Mycobacterium tuberculosis ( M.tb) has the extraordinary ability to adapt to the administration of antibiotics through the development of resistance mechanisms. By rapidly exporting drugs from within the cytosol, these pathogenic bacteria diminish antibiotic potency and drive the presentation of drug-tolerant tuberculosis (TB). The membrane integrity of M.tb is pivotal in retaining these drug-resistant traits. Silver (Ag) and zinc oxide (ZnO) nanoparticles (NPs) are established antimicrobial agents that effectively compromise membrane stability, giving rise to increased bacterial permeability to antibiotics. In this work, biodegradable multimetallic microparticles (MMPs), containing Ag NPs and ZnO NPs, were developed for use in pulmonary delivery of antituberculous drugs to the endosomal system of M.tb-infected macrophages. Efficient uptake of MMPs by M.tb-infected THP1 cells was demonstrated using an in vitro macrophage infection model, with direct interaction between MMPs and M.tb visualized with the use of electron FIB-SEM tomography. The release of Ag NPs and ZnO NPs within the macrophage endosomal system increased the potency of the model antibiotic rifampicin by as much as 76%, realized through an increase in membrane disorder of intracellular M.tb. MMPs were effective at independently driving membrane destruction of extracellular bacilli located at the exterior face of THP1 macrophages. This MMP system presents as an effective drug delivery vehicle that could be used for the transport of antituberculous drugs such as rifampicin to infected alveolar macrophages, while increasing drug potency. By increasing M.tb membrane permeability, such a system may prove effectual in improving treatment of drug-susceptible TB in addition to M.tb strains considered drug-resistant.
Bacteria play a key role in controlling the mobility of contaminants, such as uranium (U), in the environment. Uranium could be sourced from disposed radioactive waste, derived either from surface disposal trenches for Low Level Waste (LLW) that, because of the waste type and disposal concept, would typically present acidic conditions (both aerobic and anaerobic), or from the geological disposal of LLW or Intermediate Level Waste (ILW) that, because of the waste type and the disposal concept, would typically present alkaline conditions (anaerobic only). In disposed radioactive waste, there could be variable amounts of cellulosic material. Bacterial cells may be living in a range of different growth phases, depending on the growth conditions and nutrients available at the time any waste-derived U migrated to the cells. A key knowledge gap to date has been the lack of a mechanistic understanding of how bacterial growth phases (exponential, stationary, and death phase) affect the ability of bacteria to remove U(VI) from solution. To address this, we first characterised the cells using potentiometric titrations to detect any differences in proton binding to proton active sites on Pseudomonas putida cells at each growth phase under aerobic conditions, or under anaerobic conditions favourable to U(IV) reoxidation. We then conducted batch U(VI) removal experiments with bacteria at each phase suspended in 1 and 10 ppm U aqueous solutions with the pH adjusted from 2-12 as well as with culture concentrations from 0.01-10 g/L, to *Manuscript Click here to download Manuscript: KenneyBacteriaPaper16082017.docx Click here to view linked References
To assess biological risks of nanoparticle (NP) exposures, we examined the effects of silver (Ag) core Ag20-citrate (Ag20) and carbon black (CB) on human host innate immune responses to M.tb, a respiratory pathogen that causes tuberculosis. Human peripheral blood monocyte-derived macrophages (MDMs) were exposed to 1, 10, 25 and 50 μg/mL of Ag20 and CB for 4 and 24 h. At 4 h no significant cytotoxicity was observed with neither of the NPs at none of the concentrations examined relative to unexposed MDMs. At 24 h, viability of the MDMs was reduced by 60–70% and 20% following Ag20 and CB exposure, respectively, at doses ≥25 μg/mL. M.tb-induced host immune responses are mediated by the activation of TLR signalling pathways that culminate in NF-κB activation. Effects of Ag20 and CB (10μg/mL for 4 h, a nontoxic dose) on TLR signalling in M.tb-infected and uninfected MDMs were compared using a human TLR signaling pathway-specific profiler array. Ag20 exposure suppressed the M.tb-induced expression of a subset of NF-κB-mediated target genes (CSF2, CSF3, IFNG, IL1A, IL1B, IL6, IL10, TNFA, NFKB1A). Ag20-mediated suppression of M.tb-induced activation of the TLR-signalling pathway was not due to decreased uptake of M.tb by MDMs or mycobacteriocidal effects of Ag20. Ag20 exposure increased the expression of HSPA1A mRNA that encodes for the stress-induced Hsp72. In contrast, exposure to CB resulted in little effects on M.tb-induced host gene expression indicating that immunosuppressive effects of Ag20 are NP-specific. Since Hsp72 has been shown to suppress NF-κB activation, we propose that Ag20-mediated Hsp72 upregulation contributes to the suppression of M.tb-induced NF-κB activation and host immune responses. Funding NIEHS 5U19 ES019536
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