Enantioselective protonation

Mohr, Justin T.; Hong, Allen Y.; Stoltz, Brian M.

doi:10.1038/nchem.297

Cited by 239 publications

(113 citation statements)

References 112 publications

(115 reference statements)

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“…With this LBA in hand, we attempted to apply this LBA as a catalyst to the asymmetric protonation reaction12,13 of the silyl enol ether derived from 2-phenyl cyclohexanone. Among the metal triflates tested,14 La(OTf) 3 was found to be the best choice of Lewis acid activator;15 5 mol% of LBA derived from La(OTf) 3 afforded the desired protonation product in quantitative yield and 56% enantiomeric excess (ee) (eqn (2)).…”

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confidence: 99%

Development of a new Lewis base-tolerant chiral LBA and its application to catalytic asymmetric protonation reaction

2010

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confidence: 99%

Development of a new Lewis base-tolerant chiral LBA and its application to catalytic asymmetric protonation reaction

2010

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“…The catalytic addition of malonate to α,β-unsaturated amides and the successive highly enantioselective protonation was achieved using the chiral Pybox-calcium catalyst system prepared from Pybox 2 and calcium ethoxide with aryloxide 1 (Table 15) for a review of asymmetric protonation reactions, see [65,[67][68][69]. The products were obtained in good yields with high enantioselectivities, and a broad substrate generality was also observed except for the phenyl subustituted substrate (entry 9).…”

Section: Asymmetric Aldol and Related Reactionsmentioning

confidence: 92%

Chiral Ca-, Sr-, and Ba-Catalyzed Asymmetric Direct-Type Aldol, Michael, Mannich, and Related Reactions

Tsubogo

Yamashita

Kobayashi

2013

Alkaline-Earth Metal Compounds

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Recent progress in asymmetric direct-type aldol, Michael, Mannich, and related reactions using chiral Ca, Sr, and Ba catalysts was summarized in this chapter. Ca, Sr, and Ba are very attractive, because they are abundant and ubiquitous elements found in nature, and form relatively safe and environmentally benign compounds compared with heavy transition metals. However, their use as catalysts in asymmetric synthesis has been limited compared with that of transition metal catalysts. Their strong Brønsted basicity and mild Lewis acidity are promising and attractive characteristics, and can influence their catalytic activity as well as their chiral modification capability in a positive manner. It was revealed that several catalytic asymmetric carbon-carbon bond-forming and related reactions proceeded smoothly in high enantioselectivites using the chiral Ca, Sr, and Ba catalysts.

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“…Glyoxalase thereby protects cells from α-oxoaldehyde-mediated formation of advanced glycation2. In particular, the glyoxalase I-catalysed isomerization of hemithioacetals involves the sequential formation of α-hemithioacetal, deprotonation to form the enediol intermediate and its enantioselective reprotonation3, leading to the formation of enantiopure α-hydroxythioesters456 (Fig. 1a).…”

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confidence: 99%

“…1b). Of note, on contrast to enzymes, enantioselective introduction of a proton to transient enediol intermediate via synthetic route might be extremely challenging to control it in terms of enantioselectivity due to the small size of the proton37891011.…”

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Biomimetic catalytic transformation of toxic α-oxoaldehydes to high-value chiral α-hydroxythioesters using artificial glyoxalase I

et al. 2017

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Glyoxalase I plays a critical role in the enzymatic defence against glycation by catalysing the isomerization of hemithioacetal, formed spontaneously from cytotoxic α-oxoaldehydes and glutathione, to (S)-α-hydroxyacylglutathione derivatives. Upon the hydrolysis of the thioesters catalysed by glyoxalase II, inert (S)-α-hydroxy acids, that is, lactic acid, are then produced. Herein, we demonstrate highly enantioselective glyoxalase I mimic catalytic isomerization of in-situ-generated hemithioacetals, providing facile access to both enantiomers of α-hydroxy thioesters. Owing to the flexibility of thioesters, a family of optically pure α-hydroxyamides, which are highly important drug candidates in the pharmaceutical industry, were prepared without any coupling reagents. Similar to real enzymes, the enforced proximity of the catalyst and substrates by the chiral cage in situ formed by the incorporation of potassium salt can enhance the reactivity and efficiently transfer the stereochemical information.

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Enantioselective protonation

Cited by 239 publications

References 112 publications

Development of a new Lewis base-tolerant chiral LBA and its application to catalytic asymmetric protonation reaction

Development of a new Lewis base-tolerant chiral LBA and its application to catalytic asymmetric protonation reaction

Chiral Ca-, Sr-, and Ba-Catalyzed Asymmetric Direct-Type Aldol, Michael, Mannich, and Related Reactions

Biomimetic catalytic transformation of toxic α-oxoaldehydes to high-value chiral α-hydroxythioesters using artificial glyoxalase I

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