Bacteria spatially confine cellular processes like protease secretion and signal transduction in membrane platforms termed functional membrane microdomains, which in certain organisational and functional features resemble the lipid rafts of eukaryotic cells. However, a rigorous understanding of their composition, assembly and biological significance is unknown. Here we use the human pathogen methicillin-resistant Staphylococcus aureus (MRSA) to show that the organization of these platforms requires a preferential interaction between unphosphorylated membrane saccharolipids and the scaffold protein flotillin. This interaction leads to their accumulation in specific membrane microdomains concomitantly to the attraction of membrane-associated multimeric complexes, for which flotillin promotes efficient oligomerization. One of these harbored proteins is the penicillin-binding protein PBP2a, responsible for penicillin resistance in MRSA. We took PBP2a as showcase to demonstrate that flotillin mutants are also defective in PBP2a oligomerization and activity. Thus, perturbation of microdomains assembly, using commercially available drugs, interferes with PBP2a oligomerization and causes a relapse of MRSA penicillin resistance in vitro and in vivo, resulting in MRSA infections susceptible to conventional penicillin treatments. Our study shows that bacterial cells organize sophisticated programs for cellular compartmentalization and unravels a novel strategy to develop antimicrobial therapies for multi-drug resistance pathogens.