T Gallagher1, G Gilliland, L Wang, P Bryan. 1. Center for Advanced Research in Biotechnology, University of Maryland Biotechnology Institute, Rockville, USA.
Abstract
BACKGROUND: The folding of the bacterial protease subtilisin BPN' (SBT) is dependent on its 77-residue prosegment, which is then autocatalytically removed to give the mature enzyme. Mature subtilisin represents a class of proteins that lacks an efficient folding pathway. Refolding of mature SBT is extremely slow unless catalyzed by the independently expressed prosegment, leading to a bimolecular complex. RESULTS: We report the crystal structure at 2.0 A resolution of the prosegment-SBT complex and consider its implications for prosubtilisin BPN' maturation and folding catalysis. The prosegment forms a compact domain that binds SBT through an extensive interface involving the enzyme's two parallel surface helices (residues 104-116 and 133-144), supplying negatively charged caps to the N termini of these helices. The prosegment C terminus binds in the enzyme active site in a product-like manner, with Tyr77 in the P1 binding pocket. CONCLUSIONS: The structure of the complex supports a unimolecular mechanism for prosubtilisin cleavage, involving a 25 A rearrangement of the SBT N terminus in a late folding step. A mechanism of folding catalysis in which the two helices and their connecting beta strand form a prosegment-stabilized folding nucleus is proposed. While this putative nucleus is stabilized by prosegment binding, the N-terminal and C-terminal subdomains of SBT could fold by propagation.
BACKGROUND: The folding of the bacterial protease subtilisin BPN' (SBT) is dependent on its 77-residue prosegment, which is then autocatalytically removed to give the mature enzyme. Mature subtilisin represents a class of proteins that lacks an efficient folding pathway. Refolding of mature SBT is extremely slow unless catalyzed by the independently expressed prosegment, leading to a bimolecular complex. RESULTS: We report the crystal structure at 2.0 A resolution of the prosegment-SBT complex and consider its implications for prosubtilisin BPN' maturation and folding catalysis. The prosegment forms a compact domain that binds SBT through an extensive interface involving the enzyme's two parallel surface helices (residues 104-116 and 133-144), supplying negatively charged caps to the N termini of these helices. The prosegment C terminus binds in the enzyme active site in a product-like manner, with Tyr77 in the P1 binding pocket. CONCLUSIONS: The structure of the complex supports a unimolecular mechanism for prosubtilisin cleavage, involving a 25 A rearrangement of the SBT N terminus in a late folding step. A mechanism of folding catalysis in which the two helices and their connecting beta strand form a prosegment-stabilized folding nucleus is proposed. While this putative nucleus is stabilized by prosegment binding, the N-terminal and C-terminal subdomains of SBT could fold by propagation.
Authors: Regina M Day; Craig J Thalhauser; James L Sudmeier; Matthew P Vincent; Ekaterina V Torchilin; David G Sanford; Christopher W Bachovchin; William W Bachovchin Journal: Protein Sci Date: 2003-04 Impact factor: 6.725