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Biocatalytic One-Carbon Ring Expansion of Aziridines to Azetidines via a Highly Enantioselective [1,2]-Stevens Rearrangement
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We report enantioselective one-carbon ring expansion of aziridines to make azetidines as a new, abiologcal activity of engineered ‘carbene transferase’ enzymes. A laboratory-evolved variant of cytochrome P450BM3, P411-AzetS, not only overrides the inherent reactivity of aziridinium ylides to undergo cheletropic extrusion of ethylene, it also exerts unparalleled stereocontrol (99:1 er) over a [1,2]-Stevens rearrangement, a notoriously challenging reaction class for asymmetric catalysis. These unprecedented selectivities enable an entirely new strategy for the synthesis of chiral azetidine products from readily available synthetic precursors. The utility of this reaction is highlighted by the synthesis of an enantiopure azetidine on gram scale. The exquisite selectivity of the enzyme enables new-to-nature ring-expansion chemistry that overcomes a longstanding synthetic problem
Title: Biocatalytic One-Carbon Ring Expansion of Aziridines to Azetidines via a Highly Enantioselective [1,2]-Stevens Rearrangement
Description:
We report enantioselective one-carbon ring expansion of aziridines to make azetidines as a new, abiologcal activity of engineered ‘carbene transferase’ enzymes.
A laboratory-evolved variant of cytochrome P450BM3, P411-AzetS, not only overrides the inherent reactivity of aziridinium ylides to undergo cheletropic extrusion of ethylene, it also exerts unparalleled stereocontrol (99:1 er) over a [1,2]-Stevens rearrangement, a notoriously challenging reaction class for asymmetric catalysis.
These unprecedented selectivities enable an entirely new strategy for the synthesis of chiral azetidine products from readily available synthetic precursors.
The utility of this reaction is highlighted by the synthesis of an enantiopure azetidine on gram scale.
The exquisite selectivity of the enzyme enables new-to-nature ring-expansion chemistry that overcomes a longstanding synthetic problem.
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Biocatalytic One-Carbon Ring Expansion of Aziridines to Azetidines via a Highly Enantioselective [1,2]-Stevens Rearrangement
Biocatalytic One-Carbon Ring Expansion of Aziridines to Azetidines via a Highly Enantioselective [1,2]-Stevens Rearrangement
We report enantioselective one-carbon ring expansion of aziridines to make azetidines as a new-to-nature activity of engineered ‘carbene transferase’ enzymes. A laboratory-evolved ...
Biocatalytic One-Carbon Ring Expansion of Aziridines to Azetidines via a Highly Enantioselective [1,2]-Stevens Rearrangement
Biocatalytic One-Carbon Ring Expansion of Aziridines to Azetidines via a Highly Enantioselective [1,2]-Stevens Rearrangement
We report enantioselective one-carbon ring expansion of aziridines to make azetidines as a new, abiologcal activity of engineered ‘carbene transferase’ enzymes. A laboratory-evolve...
Rhodium‐Catalyzed One‐Carbon Ring Expansion of Aziridines with Vinyl‐N‐triftosylhydrazones for the Synthesis of 2‐Vinyl Azetidines
Rhodium‐Catalyzed One‐Carbon Ring Expansion of Aziridines with Vinyl‐N‐triftosylhydrazones for the Synthesis of 2‐Vinyl Azetidines
AbstractAzetidines, being four‐membered N‐heterocycles, possess significant potential in contemporary medicinal chemistry owing to their favorable pharmacokinetic properties. Regre...
Rhodium‐Catalyzed One‐Carbon Ring Expansion of Aziridines with Vinyl‐N‐triftosylhydrazones for the Synthesis of 2‐Vinyl Azetidines
Rhodium‐Catalyzed One‐Carbon Ring Expansion of Aziridines with Vinyl‐N‐triftosylhydrazones for the Synthesis of 2‐Vinyl Azetidines
AbstractAzetidines, being four‐membered N‐heterocycles, possess significant potential in contemporary medicinal chemistry owing to their favorable pharmacokinetic properties. Regre...
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The enantioselective Organocatalytic [1,2]-Rearrangement of Allylic Ammonium Ylides
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