Abstract
The mycomembrane of mycobacteria, composed primarily of long-chain mycolic acids, is critical for cell survival, structural integrity, and resistance to environmental stress, yet its underlying synthesis mechanisms remain incompletely understood. This study investigates the role of Ag85A, a key enzyme in mycomembrane synthesis, in regulating plasma membrane domains and cell envelope organization in Mycobacterium smegmatis. Using ΔAg85A deletion mutants, we combined microscopy, biochemical assays, thin-layer chromatography, and lipid analysis to evaluate changes in membrane structure, chemical accumulation, and lipid composition. Ag85A deletion leads to altered plasma membrane domain organization, increased chemical accumulation, changes in cell envelope lipid composition. Unexpectedly, lipid analysis revealed accumulation-not depletion-of mycolic acids in the mutant, suggesting that increased permeability is not directly due to mycolic acid loss. These findings highlight a novel link between mycomembrane composition and plasma membrane domain stability. Our study not only advances understanding of mycobacterial cell envelope architecture but also identifies potential targets for enhancing drug penetration in resistant mycobacterial infections.