Structure-based molecular characterization of a putative aspartic proteinase from Bacteroides fragilis

Abstract

Bacteroides fragilis resides in mammals and human intestines and secrete series of proteins and molecules outside that cause various diseases such as colon cancer and chronic colitis in the host. B. fragilis has been shown to produce numerous proteins to the infected cell surface which are involved in host colonization, microbial interactions, and pathogenicity. Among secreted proteins, a B. fragilis toxin (BFT) is a metalloprotease and disintegrates the epithelial cell layer and causes colon cancers. Except the BFT, information of secreted proteases from B. fragilis is limited and no structure is available. Aspartic proteinase cleaves a peptide bond using two aspartate residues in a catalytic site in acidic conditions, pH ranges from 3 to 6. Aspartic proteinase have been characterized mostly from eukaryotes and retroviruses but rare from bacteria including B. fragilis. A putative aspartic proteinase is identified from the B. fragilis genome and prepared recombinantly as a Bacteroides aspartic proteinase (BAPtase). The crystal structure of BAPtase was determined at 2.6 Å. Structure-based comparative and endopeptidase analyses demonstrated that BAPtase presents a two-domain structure and is a functional aspartic proteinase in unusually weak basic pHs, which would propose to be a critical in bacterial pathogenesis and in host immunity. Our observations on the distinct structural and catalytic properties of BAPtase would benefit the future development of B. fragilis-specific drugs or preventatives.