Browsing by Author "Bergen, PJ"
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- ItemArginine catabolism is essential to polymyxin dependence in Acinetobacter baumannii(Elsevier, 2024-07) Han, ML; Alsaadi, Y; Zhao, JX; Zhu, Y; Lu, J; Jiang, X; Ma, W; Patil, NA; Dunstan, RA; Le Brun, AP; Wickremasinghe, H; Hu, X; Wu, Y; Yu, HH; Wang, J; Barlow, CK; Bergen, PJ; Shen, HH; Lithgow, T; Creek, DJ; Velkov, T; Li, JPolymyxins are often the only effective antibiotics against the "Critical" pathogen Acinetobacter baumannii. Worryingly, highly polymyxin-resistant A. baumannii displaying dependence on polymyxins has emerged in the clinic, leading to diagnosis and treatment failures. Here, we report that arginine metabolism is essential for polymyxin-dependent A. baumannii. Specifically, the arginine degradation pathway was significantly altered in polymyxin-dependent strains compared to wild-type strains, with critical metabolites (e.g., L-arginine and L-glutamate) severely depleted and expression of the astABCDE operon significantly increased. Supplementation of arginine increased bacterial metabolic activity and suppressed polymyxin dependence. Deletion of astA, the first gene in the arginine degradation pathway, decreased phosphatidylglycerol and increased phosphatidylethanolamine levels in the outer membrane, thereby reducing the interaction with polymyxins. This study elucidates the molecular mechanism by which arginine metabolism impacts polymyxin dependence in A. baumannii, underscoring its critical role in improving diagnosis and treatment of life-threatening infections caused by "undetectable" polymyxin-dependent A. baumannii. ª 2024 The Author(s). Published by Elsevier Inc. This is an open access article under the CC BY-NC licence
- ItemPolysaccharide‐targeting lipid nanoparticles to kill gram‐negative bacteria(Wiley, 2023-10-05) Lai, XF; Chow, SH; Le Brun, AP; Muir, BW; Bergen, PJ; White, JF; Yu, HH; Wang, JP; Danne, J; Jiang, JH; Short, FL; Han, ML; Strugnell, RA; Song, JN; Cameron, NR; Peleg, AY; Li, J; Shen, HHThe rapid increase and spread of Gram‐negative bacteria resistant to many or all existing treatments threaten a return to the preantibiotic era. The presence of bacterial polysaccharides that impede the penetration of many antimicrobials and protect them from the innate immune system contributes to resistance and pathogenicity. No currently approved antibiotics target the polysaccharide regions of microbes. Here, describe monolaurin‐based niosomes, the first lipid nanoparticles that can eliminate bacterial polysaccharides from hypervirulent Klebsiella pneumoniae, are described. Their combination with polymyxin B shows no cytotoxicity in vitro and is highly effective in combating K. pneumoniae infection in vivo. Comprehensive mechanistic studies have revealed that antimicrobial activity proceeds via a multimodal mechanism. Initially, lipid nanoparticles disrupt polysaccharides, then outer and inner membranes are destabilized and destroyed by polymyxin B, resulting in synergistic cell lysis. This novel lipidic nanoparticle system shows tremendous promise as a highly effective antimicrobial treatment targeting multidrug‐resistant Gram‐negative pathogens. © 2023 The Authors. Published by Wiley-VCH GmbH2305052
- ItemA polytherapy based approach to combat antimicrobial resistance using cubosomes(Springer Nature, 2022-01-17) Lai, XF; Han, ML; Ding, Y; Chow, SH; Le Brun, AP; Wu, CM; Bergen, PJ; Jiang, JH; Hsu, HY; Muir, BW; White, J; Song, JN; Shen, HHA depleted antimicrobial drug pipeline combined with an increasing prevalence of Gram-negative ‘superbugs’ has increased interest in nano therapies to treat antibiotic resistance. As cubosomes and polymyxins disrupt the outer membrane of Gram-negative bacteria via different mechanisms, we herein examine the antimicrobial activity of polymyxin-loaded cubosomes and explore an alternative strategy via the polytherapy treatment of pathogens with cubosomes in combination with polymyxin. The polytherapy treatment substantially increases antimicrobial activity compared to polymyxin B-loaded cubosomes or polymyxin and cubosomes alone. Confocal microscopy and neutron reflectometry suggest the superior polytherapy activity is achieved via a two-step process. Firstly, electrostatic interactions between polymyxin and lipid A initially destabilize the outer membrane. Subsequently, an influx of cubosomes results in further membrane disruption via a lipid exchange process. These findings demonstrate that nanoparticle-based polytherapy treatments may potentially serve as improved alternatives to the conventional use of drug-loaded lipid nanoparticles for the treatment of “superbugs”. Open Access: This article is licensed under a Creative Commons Attribution 4.0 International Licence.
- ItemA polytherapy based approach to combat antimicrobial resistance using cubosomes(Springer Nature, 2022-01-17) Lai, XF; Han, ML; Ding, Y; Chow, SH; Le Brun, AP; Wu, CM; Bergen, PJ; Jiang, JH; Hsu, HY; Muir, BW; White, J; Song, JN; Li, J; Shen, HHA depleted antimicrobial drug pipeline combined with an increasing prevalence of Gram-negative ‘superbugs’ has increased interest in nano therapies to treat antibiotic resistance. As cubosomes and polymyxins disrupt the outer membrane of Gram-negative bacteria via different mechanisms, we herein examine the antimicrobial activity of polymyxin-loaded cubosomes and explore an alternative strategy via the polytherapy treatment of pathogens with cubosomes in combination with polymyxin. The polytherapy treatment substantially increases antimicrobial activity compared to polymyxin B-loaded cubosomes or polymyxin and cubosomes alone. Confocal microscopy and neutron reflectometry suggest the superior polytherapy activity is achieved via a two-step process. Firstly, electrostatic interactions between polymyxin and lipid A initially destabilize the outer membrane. Subsequently, an influx of cubosomes results in further membrane disruption via a lipid exchange process. These findings demonstrate that nanoparticle-based polytherapy treatments may potentially serve as improved alternatives to the conventional use of drug-loaded lipid nanoparticles for the treatment of “superbugs”. © The Authors - Open Access CC-BY 4.0