There is an increasing interest in the upgrading of inexpensive and abundant C1 feedstocks to higher carbon products. Linear carbon ligation routes are of particular interest due to their simplicity and potential for high carbon efficiencies. The formolase (FLS) enzyme was computationally designed to catalyze the formose reaction, where formaldehyde molecules are coupled to produce a mixture of C2 (glycolaldehyde) and C3 (dihydroxyacetone) molecules. Recent protein engineering efforts have resulted in the introduction of several FLS variants with altered catalytic properties. As is often the case with enzymes catalyzing reactions with complex and/or nonnatural trajectories, there are no mechanistic kinetic models that fully describe the activity of the FLS enzyme. FLS variants are typically evaluated by fitting rate data to empirical rate laws, with some variation of the kcat/KM ratio used to report and rank performances. The apparent parameters estimated in this manner are unlikely to capture the full catalytic performance of these enzymes. In this study, we derive a mechanistic rate law describing FLS activity as well as theory‐based figures of merit to rank FLS performance under relevant conditions. We proceed to fit the rate equation to initial rate data obtained from several FLS mutants, and use the figures of merit to compare the mutations. This study provides a theoretical framework for comparing FLS enzymes which will be essential as novel carbon ligation pathways are devised and implemented.
Protein engineering has been used to enhance the activities, selectivities, and stabilities of enzymes. Frequently tradeoffs are observed, where improvements in some features can come at the expense of others. Nature uses modular assembly of active sites for complex, multi‐step reactions, and natural “swing arm” mechanisms have evolved to transfer intermediates between active sites. Biomimetic polyethylene glycol (PEG) swing arms modified with NAD(H) have been explored to introduce synthetic swing arms into fused oxidoreductases. Here we report that increasing NAD(H)‐PEG swing arms can improve the activity of synthetic formate:malate oxidoreductases as well as the thermal and operational stabilities of the biocatalysts. The modular assembly approach enables the KM values of new enzymes to be predictable, based on the parental enzymes. We describe four unique synthetic transhydrogenases that have no native homologs, and this platform could be easily extended for the predictive design of additional synthetic cofactor‐independent transhydrogenases.
The modular assembly of synthetic transhydrogenase catalysts is demonstrated using a PEG‐NAD(H) modified formate dehydrogenase (FDH)‐SpyCatcher fusion protein. The front cover highlights how any oxidoreductase enzyme can be outfitted with a simple SpyTag peptide and conjugated to FDH‐SpyCatcher to create new cofactor‐independent biocatalysts driven by formate oxidation. The stabilities and catalytic properties of the resulting transhydrogenases are improved without detriment to the selectivities of the native active sites, emphasizing the functional modularity and predictive nature of this synthetic approach to biocatalyst design. More information can be found in the Full Paper by N. Massad and S. Banta.
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