Dual roles of FmtA in Staphylococcus aureus cell wall biosynthesis and autolysis.

The fmtA gene is a member of the Staphylococcus aureus core cell wall stimulon. The FmtA protein interacts with ß-lactams through formation of covalent species. Here, we show that FmtA has weak D-Ala-D-Ala-carboxypeptidase activity and is capable of covalently incorporating C14-Gly into cell walls. The fluorescence microscopy study showed that the protein is localized to the cell division septum. Furthermore, we show that wall teichoic acids interact specifically with FmtA and mediate recruitment of FmtA to the S. aureus cell wall. Subjection of S. aureus to FmtA concentrations of 0.1 µM or less induces autolysis and biofilm production. This effect requires the presence of wall teichoic acids. At FmtA concentrations greater than 0.2 µM, autolysis and biofilm formation in S. aureus are repressed and growth is enhanced. Our findings indicate dual roles of FmtA in S. aureus growth, whereby at low concentrations, FmtA may modulate the activity of the major autolysin (AtlA) of S. aureus and, at high concentrations, may participate in synthesis of cell wall peptidoglycan. These two roles of FmtA may reflect dual functions of FmtA in the absence and presence of cell wall stress, respectively.

Repurposing an Ancient Protein Core Structure: Structural Studies on FmtA, a Novel Esterase of Staphylococcus aureus.

FmtA is a penicillin-recognizing protein (PRP) with novel hydrolytic activity toward the ester bond between d-Ala and the backbone of teichoic acids. Teichoic acids are polyol-phosphate polymers found in the Staphylococcus aureus cell wall, and they play important roles in antibiotic resistance and pathogenesis. Two of the PRPs conserved motifs, namely, SXXK and Y(S)XN, are involved in the hydrolysis by FmtA, but the catalytic mechanism remains elusive. Here we determined the crystal structure of FmtA. FmtA shares the core structure of PRPs: an all α-helical domain and α/ß domain sandwiched together. However, it does not have the typical PRPs active-site cleft. Its active site is shallow, solvent-exposed, and enlarged. Furthermore, our mutagenesis and kinetic studies suggest that the SXXK and Y(S)XN motifs of FmtA offer all that is necessary for catalysis, and more: the active-site nucleophile (serine), the general base (lysine) required for the acylation step and the deacylation step, and an anchor (tyrosine) to hold the active-site serine, and possibly the substrate, in an optimum conformation for catalysis. Our study establishes that the FmtA esterase activity represents an expansion of the catalytic activity repertoire of the PRPs core structure, which typically displays peptidase activity. This finding points toward a novel mechanism of ester bond hydrolysis by a PRP. The structure of FmtA provides insights to the design of inhibitor molecules with the potential to serve as leads in the development of novel antibacterial chemotherapeutic agents.

The Staphylococcus aureus Methicillin Resistance Factor FmtA Is a d-Amino Esterase That Acts on Teichoic Acids.

UNLABELLED: The methicillin resistance factor encoded by fmtA is a core member of the Staphylococcus aureus cell wall stimulon, but its function has remained elusive for the past two decades. First identified as a factor that affects methicillin resistance in S. aureus strains, FmtA was later shown to interact with teichoic acids and to localize to the cell division septum. We have made a breakthrough in understanding FmtA function. We show that FmtA hydrolyzes the ester bond between d-Ala and the backbone of teichoic acids, which are polyglycerol-phosphate or polyribitol-phosphate polymers found in the S. aureus cell envelope. FmtA contains two conserved motifs found in serine active-site penicillin-binding proteins (PBPs) and ß-lactamases. The conserved SXXK motif was found to be important for the d-amino esterase activity of FmtA. Moreover, we show that deletion of fmtA (ΔfmtA) led to higher levels of d-Ala in teichoic acids, and this effect was reversed by complementation of ΔfmtA with fmtA. The positive charge on d-Ala partially masks the negative charge of the polyol-phosphate backbone of teichoic acids; hence, a change in the d-Ala content will result in modulation of their charge. Cell division, biofilm formation, autolysis, and colonization are among the many processes in S. aureus affected by the d-Ala content and overall charge of the cell surface teichoic acids. The esterase activity of FmtA and the regulation of fmtA suggest that FmtA functions as a modulator of teichoic acid charge, thus FmtA may be involved in S. aureus cell division, biofilm formation, autolysis, and colonization. IMPORTANCE: Teichoic acids are involved in cell division, cell wall synthesis, biofilm formation, attachment of bacteria to artificial surfaces, and colonization. However, the function of teichoic acids is not fully understood. Modification by glycosylation and/or d-alanylation of the polyol-phosphate backbone of teichoic acids is important in the above cell processes. The intrinsic negative charge of teichoic acid backbone plays a role in the charge and/or pH of the bacterial surface, and d-alanylation represents a means through which bacteria modulate the charge or the pH of their surfaces. We discovered that FmtA removes d-Ala from teichoic acids. We propose FmtA may provide a temporal and spatial regulation of the bacterial cell surface charge in two ways, by removing the d-Ala from LTA to make it available to wall teichoic acid (WTA) in response to certain conditions and by removing it from WTA to allow the cell to reset its surface charge to a previous condition.