Asymmetric glycine derivatives

Alkylation of protected glycine derivatives is one method of a-amino acid synthesis (75). Asymmetric synthesis of a D-cx-amino acid from a protected glycine derivative by using a phase-transfer catalyst derived from the cinchona alkaloids (8) has been reported (76). 

A tandem palladium-catalyzed reaction can effect a similar transformation to produce 2-vinyl-substituted heterocyclic systems as in Eq. 8E.11. By varying the amino acid moiety of the ligand, 83% ee could be obtained from the use of the glycine-derived ligand 129 [161]. A maximum enantioselectivity of 65% ee has been recorded for this type of reaction in an earlier study with BINAP as ligand [ 162]. Because both ( )- and (Z)-isomers gave the same enantioselectivity, attack on the rapidly interconverting 7t-allyl intermediates seems to determine the selectivity. Modest enantioselectivities have been reported for the related asymmetric preparation of 2-vinylpiperazine and 1,4-benzodioxane derivatives [163,164],... 

Enantioselective Michael addition of glycine derivatives by means of chiral phase-transfer catalysis has been developed to synthesize various functionalized a-alkyl-a-amino acids. Corey utilized 4d as catalyst for asymmetric Michael addition of glycinate Schiff base 1 to a,(3-unsaturated carbonyl substrates with high enantioselectivity (Scheme 2.15) [35,36]. With methyl acrylate as an acceptor, the a-tert-butyl-y-methyl ester of (S)-glutamic acid can be produced, a functionalized glutamic acid... 

The Maruoka group s further efforts toward simplification of the catalyst have led to the design of new, polyamine-based chiral phase-transfer catalysts of type 15, with expectation of the multiplier effect of chiral auxiliaries, as illustrated in Scheme 5.10 [13]. The chiral efficiency of such polyamine-based chiral phase-transfer catalysts (S)-15 was examined by carrying out an asymmetric alkylation of glycine derivative 2 under phase-transfer conditions. Among various commercially available polyamines, spermidine- and spermine-based polyammonium salts were found to show moderate enantioselectivity. In particular, the introduction of a 3,4,5-trifluor-ophenyl group at the 3,3 -positions of chiral binaphthyl moieties showed excellent asymmetric induction. 

As a prochiral glycine-derived SchifFbase, not only esters but also amides can be used as suitable substrates for asymmetric alkylation under phase-transfer conditions. 

Metal-based asymmetric phase-transfer catalysts have mainly been used to catalyze two carbon-carbon bond-forming reactions (1) the asymmetric alkylation of amino acid-derived enolates and (2) Darzens condensations [5]. The alkylation ofprochiral glycine or alanine derivatives [3] is a popular and successful strategy for the preparation of acyclic a-amino acids and a-methyl-a-amino acids respectively (Scheme 8.1). In order to facilitate the generation of these enolates and to protect the amine substituent, an imine moiety is used to increase the acidity of the a-hydrogens, and therefore allow the use of relatively mild bases (such as metal hydroxides) to achieve the alkylation. In the case of a prochiral glycine-derived imine (Scheme 8.1 R3 = H), if monoalkylation is desired, the new chiral methine group... 

A major breakthrough in the use of Nobin as an asymmetric phase-transfer catalyst came when Belokon and coworkers applied it to the alkylation of glycine-derived nickel(II) complex 11a under the conditions shown in Scheme 8.13 [25], Representative results are given in Table 8.1, which illustrate that benzylic and allylic halides react very rapidly and highly enantioselectively to produce a-amino acids. Intrigu-ingly, in this case (R)-Nobin catalyzes the formation of (R)-amino acids, which is the opposite enantioselectivity to that observed for the alkylation of alanine derivative 16b [21,24],... 

The very short reaction times required for the alkylation of substrate 11a with benzylic bromides using Nobin as an asymmetric phase-transfer catalyst are important for the synthesis of 18F-fluorinated amino adds for use in positron-emission tomography (PET)-imaging studies. Thus, Krasikova and Belokon have developed a synthesis of 2-[18F]fluoro-L-tyrosine and 6-[18F]fluoro-L-Dopa employing a (S)-Nobin-catalyzed asymmetric alkylation of glycine derivative 11a as the key step, as shown in Scheme 8.14 [29]. The entire synthesis (induding semi-preparative HPLC purification) could be completed in 110 to 120 min, which corresponds to one half-life of18 F. Both the chemical and enantiomeric purity of the final amino acids were found to be suitable for clinical use. 

Catalyst screening experiments resulted in the discovery that copper(salen) complex 33 was a highly effective catalyst for the conversion of alanine derivative 16b into (f )-a-methyl phenylalanine 17 under the conditions shown in Scheme 8.16. The presence of just 1 mol% of catalyst 33 was sufficient to induce the formation of compound 17 with up to 92% ee and in >70% yield [33]. Allyl bromide, 1-chloromethylnaphthalene and ethyl iodide also reacted with substrate 16b to give the corresponding (H)-a-methyl a-amino acids in the presence of 2 mol % of complex 33 [34], Complex 33 also catalyzed the asymmetric mono-alkylation of glycine-derived substrate 34 by benzylic or allylic halides, to give (H)-a-amino acid derivatives 35 with 77-81% ee. and in greater than 90% yield, as shown in Scheme 8.17. 

Table 9.1 Asymmetric Mukaiyama-type aldol reactions of a glycine derivative catalyzed by in situ-generated chiral quaternary ammonium fluoride.

