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1. Engineering of Rieske dioxygenase variants with improved cis ‐dihydroxylation activity for benzoates

   https://doi.org/10.1002/bit.28786  

   Betts, Phillip C; Blakely, Spencer J; Rutkowski, Bailey N; Bender, Brandon; Klingler, Cole; Froese, Jordan T (October 2024, Biotechnology and Bioengineering)

   Abstract Rieske dioxygenases have a long history of being utilized as green chemical tools in the organic synthesis of high‐value compounds, due to their capacity to perform thecis‐dihydroxylation of a wide variety of aromatic substrates. The practical utility of these enzymes has been hampered however by steric and electronic constraints on their substrate scopes, resulting in limited reactivity with certain substrate classes. Herein, we report the engineering of a widely used member of the Rieske dioxygenase class of enzymes, toluene dioxygenase (TDO), to produce improved variants with greatly increased activity for thecis‐dihydroxylation of benzoates. Through rational mutagenesis and screening, TDO variants with substantially improved activity over the wild‐type enzyme were identified. Homology modeling, docking studies, molecular dynamics simulations, and substrate tunnel analysis were applied in an effort to elucidate how the identified mutations resulted in improved activity for this polar substrate class. These analyses revealed modification of the substrate tunnel as the likely cause of the improved activity observed with the best‐performing enzyme variants. 

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2. A High‐Throughput in Vitro Assay System for the Detection of the Enzymatic Dihydroxylation of Aliphatic Olefins

   https://doi.org/10.1002/adsc.202400656  

   Rutkowski, Bailey_N; Talley, Ella_R; Combs, Jasney; Froese, Jordan_T (September 2024, Advanced Synthesis & Catalysis)

   Abstract Rieske dioxygenase enzymes can perform thecis‐dihydroxylation of aliphatic olefins, representing a potential green alternative to established methods of performing this important transformation. However, the activity of the natural enzymes in this context is low relative to their more well‐known activity in thecis‐dihydroxylation of aromatics. To enable the engineering of dioxygenase enzymes for improved activity in the dihydroxylation of aliphatic olefins, we have developed an assay system to detect the relevant diol metabolites produced from whole‐cell fermentation cultures. Optimization studies were carried out to maximize the sensitivity of the assay system, and its utility in thein vitroscreening of enzyme variant libraries was demonstrated. The assay system was utilized in screening studies that identified Rieske dioxygenase variants with significantly improved activity in the dihydroxylation of aliphatic olefins relative to the wild‐type enzyme. 

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3. Understanding and Improving the Activity of Flavin-Dependent Halogenases via Random and Targeted Mutagenesis

   https://doi.org/10.1146/annurev-biochem-062917-012042  

   Andorfer, Mary C.; Lewis, Jared C. (June 2018, Annual Review of Biochemistry)

   Flavin-dependent halogenases (FDHs) catalyze the halogenation of organic substrates by coordinating reactions of reduced flavin, molecular oxygen, and chloride. Targeted and random mutagenesis of these enzymes have been used to both understand and alter their reactivity. These studies have led to insights into residues essential for catalysis and FDH variants with improved stability, expanded substrate scope, and altered site selectivity. Mutations throughout FDH structures have contributed to all of these advances. More recent studies have sought to rationalize the impact of these mutations on FDH function and to identify new FDHs to deepen our understanding of this enzyme class and to expand their utility for biocatalytic applications. 

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4. Spectroscopy and crystallography define carotenoid oxygenases as a new subclass of mononuclear non-heme FeII enzymes

   https://doi.org/10.1016/j.jbc.2025.108444  

   DeWeese, Dory E; Everett, Michael P; Babicz, Jeffrey T; Daruwalla, Anahita; Solomon, Edward I; Kiser, Philip D (March 2025, Journal of Biological Chemistry)

   NA (Ed.)

   Carotenoid cleavage dioxygenases (CCDs) are non-heme FeII enzymes that catalyze the oxidative cleavage of alkene bonds in carotenoids, stilbenoids, and related compounds. How these enzymes control the reaction of O2 with their alkene substrates is unclear. Here, we apply spectroscopy in conjunction with X-ray crystallography to define the iron coordination geometry of a model CCD, CAO1, in its resting state and following substrate binding and coordination sphere substitutions. Resting CAO1 exhibits a five-coordinate (5C), square pyramidal FeII center that undergoes steric distortion towards a trigonal bipyramidal geometry in the presence of piceatannol. Titrations with the O2-analog, nitric oxide (NO), show a >100-fold increase in iron-NO affinity upon substrate binding, defining a crucial role for the substrate in activating the FeII site for O2 reactivity. The importance of the 5C FeII structure for reactivity was probed through mutagenesis of the second-sphere Thr151 residue of CAO1, which occludes ligand binding at the sixth coordination position. A T151G substitution resulted in the conversion of the iron center to a six-coordinate (6C) state and a 135-fold reduction in apparent catalytic efficiency towards piceatannol compared to the wild-type enzyme. Substrate complexation resulted in partial 6C to 5C conversion, indicating solvent dissociation from the iron center. Additional substitutions at this site demonstrated a general functional importance of the occluding residue within the CCD superfamily. Taken together, these data suggest an ordered mechanism of CCD catalysis occurring via substrate-promoted solvent replacement by O2. CCDs thus represent a new class of mononuclear non-heme FeII enzymes. 

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5. Charge Maintenance during Catalysis in Nonheme Iron Oxygenases

   https://doi.org/10.1021/acscatal.1c04770  

   Traore, Ephrahime S.; Liu, Aimin (April 2022, ACS Catalysis)

   Pimchai Chaiyen (Ed.)

   Here, the choice of the first coordination shell of the metal center is analyzed from the perspective of charge maintenance in a binary enzyme–substrate complex and an O2-bound ternary complex in the nonheme iron oxygenases. Comparing homogentisate 1,2-dioxygenase and gentisate dioxygenase highlights the significance of charge maintenance after substrate binding as an important factor that drives the reaction coordinate. We then extend the charge analysis to several common types of nonheme iron oxygenases containing either a 2-His-1-carboxylate facial triad or a 3-His or 4-His ligand motif, including extradiol and intradiol ring-cleavage dioxygenases, thiol dioxygenases, α-ketoglutarate-dependent oxygenases, and carotenoid cleavage oxygenases. After forming the productive enzyme–substrate complex, the overall charge of the iron complex at the 0, +1, or +2 state is maintained in the remaining catalytic steps. Hence, maintaining a constant charge is crucial to promote the reaction of the iron center beginning from the formation of the Michaelis or ternary complex. The charge compensation to the iron ion is tuned not only by protein-derived carboxylate ligands but also by substrates. Overall, these analyses indicate that charge maintenance at the iron center is significant when all the necessary components form a productive complex. This charge maintenance concept may apply to most oxygen-activating metalloenzymes systems that do not draw electrons and protons step-by-step from a separate reactant, such as NADH, via a reductase. The charge maintenance perception may also be useful in proposing catalytic pathways or designing prototypical reactions using artificial or engineered enzymes for biotechnological applications. 

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