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Abstract

Enoyl-CoA carboxylases/reductases (ECRs) belong to the most efficient CO2-fixing enzymes described to date. However, the molecular mechanisms underlying ECR’s extraordinary catalytic activity on the level of the protein assembly remain elusive. Here we used a combination of ambient temperature X-ray Free Electron Laser (XFEL) and cryogenic synchrotron experiments to study the structural organization of the ECR from Kitasatospora setae. K. setae ECR is a homo-tetramer that differentiates into a dimer of dimers of open- and closed-form subunits in the catalytically active state. Using molecular dynamics simulations and structure-based mutagenesis, we show that catalysis is synchronized in K. setae ECR across the pair of two dimers. This conformational coupling of catalytic domains is conferred by individual amino acids to achieve high CO2-fixation rates. Our results provide unprecedented insights into the dynamic organization and synchronized inter- and intra-subunit communications of this remarkably efficient CO2-fixing enzyme during catalysis.Significance Statement Fixation of CO2 offers real potential for reaching negative CO2 emissions in bioenergy, and bioproduct utilization. The capture and conversion of atmospheric CO2 remains a challenging task. Existing biological systems can be exploited and optimized for this use. Bacterial enoyl-CoA carboxylases/reductases (ECRs) encompass the fastest CO2-fixing enzymes found in nature to date. However, the mechanisms underlying ECR’s extraordinary catalytic activity remain elusive. Our structural, computational, and biochemical results elucidate the dynamic structural organization of the ECR complex and describe how coupled motions of catalytic domains in the ECR tetramer drive carboxylation. This mechanistic understanding is critical for engineering highly efficient CO2-fixing biocatalysts for bioenergy and bioproduct applications.Competing Interest StatementThe authors have declared no competing interest.