Litcius/Paper detail

Uptake Dynamics of Cubosome Nanocarriers at Bacterial Surfaces and the Routes for Cargo Internalization

Brendan Dyett, Haitao Yu, Sampa Sarkar, Jamie Strachan, Calum J. Drummond, Charlotte E. Conn

2021ACS Applied Materials & Interfaces54 citationsDOI

Abstract

Antibiotic-resistant bacteria pose a significant threat to humanity. Gram-negative strains have demonstrated resistance to last resort antibiotics, partially due to their outer membrane, which hinders transport of antimicrobials into the bacterium. Nanocarrier (NC)-mediated drug delivery is one proposed strategy for combating this emerging issue. Here, the uptake of self-assembled lipid nanocarriers of cubic symmetry (cubosomes) into bacteria revealed fundamental differences in the uptake mechanism between Gram-positive and Gram-negative bacteria. For Gram-positive bacteria, the NCs adhere to the outer peptidoglycan layers and slowly internalize to the bacterium. For Gram-negative bacteria, the NCs interact in two stages, fusion with the outer lipid membrane and then diffusion through the inner wall. The self-assembled nature of the cubosomes imparts a unique ability to transfer payloads via membrane fusion. Remarkably, the fusion uptake mechanism allowed rapid NC internalization by the Gram-negative bacteria, overcoming the outer membrane responsible for their heightened resilience. Here this is demonstrated by the marked reduction in the minimal inhibition concentration required for antibiotics against a pathogenic strain of Gram-negative bacteria, Escherichia coli. These results provide mechanistic insight for the development of lipid NCs as a new tool to combat bacteria.

Topics & Concepts

Bacterial outer membraneBacteriaNanocarriersGram-negative bacteriaInternalizationPeptidoglycanBiophysicsLipid IIEscherichia coliMicrobiologyDrug deliveryBiologyBiochemistryNanotechnologyMaterials scienceCellGeneGeneticsBacteriophages and microbial interactionsAntibiotic Resistance in BacteriaLipid Membrane Structure and Behavior