Abstract
Clostridium difficile infection is a leading cause of antibiotic-associated diarrhea, placing considerable economic pressure on healthcare systems and resulting in significant morbidity and mortality. The pathogen produces a proteinaceous array on its cell surface known as the S-layer, consisting primarily of the major S-layer protein SlpA and a family of SlpA homologs. CwpV is the largest member of this family and is expressed in a phase-variable manner. The protein is post-translationally processed into two fragments that form a noncovalent, heterodimeric complex. To date, no specific proteases capable of cleaving CwpV have been identified. Using site-directed mutagenesis we show that CwpV undergoes intramolecular autoproteolysis, most likely facilitated by a N-O acyl shift, with Thr-413 acting as the source of a nucleophile driving this rearrangement. We demonstrate that neighboring residues are also important for correct processing of CwpV. Based on protein structural predictions and analogy to the glycosylasparaginase family of proteins, it appears likely that these residues play key roles in determining the correct protein fold and interact directly with Thr-413 to promote nucleophilic attack. Furthermore, using a cell-free protein synthesis assay we show that CwpV maturation requires neither cofactors nor auxiliary enzymes.
Highlights
The Clostridium difficile cell wall protein CwpV is post-translationally processed by an unknown mechanism
Using site-directed mutagenesis we show that CwpV undergoes intramolecular autoproteolysis, most likely facilitated by a N-O acyl shift, with Thr-413 acting as the source of a nucleophile driving this rearrangement
Hydroxyl Group of Thr-413 Is Involved in CwpV Cleavage— Autoproteolysis of bacterial glycosylasparaginase occurs adjacent to a threonine residue located in a highly conserved region
Summary
The Clostridium difficile cell wall protein CwpV is post-translationally processed by an unknown mechanism. C. difficile produces a surface layer (S-layer), composed of the high molecular weight S-layer protein (SLP) and the low molecular weight SLP [3] These SLPs are produced from a common precursor SlpA [3] via post-translational cleavage by a specific, surface layerassociated cysteine protease Cwp84 [4, 5]. Together, they form a heterodimeric complex that assembles into a two-dimensional array completely surrounding the bacterial cell [6]. The protein is surface expressed in a phase variable manner [8] and is post-translationally processed into two fragments that reassociate to form a stable, noncovalently associated complex [9]. Fulllength CwpV is never observed within the S-layer, even when
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