Acyl Enzyme Intermediates in Sortase-Catalyzed Pilus Morphogenesis in Gram-Positive Bacteria

In gram-positive bacteria, covalently linked pilus polymers are assembled by a specific transpeptidase enzyme called pilus-specific sortase. This sortase is postulated to cleave the LPXTG motif of a pilin precursor between threonine and glycine and to form an acyl enzyme intermediate with the substrate. Pilus polymerization is believed to occur through the resolution of this intermediate upon specific nucleophilic attack by the conserved lysine located within the pilin motif of another pilin monomer, which joins two pilins with an isopeptide bond formed between threonine and lysine. Here, we present evidence for sortase reaction intermediates in Corynebacterium diphtheriae. We show that truncated SrtA mutants that are loosely bound to the cytoplasmic membrane form high-molecular-weight complexes with SpaA polymers secreted into the extracellular milieu. These complexes are not formed with SpaA pilin mutants that have alanine substitutions in place of threonine in the LPXTG motif or lysine in the pilin motif. The same phenotype is observed with alanine substitutions of either the conserved cysteine or histidine residue of SrtA known to be required for catalysis. Remarkably, the assembly of SpaA pili, or the formation of intermediates, is abolished with a SrtA mutant missing the membrane-anchoring domain. We infer that pilus polymerization involves the formation of covalent pilin-sortase intermediates, which occurs within a molecular platform on the exoplasmic face of the cytoplasmic membrane that brings together both sortase and its cognate substrates in close proximity to each other, likely surrounding a secretion apparatus. We present electron microscopic data in support of this picture.Adherence to specific host tissue is a key step in bacterial colonization and the establishment of a successful infection by bacterial pathogens. Bacteria express a variety of adhesive cell surface molecules to bind host cells or other substrates in their natural habitat. The proteinaceous filaments known as pili or fimbriae are a clinically important class of these molecules. Both gram-negative and gram-positive bacteria express pili (6, 8). The gram-positive bacterial pili are unique in three respects (12, 25, 31). First, they represent heterodimeric or heterotrimeric protein polymers in which individual pilin subunits are covalently joined to each other (2, 9, 32). Second, the polymer itself is covalently attached to the cell wall (3, 31). Third, unlike pilus assembly in gram-negative bacteria, many of which require chaperones (26), the polymerization of the gram-positive pili and their cell wall attachment require specific transpeptidase enzymes called sortases (31).Mazmanian and colleagues discovered the sortase SrtA as an enzyme that linked the surface protein A of Staphylococcus aureus to its cell wall (15). Genome sequences revealed that sortases are ubiquitously expressed in gram-positive bacteria, including significant pathogens, such as Actinomyces naeslundii, Bacillus cereus, Corynebacterium diphtheriae, Enterococcus faecalis, Streptococcus agalactiae, and Streptococcus pneumoniae (4, 5, 28). Sortases are classified according to their functions and phylogenic relationships (4, 5). The class that closely matches SrtA of S. aureus in structure and function is now called a housekeeping sortase. Its function is to attach numerous surface proteins to the cell wall (16). Common to each of these cell surface proteins is a cell wall sorting signal with an LPXTG motif that is absolutely necessary for cell wall anchoring (18). Elegant genetic, biochemical, and structural work by the Schneewind laboratory illuminated the universal reaction mechanism of protein sorting in the gram-positive cell wall (14). Cell wall anchoring of surface proteins is catalyzed in two steps. In the first step, SrtA cleaves the TG peptide bond of the LPXTG motif of protein A and forms an acyl enzyme intermediate involving the threonine of protein A and the catalytic cysteine of sortase (22, 27, 29). In the second step, the cleaved protein A is transferred to the cell wall when a nucleophile amine from the lipid II precursor attacks and resolves the acyl enzyme intermediate (20, 21, 30). This seminal work formed the basis of our current model of pilus assembly catalyzed by pilus-specific sortases (12).We have used C. diphtheriae as a model for studies of the mechanism of pilus biogenesis. The corynebacterial genome encodes six different sortases (32). We now know that while five of