Iterative, nonreducing polyketide
synthases (NR-PKSs) are multidomain
enzymes responsible for the construction of the core architecture
of aromatic polyketide natural products in fungi. Engineering these
enzymes for the production of non-native metabolites has been a long-standing
goal. We conducted a systematic survey of in vitro “domain swapped” NR-PKSs using an enzyme deconstruction
approach. The NR-PKSs were dissected into mono- to multidomain fragments
and recombined as noncognate pairs in vitro, reconstituting
enzymatic activity. The enzymes used in this study produce aromatic
polyketides that are representative of the four main chemical features
set by the individual NR-PKS: starter unit selection, chain-length
control, cyclization register control, and product release mechanism.
We found that boundary conditions limit successful chemistry, which
are dependent on a set of underlying enzymatic mechanisms. Crucial
for successful redirection of catalysis, the rate of productive chemistry
must outpace the rate of spontaneous derailment and thioesterase-mediated
editing. Additionally, all of the domains in a noncognate system must
interact efficiently if chemical redirection is to proceed. These
observations refine and further substantiate current understanding
of the mechanisms governing NR-PKS catalysis.
Summary
Fungal polyketide synthases (PKSs) are large, multi-domain enzymes that biosynthesize a wide range of natural products. A hallmark of these megasynthases is the iterative use of catalytic domains to extend and modify a series of enzyme-bound intermediates. A subset of these iterative PKSs (iPKSs) contains a C-methyltransferase (CMeT) domain that adds one or more S-adenosylmethionine (SAM)-derived methyl groups to the carbon framework. Neither the basis by which only specific positions on the growing intermediate are methylated (“programming”) nor the mechanism of methylation are well understood. Domain dissection and reconstitution of PksCT, the fungal non-reducing PKS (NR-PKS) responsible for the first isolable intermediate in citrinin biosynthesis, demonstrates the role of CMeT-catalyzed methylation in precursor elongation and pentaketide formation. The crystal structure of the S-adenosyl-homocysteine (SAH) coproduct-bound PksCT CMeT domain reveals a two-subdomain organization with a novel N-terminal subdomain characteristic of PKS C-methyltransferase domains and provides insights into cofactor and ligand recognition.
Polyketide synthases (PKSs) are microbial multienzymes for the biosynthesis of biologically potent secondary metabolites. Polyketide production is initiated by the loading of a starter unit onto an integral acyl carrier protein (ACP) and its subsequent transfer to the ketosynthase (KS). Initial substrate loading is achieved either by multidomain loading modules or by the integration of designated loading domains, such as starter unit acyltransferases (SAT), whose structural integration into PKS remains unresolved. A crystal structure of the loading/condensing region of the nonreducing PKS CTB1 demonstrates the ordered insertion of a pseudodimeric SAT into the condensing region, which is aided by the SAT-KS linker. Cryo-electron microscopy of the post-loading state trapped by mechanism-based crosslinking of ACP to KS reveals asymmetry across the CTB1 loading/condensing region, in accord with preferential 1:2 binding stoichiometry. These results are critical for re-engineering the loading step in polyketide biosynthesis and support functional relevance of asymmetric conformations of PKSs.
Playing by the rules: Combinatorial domain swaps among “deconstructed” non‐reducing polyketide synthases (NR‐PKSs) revealed the rules behind product assembly (see scheme). The control exerted by individual catalytic domains was found to be sufficiently great that heterocombinations of domains from different NR‐PKSs synthesized products in a predictable manner.
Nach den Regeln spielen: Der kombinatorische Domänenaustausch zwischen „abgebauten“ nichtreduzierenden Polyketid‐Synthasen (NR‐PKSs) deckt die Regeln auf, nach denen der Zusammenbau der Produkte erfolgt. Die von einzelnen katalytischen Domänen ausgeübte Kontrolle ist genügend groß, damit Heterokombinationen von Domänen unterschiedlicher NR‐PKSs Produkte in vorhersagbarer Weise synthetisieren.
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