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1. Flavin-dependent halogenases catalyze enantioselective olefin halocyclization

   https://doi.org/10.1038/s41467-021-23503-3  

   Mondal, Dibyendu; Fisher, Brian F.; Jiang, Yuhua; Lewis, Jared C. (December 2021, Nature Communications)

   null (Ed.)

   Abstract Halocyclization of alkenes is a powerful bond-forming tool in synthetic organic chemistry and a key step in natural product biosynthesis, but catalyzing halocyclization with high enantioselectivity remains a challenging task. Identifying suitable enzymes that catalyze enantioselective halocyclization of simple olefins would therefore have significant synthetic value. Flavin-dependent halogenases (FDHs) catalyze halogenation of arene and enol(ate) substrates. Herein, we reveal that FDHs engineered to catalyze site-selective aromatic halogenation also catalyze non-native bromolactonization of olefins with high enantioselectivity and near-native catalytic proficiency. Highly selective halocyclization is achieved by characterizing and mitigating the release of HOBr from the FDH active site using a combination of reaction optimization and protein engineering. The structural origins of improvements imparted by mutations responsible for the emergence of halocyclase activity are discussed. This expansion of FDH catalytic activity presages the development of a wide range of biocatalytic halogenation reactions. 

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2. Flexible on-site halogenation paired with hydrogenation using halide electrolysis

   https://doi.org/10.1039/D0GC04362A  

   Shang, Xiao; Liu, Xuan; Sun, Yujie (March 2021, Green Chemistry)

   Direct electrochemical halogenation has appeared as an appealing approach in synthesizing organic halides in which inexpensive inorganic halide sources are employed and electrical power is the sole driving force. However, the intrinsic characteristics of direct electrochemical halogenation limit its reaction scope. Herein, we report an on-site halogenation strategy utilizing halogen gas produced from halide electrolysis while the halogenation reaction takes place in a reactor spatially isolated from the electrochemical cell. Such a flexible approach is able to successfully halogenate substrates bearing oxidatively labile functionalities, which are challenging for direct electrochemical halogenation. In addition, low-polar organic solvents, redox-active metal catalysts, and variable temperature conditions, inconvenient for direct electrochemical reactions, could be readily employed for our on-site halogenation. Hence, a wide range of substrates including arenes, heteroarenes, alkenes, alkynes, and ketones all exhibit excellent halogenation yields. Moreover, the simultaneously generated H 2 at the cathode during halide electrolysis can also be utilized for on-site hydrogenation. Such a strategy of paired halogenation/hydrogenation maximizes the atom economy and energy efficiency of halide electrolysis. Taking advantage of the on-site production of halogen and H 2 gases using portable halide electrolysis but not being suffered from electrolyte separation and restricted reaction conditions, our approach of flexible halogenation coupled with hydrogenation enables green and scalable synthesis of organic halides and value-added products. 

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3. The chloroalkaloid (−)-acutumine is biosynthesized via a Fe(II)- and 2-oxoglutarate-dependent halogenase in Menispermaceae plants

   https://doi.org/10.1038/s41467-020-15777-w  

   Kim, Colin Y.; Mitchell, Andrew J.; Glinkerman, Christopher M.; Li, Fu-Shuang; Pluskal, Tomáš; Weng, Jing-Ke (April 2020, Nature Communications)

   Abstract Plant halogenated natural products are rare and harbor various interesting bioactivities, yet the biochemical basis for the involved halogenation chemistry is unknown. While a handful of Fe(II)- and 2-oxoglutarate-dependent halogenases (2ODHs) have been found to catalyze regioselective halogenation of unactivated C–H bonds in bacteria, they remain uncharacterized in the plant kingdom. Here, we report the discovery of dechloroacutumine halogenase (DAH) from Menispermaceae plants known to produce the tetracyclic chloroalkaloid (−)-acutumine. DAH is a 2ODH of plant origin and catalyzes the terminal chlorination step in the biosynthesis of (−)-acutumine. Phylogenetic analyses reveal that DAH evolved independently in Menispermaceae plants and in bacteria, illustrating an exemplary case of parallel evolution in specialized metabolism across domains of life. We show that at the presence of azide anion, DAH also exhibits promiscuous azidation activity against dechloroacutumine. This study opens avenues for expanding plant chemodiversity through halogenation and azidation biochemistry. 

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4. Repurposing Iron‐ and 2‐Oxoglutarate‐Dependent Oxygenases to Catalyze Olefin Hydration

   https://doi.org/10.1002/anie.202311099  

   Wang, Bingnan; Lu, Yong; Cha, Lide; Chen, Tzu‐Yu; Palacios, Philip M.; Li, Liping; Guo, Yisong; Chang, Wei‐chen; Chen, Chuo (September 2023, Angewandte Chemie International Edition)

   Abstract Mononuclear nonheme iron(II) and 2‐oxoglutarate (Fe/2OG)‐dependent oxygenases and halogenases are known to catalyze a diverse set of oxidative reactions, including hydroxylation, halogenation, epoxidation, and desaturation in primary metabolism and natural product maturation. However, their use in abiotic transformations has mainly been limited to C−H oxidation. Herein, we show that various enzymes of this family, when reconstituted with Fe(II) or Fe(III), can catalyze Mukaiyama hydration—a redox neutral transformation. Distinct from the native reactions of the Fe/2OG enzymes, wherein oxygen atom transfer (OAT) catalyzed by an iron‐oxo species is involved, this nonnative transformation proceeds through a hydrogen atom transfer (HAT) pathway in a 2OG‐independent manner. Additionally, in contrast to conventional inorganic catalysts, wherein a dinuclear iron species is responsible for HAT, the Fe/2OG enzymes exploit a mononuclear iron center to support this reaction. Collectively, our work demonstrates that Fe/2OG enzymes have utility in catalysis beyond the current scope of catalytic oxidation. 

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5. Discovery and Functional Characterization of SnFDHal, an Efficient Tryptophan 5-Halogenase from Streptomyces noursei

   https://doi.org/10.1007/s12010-025-05449-0  

   Sher, Hassan; Hardtke, Haley_A; Gold, Mark_D; Johnson, Sean_J; Zhang, Y_Jessie; Zhan, Jixun (November 2025, Applied Biochemistry and Biotechnology)

   Abstract Flavin-dependent halogenases (FDHs) are a class of enzymes renowned for their regioselective ability to precisely insert halogen atoms into small aromatic compounds. Halogen incorporation can enhance the physicochemical and biological properties of molecules, making them valuable for agrochemical and pharmaceutical applications. Through bioinformatic mining of bacterial genomes, we discovered and functionally characterized SnFDHal, an efficient tryptophan 5-halogenase fromStreptomyces nourseiNRRL B-1714. This halogenase operates across a broad pH range and exhibits a melting temperature of 46.7 °C at both pH 6 and pH 8, which is comparable to thermophilic halogenases such as Th-Hal and BorH, and notably higher than those of mesophilic counterparts. Steady-state kinetic analysis revealed that SnFDHal displays superior catalytic efficiency for the chlorination of L-tryptophan compared to other FDHs reported to date. Structural modeling of its active site suggests that a conserved bulky phenylalanine residue (F49) promotes halogenation at the C-5 position of L-tryptophan, consistent with experimental findings. The combination of high catalytic efficiency and thermostability positions SnFDHal as a promising biocatalyst for applications in agrochemical and pharmaceutical industries. 

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