Purification and characterization of a flavin reductase from the biodesulfurizing bacterium Mycobacterium goodii X7B

Functional and structural characterization of a thermostable flavin reductase from Geobacillus mahadii Geo-05

Flavin reductases play a vital role in catalyzing the reduction of flavin through NADH or NADPH oxidation. The gene encoding flavin reductase from the thermophilic bacterium Geobacillus mahadii Geo-05 (GMHpaC) was cloned, overexpressed in Escherichia coli BL21 (DE3) pLysS, and purified to homogeneity. The purified recombinant GMHpaC (Class II) contains chromogenic cofactors, evidenced by maximal absorbance peaks at 370 nm and 460 nm. GMHpaC stands out as the most thermostable and pH-tolerant flavin reductase reported to date, retaining up to 95 % catalytic activity after incubation at 70 °C for 30 min and maintaining over 80 % activity within a pH range of 2-12 for 30 min. Furthermore, GMHpaC's catalytic activity increases by 52 % with FMN as a co-factor compared to FAD and riboflavin. GMHpaC, coupled with 4-hydroxyphenylacetate-3-monooxygenase (GMHpaB) from G. mahadii Geo-05, enhances the hydroxylation of 4-hydroxyphenylacetate (HPA) by 85 %. The modeled structure of GMHpaC reveals relatively conserved flavin and NADH binding sites. Modeling and docking studies shed light on structural features and amino acid substitutions that determine GMHpaC's co-factor specificity. The remarkable thermostability, high catalytic activity, and general stability exhibited by GMHpaC position it as a promising enzyme candidate for various industrial applications.

Functional characterization of a novel flavin reductase from a deep-sea sediment metagenomic library and its application for indirubin production

Microbial synthesis is a desirable approach to produce indirubin but suffers from low synthetic efficiency. Insufficient supply of reduced flavins is one major factor limiting synthetic efficiency. To address this, a novel flavin reductase, MoxB, was discovered through screening of the metagenomic library. MoxB showed a strong preference for NADH over NADPH as the electron source for FMN/FAD reduction and exhibited the highest activity at pH 8.0 and 30°C. It displayed remarkable thermostability by maintaining 80% of full activity after incubation at 60°C for 1 h. Furthermore, MoxB showed great organic solvent tolerance and its activity could be significantly increased by bivalent metal ions. In addition, heterologous expression of the moxB gene in the indirubin-producing E. coli significantly improved indirubin production up to 15.12-fold. This discovery expands the understanding of flavin reductases and provides a promising catalytic tool for microbial indirubin production.IMPORTANCEMuch effort has been exerted to produce indirubin using engineered Escherichia coli, but high-level production has not been achieved so far. Insufficient supply of reduced flavins is one key factor limiting the catalytic efficiency. However, the flavin reductases involved in indirubin biosynthesis have not been hitherto reported. Discovery of the novel flavin reductase MoxB provides a useful tool for enhancing indirubin production by E. coli. Overexpression of MoxB in indirubin-producing E. coli increased indirubin production by 15.12-fold in comparison to the control strain. Our results document the function of flavin reductase that reduces flavins during indirubin biosynthesis and provide an important foundation for using the flavin reductases to improve indirubin production by engineered microorganisms.

Hyperthermophilic flavin reductase from Sulfolobus solfataricus P2: Production and biochemical characterization

Nicotinamide adenine dinucleotide phosphate (NAD(P)H)-flavin oxidoreductases (flavin reductases) catalyze the reduction of flavin by NAD(P)H and provide the reduced form of flavin mononucleotide (FMN) to flavin-dependent monooxygenases. Based on bioinformatics analysis, we identified a putative flavin reductase gene, sso2055, in the genome of hyperthermophilic archaeon Sulfolobus solfataricus P2, and further cloned this target sequence into an expression vector. The cloned flavin reductase (EC. 1.5.1.30) was purified to homogeneity and characterized further. The purified enzyme exists as a monomer of 17.8 kDa, free of chromogenic cofactors. Homology modeling revealed this enzyme as a TIM barrel, which is also supported by circular dichroism measurements revealing a beta-sheet rich content. The optimal pH for SSO2055 activity was pH 6.5 in phosphate buffer and the highest activity observed was at 120 °C within the measurable temperature. We showed that this enzyme can use FMN and flavin adenine dinucleotide (FAD) as a substrate to generate their reduced forms. The purified enzyme is predicted to be a potential flavin reductase of flavin-dependent monooxygenases that could be involved in the biodesulfurization process of S. solfataricus P2.

Cryptic indole hydroxylation by a non-canonical terpenoid cyclase parallels bacterial xenobiotic detoxification

Terpenoid natural products comprise a wide range of molecular architectures that typically result from C–C bond formations catalysed by classical type I/II terpene cyclases. However, the molecular diversity of biologically active terpenoids is substantially increased by fully unrelated, non-canonical terpenoid cyclases. Their evolutionary origin has remained enigmatic. Here we report the in vitro reconstitution of an unusual flavin-dependent bacterial indoloterpenoid cyclase, XiaF, together with a designated flavoenzyme-reductase (XiaP) that mediates a key step in xiamycin biosynthesis. The crystal structure of XiaF with bound FADH₂ (at 2.4 Å resolution) and phylogenetic analyses reveal that XiaF is, surprisingly, most closely related to xenobiotic-degrading enzymes. Biotransformation assays show that XiaF is a designated indole hydroxylase that can be used for the production of indigo and indirubin. We unveil a cryptic hydroxylation step that sets the basis for terpenoid cyclization and suggest that the cyclase has evolved from xenobiotics detoxification enzymes.

The biosynthesis of xiamycin, an antimicrobial bacterial indolosesquiterpenoid, involves an unusual cyclization cascade. Here, the authors characterise the XiaF enzyme, which resembles xenobiont-degrading enzymes and is responsible for a hidden indole hydroxylation step that triggers the cyclization reaction.