Preparation of chiral isoxazole carbinols via catalytic asymmetric Corey-Bakshi-Shibata reduction.

Rider, Kevin C.; Burkhart, David J.; Li, Chun; McKenzie, Andrew R.; Nelson, Jared K.; Natale, Nicholas R.

doi:10.3998/ark.5550190.0011.809

Cited by 4 publications

(4 citation statements)

References 15 publications

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“…A second potential use for unsymmetrically halogenated AIMs was suggested during our consideration of the plausible metabolic fates of the anthracene. One of our planned roles for the isoxazoles was to direct Cyp3A4 metabolism away from potentially toxic metabolites at the anthracene ring, and both prior models in the literature [11] and Smart-Cyp density function computations [12] suggest that hydroxylation at the C-5 alkyl group of the isoxazole is a reasonable route; however, the docking of the alkoxy AIM shown presents the side of the anthracene directly over the heme of the Cyp [13] (Figure 3B). We decided that we should anticipate this by using the tactic of blocking the position with a halogen, and a bromine could provide either a metabolism blocking effect intrinsically (as in Vandetanib [14]) or serve as a precursor to the strategically positioned fluorine [15,16]. )…”

Section: Ic50 µM (Sdmentioning

confidence: 99%

Synthesis and Structure of Unsymmetrical Anthracenyl-Isoxazole Antitumor Agents Via the Diastereoselective Bromination of 3-(9′-Anthryl)-Isoxazole Esters

Campbell,

Decato,

et al. 2024

Crystals

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In pursuit of unsymmetrical precursors for the novel series of anthracenyl-isoxazole amide (AIM) antitumor agents, a series of substituted anthracenes were subjected to bromination and re-aromatization in our study, during which we solved four single crystal X-ray diffractometry (Sc-xrd) structures which we report herein. The C-9 nitrile oxide, after its reaction with bromine, was isolated, but when subjected to re-aromatization, it returned to the starting 10-bromo nitrile oxide 1, which did provide an accurate crystal structure, with R = 0.018. The 10-halogenated 3-(9’-anthryl)-isoxazole esters were subjected to bromination and re-aromatization. Surprisingly, the yields obtained in the presence of the isoxazole were reasonably good (62–68% isolated yields), and the major diastereomers allowed for the characterization using Sc-xrd. The penta bromo product 2 showed a trans, trans, cis relationship for the four bromines on the A-ring of the anthracene, and we observed that for the unit cell, the atropisomers displayed a 1:1 ratio at the chiral axis between the isoxazole and anthrancene rings. Similarly, the 10-chloro 3 indicated a ratio of 1:1 at the chiral axis in the crystal structure. A base-induced re-aromatization afforded 3,10-dihalogenated analogues selectively in very good yields (X = Cl, 89%; X = Br 92%), of which the dibromo 4 was characterized using Sc-xrd. The improved yields of the unique diastereomeric bromination products suggested the consideration of a novel electrophilic aromatic substitution mechanism driven by the stereo-electronic environment, imposed by the isoxazole ester substituent. The promise of the application of this chemistry in the future development of AIM antitumor agents is suggested.

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Section: Ic50 µM (Sdmentioning

confidence: 99%

Synthesis and Structure of Unsymmetrical Anthracenyl-Isoxazole Antitumor Agents Via the Diastereoselective Bromination of 3-(9′-Anthryl)-Isoxazole Esters

Campbell,

Decato,

et al. 2024

Crystals

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“…Usually, anthracenes are oxidized in vivo predominantly by cytochrome P450, leading to a potentially toxic arene oxide (Silverman et al, 2014). The rationale for the isoxazole series is that the C-5 isoxazole methyl group represents an opportunity for safer metabolism (Natale et al, 2010). The observation in this manuscript suggests that intramolecular dioxygenation, which would likely be mediated in vivo by mono amine oxidase (MAO), is another plausible route (Silverman, 2002).…”

Section: Chemical Contextmentioning

confidence: 99%

Syntheses and crystal structures of a nitro–anthracene–isoxazole and its oxidation product

