Nonribosomal peptide synthetases (NRPSs) are microbial enzymes that produce a
wealth of important natural products by condensing substrates in an assembly line manner.
The proper sequence of substrates is obtained by tethering them to phosphopantetheinyl
arms of holo carrier proteins (CPs) via a thioester bond. CPs in holo and substrate-loaded
forms visit NRPS catalytic domains in a series of transient interactions. A lack of
structural information on substrate-loaded carrier proteins has hindered our understanding
of NRPS synthesis. Here, we present the first structure of an NRPS aryl carrier protein
loaded with its substrate via a native thioester bond, together with the structure of its
holo form. We also present the first quantification of NRPS CP backbone dynamics. Our
results indicate that prosthetic moieties in both holo and loaded forms are in contact
with the protein core, but they also sample states in which they are disordered and extend
in solution. We observe that substrate loading induces a large conformational change in
the phosphopantetheinyl arm, thereby modulating surfaces accessible for binding to other
domains. Our results are discussed in the context of NRPS domain interactions.
NMR structural studies of large monomeric and multimeric proteins face distinct challenges. In large monomeric proteins, the common occurrence of frequency degeneracies between residues impedes unambiguous assignment of NMR signals. To overcome this barrier, non-uniform sampling is used to measure spectra with optimal resolution within reasonable time, new correlation maps resolve previous impasses in assignment strategies, and novel selective methyl labeling schemes provide additional structural probes without cluttering NMR spectra. These advances push the limits of NMR studies of large monomeric proteins. Large multimeric and multi-domain proteins are studied by NMR when individual components can also be studied by NMR and have known structures. The structural properties of large assemblies are obtained by identifying binding surfaces, by orienting domains, and employing limited distance constraints. Segmental labeling and the combination of NMR with other methods have helped popularise NMR studies of such systems.
Carrier proteins (CPs) play a central role in nonribosomal peptide synthetases (NRPSs) as they shuttle covalently attached substrates between active sites. Understanding how the covalent attachment of a substrate (loading) influences the molecular properties of CPs is key to determining the mechanism of NRPS synthesis. However, structural studies have been impaired by substrate hydrolysis. Here, we used nuclear magnetic resonance spectroscopy to monitor substrate loading of a CP and to overcome hydrolysis. Our results reveal the spectroscopic signature of substrate loading and provide evidence of molecular communication between an NRPS carrier protein and its covalently attached substrate.
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