Asymmetric Epoxidation Research Articles

A highly efficient chemoenzymatic process to produce (R)-6,7-dihydroxygeraniol

The efficient asymmetric dihydroxylation of 6,7-epoxygeraniol was performed using a chemoenzymatic process employing a yeast epoxide hydrolase (EH) resolution stereoinversion step, followed by stereoretentive chemical hydrolysis of the remaining epoxide to produce (6 R)-6,7-dihydroxygeraniol at unprecedented high enantiometic excess (ee) (>97.5%) and high isolated yield (72 mol % overall yield over 5 steps from commercially available geraniol). The enzymatic process was completed within 2 h at 250 g/L substrate loading reaching > 49.5 mass % conversion of the racemic epoxide. The reaction was self-limiting and furnished both the homochiral (6 R)-triol and the residual (6 R)-epoxide at > 99% ee, due to enantio-inversion of the (6S)-epoxide. The (6 R)-epoxide was subsequently chemically hydrolysed, without first needing to separate the epoxide and triol products, to afford the desired (6 R)-triol product in >97.5% ee, at multigram scale. This chemoenzymatic procedure offers an excellent alternative to chemical asymmetric epoxidation or dihydroxylation for the production of enantiopure 6,7-dihydroxygeranyl and 6,7-epoxygeranyl type compounds in general. It exemplifies the benefits of using greener EH bioprocesses to produce such compounds in high ee’s and high isolated yields.

Total Synthesis of the Phenylnaphthacenoid Type II Polyketide Antibiotic Formicamycin H via Regioselective Ruthenium-Catalyzed Hydrogen Auto-Transfer [4 + 2] Cycloaddition.

The first total synthesis of the pentacyclic phenylnaphthacenoid type II polyketide antibiotic formicamycin H is described. A key feature of the synthesis involves the convergent, regioselective assembly of the tetracyclic core via ruthenium-catalyzed α-ketol-benzocyclobutenone [4 + 2] cycloaddition. Double dehydration of the diol-containing cycloadduct provides an achiral enone, which upon asymmetric nucleophilic epoxidation and further manipulations delivers the penultimate tetracyclic trichloride in enantiomerically enriched form. Subsequent chemo- and atroposelective Suzuki cross-coupling of the tetracyclic trichloride introduces the E-ring to complete the total synthesis. Single-crystal X-ray diffraction analyses of two model compounds suggest that the initially assigned stereochemistry of the axially chiral C6-C7 linkage may require revision.

Conformational Analysis and Organocatalytic Activity of Helical Stapled Peptides Containing α-Carbocyclic α,α-Disubstituted α-Amino Acids.

Conformational freedom-restricted peptides, such as stapled peptides, play a crucial role in the advancement of functional peptide development. We synthesized stapled octapeptides using α-carbocyclic α,α-disubstituted α-amino acids, particularly 3-allyloxy-1-aminocyclopentane-1-carboxylic acid, as the crosslink motifs. The organocatalytic capabilities of the synthesized stapled peptides were assessed in an asymmetric nucleophilic epoxidation reaction because the catalytic activities are known to be proportional to α-helicity. Despite incorporating side-chain crosslinks, the enantioselectivities of the epoxidation reaction catalyzed by stapled octapeptides were found to be comparable to those obtained using unstapled peptides. Interestingly, the stapled peptides using α-carbocyclic α,α-disubstituted α-amino acids demonstrated higher reactivities and stereoselectivities (up to 99% ee) compared to stapled peptides derived from (S)-α-(4-pentenyl)alanine, a commonly used motif for stapled peptides. These differences could be attributed to the increased α-helicity of the former stapled peptide in contrast to the latter, as evidenced by the X-ray crystallographic structures of their N-tert-butoxycarbonyl derivatives.

