Surface proteins in gram-positive bacteria are frequently required for virulence, and many are attached to the cell wall by sortase enzymes. Bacteria frequently encode more than one sortase enzyme and an even larger number of potential sortase substrates that possess an LPXTG-type cell wall sorting signal. In order to elucidate the sorting pathways present in gram-positive bacteria, we performed a comparative analysis of 72 sequenced microbial genomes. We show that sortase enzymes can be partitioned into five distinct subfamilies based upon their primary sequences and that most of their substrates can be predicted by making a few conservative assumptions. Most bacteria encode sortases from two or more subfamilies, which are predicted to function nonredundantly in sorting proteins to the cell surface. Only ϳ20% of sortase-related proteins are most closely related to the well-characterized Staphylococcus aureus SrtA protein, but nonetheless, these proteins are responsible for anchoring the majority of surface proteins in gram-positive bacteria. In contrast, most sortase-like proteins are predicted to play a more specialized role, with each anchoring far fewer proteins that contain unusual sequence motifs. The functional sortase-substrate linkage predictions are available online (http://www.doe-mbi.ucla.edu/Services/Sortase/) in a searchable database.Pathogenic bacteria display an array of surface proteins to adhere to a site of infection, invade host cells, and evade the immune response. Many surface proteins are covalently attached to the cell wall by membrane-associated transpeptidases, called sortases (reviewed in references 18, 45, 48, and 53). The archetype sortase is the SrtA protein from Staphylococcus aureus, which anchors proteins that contain a C-terminal cell wall sorting signal (CWS) consisting of an LPXTG motif, followed by a hydrophobic domain and a tail of mostly positively charged residues (see Fig. 1A). An N-terminal secretion signal enables the precursor surface protein to be translocated across the membrane, where SrtA cleaves it in between the threonine and glycine residues of the LPXTG motif (47). SrtA then catalyzes the formation of an amide link between the carboxyl-group of the threonine and the cell wall precursor lipid II (57, 61), which is subsequently incorporated into the peptidoglycan via the transglycosylation and transpeptidation reactions of bacterial cell wall synthesis (66). An analysis of bacterial genomes indicates that this anchoring mechanism is conserved in gram-positive bacteria, since nearly all species encode SrtA homologs and proteins bearing a CWS (34, 55). Sortases may be excellent targets for new antimicrobial agents, since pathogens deficient in these enzymes exhibit reduced virulence (11,12,23,35,43,46).A large number of proteins are related to SrtA, but their functions have yet to be determined (55). Consistent with playing a role in surface protein chemistry, all SrtA homologs contain appropriately positioned active site residues (SrtA residues H120 and C184) (32)...
