The modular polyketide synthases (PKSs) and nonribosomal peptide synthetases (NRPSs) are among the largest and most complicated enzymes in nature. In these biosynthetic systems, independently folding ...protein domains, which are organized into units called 'modules', operate in assembly-line fashion to construct polymeric chains and tailor their functionalities. Products of PKSs and NRPSs include a number of blockbuster medicines, and this has motivated researchers to understand how they operate so that they can be modified by genetic engineering. Beginning in the 1990s, structural biology has provided a number of key insights. The emerging picture is one of remarkable dynamics and conformational programming in which the chemical states of individual catalytic domains are communicated to the others, configuring the modules for the next stage in the biosynthesis. This unexpected level of complexity most likely accounts for the low success rate of empirical genetic engineering experiments and suggests ways forward for productive megaenzyme synthetic biology.
Multienzyme polyketide synthases (PKSs) are molecular-scale assembly lines which construct complex natural products in bacteria. The underlying modular architecture of these gigantic catalysts ...inspired, from the moment of their discovery, attempts to modify them by genetic engineering to produce analogues of predictable structure. These efforts have resulted in hundreds of metabolites new to nature, as detailed in this review. However, in the face of many failures, the heady days of imagining the possibilities for a truly 'combinatorial biosynthesis' of polyketides have faded. It is now more appropriate to talk about 'PKS synthetic biology' with its more modest goals of delivering specific derivatives of known structure in combination with and as a complement to synthetic chemistry approaches. The reasons for these failures will be discussed in terms of our growing understanding of the three-dimensional architectures and mechanisms of these systems. Finally, some thoughts on the future of the field will be presented.
The modular polyketide synthases (PKSs) are multienzyme proteins responsible for the assembly of diverse secondary metabolites of high economic and therapeutic importance. These molecular 'assembly ...lines' consist of repeated functional units called 'modules' organized into gigantic polypeptides. For several decades, concerted efforts have been made to understand in detail the structure and function of PKSs in order to facilitate genetic engineering of the systems towards the production of polyketide analogues for evaluation as drug leads. Despite this intense activity, it has not yet been possible to solve the crystal structure of a single module, let alone a multimodular subunit. Nonetheless, on the basis of analysis of the structures of modular fragments and the study of the related multienzyme of animal fatty acid synthase (FAS), several models of modular PKS architecture have been proposed. This year, however, the situation has changed - three modular structures have been characterized, not by X-ray crystallography, but by the complementary methods of single-particle cryo-electron microscopy and small-angle X-ray scattering. This review aims to compare the cryo-EM structures and SAXS-derived structural models, and to interpret them in the context of previously obtained data and existing architectural proposals. The consequences for genetic engineering of the systems will also be discussed, as well as unresolved questions and future directions.
The biosynthesis of reduced polyketides in bacteria by modular polyketide synthases (PKSs) proceeds with exquisite stereocontrol. As the stereochemistry is intimately linked to the strong bioactivity ...of these molecules, the origins of stereochemical control are of significant interest in attempts to create derivatives of these compounds by genetic engineering. In this review, we discuss the current state of knowledge regarding this key aspect of the biosynthetic pathways. Given that much of this information has been obtained using chemical biology tools, work in this area serves as a showcase for the power of this approach to provide answers to fundamental biological questions.
During biosynthesis by multi-modular trans-AT polyketide synthases, polyketide structural space can be expanded by conversion of initially-formed electrophilic β-ketones into β-alkyl groups. These ...multi-step transformations are catalysed by 3-hydroxy-3-methylgluratryl synthase cassettes of enzymes. While mechanistic aspects of these reactions have been delineated, little information is available concerning how the cassettes select the specific polyketide intermediate(s) to target. Here we use integrative structural biology to identify the basis for substrate choice in module 5 of the virginiamycin M trans-AT polyketide synthase. Additionally, we show in vitro that module 7, at minimum, is a potential additional site for β-methylation. Indeed, analysis by HPLC-MS coupled with isotopic labelling and pathway inactivation identifies a metabolite bearing a second β-methyl at the expected position. Collectively, our results demonstrate that several control mechanisms acting in concert underpin β-branching programming. Furthermore, variations in this control - whether natural or by design - open up avenues for diversifying polyketide structures towards high-value derivatives.