these sortases (SrtA to -E) are devoted to pilus assembly, even the housekeeping sortase, SrtF, is required for efficient attachment of pili to the cell wall (23). Corynebacteria produce three distinct types of heterotrimeric pili, which are encoded by three pilus islands, each encoding three pilins (namely, SpaABC, SpaDEF, and SpaGHI) plus one or two cognate sortases essential for the assembly of the respective pilus (7, 24, 32). In each case, the prototype pilus represents a shaft structure made of a specific major pilin (namely, SpaA, SpaD, and SpaH) (12). Each type of pilus also contains a minor pilin at the tip (SpaC, SpaF, and SpaG) and another minor pilin dispersed along the shaft, as well as at the base of the pilus (SpaB, SpaE, and SpaI) (12). How are these polymers assembled, and how are they attached to the cell wall? All pilin proteins are predicted to contain in their amino termini a hydrophobic signal sequence necessary for export to the exoplasm by the Sec machinery. In addition, like the cell wall-anchored protein A of S. aureus, a cell wall sorting signal including the LPXTG motif is also present at the carboxy terminus of each of the Spa proteins of corynebacteria and other pilus proteins found in different gram-positive organisms (17). It is thus logical to imagine that the pilus-specific sortase utilizes the LPXTG motif for pilus polymerization, its cell wall anchoring, or both. Substantial genetic, biochemical, and ultrastructural analyses have proved this prediction. Consequently, Ton-That and Schneewind proposed a model of pilus assembly which posited that the basic mechanism of catalysis is conserved between cell wall sorting of surface proteins and the assembly of the pilus (31).According to our current working model (Fig. ​(Fig.1A),1A), the prototype SpaA pilus is assembled as follows. SrtA, which is essential and also specific for SpaA pilus formation, captures and cleaves cognate pilins at the LPXTG motif and forms an acyl enzyme intermediate. To form a dimer of SpaA and SpaC, the proposed tip entity, a conserved lysine in the SpaA pilin motif attacks the Cys-Thr bond of the SpaC-SrtA acyl enzyme intermediate. Shaft formation ensues by the cyclic addition of SpaA to the SpaC-SpaA dimer and the SpaC-SpaA_n oligomer formed in the preceding reaction. When a SpaB is attached to the growing pilus terminus by a similar mechanism involving a critical lysine of SpaB, it acts as a switch, terminating pilus polymerization in favor of cell wall anchoring (11). This happens by the classic resolution reaction mentioned above, which involves the lipid II precursor (28), followed by its linkage to the cell wall (11). Alternatively, the SpaB-containing pilus can elongate further by adding a SpaA subunit to SpaB (11). This model explains all the available genetic and biochemical data we have obtained so far in the corynebacterial system, as well as other systems reported by various investigators.Open in a separate windowFIG. 1.(A) Working model of pilus assembly in C. diphtheriae. Spa pilins are synthesized in the cytoplasm and transported across the cytoplasmic membrane by the Sec machinery. The membrane-bound pilus-specific sortase SrtA cleaves the Spa pilins at the LPXTG motif and forms an acyl enzyme intermediate with the substrates. Pilus polymerization occurs when this intermediate is resolved by a nucleophilic attack by the lysine residue within the pilin motif of an adjacent intermediate. Cell wall anchoring terminates pilus polymerization when SpaB is incorporated into the pilus base by the housekeeping sortase, SrtF (see the text for details). (B) Membrane localization of the pilus-specific sortase SrtA. Corynebacteria grown to mid-log phase were separated from the culture medium (M) by centrifugation. The cell wall (W) was removed from its protoplast by muramidase treatment of the cells. The protoplasts were lysed, and membrane (P*) and cytoplasmic (C) compartments were obtained by ultracentrifugation. Protein samples were separated on 4 to 12% Tris-glycine gradient gels and detected by immunoblotting them with the specific antisera α-SrtA, α-SecA, and α-SpaA. The positions of molecular mass markers (kDa) are indicated. WT, wild type.Significantly, there has been no report demonstrating the proposed intermediates of pilus assembly, to our knowledge. The present study was initiated to explore this key element of our model of pilus assembly, as well as the localization of the sortase in the membrane and its organization in the exoplasmic membrane in relation to the cognate pilins and the general secretion machinery.