Controlling Megasynthetase Module-Module Interactions through β-Hairpin Docking Domain Engineering.

SummaryModular polyketide synthases and nonribosomal peptide synthetases are molecular assembly lines consisting of several multienzyme subunits that undergo dynamic self-assembly to form a functional mega-complex. N- and C-terminal docking domains are usually responsible for mediating interactions between subunits. Here we show that communication between two nonribosomal peptide synthetase subunits responsible for chain release from the enacyloxin polyketide synthase, which assembles an antibiotic with promising activity against Acinetobacter baumannii, is mediated by an intrinsically disordered short linear motif and a β-hairpin docking domain. The structures, interactions and dynamics of these subunits are characterised using several complementary biophysical techniques, providing extensive insights into binding and catalysis. Bioinformatics analyses reveal that short linear motif/β-hairpin docking domain pairs mediate subunit interactions in numerous nonribosomal peptide and hybrid polyketide-nonribosomal peptide synthetases, including those responsible for assembling several important drugs. Short linear motifs and β-hairpin docking domains from heterologous systems are shown to interact productively, highlighting the potential of such interfaces as tools for biosynthetic engineering.

Since the discovery and sequencing of 6 deoxyerythronolide B synthase twenty years ago, this exceptionally large, multifunctional protein remains the paradigm for the understanding of the structure and biochemical function of modular polyketide synthases.

Epothilones are thiazole-containing natural products with anticancer activity that are biosynthesized by polyketide synthase (PKS)-nonribosomal peptide synthetase (NRPS) enzymes EpoA-F. A cyclization domain of EpoB (Cy) assembles the thiazole functionality from an acetyl group and l-cysteine via condensation, cyclization, and dehydration. The PKS carrier protein of EpoA contributes the acetyl moiety, guided by a docking domain, whereas an NRPS EpoB carrier protein contributes l-cysteine. To visualize the structure of a cyclization domain with an accompanying docking domain, we solved a 2.03-Å resolution structure of this bidomain EpoB unit, comprising residues M1-Q497 (62 kDa) of the 160-kDa EpoB protein. We find that the N-terminal docking domain is connected to the V-shaped Cy domain by a 20-residue linker but otherwise makes no contacts to Cy. Molecular dynamic simulations and additional crystal structures reveal a high degree of flexibility for this docking domain, emphasizing the modular nature of the components of PKS-NRPS hybrid systems. These structures further reveal two 20-Å-long channels that run from distant sites on the Cy domain to the active site at the core of the enzyme, allowing two carrier proteins to dock with Cy and deliver their substrates simultaneously. Through mutagenesis and activity assays, catalytic residues N335 and D449 have been identified. Surprisingly, these residues do not map to the location of the conserved HHxxxDG motif in the structurally homologous NRPS condensation (C) domain. Thus, although both C and Cy domains have the same basic fold, their active sites appear distinct.

Non-ribosomal peptide synthetases (NRPSs) are large multienzyme machineries. They synthesize numerous important natural products starting from amino acids. For peptide synthesis functionally specialized NRPS modules interact in a defined manner. Individual modules are either located on a single or on multiple different polypeptide chains. The “peptide-antimicrobial-Xenorhabdus” (PAX) peptide producing NRPS PaxS from Xenorhabdus bacteria consists of the three proteins PaxA, PaxB and PaxC. Different docking domains (DDs) located at the N-termini of PaxB and PaxC and at the C-termini of PaxA and BaxB mediate specific non-covalent interactions between them. The N-terminal docking domains precede condensation domains while the C-terminal docking domains follow thiolation domains. The binding specificity of individual DDs is important for the correct assembly of multi-protein NRPS systems. In many multi-protein NRPS systems the docking domains are sufficient to mediate the necessary interactions between individual protein chains. However, it remains unclear if this is a general feature for all types of structurally different docking domains or if the neighboring domains in some cases support the function of the docking domains. Here, we report the 1H, 13C and 15 N NMR resonance assignments for a C-terminal di-domain construct containing a thiolation (T) domain followed by a C-terminal docking domain (CDD) from PaxA and for its binding partner – the N-terminal docking domain (NDD) from PaxB from the Gram-negative entomopathogenic bacterium Xenorhabdus cabanillasii JM26 in their free states and for a 1:1 complex formed by the two proteins. These NMR resonance assignments will facilitate further structural and dynamic studies of this protein complex.

