Brpnsted base/acid catalysis bond formation

Bifunctional catalysts have proven to be very powerful in asymmetric organic transformations [3], It is proposed that these chiral catalysts possess both Brpnsted base and acid character allowing for activation of both electrophile and nucleophile for enantioselective carbon-carbon bond formation [89], Pioneers Jacobsen, Takemoto, Johnston, Li, Wang and Tsogoeva have illustrated the synthetic utility of the bifunctional catalysts in various organic transformations with a class of cyclohexane-diamine derived catalysts (Fig. 6). In general, these catalysts contain a Brpnsted basic tertiary nitrogen, which activates the substrate for asymmetric catalysis, in conjunction with a Brpnsted acid moiety, such as urea or pyridinium proton. 

Normalized p values for this reaction catalyzed by three different aryloxide ions are reported in Table 12 while Brpnsted coefficients for this type of catalysis are summarized in Table 13. The rather low values (high a(k )) suggest that the proton transfer from the attacking methanol nucleophile to the buffer base has made much less progress than the C-0 bond formation at the transition state (or that in the reverse direction protonation of the departing MeO by the buffer acid is ahead of C-0 bond cleavage), as shown in 82 on MeO group). 

Chen et al. [26] reported the use of a bifunctional thiourea catalyst 61 during the organocatalyzed thia-Michael addition of thiophenol to unsaturated imide 58c (Scheme 3.29). Michael adduct 60c was obtained in 60% ee and 97% yield by conducting the reaction in dichloromethane at -78°C. The authors speculated that while the tertiary amine of the bifunctional catalyst 61 would act as a proton shuttle according to a Brpnsted acid/base catalysis, the presence of the thiourea moiety might possibly cooperate in the stabilization of the more stable Z-enolate intermediate via hydrogen bond formation as illustrated in Scheme 3.31. 

To discuss acid-base catalysis, it is helpful to recall the definitions of acids and bases. In the Brpnsted-Lowry definition, an acid is a proton donor and a base is a proton acceptor. The concept of general acid-base catalysis depends on donation and acceptance of protons by groups such as the imidazole, hydroxyl, carboxyl, sulfhydryl, amino, and phenolic side chains of amino acids all these functional groups can act as acids or bases. The donation and acceptance of protons gives rise to the bond breaking and re-formation that constitute the enzymatic reaction. 

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