ABSTRACT
Alkenes are industrially important platform chemicals with broad applications. In this study, we report a microbial conversion route for direct biosynthesis of medium and long chain terminal alkenes from fermentable sugars by harnessing a novel P450 fatty acid (FA) decarboxylase from Macrococcus caseolyticus (OleTMC). We first characterized OleTMC and demonstrated its in vitro H2O2-independent activities towards linear and saturated C10:0-C18:0 FAs, with the highest activity for C16:0 and C18:0 FAs. Combining protein homology modeling, in silico residue mutation analysis, and docking simulation with direct experimental evidence, we elucidated the underlying mechanism for governing the observed substrate preference of OleTMC, which depends on the size of FA binding pocket, not the catalytic site. Next, we engineered the terminal alkene biosynthesis pathway, consisting of an engineered E. coli thioesterase (TesA*) and OleTMC, and introduced this pathway into E. coli for direct terminal alkene biosynthesis from glucose. The recombinant strain E. coli EcNN101 produced a total of 17.78 ± 0.63 mg/L odd-chain terminal alkenes, comprising of 0.9% ± 0.5% C11 alkene, 12.7% ± 2.2% C13 alkene, 82.7% ± 1.7% C15 alkene, and 3.7% ± 0.8% C17 alkene, and a yield of 0.87 ± 0.03 (mg/g) on glucose after 48 h in baffled shake flasks. To improve the terminal alkene production, we identified and overcame the electron transfer limitation in OleTMC, by introducing a two-component redox system, consisting of a putidaredoxin reductase CamA and a putidaredoxin CamB from Pseudomonas putida, into EcNN101, and demonstrated the terminal alkene production increased ∼2.8 fold after 48 h. Overall, this study provides a better understanding of the function of P450 FA decarboxylases and helps guide future protein and metabolic engineering for enhanced microbial production of target designer alkenes in a recombinant host.