Stereocomplementary Unspecific Peroxygenases for Asymmetric Anti-Markovnikov Wacker-Type Oxidation and Epoxidation of Styrenes

Stereocomplementary Unspecific Peroxygenases for Asymmetric Anti-Markovnikov Wacker-Type Oxidation and Epoxidation of Styrenes

Chiral phosphoric acid-catalyzed asymmetric epoxidation of alkenyl aza-heteroarenes using hydrogen peroxide

The synthesis of chiral α-azaheteroaryl oxiranes via enantioselective catalysis is a formidable challenge due to the required complex stereoselectivity and diverse N-heterocyclic structures. These compounds play a crucial role in developing bioactive molecules, where precise chirality significantly influences biological activity. Here we show that using chiral phosphoric acid as a catalyst, our method efficiently addresses these challenges. This technique not only achieves high enantio- and diastereoselectivity but also demonstrates superior chemo- and stereocontrol during the epoxidation of alkenyl aza-heteroarenes. Our approach leverages a synergistic blend of electrostatic and hydrogen-bonding interactions, enabling the effective activation of both substrates and hydrogen peroxide. The resulting chiral oxiranes exhibit enhanced diversity and functionality, aiding the construction of complex chiral azaaryl compounds with contiguous stereocenters. Kinetic and density functional theory studies elucidate the mechanism, highlighting chiral phosphoric acid’s pivotal role in this intricate enantioselective process.

Thermostabilization and molecular dynamics simulation of NaStyA for highly enantioselective (R)-epoxidation of styrene analogues

Chiral epoxides are one of the most versatile building blocks in organic synthesis, but the asymmetric epoxidation of unfunctionalized terminal olefins remains a challenge. NaStyA is a styrene monooxygenase from Nocardia altamirensis that functions as an enantioselective epoxygenase for terminal olefins. To improve its robustness, we investigated over 50 mutants designed via evolutionary- and energy-based approaches, and successfully identified 18 beneficial mutations, which then led to a combinatorial mutant of TM18 with drastically enhanced thermostability and solvent tolerance while retaining excellent activity and enantioselectivity. Its turnover frequency and half-life at 50 °C were increased to 5- and 148-fold of the parental. In the epoxidation of terminal olefins, TM18 achieved high product yields of over 4-fold of the parental, and excellent enantiomeric excess of 99 % to >99 % ee. The analysis of trajectory data from molecular dynamics simulations further validated that the mutations in TM18 increased its local rigidity, as inferred by RMSF and PCA analyses and through novel salt bridges formation. Furthermore, TM18 displayed reduced residue cross-correlation motions. The combined effects of these mutations result in an overall improvement in the structural and dynamic thermostability of TM18.

Enantioselective Synthesis of Antifungal Agent Voriconazole via Asymmetric Epoxidation of Tetrasubstituted (Z)‐Alkene

AbstractA concise asymmetric synthesis of triazole antifungal agent voriconazole is described. Salient features of this synthesis include a LiOH‐controlled highly stereospecific formation of (Z)‐enol triflate from 2‐difluorobenzene acetoacetate to access the crucial tetrasubstituted (Z)‐allylic alcohol, and a highly enantioselective VO(OiPr)3/BHA ligand‐catalyzed epoxidation to construct the critical contiguous carbon stereocenters in a single step.

Asymmetric Synthesis of Three Alkenyl Epoxides: Crafting the Sex Pheromones of the Elm Spanworm and the Painted Apple Moth.

A concise synthesis of the sex pheromones of elm spanworm as well as painted apple moth has been achieved. The key steps were the alkylation of acetylide ion, Sharpless asymmetric epoxidation and Brown's P2-Ni reduction. This approach provided the sex pheromone of the elm spanworm (1) in 31% total yield and those of the painted apple moth (2, 3) in 26% and 32% total yields. The ee values of three final products were up to 99%. The synthesized pheromones hold promising potential for use in the management and control of these pests.

Asymmetric Additions Empowered by OrganoCatalysts, Metal Catalysts, and Deep Natural Eutectic Solvents (NADES).

This article is a history of an industrial-academic partnership that started almost two decades ago and details the evolution of a relationship between a small academic research group and a spin-out company located in Portugal. Their activities have ranged from the development of new metal-based catalytic systems for asymmetric epoxidations, allylic alkylations, and arylations to the development of novel cinchona-based organocatalysts for asymmetric hydrosilylations and Michael additions. Current common interests are centered on the development of novel chiral Natural Deep Eutectic Solvent systems, which they are investigating in different types of reaction systems.

Deciphering the Absolute Configuration of Murgantiol Isomers in the Pheromone Blend of the Rice Stink Bug, Mormidea v-luteum (Hemiptera, Pentatomidae).

