Nonribosomal peptides are therapeutically important
natural products produced through pathways that utilize large
multimodular enzymes, termed nonribosomal peptide synthetases
(NRPSs). Central to the assembly line methodology, the monomer
building blocks and the growing polymer chain are covalently linked
to dedicated peptidyl carrier protein domains as
phosphopantetheinyl thioesters. Although structures of multidomain
NRPS fragments have been solved recently, the active conformation
of the carrier domains with their attached phosphopantetheinyl arms
has not been determined. Significant conformational changes in
carrier domains are likely to occur as the domains shuttle peptidyl
phosphopantetheinyl thioesters between the active sites of the
partner domains. This thesis focuses on the application of the
synthetic isosteric non-hydrolyzable CoA analogs to manipulate
carrier domain geometry of NRPS assemblies through. The synthetic
conjugates are designed to deliver an inhibitor moiety to a domain
of interest. Using this strategy, various complexes have been
designed to direct the phosphopantetheinyl arm to active sites of
adenylation domains and thioesterase domains in catalytically
relevant conformations. The structurally restrained multidomain
NRPS assemblies are useful for elucidating the complex structure
and mechanism of NRPSs. An X-ray crystal structure of a peptidyl
carrier-thioesterase NRPS didomain fragment from enterobactin
synthetase has been solved with a phosphopantetheinyl analog which
forms a cross-link between the two domains. This structure
provides, for the first time, detailed insights into the
phosphopantetheinyl arm interaction with an NRPS partner domain, as
well as an active confirmation of a mutidomain NRPS in the
holo-form. In addition, the hydrolytically stable CoA analogs have
been successfully used as probes in the structural and mechanistic
study of a CoA-utilizing enzyme DpgC, a unique cofactor-independent
dioxygenase involved in vancomycin biosynthesis.