Control of directionality in nonribosomal peptide synthesis: role of the condensation domain in preventing misinitiation and timing of epimerization.

Abstract

Product assembly by nonribosomal peptide synthetases (NRPS) is initiated by starter modules that comprise an adenylation (A) and a peptidyl carrier protein (PCP) domain. Elongation modules of NRPS have in addition a condensation (C) domain that is located upstream of the A domain. They cannot initiate peptide bond formation. To understand the role of domain arrangements and the influence of the domains present upstream of the A domains of the elongation modules of TycB on the initiation and epimerization activities, we constructed a set of proteins derived from the tyrocidine synthetases of Bacillus brevis, which represent several N-terminal truncations of TycB and the first module of TycC. The latter was fused with the thioesterase domain (Te) to give TycC(1)-CAT-Te and to ensure product turnover. TycB(2)(-)(3)-AT.CATE and TycB(3)-ATE, lacking an N-terminal C domain, were capable of initiating peptide synthesis and epimerizing. In contrast, the corresponding constructs with a cognate N-terminal C domain, TycB(2)(-)(3)-T.CATE and TycB(3)-CATE, were strongly reduced in initiation and epimerization. Evidence is also provided that this reduction is due to substrate binding in an enantioselective binding pocket at the acceptor position of the C domains. By using TycB(2)(-)(3)-AT.CATE and TycB(3)-ATE, we were able to turn an elongation module into an initiation module, and to establish an in-trans system for the formation of new di- and tripeptides with recombinant NRPS modules. We also show that epimerization domains of elongation modules can in principle epimerize both aminoacyl-S-Ppant (TycB(3)-ATE) and peptidyl-S-Ppant (TycB(2)(-)(3)-AT.CATE) substrates, although the efficiency for epimerizing the noncognate aminoacyl-S-Ppant substrates appears to be lowered.