ionized argon gas was not bactericidal. Biofilms partly protected bacteria, with the efficiency of protection dependent on biofilm thickness. Bacteria in deeper biofilm layers survived better after the plasma treatment. A rat model of a superficial slash wound infected with P. aeruginosa and the plasma-sensitive Staphylococcus aureus strain Sa 78 was used to assess the efficiency of argon plasma treatment. A 10 min treatment significantly reduced bacterial loads on the wound surface. A 5-day course of daily plasma treatments eliminated P. aeruginosa from the plasma-treated animals 2 days earlier than from the control ones. A statistically significant increase in the rate of wound closure was observed in plasma-treated animals after the third day of the course. Wound healing in plasma-treated animals slowed down after the course had been completed. Overall, the results show considerable potential for non-thermal argon plasma in eliminating pathogenic bacteria from biofilms and wound surfaces.Abbreviation: CI, confidence interval.
SummaryPrfA, a transcription factor structurally related to Crp/ Fnr, activates Listeria monocytogenes virulence genes during intracellular infection. We report two new PrfA* mutations causing the constitutive overexpression of the PrfA regulon. Leu-140Phe lies in a a a a D adjacent to the DNA-binding motif in the C-terminal domain, like a previously characterized PrfA* mutation (Gly-145Ser). Ile-45Ser, in contrast, maps to the N-terminal b b b b -roll, a structure similar to that of the Crp cAMP binding site. The in vitro transcriptional properties of recombinant PrfA* I45S and PrfA* G145S were compared to those of PrfA WT at two differentially regulated PrfA-dependent promoters, P plcA and P actA . The two PrfA* mutations increased the affinity for the target DNA to a different extent, and the differences in DNA binding (PrfA* G145S > PrfA* I45S >>> PrfA WT ) correlated with proportional differences in transcriptional activity. The use of the PrfA* proteins revealed that P plcA had a greater affinity for, and was more sensitive to, PrfA than P actA . RNA polymerase (RNAP) initiated transcription independently of PrfA at P plcA , but not at P actA , consistent with bandshift experiments suggesting that P plcA has a greater affinity for RNAP than P actA . Thus, differences in affinity for both PrfA and RNAP appear to determine the different expression pattern of PrfA-regulated promoters. Modelling of the PrfA* mutations in the crystal structure of PrfA and comparison with structure-function analyses of Crp, in which similar mutations lead to constitutively active (cAMPindependent) Crp* proteins, suggested that PrfA shares with Crp an analogous mechanism of cofactormediated allosteric shift. Our data support a regulatory model in which changes in PrfA-dependent gene expression are primarily accounted for by changes in PrfA activity.
SummaryVirulence genes from the facultative intracellular pathogen Listeria mono cytogenes are controlled by the transcriptional regulator PrfA. Although PrfA synthesis is activated at 37 ∞ ∞ ∞ ∞ C, PrfA-dependent expression remains low in rich medium. However, a strong induction of the PrfA regulon is observed when L. monocytogenes is cultured in the presence of activated charcoal. Here, we show that the 'charcoal effect' results from the adsorption of a diffusible autorepressor substance released by L. monocytogenes during exponential growth. Analyses using an L. monocytogenes strain in which the prfA gene is expressed constitutively at 37 ∞ ∞ ∞ ∞ C from a plasmid indicate that the autoregulatory substance represses PrfA-dependent expression by inhibiting PrfA activity. PrfA presumably functions via an allosteric activation mechanism. The inhibitory effect is bypassed by a PrfA* mutation that locks PrfA in fully active conformation, suggesting that the autorepressor interferes with the allosteric shift of PrfA. Our data indicate that the listerial autorepressor is a low-molecular-weight hydrophobic substance. We suggest that this diffusible substance mediates a quorum-sensing mechanism by which L. monocytogenes restricts the expression of its PrfA virulence regulon. This autoregulatory pathway could serve L. monocytogenes to ensure the silencing of virulence genes during extracellular growth at 37 ∞ ∞ ∞ ∞ C. It may also play a role during intracellular infection, by limiting the damage to the host cell caused by an excess production of cytotoxic PrfA-dependent virulence factors in the PrfA-activating cytosolic compartment.
