Polyketide natural products have broad applications in medicine. Exploiting the modular nature of polyketide synthases to alter stereospecificity is an attractive strategy for obtaining natural product analogues with altered pharmaceutical properties. We demonstrate that by retaining a dimerization element present in LipPks1+TE, we are able to use a ketoreductase domain exchange to alter α-methyl group stereochemistry with unprecedented retention of activity and simultaneously achieve a novel alteration of polyketide product stereochemistry from anti to syn. The substrate promiscuity of LipPks1+TE further provided a unique opportunity to investigate the substrate dependence of ketoreductase activity in a polyketide synthase module context.

Polyketides have enormous structural diversity, yet polyketide synthases (PKSs) have thus far been engineered to produce only drug candidates or derivatives thereof. Thousands of other molecules, including commodity and specialty chemicals, could be synthesized using PKSs if composing hybrid PKSs from well-characterized parts derived from natural PKSs was more efficient. Here, using modern mass spectrometry techniques as an essential part of the design–build–test cycle, we engineered a chimeric PKS to enable production one of the most widely used commodity chemicals, adipic acid. To accomplish this, we introduced heterologous reductive domains from various PKS clusters into the borrelidin PKS’ first extension module, which we previously showed produces a 3-hydroxy-adipoyl intermediate when coincubated with the loading module and a succinyl-CoA starter unit. Acyl-ACP intermediate analysis revealed an unexpected bottleneck at the dehydration step, which was overcome by introduction of a carboxyacyl-processing dehydratase domain. Appending a thioesterase to the hybrid PKS enabled the production of free adipic acid. Using acyl-intermediate based techniques to “debug” PKSs as described here, it should one day be possible to engineer chimeric PKSs to produce a variety of existing commodity and specialty chemicals, as well as thousands of chemicals that are difficult to produce from petroleum feedstocks using traditional synthetic chemistry.Keywords: adipic acid; polyketide synthase; tandem mass-spectrometry;

Polyketides, an important class of natural products with complex chemical structures, are widely used as antibiotics and other pharmaceutical agents. A clear barrier to heterologous polyketide biosynthesis in Escherichia coli is the lack of (2S)-methylmalonyl-CoA, a common substrate of multimodular polyketide synthases. Here we report a route for synthesizing (2S)-methylmalonyl-CoA from malonyl-CoA with a 3-hydroxypropionate cycle in thermoacidophilic crenarchaeon. The engineered E. coli strain produced both propionyl-CoA and methylmalonyl-CoA at intracellular levels similar to those of acetyl-CoA and succinyl-CoA, respectively. This approach may open a way to produce a variety of polyketide drugs in E. coli from renewable carbon sources.