The males-produced pheromone blend of the Mormidea v-luteum (Hemiptera, Pentatomidae) consists in two isomers of zingiberenol (1) and three of murgantiol (2). While the absolute configuration of the zingiberenol isomers has been described, the configurations of the murgantiol isomers remained unexplored. So, our objective was to identify the absolute configuration of the murgantiol isomers (2 a-c) in the pheromone blend. To achieve this, we initially performed dehydration of the natural extract followed by enantiomeric resolution and, as a result, the three isomers was identified as (4R,1'S)-murgantiol. By leveraging the fixed cis and trans relationships among all pheromone components, we established the configuration at C-1 for isomers 2 a and 2 b is S, while that of 2 c is R. Finally, employing microchemical Sharples asymmetric dihydroxylation and epoxide ring closure, we determined the absolute configuration of the epoxide ring. Consequently, the natural isomers 2 a, 2 b, and 2 c were identified as (1S,4R,1'S,4'R)-, (1S,4R,1'S,4'S)-, and (1R,4R,1'S,4'S)-murgantiol, respectively.

Trifluoromethyl Ketone Galactose Catalyst for Asymmetric Epoxidation: Experimental and Theoretical Model

AbstractSince the introduction of the Shi catalyst, the organocatalytic epoxidation of olefins has become an area of continued research interest. To explore the possibility of enhancing the efficiency and stability of the catalyst, the synthesis of a galactose‐derived trifluoromethyl ketone, and its use for stereoselective epoxidation reaction that exploits a transitory dioxirane as active species are herein reported. The trifluoromethyl ketone was built on the C6 of a protected d‐galactopyranose. The organocatalyst was obtained smoothly in a few steps, and when utilized for stereoselective epoxidation exhibited excellent stability as no chemical alterations were observed during the reaction. The stereoselectivity, although sometimes moderate, appears surprisingly high considering the conformational freedom of the trifluoromethyl ketone moiety.DFT calculations were performed to investigate the interactions involved in regulating the observed selectivities. Moreover, a new mnemonic model has been developed to serve as a fast‐predicting tool for epoxidation of new substrates.

Stereoselective Shi-type epoxidation with 3-oxo-4,6-O-benzylidene pyranoside catalysts: unveiling the role of carbohydrate skeletons.

Asymmetric epoxidation represents a hot topic in organic synthesis. In recent years, organocatalysts based on sugar skeletons have been exploited in asymmetric epoxidation to achieve enantiomeric pure epoxides. In this work, two different endocyclic ketones derived from glucose and galactose protected with a 4,6-O-benzylidene group have been prepared and exploited for Shi-type epoxidation. The two carbohydrates show an opposite preferential stereoselective epoxidation on various olefins, affording the epoxides in high conversions and modest enantioselectivities. DFT calculations disclosed the reasons behind the inversion of selectivity achieved by the two catalysts, showing that a delicate balance between the catalyst conformation, its protecting groups, and the secondary interactions with the substrate govern the final observed results.

Chiral imidazolium and triazolium salts as NHC and aNHC ligand precursors: A promising framework for asymmetric epoxidation catalysis

Two chiral imidazolium salts and one chiral triazolium salt were synthesized containing a chiral cyclohexane bridge based on the salen ligand framework of the Jacobsen-Katsuki epoxidation catalysts. They are promising NHC and aNHC ligand precursors for asymmetric epoxidation or C–H oxidation catalyzed by organometallic compounds. The ligand framework offers plenty of opportunities for modification.

Asymmetric Epoxidation vs syn-Hydroxy-Acyloxylation of Olefins in the Presence of Sterically Demanding Nonheme Manganese Complexes

Asymmetric Epoxidation vs <i>syn</i>-Hydroxy-Acyloxylation of Olefins in the Presence of Sterically Demanding Nonheme Manganese Complexes

A Lewis Acid-Controlled Enantiodivergent Epoxidation of Aldehydes.

Two epoxidation catalysts, one of which consists of two VANOL ligands and an aluminum and the other that consists of two VANOL ligands and a boron, were compared. Both catalysts are highly effective in the catalytic asymmetric epoxidation of a variety of aromatic and aliphatic aldehydes with diazoacetamides, giving high yields and excellent asymmetric inductions. The aluminum catalyst is effective at 0 °C and the boron catalyst at -40 °C. Although both the aluminum and boron catalysts of (R)-VANOL give very high asymmetric inductions (up to 99% ee), they give opposite enantiomers of the epoxide. The mechanism, rate- and enantioselectivity-determining step, and origin of enantiodivergence are evaluated using density functional theory calculations.

