Analysis of the role of the QseBC two-component sensory system in epinephrine-induced motility and intracellular replication of Burkholderia pseudomallei

Burkholderia pseudomallei is a facultative intracellular bacterial pathogen that causes melioidosis, a severe invasive disease of humans. We previously reported that the stress-related catecholamine hormone epinephrine enhances motility of B. pseudomallei, transcription of flagellar genes and the production of flagellin. It has been reported that the QseBC two-component sensory system regulates motility and virulence-associated genes in other Gram-negative bacteria in response to stress-related catecholamines, albeit disparities between studies exist. We constructed and whole-genome sequenced a mutant of B. pseudomallei with a deletion spanning the predicted qseBC homologues (bpsl0806 and bpsl0807). The ΔqseBC mutant exhibited significantly reduced swimming and swarming motility and reduced transcription of fliC. It also exhibited a defect in biofilm formation and net intracellular survival in J774A.1 murine macrophage-like cells. While epinephrine enhanced bacterial motility and fliC transcription, no further reduction in these phenotypes was observed with the ΔqseBC mutant in the presence of epinephrine. Plasmid-mediated expression of qseBC suppressed bacterial growth, complicating attempts to trans-complement mutant phenotypes. Our data support a role for QseBC in motility, biofilm formation and net intracellular survival of B. pseudomallei, but indicate that it is not essential for epinephrine-induced motility per se

Neutrophils form extracellular traps in response to Opisthorchis viverrini crude antigens and these traps are elevated in neutrophils from opisthorchiasis patients with hepatobiliary abnormalities.

Opisthorchis viverrini (Ov) infection can cause several disease conditions of the bile duct including hepatobiliary abnormalities (HBAs) and the most severe, cholangiocarcinoma (CCA). Fibrosis occurs when tissues are damaged and normal wound-healing responses are dysregulated. Neutrophils are the first cells to migrate to an infection site to protect the host from intruding extracellular pathogens through a wide range of effector mechanisms such as phagocytosis, production of reactive oxygen species, proteases, or release of neutrophil extracellular traps (NETs). In this work, we used confocal microscopy to assess whether Ov crude antigens can cause release of NETs from neutrophils from Ov-free individuals. We demonstrated for the first time that these antigens could induce release of NETs ex-vivo in a dose-dependent manner from neutrophils isolated from Ov-free individuals. Intriguingly, when we measured NETs from neutrophils isolated from Ov-infected patients, we found increased spontaneous production of NETs in patients with HBAs. Interestingly, exposure to Ov crude antigens lowered the level of NETs released by neutrophils from patients with active Ov infection regardless of HBA status. We propose that in the case of acute Ov infection, even when concentration of Ov antigens is relatively low, neutrophils can form NETs. However, when this infection becomes chronic, manifesting as a definite HBA, the levels of NET production are reduced when treated with Ov crude antigens. Excessive production of proinflammatory mediators from these NETs might have effects on the parasites, but may also lead to excessive injury of surrounding tissues resulting in HBAs and may lead eventually to the most severe complications such as CCA

Environmental Free-Living Amoebae Isolated from Soil in Khon Kaen, Thailand, Antagonize Burkholderia pseudomallei.

Presence of Burkholderia pseudomallei in soil and water is correlated with endemicity of melioidosis in Southeast Asia and northern Australia. Several biological and physico-chemical factors have been shown to influence persistence of B. pseudomallei in the environment of endemic areas. This study was the first to evaluate the interaction of B. pseudomallei with soil amoebae isolated from B. pseudomallei-positive soil site in Khon Kaen, Thailand. Four species of amoebae, Paravahlkampfia ustiana, Acanthamoeba sp., Naegleria pagei, and isolate A-ST39-E1, were isolated, cultured and identified based on morphology, movement and 18S rRNA gene sequence. Co-cultivation combined with a kanamycin-protection assay of B. pseudomallei with these amoebae at MOI 20 at 30°C were evaluated during 0-6 h using the plate count technique on Ashdown's agar. The fate of intracellular B. pseudomallei in these amoebae was also monitored by confocal laser scanning microscopy (CLSM) observation of the CellTracker™ Orange-B. pseudomallei stained cells. The results demonstrated the ability of P. ustiana, Acanthamoeba sp. and isolate A-ST39-E1 to graze B. pseudomallei. However, the number of internalized B. pseudomallei substantially decreased and the bacterial cells disappeared during the observation period, suggesting they had been digested. We found that B. pseudomallei promoted the growth of Acanthamoeba sp. and isolate A-ST39-E1 in co-cultures at MOI 100 at 30°C, 24 h. These findings indicated that P. ustiana, Acanthamoeba sp. and isolate A-ST39-E1 may prey upon B. pseudomallei rather than representing potential environmental reservoirs in which the bacteria can persist

Intracellular survival through time of <i>B</i>. <i>pseudomallei</i> in <i>P</i>. <i>ustiana</i> (A), <i>Acanthamoeba</i> sp. (B) and isolate A-ST39-E1 (C).

<p>Time zero represents 3 hours after <i>B</i>. <i>pseudomallei</i> feeding. Bars represent the standard errors of the means of duplicate, three times independent experiments, * <i>p</i> < 0. 0001 using ANOVA.</p

Numbers of <i>Acanthamoeba</i> sp. and isolate A-ST39-E1 over time (A-B and C-D respectively) after feeding with <i>B</i>. <i>pseudomallei</i> (▲) or <i>E</i>. <i>coli</i> (positive control) (■) or deprived of bacteria as a negative control (●).

<p>Graphs and figures show no significant differences between amoebae fed on <i>B</i>. <i>pseudomallei</i> and <i>E</i>. <i>coli</i>. However, numbers of amoebae in the negative control group were significantly lower than in the pother groups (<i>p</i> ≤ 0.0001). Data are mean ± SD from duplicates of the three independent experiments.</p

Specific primers for the 18s rRNA gene of amoebae.

<p>Specific primers for the 18s rRNA gene of amoebae.</p

Dead and live cells in 2-day old biofilm of <i>B</i>. <i>pseudomallei</i> K96243 and <i>B</i>. <i>thailandensis</i> E264 after treated with 16×MIC of each antibiotic in MVBM and 0.1×MVBM for 16 h.

<p>(A) Live/Dead ratios of <i>B</i>. <i>pseudomallei</i> K96243 and <i>B</i>. <i>thailandensis</i> E264. Data are the mean value of live/dead ratios from 6 random areas. *<i>p</i> < 0.01 compared to control in the same medium, ^#<i>p</i> < 0.01 compared to the same antibiotic in MVBM. The 3D reconstruction of <i>B</i>. <i>pseudomallei</i> K96243 (B) and <i>B</i>. <i>thailandensis</i> E264 (C) biofilm stained with LIVE/DEAD BacLight Bacterial Viability kit; SYTO 9 showing live cells in green and propidium iodide showing dead cells in red (10× objective).</p