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Identification of overoxidizing and non-overoxidizing NAD-dependent methanol dehydrogenases and implications for synthetic methylotrophy

Philipp Keller, Emese Hegedis, Benedikt Jäger, Simon Rüdisser, Hedwig Schultz, L Büchel, Andrea M. Ochsner, Timothy J. Bradley, Michael Reiter, Donald Hilvert, Julia A. Vorholt

2025Nature Communications6 citationsDOIOpen Access PDF

Abstract

Synthetic methylotrophy offers opportunities for sustainable chemical and biofuel production. While recently established methylotrophic E. coli can grow on methanol, undesirable formate accumulation occurs during growth and bioproduction. Here, we show that NAD-dependent methanol dehydrogenase Mdh2 from Cupriavidus necator inherently overoxidizes methanol to formate, a trait we find to be widespread among NAD-dependent Mdh enzymes. In contrast, Mdh/Mdh1 enzymes from Bacillus methanolicus exclusively oxidize methanol to formaldehyde without overoxidation, as we validate in vitro for Mdh Bm MGA3 with and without activator protein Act. Since only formaldehyde is assimilated via the ribulose monophosphate pathway, this explains the physiological role of Mdh/Mdh1 paralogs in natural methylotrophs and highlights the importance of selecting appropriate Mdh variants for synthetic methylotrophy. We demonstrate methanol-dependent growth using non-overoxidizing Mdh Bm MGA3, strongly reducing formate accumulation and carbon loss. Our findings reveal a characteristic of NAD-dependent Mdh enzymes and provide insights for engineering synthetic methylotrophs. Formate produced by synthetic methylotrophic E. coli can lead to carbon loss and negatively impact bioproduction efficiency. Here, the authors report the production of formate as a widespread property of NAD-dependent methanol dehydrogenases and identify Mdhs without this overoxidation activity.

Topics & Concepts

Methanol dehydrogenaseFormateBiochemistryCupriavidus necatorFormate dehydrogenaseMethanolEnzymeChemistryRibuloseCitric acid cycleBiologyFormaldehydeMalate dehydrogenaseBacteriaFormaldehyde dehydrogenaseHydrogenaseAlcohol oxidoreductaseSynthetic biologyMethanotrophMetabolic pathwayAlcohol dehydrogenaseMetabolismBiosynthesisFumaraseMicrobial metabolismFermentationComputational biologyMetabolic engineeringProtein engineeringIn silicoBacillus subtilisBioconversionMetabolomicsTricarboxylic acidMicrobial metabolism and enzyme functionMicrobial Metabolic Engineering and BioproductionMetalloenzymes and iron-sulfur proteins
Identification of overoxidizing and non-overoxidizing NAD-dependent methanol dehydrogenases and implications for synthetic methylotrophy | Litcius