Abstract
Carboxylate reductases (CARs, E.C. 1.2.1.30) generate aldehydes from their corresponding carboxylic acid with high selectivity. Little is known about the structure of CARs and their catalytically important amino acid residues. The identification of key residues for carboxylate reduction provides a starting point to gain deeper understanding of enzymatic carboxylate reduction. A multiple sequence alignment of CARs with confirmed activity recently identified in our lab and from the literature revealed a fingerprint of conserved amino acids. We studied the function of conserved residues by multiple sequence alignments and mutational replacements of these residues. In this study, single-site alanine variants of Neurospora crassa CAR were investigated to determine the contribution of conserved residues to the function, expressability or stability of the enzyme. The effect of amino acid replacements was investigated by analyzing enzymatic activity of the variants in vivo and in vitro. Supported by molecular modeling, we interpreted that five of these residues are essential for catalytic activity, or substrate and co-substrate binding. We identified amino acid residues having significant impact on CAR activity. Replacement of His 237, Glu 433, Ser 595, Tyr 844, and Lys 848 by Ala abolish CAR activity, indicating their key role in acid reduction. These results may assist in the functional annotation of CAR coding genes in genomic databases. While some other conserved residues decreased activity or had no significant impact, four residues increased the specific activity of NcCAR variants when replaced by alanine. Finally, we showed that NcCAR wild-type and mutants efficiently reduce aliphatic acids.
Highlights
Aldehydes are widely used as flavors and fragrances (Hagedorn and Kaphammer, 1994; LesageMeessen et al, 1996; Thibault et al, 1998; Kunjapur et al, 2014), chemicals and precursors for pharmaceuticals (Tripathi et al, 1997)
The goal of this study was to identify essential residues for enzymatic carboxylate reduction within these conserved residues to broaden our understanding of carboxylate reductases (E.C. 1.2.1.30) in general, and type III CARs in particular
For the essential post-translational modification, phosphopantetheine transferase (PPTase) from E. coli was co-expressed with NcCAR from one plasmid
Summary
Aldehydes are widely used as flavors and fragrances (Hagedorn and Kaphammer, 1994; LesageMeessen et al, 1996; Thibault et al, 1998; Kunjapur et al, 2014), chemicals and precursors for pharmaceuticals (Tripathi et al, 1997). They are precursors for fatty alcohols, which, in turn, can be used as biofuels (Akhtar et al, 2013), polymer constituents, surfactants, detergents, and cosmetics (Noweck and Grafahrend, 2006). CARs accept a broad range of substrates, while being product-selective (no overreduction of the aldehydes to the respective alcohols), chemo-selective (no reduction of other reducible moieties), and to some degree enantioselective (Napora-Wijata et al, 2014; Qu et al, 2018; Winkler, 2018)
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