The presence of dry biofilms harbouring bacterial pathogens is virtually universal on commonly used items in healthcare settings. The role of dry biofilms in spreading HCAIs may be underestimated. The risk may be further exacerbated by inefficient cleaning and disinfection practices for hospital surfaces.
Aim: The extensive use of microbicides in a wide range of applications has been questioned with regard to their role in the development of bacterial resistance to antimicrobials. This study aims to measure the phenotypic and genotypic changes in Burkholderia lata strain 383 exposed to chlorhexidine gluconate (CHG) and benzalkonium chloride (BZC), two commonly used cationic microbicides. Methods and Results: The susceptibility of B. lata strain 383 to CHG and BZC and a range of antibiotics was determined using standardized MIC, MBC and antibiotic susceptibility testing protocols before and after short-term exposure to a low microbicide concentration. Measurements were performed on four separate occasions over a 1-year period. Changes in gene expression were investigated using quantitative real-time PCR. Although the susceptibility profile to CHG and BZC was not altered, a change in antibiotic susceptibility profile was observed for ceftazidime, and for imipenem and ciprofloxacin in 2/4 repeats. An outer membrane protein and ABC transporter were found to be significantly upregulated following treatment with BZC and CHG, respectively. Conclusions: The comparison of MIC and MBC results following microbicide exposure with baseline data offered a prospective protocol to quantify any change in bacterial susceptibility profile. However, the use of a standardized antibiotic susceptibility protocol with B. lata strain 383 showed some inconsistencies in results between repeats. Significance and Impact of the Study: With ever-increasing interest in the impact of microbicides on emerging antimicrobial resistance in bacteria growing, this study demonstrated that comparing susceptibility profile obtained after exposure to microbicides with baseline susceptibility values could play a role in establishing the potential risk of microbicide resistance and cross-resistance development and also in the development of a protocol that allows the prediction of microbicide resistance.
Background Bariatric surgery, used to achieve effective weight loss in individuals with severe obesity, modifies the gut microbiota and systemic metabolism in both humans and animal models. The aim of the current study was to understand better the metabolic functions of the altered gut microbiome by conducting deep phenotyping of bariatric surgery patients and bacterial culturing to investigate causality of the metabolic observations. Methods Three bariatric cohorts (n = 84, n = 14 and n = 9) with patients who had undergone Roux-en-Y gastric bypass (RYGB), sleeve gastrectomy (SG) or laparoscopic gastric banding (LGB), respectively, were enrolled. Metabolic and 16S rRNA bacterial profiles were compared between pre- and post-surgery. Faeces from RYGB patients and bacterial isolates were cultured to experimentally associate the observed metabolic changes in biofluids with the altered gut microbiome. Results Compared to SG and LGB, RYGB induced the greatest weight loss and most profound metabolic and bacterial changes. RYGB patients showed increased aromatic amino acids-based host-bacterial co-metabolism, resulting in increased urinary excretion of 4-hydroxyphenylacetate, phenylacetylglutamine, 4-cresyl sulphate and indoxyl sulphate, and increased faecal excretion of tyramine and phenylacetate. Bacterial degradation of choline was increased as evidenced by altered urinary trimethylamine-N-oxide and dimethylamine excretion and faecal concentrations of dimethylamine. RYGB patients’ bacteria had a greater capacity to produce tyramine from tyrosine, phenylalanine to phenylacetate and tryptophan to indole and tryptamine, compared to the microbiota from non-surgery, normal weight individuals. 3-Hydroxydicarboxylic acid metabolism and urinary excretion of primary bile acids, serum BCAAs and dimethyl sulfone were also perturbed following bariatric surgery. Conclusion Altered bacterial composition and metabolism contribute to metabolic observations in biofluids of patients following RYGB surgery. The impact of these changes on the functional clinical outcomes requires further investigation.
Burkholderia cepacia complex (Bcc) bacteria are intrinsically antimicrobial resistant opportunistic pathogens and key risk species in the contamination of non-food industrial products. New agents and formulations to prevent growth of Burkholderia in home care (cleaning agents) and personal care (cosmetics and toiletries) products are required. We characterised how ethylzingerone [4-(3-ethoxy-4-hydroxyphenyl) butan-2-one)] (HEPB) acts as a preservative with activity against Burkholderia species encountered in industry. Burkholderia (n = 58) and non-Burkholderia (n = 7) bacteria were screened for susceptibility to HEPB, and its mode of action/resistance determined for a model B. vietnamiensis strain using transposon mutagenesis, transcriptomics and genome resequencing analysis. The susceptibility of Burkholderia spp. to HEPB (MIC = 0.45 ±0.11 % w/v; MBC = 0.90 ±0.3 % w/v) was characterised, with limited inter-/intra-species differences. HEPB (1% w/v) was rapidly bactericidal producing a 6-Log reduction in viability within 4 hours. Spontaneous resistance to HEPB did not develop, but transient phenotypes with altered growth characteristics and susceptibility to antibiotics were identified after prolonged exposure to sub-lethal HEPB concentrations. Transposon mutagenesis and RNA-sequencing analysis identified multiple genetic pathways associated with HEPB exposure, including stress response mechanisms, altered permeability, regulation of intracellular pH, damage/repair of intracellular components and alteration/repair of lipopolysaccharides. Key pathways included the stringent response, homeostasis of intracellular pH by the kdp operon, protection against electrophiles by KefC, and repair of oxidised proteins by methionine sulfoxide reductase enzymes. In summary, we show that HEPB has potent, targeted efficacy against Burkholderia bacteria without promoting wider stable antimicrobial resistance. The mode of action of HEPB against Burkholderia is multifactorial but killing by intracellular oxidation is a key mechanism of this promising agent. Importance. Burkholderia bacteria are opportunistic pathogens that can overcome preservatives used in the manufacture of non-sterile industrial products, and occasionally cause contamination. Consequently, new preservatives to prevent the growth of key risk Burkholderia cepacia complex bacteria in non-food industrial products are urgently required. Here we show that ethylzingerone is active against these problematic bacteria, killing them via a multifactorial mode of action which involves intracellular oxidation.
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