Iron is essential to many biological processes but its poor solubility in aerobic environments restricts its bioavailability. To overcome this limitation, bacteria have evolved a variety of ...strategies, including the production and secretion of iron-chelating siderophores. Here, we describe the discovery of four series of siderophores from
ATCC23877, three of which are unprecedented. MS/MS-based molecular networking revealed that one of these series corresponds to acylated desferrioxamines (acyl-DFOs) recently identified from
. The remaining sets include tetra- and penta-hydroxamate acyl-DFO derivatives, all of which incorporate a previously undescribed building block. Stable isotope labeling and gene deletion experiments provide evidence that biosynthesis of the acyl-DFO congeners requires unprecedented crosstalk between two separate non-ribosomal peptide synthetase (NRPS)-independent siderophore (NIS) pathways in the producing organism. Although the biological role(s) of these new derivatives remain to be elucidated, they may confer advantages in terms of metal chelation in the competitive soil environment due to the additional bidentate hydroxamic functional groups. The metabolites may also find application in various fields including biotechnology, bioremediation, and immuno-PET imaging.IMPORTANCEIron-chelating siderophores play important roles for their bacterial producers in the environment, but they have also found application in human medicine both in iron chelation therapy to prevent iron overload and in diagnostic imaging, as well as in biotechnology, including as agents for biocontrol of pathogens and bioremediation. In this study, we report the discovery of three novel series of related siderophores, whose biosynthesis depends on the interplay between two NRPS-independent (NIS) pathways in the producing organism
the first example to our knowledge of such functional cross-talk. We further reveal that two of these series correspond to acyl-desferrioxamines which incorporate four or five hydroxamate units. Although the biological importance of these novel derivatives is unknown, the increased chelating capacity of these metabolites may find utility in diagnostic imaging (for instance,
Zr-based immuno-PET imaging) and other applications of metal chelators.
Modular trans‐acyltransferase polyketide synthases (trans‐AT PKSs) are enzymatic assembly lines that biosynthesize complex polyketide natural products. Relative to their better studied cis‐AT ...counterparts, the trans‐AT PKSs introduce remarkable chemical diversity into their polyketide products. A notable example is the lobatamide A PKS, which incorporates a methylated oxime. Here we demonstrate biochemically that this functionality is installed on‐line by an unusual oxygenase‐containing bimodule. Furthermore, analysis of the oxygenase crystal structure coupled with site‐directed mutagenesis allows us to propose a model for catalysis, as well as identifying key protein‐protein interactions that support this chemistry. Overall, our work adds oxime‐forming machinery to the biomolecular toolbox available for trans‐AT PKS engineering, opening the way to introducing such masked aldehyde functionalities into diverse polyketides.
Benzolactone enamides, a number of which incorporate a methylated oxime moiety, are produced by a range of organisms, and constitute a family of cytotoxic natural products. Here, we determine how this capped oxime group is installed during assembly of the model polyketide lobatamide by a modular trans‐AT polyketide synthase and provide molecular insight into the responsible mono‐oxygenase domain by X‐ray crystallography.
Myxobacteria nolable for their complex, multi-cellular lifecycles, produce a wide range of secondary metabolites with promising bioactivity.
Myxobacteria are soil-dwelling, Gram-negative bacteria ...which are notable not only for their multi-cellular ‘social’ lifestyles, but for production of structurally diverse secondary metabolites with potential in clinical therapy. Here we briefly review the history of myxobacterial natural products research, provide an overview of their unique secondary metabolism, with an emphasis on assembly line biosynthesis of polyketide and non-ribosomal peptide metabolites, and look to the future of the field.