Autoproteolytic activation of a symbiosis-regulated truffle phospholipase A2

Abstract

Background: TbSP1 is a phospholipase A2 strongly up-regulated during the symbiotic phase of the truffle Tuber borchii. Results: An activated enzyme species composed of five-helices is generated by self-proteolysis through an intermolecular reaction. Conclusion: TbSP1 autoproteolysis is a site-specific post-translational modification not involving the phospholipase active site. Significance: Autoproteolytic activation is described for the first time for a microbial PLA2, with possible implications for symbiosis establishment. Fungal phospholipases are members of the fungal/bacterial group XIV secreted phospholipases A2 (sPLA2s). TbSP1, the sPLA2 primarily addressed in this study, is up-regulated by nutrient deprivation and is preferentially expressed in the symbiotic stage of the ectomycorrhizal fungus Tuber borchii. A peculiar feature of this phospholipase and of its ortholog from the black truffle Tuber melanosporum is the presence of a 54-amino acid sequence of unknown functional significance, interposed between the signal peptide and the start of the conserved catalytic core of the enzyme. X-ray diffraction analysis of a recombinant TbSP1 form corresponding to the secreted protein previously identified in T. borchii mycelia revealed a structure comprising the five-helices that form the phospholipase catalytic module but lacking the N-terminal 54 amino acids. This finding led to a series of functional studies that showed that TbSP1, as well as its T. melanosporum ortholog, is a self-processing pro-phospholipase A2, whose phospholipase activity increases up to 80-fold following autoproteolytic removal of the N-terminal peptide. Proteolytic cleavage occurs within a serine-rich, intrinsically flexible region of TbSP1, does not involve the phospholipase active site, and proceeds via an intermolecular mechanism. Autoproteolytic activation, which also takes place at the surface of nutrient-starved, sPLA2 overexpressing hyphae, may strengthen and further control the effects of phospholipase up-regulation in response to nutrient deprivation, also in the context of symbiosis establishment and mycorrhiza formation. © 2013 by The American Society for Biochemistry and Molecular Biology, Inc.