Enantioselective addition asymmetric autocatalysis

Design of chiral catalysis and asymmetric autocatalysis for diphenyl-(l-methyl-pyrrolidin-2-yl) methanol-catalyzed enantioselective additions of organozinc reagents 97YGK994. 

In these systems, after the crystal chirality induced the chirality of asymmetric carbon in external organic compound, the subsequent asymmetric autocatalysis gives the greater amount of enantiomerically amplified product. These results clearly demonstrate that the crystal chirality of achiral organic compound is responsible for the enantioselective addition of /-Pr2Zn to pyrimidine-5-carbalde-hyde Ic. 

Nowadays, this chemistry includes a wide range of applications. The organozinc compounds employed in the enantioselective addition include dialkylzincs, dialkenylzincs, dialkynylzincs, diarylzincs and the related unsymmetrical diorganozincs. Electrophiles have been expanded to aldehydes, ketones and imines. Asymmetric amplification has been observed in the enantioselective addition of organozincs. Recently, asymmetric autocatalysis, i.e. automultiplication of chiral compounds, has been created in organozinc addition to aldehydes. 

As described in the preceding section, asymmetric amplification has been reported in the non-autocatalytic enantioselective addition of dialkylzincs. In asymmetric autocatalysis, amplification of has a more significant role, because the product of the asymmetric autocatalysis itself is capable of acting as the asymmetric autocatalyst. Once the product, i.e. the asymmetric autocatalyst with an enhanced , is formed in the asymmetric autocatalytic reaction, the product catalyzes the formation of itself with higher . From the viewpoint of the molecule, an asymmetric autocatalyst with dominant absolute configuration catalyzes... 

The first asymmetric autocatalysis with amplification of was observed in the automultiplication of a 5-pyrimidyl alkanol 80 (Figure l)169. When (5)-5-pyrimidyl alkanol 80 with as low as 2% is used as the asymmetric autocatalyst for enantioselective addition of diisopropylzinc to pyrimidine-5-carbaldehyde 88, the of the produced pyrimidyl alkanol (and the initial asymmetric autocatalyst) 80 increases to 10% (Figure 1, 1st run). Consecutive asymmetric autocatalyses using 5-pyrimidyl alkanol 80 with 10% have increased its to 57%, 81% and 88% , successively. During the reactions, the major (S)-enantiomer in the initial asymmetric autocatalyst has automultiplied by a factor of 238, while the slightly minor (R)-enantiomer has automultiplied by a factor of only 16. 

When enantioselective addition of diisopropylzinc to pyrimidine-5-carbaldehyde 89 was examined, simple 2-butanol with low (ca 0.1%) induces a tiny chirality in the initially produced alkanol 81 and the value of the finally obtained alkanol becomes higher (73-76%) due to the asymmetric autocatalysis (Table 2). Note that the value can be further amplified by subsequent asymmetric autocatalysis, as described in the preceding section. Various chiral compounds have been proved to act as chiral initiators. 

In the course of the continuing study [9a,b] on the enantioselective addition of dialkylzincs to aldehydes by using chiral amino alcohols such as diphenyl(l-methyl-2-pyrrolidinyl)methanol (45) (DPMPM) [48] A. A -dibutylnorephedrine 46 (DBNE) [49], and 2-pyrrolidinyl-l-phenyl-1-propanol (47) [50] as chiral catalysts, Soai et al. reacted pyridine-3-carbaldehyde (48) with dialkylzincs using (lS,2/ )-DBNE 46, which gave the corresponding chiral pyridyl alkanols 49 with 74-86% ee (Scheme 9.24) [51]. The reaction with aldehyde 48 proceeded more rapidly (1 h) than that with benzaldehyde (16 h), which indicates that the product (zinc alkoxide of pyridyl alkanol) also catalyzes the reaction to produce itself. This observation led them to search for an asymmetric autocatalysis by using chiral pyridyl alkanol. 

Scheme 4 Highly enantioselective asymmetric autocatalysis of pyrimidyl alkanol in enantioselective z -Pr2Zn addition...

