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A new therapeutic strategy for infectious diseases against intracellular multidrug-resistant bacteria

Zhao-Jie Wang, Yan-Yan Zhu, Li-Yu Bai, Dongmei Tang, Zhong-Shun Zhou, Mei-Zhen Wei, Jinbiao He, Yu-Duan, Xiao‐Dong Luo

2024Journal of Controlled Release38 citationsDOIOpen Access PDF

Abstract

Bacterial infections result in 7,700,000 deaths per year globally, with intracellular bacteria causing repeated and resistant infection. No drug is currently licenced for the treatment of intracellular bacteria. A new screening platform mimicking the host milieu has been established to explore phytochemical antibiotic adjuvants. Previously neglected isoprenylated flavonoids were found to be effective against methicillin-resistant Staphylococcus aureus (MRSA) and vancomycin-resistant enterococci (VRE). Specifically, the synergistic effect between glabrol and streptomycin against intracellular bacteria was observed for the first time. The glabrol-streptomycin combination targets bacterial inner membrane phospholipids, disrupts arginine biosynthesis, inhibits cell wall proteins and biofilm formation genes ( agrA/B/C/D ), and promotes ROS production, causing subsequent membrane and wall damage. To enhance the selective uptake of combination drug into infected cells, hyaluronic acid-streptomycin-lipoic acid-glabrol nanoparticles (HSLGS-S) were designed and synthesized to trigger the intracellular delivery of the glabrol-streptomycin combination. Thus, the treatment can be transported into the infected intracellular region and selectively release the glabrol-streptomycin combination to the bacterial at site. The bioactivity of HSLGS-S in clearing intracellular bacteria was 20-fold higher than that of the glabrol-streptomycin combination alone in vitro and 2- to 10-fold higher in vivo. • A new screening platform to explore antibiotic adjuvants with the previously neglected phytochemicals. • Glabrol-streptomycin destroyed bacterial inner membrane, arginine biosynthesis, the cell wall proteins and biofilm formation. • HSLGS-S against intracellular MDR bacteria in vivo and in vitro.

Topics & Concepts

StreptomycinIntracellularMicrobiologyIntracellular parasiteBacteriaBiologyAntibioticsBiofilmChemistryBiochemistryGeneticsAntimicrobial Peptides and ActivitiesPneumocystis jirovecii pneumonia detection and treatmentAntimicrobial agents and applications
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