Direct nitration and azidation of aliphatic carbons by an iron-dependent halogenase

Matthews, Megan L.; Chang, Wei‐chen; Layne, Andrew P.; Miles, Linde A.; Krebs, Carsten; Bollinger, J. Martin

doi:10.1038/nchembio.1438

Cited by 146 publications

(180 citation statements)

References 46 publications

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“…In particular, SyrB2 performs azidation and nitration of tethered L-2-aminobutyrate substrate, using azide and nitrite, respectively (68). On the basis of kinetic and spectroscopic results, a ferryl intermediate is proposed to be responsible for these transformations, similar to the halogenation and hydroxylation transformations (68).…”

Section: Halogenationmentioning

confidence: 99%

Catalytic Mechanisms of Fe(II)- and 2-Oxoglutarate-dependent Oxygenases

Martinez

Hausinger

2015

Journal of Biological Chemistry

379

451

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Section: Halogenationmentioning

confidence: 99%

Catalytic Mechanisms of Fe(II)- and 2-Oxoglutarate-dependent Oxygenases

Martinez

Hausinger

2015

Journal of Biological Chemistry

379

451

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“…Combined with their ability to take on non-natural activities such as direct C–H amination, 24 enzymes represent a versatile platform for catalyst development to solve challenging selectivity problems in organic chemistry.…”

mentioning

confidence: 99%

Enzyme-Controlled Nitrogen-Atom Transfer Enables Regiodivergent C–H Amination

et al. 2014

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We recently demonstrated that variants of cytochrome P450BM3 (CYP102A1) catalyze the insertion of nitrogen species into benzylic C–H bonds to form new C–N bonds. An outstanding challenge in the field of C–H amination is catalyst-controlled regioselectivity. Here, we report two engineered variants of P450BM3 that provide divergent regioselectivity for C–H amination—one favoring amination of benzylic C–H bonds and the other favoring homo-benzylic C–H bonds. The two variants provide nearly identical kinetic isotope effect values (2.8–3.0), suggesting that C–H abstraction is rate-limiting. The 2.66-Å crystal structure of the most active enzyme suggests that the engineered active site can preorganize the substrate for reactivity. We hypothesize that the enzyme controls regioselectivity through localization of a single C–H bond close to the iron nitrenoid.

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“…The Arnold group applied related logic to engineer P450s that promote carbene insertions into N–H bonds and to develop a C-H amination reaction using sulfonyl azide substrates [41•,42]. Most recently, this general approach has been extended beyond P450s with the report of C–N bond-forming reactions promoted by wild-type and engineered variants of the non-heme iron(II)-dependent halogenase SyrB2 in the presence of both azide and nitrite anions [43•]. …”

Section: Engineering Enzymes To Display Non-biological Reactivity In mentioning

confidence: 99%

Opportunities for merging chemical and biological synthesis

Wallace

Balskus

2014

Current Opinion in Biotechnology

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Organic chemists and metabolic engineers use largely orthogonal technologies to access small molecules like pharmaceuticals and commodity chemicals. As the use of biological catalysts and engineered organisms for chemical production grows, it is becoming increasingly evident that future efforts for chemical manufacture will benefit from the integration and unified expansion of these two fields. This review will discuss approaches that combine chemical and biological synthesis for small molecule production. We highlight recent advances in combining enzymatic and non-enzymatic catalysis in vitro, discuss the application of design principles from organic chemistry for engineering non-biological reactivity into enzymes, and describe the development of biocompatible chemistry that can be interfaced with microbial metabolism.

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Direct nitration and azidation of aliphatic carbons by an iron-dependent halogenase

Cited by 146 publications

References 46 publications

Catalytic Mechanisms of Fe(II)- and 2-Oxoglutarate-dependent Oxygenases

Catalytic Mechanisms of Fe(II)- and 2-Oxoglutarate-dependent Oxygenases

Enzyme-Controlled Nitrogen-Atom Transfer Enables Regiodivergent C–H Amination

Opportunities for merging chemical and biological synthesis

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