Comparative structural modeling of six old yellow enzymes (OYEs) from the necrotrophic fungus Ascochyta rabiei: insight into novel OYE classes with differences in cofactor binding, organization of active site residues and stereopreferences.

Shadab Nizam,Valerie de Crécy-Lagard,Sandhya Verma,Rajesh Kumar Gazara,Kunal Singh,Praveen Kumar Verma

doi:10.1371/journal.pone.0095989

Shadab Nizam, Valerie de Crécy-Lagard + Show 4 more

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https://doi.org/10.1371/journal.pone.0095989

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Journal: PloS one	Publication Date: Apr 28, 2014
Citations: 22	License type: CC BY 4.0

Affiliation: National Institute of Plant Genome Research

Abstract

Old Yellow Enzyme (OYE1) was the first flavin-dependent enzyme identified and characterized in detail by the entire range of physical techniques. Irrespective of this scrutiny, true physiological role of the enzyme remains a mystery. In a recent study, we systematically identified OYE proteins from various fungi and classified them into three classes viz. Class I, II and III. However, there is no information about the structural organization of Class III OYEs, eukaryotic Class II OYEs and Class I OYEs of filamentous fungi. Ascochyta rabiei, a filamentous phytopathogen which causes Ascochyta blight (AB) in chickpea possesses six OYEs (ArOYE1-6) belonging to the three OYE classes. Here we carried out comparative homology modeling of six ArOYEs representing all the three classes to get an in depth idea of structural and functional aspects of fungal OYEs. The predicted 3D structures of A. rabiei OYEs were refined and evaluated using various validation tools for their structural integrity. Analysis of FMN binding environment of Class III OYE revealed novel residues involved in interaction. The ligand para-hydroxybenzaldehyde (PHB) was docked into the active site of the enzymes and interacting residues were analyzed. We observed a unique active site organization of Class III OYE in comparison to Class I and II OYEs. Subsequently, analysis of stereopreference through structural features of ArOYEs was carried out, suggesting differences in R/S selectivity of these proteins. Therefore, our comparative modeling study provides insights into the FMN binding, active site organization and stereopreference of different classes of ArOYEs and indicates towards functional differences of these enzymes. This study provides the basis for future investigations towards the biochemical and functional characterization of these enigmatic enzymes.

Highlights

Old Yellow Enzyme (OYE1) was initially isolated from the yeast Saccharomyces pastorianus by Warburg & Christian (1933) [1]
Combinations of site-directed mutagenesis (SDM) and crystal structure studies have characterized the active site residues of OYE1 (OYE from S. pastorianus), which are well conserved across similar Old Yellow Enzymes (OYEs) proteins
In order to gain some insight regarding the physiological function of OYEs in fungi, a comprehensive genome-wide identification of OYE proteins was carried out in 60 fungal species [32]

Summary

Introduction

Old Yellow Enzyme (OYE1) was initially isolated from the yeast Saccharomyces pastorianus by Warburg & Christian (1933) [1]. Numerous metabolic functions for OYE homologs have been suggested including degradation of nitrate ester explosives in bacteria [11,12,13], oxidative stress response in yeasts [14,15,16], jasmonic acid biosynthesis in plants [17], and ergot alkaloid biosynthesis in filamentous fungi Aspergillus fumigatus and Claviceps purpuria [18]. Biochemical characterizations of OYEs have revealed their potential to catalyze the stereoselective reduction of activated C = C bonds of structurally diverse a,bunsaturated compounds [19]. These optically active reduced products include many commercially useful substrates for industrial applications [20]. From the last few years, OYEs are being investigated as biocatalysts for the affordable production of a variety of biotechnological and pharmaceutical compounds

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