Cloning and Expression of an Oligopeptidase, PepO, with Novel Specificity from Lactobacillus rhamnosus HN001 (DR20)

ABSTRACT Oligopeptidases of starter and nonstarter lactic acid bacteria contribute to the proteolytic events important in maturation and flavor development processes in cheese. This paper describes the molecular cloning, expression, and specificity of the oligopeptidase PepO from the probiotic nonstarter strain Lactobacillus rhamnosus HN001 (DR20). The pepO gene encodes a protein of 70.9 kDa, whose primary sequence includes the HEXXH motif present in certain classes of metallo-oligopeptidases. The pepO gene was cloned in L. rhamnosus HN001 and overexpressed in pTRKH2 from its own promoter, which was mapped by primer extension. It was further cloned in both pNZ8020 and pNZ8037 and overexpressed in Lactococcus lactis subsp. cremoris NZ9000 from the nisA promoter. The purified PepO enzyme demonstrated unique cleavage specificity for αs1-casein fragment 1–23, hydrolyzing the bonds Pro-5-Ile-6, Lys-7-His-8, His-8-Gln-9, and Gln-9-Gly-10. The impact of this enzyme in cheese can now be assessed.

Evidence that SpoIVFB Is a Novel Type of Membrane Metalloprotease Governing Intercompartmental Communication duringBacillus subtilis Sporulation

ABSTRACT Processing of pro-ςK in the mother cell compartment of sporulating Bacillus subtilis involves SpoIVFB and is governed by a signal from the forespore. SpoIVFB has an HEXXH motif characteristic of metalloproteases embedded in one of its transmembrane segments. Several conservative single amino acid changes in the HEXXH motif abolished function. However, changing the glutamic acid residue to aspartic acid, or changing the isoleucine residue that precedes the motif to proline, permitted SpoIVFB function. Only one other putative metalloprotease, site 2 protease has been shown to tolerate aspartic acid rather than glutamic acid in its HEXXH sequence. Site 2 protease and SpoIVFB share a second region of similarity with a family of putative membrane metalloproteases. A conservative change in this region of SpoIVFB abolished function. Interestingly, SpoIVFA increased the accumulation of certain mutant SpoIVFB proteins but was unnecessary for accumulation of wild-type SpoIVFB.