Synthesis of Novel C 2 Bishydroxamic Acid Ligands and their Application in Asymmetric Epoxidation Reactions

AbstractAsymmetric oxidation reactions have significantly benefited from bishydroxamic Brønsted acid ligands, and they can proceed with remarkable stereoselectivity. Designing and synthesizing these ligands are essential for achieving high enantioselectivity in metal-catalyzed oxidation reactions. This paper presents a straightforward method for synthesizing novel phenyl-ring-centric bishydroxamic acids (BHA). A preliminary analysis of Ti-BHA-catalyzed reactions resulted in asymmetric epoxides with an exceptional enantiomeric excess (&gt;99% ee). At the same time, ongoing experiments aim to improve the reaction conversion for enhanced overall efficiency.

Scalable, Stereocontrolled, Total Synthesis of Carolacton

AbstractA route for the scalable, stereocontrolled, total synthesis of carolacton is presented starting from commercially available S-Roche ester, d-ribose, and a known allylic alcohol. Key transformations in the total synthesis include a [3,3]-Claisen rearrangement, Sharpless asymmetric epoxidation–methyl ring-opening, or Leighton asymmetric crotylation, Evans aldol–reductive deoxygenation, and ring closing metathesis (RCM). The total synthesis of carolacton (151 mg isolated, 9.2% overall yield) was completed in 23 linear steps. Additionally, 56 mg of the carolacton C15–C16 cis-olefin isomer was obtained.

Titanium Salalen Catalyzed Enantioselective Benzylic Hydroxylation

AbstractThe titanium complex of the cis‐1,2‐diaminocyclohexane (cis‐DACH) derived Berkessel‐salalen ligand is a highly efficient and enantioselective catalyst for the asymmetric epoxidation of terminal olefins with hydrogen peroxide (“Berkessel‐Katsuki catalyst”). We herein report that this epoxidation catalyst also effects the highly enantioselective hydroxylation of benzylic C−H bonds with hydrogen peroxide. Mechanism‐based ligand optimization identified a novel nitro‐salalen Ti‐catalyst of the highest efficiency ever reported for asymmetric catalytic benzylic hydroxylation, with enantioselectivities of up to 98 % ee, while overoxidation to ketone is marginal. The novel nitro‐salalen Ti‐catalyst also shows enhanced epoxidation efficiency, as evidenced by e.g. the conversion of 1‐decene to its epoxide in 90 % yield with 94 % ee, at a catalyst loading of 0.1 mol‐% only.

Titanium Salalen Catalyzed Enantioselective Benzylic Hydroxylation.

The titanium complex of the cis-1,2-diaminocyclohexane (cis-DACH) derived Berkessel-salalen ligand is a highly efficient and enantioselective catalyst for the asymmetric epoxidation of terminal olefins with hydrogen peroxide ("Berkessel-Katsuki catalyst"). We herein report that this epoxidation catalyst also effects the highly enantioselective hydroxylation of benzylic C-H bonds with hydrogen peroxide. Mechanism-based ligand optimization identified a novel nitro-salalen Ti-catalyst of the highest efficiency ever reported for asymmetric catalytic benzylic hydroxylation, with enantioselectivities of up to 98 % ee, while overoxidation to ketone is marginal. The novel nitro-salalen Ti-catalyst also shows enhanced epoxidation efficiency, as evidenced by e.g. the conversion of 1-decene to its epoxide in 90 % yield with 94 % ee, at a catalyst loading of 0.1 mol-% only.

Asymmetric Epoxidation of Alkenes Catalyzed by a Cobalt Complex.

Asymmetric epoxidation of alkenes catalyzed by nonheme chiral Mn-O and Fe-O catalysts has been well established, but chiral Co-O catalysts for the purpose remain virtually undeveloped due to the oxo wall. Herein is first reported a chiral cobalt complex to realize the enantioselective epoxidation of cyclic and acyclic trisubstituted alkenes by using PhIO as the oxidant in acetone, wherein the tetra-oxygen-based chiral N,N'-dioxide with sterically hindered amide subunits plays a crucial role in supporting the formation of the Co-O intermediate and enantioselective electrophilic oxygen transfer. Mechanistic studies, including HRMS measurements, UV-vis absorption spectroscopy, magnetic susceptibility, as well as DFT calculations, were carried out, confirming the formation of Co-O species as a quartet Co(III)-oxyl tautomer. The mechanism and the origin of enantioselectivity were also elucidated based on control experiments, nonlinear effects, kinetic studies, and DFT calculations.