BackgroundThe gram-positive pathogenic bacterium Listeria monocytogenes is widely spread in the nature. L. monocytogenes was reported to be isolated from soil, water, sewage and sludge. Listeriolysin O (LLO) is a L. monocytogenes major virulence factor. In the course of infection in mammals, LLO is required for intracellular survival and apoptosis induction in lymphocytes. In this study, we explored the potential of LLO to promote interactions between L. monocytogenes and the ubiquitous inhabitant of natural ecosystems bacteriovorous free-living ciliate Tetrahymena pyriformis.ResultsWild type L. monocytogenes reduced T. pyriformis trophozoite counts and stimulated encystment. The effects were observed starting from 48 h of co-incubation. On the day 14, trophozoites were eliminated from the co-culture while about 5 × 104 cells/ml remained in the axenic T. pyriformis culture. The deficient in the LLO-encoding hly gene L. monocytogenes strain failed to cause mortality among protozoa and to trigger protozoan encystment. Replenishment of the hly gene in the mutant strain restored toxicity towards protozoa and induction of protozoan encystment. The saprophytic non-haemolytic species L. innocua transformed with the LLO-expressing plasmid caused extensive mortality and encystment in ciliates. During the first week of co-incubation, LLO-producing L. monocytogenes demonstrated higher growth rates in association with T. pyriformis than the LLO-deficient isogenic strain. At latter stages of co-incubation bacterial counts were similar for both strains. T. pyriformis cysts infected with wild type L. monocytogenes caused listerial infection in guinea pigs upon ocular and oral inoculation. The infection was proved by bacterial plating from the internal organs.ConclusionsThe L. monocytogenes virulence factor LLO promotes bacterial survival and growth in the presence of bacteriovorous ciliate T. pyriformis. LLO is responsible for L. monocytogenes toxicity for protozoa and induction of protozoan encystment. L. monocytogenes entrapped in cysts remained viable and virulent. In whole, LLO activity seems to support bacterial survival in the natural habitat outside of a host.
Listeria monocytogenes is a causative agent of foodborne infection in humans and animals. The virulence factor InlB interacts with mammalian receptor c-Met via its internalin domain to provide L. monocytogenes invasion in non-professional phagocytes. Naturally occurring InlB internalin domain variants form four subclusters on the maximal likelihood tree. Four variants belonging to distinct subclusters were cloned into the vector carrying 3΄ and 5΄-flanking sequences to restore full length inlB and expressed in the L. monocytogenes strain EGDeΔinlB. The substitutions Val132Ile, Thr117Ala and Ile138Leu, Thr251Met/Ser were specific for variants 13, 14 and 1, respectively, the variant 9 carried Ser73Asn, Ile91Val, Leu164Pro, Met251Ser/Thr substitutions. All InlB variants improved invasion of the parental strain in murine colon carcinoma C26 cells with 4.6-fold difference between the most and least effective variants (variants 14 and 13, respectively, P < 0.05). Bacterial loads in livers of intragastrically infected mice were 258, 149 and 92 times higher for variant 14, 13 and 1 carrying strains, respectively, than for EGDeΔinlB (P < 0.01). In contrast, the variant 9 did not noticeably improve infection comparatively to the parental strain. Overall, obtained results demonstrated that naturally occurred InlB internalin domain variants differed in their ability to support intragastric infection in mice.
Inactivation of microorganisms by plasma of a positive (PC) and negative corona (NC) discharge in air at atmospheric pressure was investigated. Gram-positive bacteria Staphylococcus aureus and Gram-negative bacteria Pseudomonas aeruginosa were chosen for the discharge inactivation. PC and NC produce three types of bactericidal agents, which are ultraviolet radiation (UV), neutral reactive species (R), and electric field and charged particles (E), respectively. We elucidated the contribution of each bioactive agent to the inactivation of S. aureus and P. aeruginosa. The influence of the charged particles in PC and NC on the cell inactivation is caused by different electrophysical effects, which lead nevertheless to an identical consequence: the cell membrane becomes more transparent for neutral reactive species. It gives additional possibility for neutral reactive species to increase the inactivation of cell by biochemical mechanisms. Due to that, total UV þ R þ E bactericidal effect in PC and NC is approximately the same and great -only a few tens of seconds is enough to inactivate completely S. aureus and P. aeruginosa cells.
Biofilms are three-dimensional structures formed by surface-attached microorganisms and their extracellular products. Biofilms formed by pathogenic microorganisms play an important role in human diseases. Higher resistance to antimicrobial agents and changes in microbial physiology make treating biofilm infections very complex. Atmospheric pressure nonthermal plasmas (NTPs) are a novel and powerful tool for antimicrobial treatment. The microbicidal activity of NTPs has an unspecific character due to the synergetic actions of bioactive components of the plasma torch, including charged particles, reactive species, and UV radiation. This review focuses on specific traits of biofilms, their role in human diseases, and those effects of NTP that are helpful for treating biofilm infections. The authors discuss NTP-based strategies for biofilm control, such as surface modifications to prevent bacterial adhesion, killing bacteria in biofilms, and biofilm destruction with NTPs. The unspecific character of microbicidal activity, proven polymer modification and destruction abilities, low toxicity for human tissues and absence of long-living toxic compounds make NTPs a very promising tool for biofilm prevention and control.
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