Towards improved understanding of intersubunit interactions in modular polyketide biosynthesis: Docking in the enacyloxin IIa polyketide synthase

Natural products that produced by animals, plants or microorganisms, especially polyketides (PKs), non-ribosomal peptides (NRPs) and their hybrids, exhibit an extremely wide range of biological activities, include antibacterial, antifungal, antitumor, antiviral and immunosuppressive activities, which underlie the critical roles of natural products in medical industry as various drugs. The biosynthetic pathways of PKs, NRPs and their hybrids share a templated multifunctional enzymology for skeleton assembly. Polyketide synthases (PKSs) usually catalyze C−C bond formation using short carboxylic acid as monomers, whereas non-ribosomal peptide synthetases (NRPSs) incorporate amino acids through C−N bond formation. Consistent with their catalytic cycles, both PKSs and NRPSs are often giant enzymes organized into modules, which each contains a common thiolation (T) domain for loading building blocks. A prototype of a PKS module consists of an acyltransferase (AT), a T domain and a β-ketoacyl synthase (KS) domain. A minimum NRPS module contains an adenylation (A) domain, a T domain and a condensation (C) domain. AT or A domain is responsible for recognition and activation of building blocks, while KS or C domain catalyzes the elongation of the growing skeleton. In general, modular PKSs or NRPSs appear to function as assembly lines, which program monomer polymerization/modification and chain tailoring/termination following a non-iteratively ″one domain, one function″ like co-linearity rule. Thus, the domain composition of each module and the number of modules can be used to predict the structure of skeleton. However, there are exceptions reported in recent years, as modules are now known to be both skipped and iterated during the normal biosynthetic processes. In addition, another origin for a lack of correlation between domain composition of the multienzyme complex and the final product structure has been identified recently. In this case, the missing building blocks are normally incorporated on the assembly lines, but they will be removed by the post-assembly modifications. These kind of building blocks which would not appear in the final products seem ″unnecessary″, but they are essential in the biosynthetic pathways exactly. In this review, we summarize these ″auxiliary″ building blocks, focus on the chemical mechanisms of the incorporation and removal of them and discuss their biological functions that have been reported since 2000. The related building blocks here include fatty acyls, amino acids, unnatural amino acids and fatty acyl-amino acids. Some of these ″auxiliary″ build blocks are involved in the biosynthesis of natural products with specific structures, such as 2,2′-bipyridine cores, tetrahydroisoquinoline alkaloids, β-lactam and macrocyclic lactam antibiotics. In this case, building blocks are incorporated by the PKSs, NRPSs or their hybrids assembly lines, but the chemical mechanisms are unusual. The biological functions of these kind of building blocks are considered to be strategies for protection of the reactive groups and mediation of molecular assembly and modifications. On the other hand, some of the ″auxiliary″ building blocks are present in biosynthesis of natural products which are structurally different from each other, however, the ″unnecessary″ building blocks are almost same and their chemical mechanisms of incorporation and removal are similar. These kind of building blocks are proposed to be very important for protection the chemical producers by prodrug generation. In summary, the molecules mentioned in this review could increase the knowledge regarding the ″auxiliary″ building blocks, add another layer of complexity to natural product biosynthesis, help to hypothesize biosynthetic pathways of other natural products with specific structures and assist the association of molecules and their gene clusters.

Analysis of the enzymatic domains in the modular portion of the coronafacic acid polyketide synthase

The biosynthetic gene cluster for the antitumor drug bleomycin from Streptomyces verticillus ATCC15003 supporting functional interactions between nonribosomal peptide synthetases and a polyketide synthase

An approach for obtaining perfect hybridization probes for unknown polyketide synthase genes: a search for the epothilone gene cluster.

Non‐ribosomal peptide synthetases (NRPS) produce natural products from amino acid building blocks. They often consist of multiple polypeptide chains which assemble in a specific linear order via specialized N‐ and C‐terminal docking domains (N/CDDs). Typically, docking domains function independently from other domains in NRPS assembly. Thus, docking domain replacements enable the assembly of “designer” NRPS from proteins that normally do not interact. The multiprotein “peptide‐antimicrobial‐Xenorhabdus” (PAX) peptide‐producing PaxS NRPS is assembled from the three proteins PaxA, PaxB and PaxC. Herein, we show that the small CDD of PaxA cooperates with its preceding thiolation (T1) domain to bind the NDD of PaxB with very high affinity, establishing a structural and thermodynamical basis for this unprecedented docking interaction, and we test its functional importance in vivo in a truncated PaxS assembly line. Similar docking interactions are apparently present in other NRPS systems.

Hybrid Peptide–Polyketide Natural Products: Biosynthesis and Prospects toward Engineering Novel Molecules

In nature, various enzymes govern diverse biochemical reactions through their specific three-dimensional structures, which have been harnessed to produce many useful bioactive compounds including clinical agents and commodity chemicals. Polyketide synthases (PKSs) and non-ribosomal peptide synthetases (NRPSs) are particularly unique multifunctional enzymes that display modular organization. Individual modules incorporate their own specific substrates and collaborate to assemble complex polyketides or non-ribosomal polypeptides in a linear fashion. Due to the modular properties of PKSs and NRPSs, they have been attractive rational engineering targets for novel chemical production through the predictable modification of each moiety of the complex chemical through engineering of the cognate module. Thus, individual reactions of each module could be separated as a retro-biosynthetic biopart and repurposed to new biosynthetic pathways for the production of biofuels or commodity chemicals. Despite these potentials, repurposing attempts have often failed owing to impaired catalytic activity or the production of unintended products due to incompatible protein–protein interactions between the modules and structural perturbation of the enzyme. Recent advances in the structural, computational, and synthetic tools provide more opportunities for successful repurposing. In this review, we focused on the representative strategies and examples for the repurposing of modular PKSs and NRPSs, along with their advantages and current limitations. Thereafter, synthetic biology tools and perspectives were suggested for potential further advancement, including the rational and large-scale high-throughput approaches. Ultimately, the potential diverse reactions from modular PKSs and NRPSs would be leveraged to expand the reservoir of useful chemicals.