Weaver

Campbell

et al. 2022

Acta Cryst E

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The syntheses and structures of an unexpected by-product from an iodination reaction, namely, ethyl 5-methyl-3-(10-nitroanthracen-9-yl)isoxazole-4-carboxylate, C21H16N2O5, (I), and its oxidation product, ethyl 3-(9-hydroxy-10-oxo-9,10-dihydroanthracen-9-yl)-5-methylisoxazole-4-carboxylate, C21H17NO5 (V) are described. Compound (I) crystallizes with two molecules in the asymmetric unit in which the dihedral angles between the anthracene fused-ring systems and isoxazole ring mean planes are 88.67 (16) and 85.64 (16)°; both molecules feature a disordered nitro group. In (V), which crystallizes with one molecule in the asymmetric unit, the equivalent dihedral angle between the almost planar anthrone ring system (r.m.s. deviation = 0.029 Å) and the pendant isoxazole ring is 89.65 (5)°. In the crystal of (I), the molecules are linked by weak C—H...O interactions into a three-dimensional network and in the extended structure of (V), inversion dimers linked by pairwise O—H...O hydrogen bonds generate R 2 2(14) loops.

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“…The CBS reduction of prochiral ketones has been widely employed in organic syntheses due to their generally high enantioselectivity and broad substrate scope using, e.g., lactones, alkaloids, and steroids. 3−5 For instance, it has been employed in the preparation of chiral isoxazole carbinols, 6 the synthesis of (R)-phenylephrine, 7 as well as the enantioselective syntheses of massadine, 8 FR901464, and spliceostatin A. 9 The lessons learned from such a challenging transformation could potentially be applied to other instances.…”

Section: ■ Introductionmentioning

confidence: 99%

“…This catalyst coordinates to borane (BH 3 ), the reducing agent, and together, they facilitate the reduction of the ketone in an enantioselective manner. The CBS reduction of prochiral ketones has been widely employed in organic syntheses due to their generally high enantioselectivity and broad substrate scope using, e.g., lactones, alkaloids, and steroids. − For instance, it has been employed in the preparation of chiral isoxazole carbinols, the synthesis of ( R )-phenylephrine, as well as the enantioselective syntheses of massadine, FR901464, and spliceostatin A …”

Section: Introductionmentioning

confidence: 99%

Leveraging Limited Experimental Data with Machine Learning: Differentiating a Methyl from an Ethyl Group in the Corey–Bakshi–Shibata Reduction

Pereira,

Ruth,

Gerbig

et al. 2024

J. Am. Chem. Soc.

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We present a case study on how to improve an existing metal-free catalyst for a particularly difficult reaction, namely, the Corey−Bakshi−Shibata (CBS) reduction of butanone, which constitutes the classic and prototypical challenge of being able to differentiate a methyl from an ethyl group. As there are no known strategies on how to address this challenge, we leveraged the power of machine learning by constructing a realistic (for a typical laboratory) small, albeit high-quality, data set of about 100 reactions (run in triplicate) that we used to train a model in combination with a key-intermediate graph (of substrate and catalyst) to predict the differences in Gibbs activation energies ΔΔG ‡ of the enantiomeric reaction paths. With the help of this model, we were able to select and subsequently screen a small selection of catalysts and increase the selectivity for the CBS reduction of butanone to 80% enantiomeric excess (ee), the highest possible value achieved to date for this substrate with a metal-free catalyst, thereby also exceeding the best available enzymatic systems (64% ee) and the selectivity with Corey's original catalyst (60% ee). This translates into a >50% improvement in relative ΔG ‡ from 0.9 to 1.4 kcal mol −1 . We underscore the transformative potential of machine learning in accelerating catalyst design because we rely on a manageable small data set and a keyintermediate graph representing a combination of catalyst and substrate graphs in lieu of a transition-state model. Our results highlight the synergy of synthetic chemistry and data-centric approaches and provide a blueprint for future catalyst optimization.

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Preparation of chiral isoxazole carbinols via catalytic asymmetric Corey-Bakshi-Shibata reduction.

Cited by 4 publications

References 15 publications

Synthesis and Structure of Unsymmetrical Anthracenyl-Isoxazole Antitumor Agents Via the Diastereoselective Bromination of 3-(9′-Anthryl)-Isoxazole Esters

Synthesis and Structure of Unsymmetrical Anthracenyl-Isoxazole Antitumor Agents Via the Diastereoselective Bromination of 3-(9′-Anthryl)-Isoxazole Esters

Syntheses and crystal structures of a nitro–anthracene–isoxazole and its oxidation product

Leveraging Limited Experimental Data with Machine Learning: Differentiating a Methyl from an Ethyl Group in the Corey–Bakshi–Shibata Reduction

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