We reasoned that chiral organic compounds with low ee induced by CPL can act as a chiral trigger in the enantioselective addition of z -Pr2Zn to pyrimidine-5-carbaldehyde, and that the subsequent asymmetric autocatalysis of pyrimidyl alkanol, formed in situ, amplifies its ee to produce highly enantioenriched pyrimidyl alkanol with an absolute configuration corresponding to that of the handedness of the CPL. 

We found that inorganic helical structures such as helical silica serve as chiral triggers for asymmetric autocatalysis (Scheme 23). In the presence of helical silica, the enantioselective addition of z-P Zn to 2-alkynylpyrimidine-5-carbaldehyde 11 was examined. In the presence of right-handed helical silica, (S)-5-pyrimidyl alkanol 12 was formed [123]. In contrast, in the presence of left-handed helical silica, (S)-5-pyrimidyl alkanol 12 with high ee was obtained. These results clearly show that asymmetric auto catalysis can discriminate the helical structure in artificially tuned inorganic silica. 

Chiral organic-inorganic hybrid materials such as silsesquioxane and ephedrine immobilized on silica gel also act as chiral inducers of asymmetric autocatalysis (Scheme 24) [124-126]. Enantioselective addition of z-Pr2Zn... 

In 1995, Soai and coworkers reported a highly enantiose-lective asymmetric autocatalysis of pyrimidyl alkanol in the enantioselective addition reaction of I-Pr2Zn to pyrimidine-5-carboxaldehyde (equation 63). When a 5-pyrimidyl alkanol with a small enantiomeric excess such as 5x10 % is added to j-Pr2Zn and pyrimidine-5-carboxaldehyde, then the reaction... 

We found asymmetric autocatalysis of pyrimidyl alkanol 1 [1-10], Pyrimidyl alkanol 1 acts as asymmetric autocatalyst in the enantioselective addition of diisopropylzinc (/-Pr2Zn) to pyrimidine-5-carbaldehyde 2 to produce more of itself with the same absolute configuration [11] of >99.5% enantiomeric excess (ee) in a yield of >99% (Scheme 1) [12]. Thus, pyrimidyl alkanol 1 automultiplies in... 

As described in the preceding sections, we already had experience on the enantioselective alkylation of aldehydes with dialkylzincs and the enantioselective synthesis of 3-pyridyl alkanol. In 1990, we found the first asymmetric autocatalysis of (5)-3-pyridyl alkanol 6 in the enantioselective addition of i-Pr2Zn to pyridine-3-carbaldehyde 7 to produce more of itself of 35% ee with the same S configuration (Scheme 6) [24]. Although the ee of product 6 decreased compared to that of the initial catalyst, the newly formed predominant enantiomer of the product is the same with that of asymmetric autocatalyst 6. We claim that this is the first asymmetric autocatalysis, that is, catalytic replication of chiral compound with the generation of new stereogenic centers. 

This is the first example of a highly enantioselective reaction induced by chirality resulting from deuterium substitution of amino acids. In addition, chirally deuterated primary alcohols [52] and chiral amino acid derivatives with partially deuterated substituent such as monodeuterated methyl group (—CDH2) can induce the chirality in asymmetric autocatalysis [53]. 

In summary, we have described how we find out the asymmetric autocatalysis with amplification of chirality in the reaction between pyrimidine-5-carbaldehyde and i-Pr2Zn. 2-Alkynyl-5-pyrimidyl alkanol is a highly enantioselective asymmetric autocatalyst with greater than 99.5% enantioselectivity for the addition of i-Pr2Zn to the corresponding pyrimidine-5-carbaldehydes. Furthermore, it was found that enantiomeric excess of asymmetric autocatalyst enhances during the reaction. Thus, (5)-pyrimidyl alkanol with as low as ca. 0.00005% ee enhanced its ee to... 

Abstract The addition of diisopropylzinc to prochiral pyrimidine carbaldehydes (Soai reaction) is the only known example of spontaneous asymmetric synthesis in organic chemistry. It serves as a model system for the spontaneous occurrence of chiral asymmetry from achiral initial conditions. This review describes the possible kinetic origin of specific experimental features of this reaction. It is shown that generic kinetic models, including enantioselective autocatalysis and mutual inhibition between the enantiomers,... 

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