Computational investigations in inhibition of alcohol/aldehyde dehydrogenase in lignocellulosic hydrolysates

Abstract

AbstractSecond generation alcoholic biofuels synthesis from lignocellulosic biomass (LB) consists three steps viz., pre-treatment, detoxification, and fermentation. This dilute acid pre-treatment process generates several compounds like acids, aldehydes, ketones, oxides and their phenolic derivatives that are potential inhibitors of some of the crucial enzymes in the metabolic pathway of ABE fermentation. With application of hybrid quantum mechanics/ molecular mechanics (QM/MM) approach, our aim is to discern the molecular mechanism of inhibition of keyAADsacross solventogenic species. The objectives of present study are: (1) identification and homology modelling of keyAADs; (2) validation, quality assessment and physiochemical characterization of the modelled enzymes; (3) identification, construction and optimization of chemical structure of potent microbial inhibitors in LH; and (4) applications of hybrid QM/MM simulations to profile the molecular interactions between microbial inhibitors and keyAADs. Our computational investigation has revealed various important facets of inhibition of theAADenzymes, which could guide structural biologist in designing efficient and robust enzymes. Moreover, our methodology also provides a general framework which could applied for deciphering the molecular mechanism of inhibition behaviour of other enzymes.HighlightsHomology modelling of 7alcohol/aldehyde dehydrogenase(AAD) in solventogenicClostridiaIdentification and structural optimization of potent microbial inhibitors in lignocellulosic hydrolysatesQM/MM simulations to profile the molecular interactions between 10 inhibitors and 7AADsDiscernment of the molecular mechanism of inhibition of keyalcohol/aldehyde dehydrogenaseA methodological framework for deciphering the molecular mechanism of enzyme inhibition