Evolutionary conservative analysis revealed novel functional sites in the efflux pump NorA of Staphylococcus aureus.

Abstract

The NorA antiporter of Staphylococcus aureus belongs to the major facilitator superfamily (MFS) and extrudes various kinds of drugs. With no structure available for this drug efflux pump, the aim of this study was to explore its important structural elements that contribute to substrate binding and drug transport. Evolutionary conservative analyses were conducted on different compilations of NorA homologues to identify conservative motifs and residues. Site-directed mutations were constructed to verify the functional changes in NorA efflux capacities and the conformational changes were further measured by fluorescence resonance energy transfer (FRET) and microscale thermophoresis (MST) analysis. Besides Motif-A, Motif-B and Motif-C that were reported previously in MFS proteins, two other motifs, Motif-1 and Motif-2, were identified in NorA. Site-directed mutations of Motif-1 and Motif-2 as well as 11 predicted binding sites all caused remarkable reductions in drug resistance and efflux activity. Among these, mutant F16A/E222A/F303A/D307A showed an altered binding affinity for tetraphenylphosphonium chloride when measured by MST and Motif-1 mutant G114D/A117E/D118G/V119I and Motif-2 mutant Q325E/G326E/A328E/G330E displayed obvious conformational alterations when compared with the wild-type NorA in the FRET signal spectra. The NorA structure agrees well with the typical structures of MFS proteins, with two newly identified motifs (Motif-1 and Motif-2) that are critical to the structural stability of NorA, and sites F16, E222, F303 and D307 are involved in substrate binding.