Megasynthase enzymes such as type I modular polyketide synthases (PKSs) and nonribosomal peptide synthetases (NRPSs) play a central role in microbial chemical warfare because they can evolve rapidly by shuffling parts (catalytic domains) to produce novel chemicals. If we can understand the design rules to reshuffle these parts, PKSs and NRPSs will provide a systematic and modular way to synthesize millions of molecules including pharmaceuticals, biomaterials, and biofuels. However, PKS and NRPS engineering remains difficult due to a limited understanding of the determinants of PKS and NRPS fold and function. We developed ClusterCAD to streamline and simplify the process of designing and testing engineered PKS variants. Here, we present the highly improved ClusterCAD 2.0 release, available at https://clustercad.jbei.org. ClusterCAD 2.0 boasts support for PKS-NRPS hybrid and NRPS clusters in addition to PKS clusters; a vastly enlarged database of curated PKS, PKS-NRPS hybrid, and NRPS clusters; a diverse set of chemical ‘starters’ and loading modules; the new Domain Architecture Cluster Search Tool; and an offline Jupyter Notebook workspace, among other improvements. Together these features massively expand the chemical space that can be accessed by enzymes engineered with ClusterCAD.

A diverse collection of 60 marine-sediment-derived Actinobacteria representing 52 operational taxonomic units was screened by PCR for genes associated with secondary-metabolite biosynthesis. Three primer sets were employed to specifically target adenylation domains associated with nonribosomal peptide synthetases (NRPSs) and ketosynthase (KS) domains associated with type I modular, iterative, hybrid, and enediyne polyketide synthases (PKSs). In total, two-thirds of the strains yielded a sequence-verified PCR product for at least one of these biosynthetic types. Genes associated with enediyne biosynthesis were detected in only two genera, while 88% of the ketosynthase sequences shared greatest homology with modular PKSs. Positive strains included representatives of families not traditionally associated with secondary-metabolite production, including the Corynebacteriaceae, Gordoniaceae, Intrasporangiaceae, and Micrococcaceae. In four of five cases where phylogenetic analyses of KS sequences revealed close evolutionary relationships to genes associated with experimentally characterized biosynthetic pathways, secondary-metabolite production was accurately predicted. Sequence clustering patterns were used to provide an estimate of PKS pathway diversity and to assess the biosynthetic richness of individual strains. The detection of highly similar KS sequences in distantly related strains provided evidence of horizontal gene transfer, while control experiments designed to amplify KS sequences from Salinispora arenicola strain CNS-205, for which a genome sequence is available, led to the detection of 70% of the targeted PKS pathways. The results provide a bioinformatic assessment of secondary-metabolite biosynthetic potential that can be applied in the absence of fully assembled pathways or genome sequences. The rapid identification of strains that possess the greatest potential to produce new secondary metabolites along with those that produce known compounds can be used to improve the process of natural-product discovery by providing a method to prioritize strains for fermentation studies and chemical analysis.

The modular polyketide synthases (PKS), common to many bacterial antibiotic-producers, are huge multienzyme, multidomain systems which can be likened to molecular assembly lines.1 An understanding of the structural and mechanistic aspects which underpin interdomain cooperation during biosynthesis by modular PKS is crucial to ongoing efforts to re-engineer these systems for the production of novel compounds of medicinal value.2 Previous attempts to solve the structures of PKS modules by X-ray crystallography have been unsuccessful, likely due to the high, inherent flexibility of the multienzymes. Here, we have employed an alternative technique, small-angle X-ray scattering (SAXS), in combination with NMR structure elucidation and homology modelling of individual domains, to obtain the first low-resolution structural data on an entire apo PKS module. The model system comprises a multidomain region of the virginiamycin M1 PKS from Streptomyces virginiae, a target of relevance for its involvement in production of the commercial antibiotic dalfopristin. The investigated region, which comprises a ketosynthase (KS) and two consecutive acyl carrier protein (ACP) domains, interacts with a wide range of protein partners, including notably, a complex of discrete enzymes responsible for β-methylation of the polyketide, and the N-terminus of the downstream PKS protein, VirFG.3 In our solved structure (Fig. 1), the homodimeric KS, which is flanked by well-folded linker regions, occupies the center of the module. While the first ACP is located close to the KS, the second is situated at the end of a flexible linker, and mobile. Taken together, these data provide a physical explanation for the functional non-equivalence previously observed for certain tandem ACPs of this class of PKS. Furthermore, the overall open shape of the module renders the second ACP highly accessible, which may be critical for its interaction with its multiple in trans catalytic partners. Finally, our analysis redefines the function of a putative dimerization motif of tandem ACPs as a docking domain, suggesting that the module likely adopts a more closed form in order to affect transfer of the chain extension intermediate to the subsequent module.