An important issue is the right choice of substrate 1 which functions as an anion precursor. Successful organocatalytic conversions have been reported with indanones and benzophenone imines of glycine derivatives. The latter compounds are, in particular, useful for the synthesis of optically active a-amino acids. Excellent enantioselectivity has been reported for these conversions. In the following text the main achievements in this field of asymmetric organocatalytic nucleophilic substitutions are summarized [1, 2], The related addition of the anions 2 to Michael-acceptors is covered by chapter 4. 

The asymmetric addition of glycine enolates to acrylates was also achieved by use of the tartaric acid-derived phase-transfer catalysts 27 and 28 (Scheme 4.9). Arai, Nishida and Tsuji [13] showed that the C2-symmetric ammonium cations 27a,b afford up to 77% ee when t-butyl acrylate is used as acceptor. The cations 28 are the most effective/selective PTC identified by broad variation of the substituents present on both the acetal moiety and nitrogen atoms [14], In this study by Shibasaki et al. enantiomeric excesses up to 82% were achieved by use of the catalyst 28a (Scheme 4.9) [14], Scheme 4.9 also shows the structure of the guanidine 29 prepared by Ma and Cheng in the absence of additional base this also catalyzes the Michael addition of the glycine derivative 22 to ethyl acrylate, albeit with modest ee of 30% [15],... 

Modified guanidines 3 efficiently catalyzed the asymmetric Michael addition of a prochiral glycine derivatives with acrylate, acrylonitrile and methyl vinyl ketone under simple and mild conditions. Remarkably, both product formation and enantioselectivity were dramatically improved using solvent-free conditions (Scheme 12) [34]. The addition of alcohols to methyl propiolate was performed using fluorous phosphines such as P[(CH2)2 (CF2)7 CF3]3 and again better yields of 99% have been obtained under solvent-free conditions. Toluene was added to efficiently separate the product from the solid catalyst, which was then reused without loss of activity [35],... 

Asymmetric alkylations of the glycine derivative 3 have become the standard by which chiral phase transfer catalysts are judged, and enable the preparation of a wide range of unnatural... 

In addition to the high efficiency and broad generality, the characteristic feature of the 32e-catalyzed asymmetric alkylation strategy is visualized by direct stereoselective introduction of two different side chains to glycine-derived aldimine... 

Enantioselective Michael addition of glycine derivatives by means of chiral phase-transfer catalysis has been developed to synthesize various functionalized a-alkyl-amino acids. Corey and colleagues utilized 30d as a catalyst for the asymmetric... 

Belokon and co-workers designed a glycine-derived nickel complex 60 and examined its asymmetric addition to methyl acrylate under phase-transfer conditions. The screening of various NOBIN and iso-NOBIN derivatives in combination with NaH as a base revealed that N-pivaloyl-iso-NOBIN (62b) proved to be highly efficient catalyst, affording the product 61 in 80% yield with 96% ee, as illustrated in Scheme 4.20 [59]. 

Bagley MC, Brace C, Dale JW, Ohnesorge M, Phillips NG, Xiong X, Bower J (2002) J Chem Soc [Perkin 1] 1663 Belattar A, Saxton JE (1992) J Chem Soc [Perkin 1] 679 Bernardi L, Gothelf AS, Hazell RG, Jprgensen KA (2003) Catalytic asymmetric Mannich reactions of glycine derivatives with imines. A new approach to optically active alpha,beta-diamino acid derivatives. J Org Chem 68 2583-2591... 

D-Glucose-derived oxazinones, which can be considered as chiral glycine derivatives, were also employed in asymmetric alkylation reactions [155]. The oxazinone represents a rigid... 

SCHEME 10.70 Chiral glycine derivatives such as d-glucose-derived oxazinones are useful in asymmetric alkylation reactions. 

The asymmetric alkylation of glycine derivatives is one of the most simple methods by which to obtain optically active a-amino acids [31]. The enantioselective alkylation of glycine Schiff base 52 under phase-transfer catalysis (PTC) conditions and catalyzed by a quaternary cinchona alkaloid, as pioneered by O Donnell [32], allowed impressive degrees of enantioselection to be achieved using only a very simple procedure. Some examples of polymer-supported cinchona alkaloids are shown in Scheme 3.14. Polymer-supported chiral quaternary ammonium salts 48 have been easily prepared from crosslinked chloromethylated polystyrene (Merrifield resin) with an excess of cinchona alkaloid in refluxing toluene [33]. The use of these polymer-supported quaternary ammonium salts allowed high enantioselectivities (up to 90% ee) to be obtained. 

A few years ago Cahard reported a series of studies on the use of immobilized cinchona alkaloid derivatives in asymmetric reactions with phase-transfer catalysts [17[. Two types of polymer-supported ammonium salts of cinchona alkaloids (types A and B in Scheme 8.4) were prepared from PS, and their activity was evaluated. The enantioselectivity was found to depend heavily on the alkaloid immobilized, with the type B catalysts usually giving better results than the type A catalysts. By performing the reaction in toluene at -50 °C in the presence of an excess of solid cesium hydroxide and 0.1 mol equiv of catalyst 10, benzylation of the tert-butyl glycinate-derived benzophenone imine afforded the expected (S)-product in 67% yield with 94% ee, a value very close to that observed with the nonsupported catalyst. (Scheme 8.4, Equation b) Unfortunately-and again, inexplicably-the pseudoenantiomer of 10 proved to be much less stereoselective, affording the R)-product in only 23% ee. No mention of catalyst recycling was reported [18]. 

---