Cyanate reaction with amino acids

Extension of this reaction toward a one-pot asymmetric Mannich-hydrocyanation reaction sequence was also reported by the Barbas group [29]. In this one-pot two-step process proline-catalyzed asymmetric Mannich reaction of unmodified aldehydes with the a-imino glyoxylate was performed first, then diastereoselective in situ cyanation. The resulting /i-cyanohydroxymethyl a-amino acids were obtained with high enantioselectivity (93-99% ee) [29]. Another one-pot two-step reaction developed by Barbas et al. is the Mannich-allylation reaction in which the proline-catalyzed Mannich reaction is combined with an indium-promoted allylation [30], This one-pot synthesis was conducted in aqueous media and is the first example of a direct organocatalytic Mannich reaction in aqueous media [28, 30]. 

Another way to form a-aminoketones from a-amino acids is via the Dakin-West reaction, in which amino acids are treated with aliphatic acid anhydrides to give ketone amides. Thus, reaction of ( )-phenylalanine with the appropriate aliphatic acid anhydrides followed by acidic hydrolysis afforded keto-amide 1271. Cyclization of 1272 with potassium cyanate gave 5-alkyl-4-benzyl-l,3-dihydroimidazol-2-ones 1273 (Scheme 322) <2002JHC375>. 

Synthesis from OC-Amino Acids and Related Compounds. Addition of cyanates, isocyanates, and uiea derivatives to a-amino acids yields hydantoin piecuisois. This method is called the Read synthesis (2), and can be considered as the reverse of hydantoin hydrolysis. Thus the reaction of a-amino acids with alkaline cyanates affords hydantoic acids, which cyclize to hydantoins in an acidic medium. 

Substitution of alkaline cyanates by isocyanates allows the preparation of 3-substituted hydantoias, both from amino acids (64) and amino nitriles (65). The related reaction between a-amino acids and phenyl isothiocyanate to yield 5-substituted 3-phenyl-2-thiohydantoiQS has been used for the analytical characterization of amino acids, and is the basis of the Edman method for the sequential degradation of peptides with concomitant identification of the /V-terminal amino acid. 

Complexation of an amino acid derivative with a transition metal to provide a cyanation catalyst has been the subject of investigation for some years. It has been shown that the complex formed on reaction of titanium(IV) ethoxide with the imine (40) produces a catalyst which adds the elements of HCN to a variety of aldehydes to furnish the ( R)-cyanohydrins with high enantioselectivity[117]. Other imines of this general type provide the enantiomeric cyanohydrins from the same range of substrates11171. 

Another addition reaction of amino groups is carbamoylation with sodium cyanate (Eq. 3-35). A displacement reaction by an amino group on an acid... 

The oxazolidin-2-ones 53 (R = H=CCH=CH2 or COEt) are obtained in a one-pot reaction of amino alcohol carbamates 52 with sodium hydroxide, followed by allyl bromide or propi-onyl chloride (94TL9533). A modified procedure for the preparation of chiral oxazolidin-2-ones 56 from a-amino acids 54, which avoids the hazardous reduction of the acids with borane and the intermediacy of water-soluble amino alcohols, is treatment of the methyl ester of the amino acid with ethyl chloro-formate to give 55, followed by reduction with sodium borohydride and thermal ring-closure of the resulting carbamate f95SC561). The 2-prop-ynylcarbamates 57 (R = Ts, Ac, Bz, Ph or allyl) cyclize to the methyleneoxazolidinones 58 under the influence of silver cyanate or copper(I) chloride/triethylamine (94BCJ2838). 

The corresponding /i-amino aldehydes are reduced in situ and the corresponding amino alcohols are isolated in good yield with up to >99 % ee. The Mannich reactions proceed with excellent chemoselectivity and inline formation occurs with the acceptor aldehyde at a faster rate than C-C bond-formation. Moreover, the one-pot three-component direct asymmetric cross-Mannich reaction enables aliphatic aldehydes to serve as acceptors. The absolute stereochemistry of the reaction was determined by synthesis and reveled that L-proline provides syn /i-amino aldehydes with (S) stereochemistry of the amino group. In addition, the proline-catalyzed direct asymmetric Mannich-type reaction has been connected to one-pot tandem cyanation and allylation reaction in THF and aqueous media affording functional a-amino acid derivatives [39, 42]. 

Since an important feature of Biicherer-Bergs hydantoin formation is that the process can only work for a-aminonitriles without substituent on the amino group, it follows that one compound of the equilibrium mixture formed from an aldehyde, ammonia, and cyanide is selectively reacted through an irreversible process leaving N-alkylated aminonitriles or imino-dinitriles unreacted. However, the difficulty with this process is that CAAs and hydantoins are poorly reactive towards hydrolysis and need long periods of time to be converted into free AAs. But, CAAs may also have per se a prebi-otic importance in activation pathways towards polypeptides (see Sect. 3.3.7). CAAs can also be synthesized by reaction of free amino acids with cyanic acid/cyanate (a likely prebiotic compound [50]). In the presence of a steady-state concentration of either cyanate or urea in aqueous medium, CAAs are at equilibrium with A A [51]. 

An important application of oxidation of a C-H bond adjacent to a nitrogen atom is the selective oxidation of amides. This reaction proceeds in the presence of ferf-BuOOH as the oxidant and Ru(II) salts. Thus in the example of Eq. (36), the a-tert-butylperoxy amide of the isoquinoline was obtained, which is an important synthetic intermediate for natural products [138]. This product can be conveniently reacted with a nucleophile in the presence of a Lewis add. Direct trapping of the iminium ion complex by a nudeophile was achieved in the presence of trimethylsilyl cyanide, giving a-cyanated amines as shown in Eq. (37) [45]. This ruthenium/peracid oxidation reaction provides an alternative to the Strecker reaction for the synthesis of a-amino acid derivatives since they involve the same a-cyano amine intermediates. In this way N-methyl-N-(p-methoxyphenyl) glycine could be prepared from N,N-dimethyl-p-methoxyaniline in 82% yield. 

The Marckwald synthesis116 employed the reaction of a-amino-ketones with cyanates, thiocyanates, and isothiocyanates to yield 3 -imidazol-2-ones or AH-imidazole-2-thiones which are readily converted into imidazoles. The chief limitation of this method, which has been discussed adequately in earlier reviews,1-3 is in the synthesis of the a-aminocarbonyl compounds. The most convenient procedure is by reduction with sodium amalgam of a-amino acids.117 Among recent applications of the method118 119 is the synthesis118 of 4,5-... 

The earliest method of this type, developed by Marckwald, employed the reaction of a-aminocarbonyl compounds (or their acetals) with cyanates, thiocyanates or isothiocyanates to give 3//-imidazoline-2-thiones. These compounds can be converted readily into imidazoles by oxidation or dehydrogenation. The major limitations of this synthetic procedure are the difficulty of synthesis of a wide variety of the a-aminocarbonyl compounds, and the limited range of 2-substituents which are introduced. The reduction of a-amino acids with aluminum amalgam provides one source of starting materials. The method has been applied to the preparation of 4,5-trimethyleneimidazole (83) from 2-bromocyclopentanone (70AHC(12)103), and to the synthesis of pilocarpine (84 Scheme 47) (80AHC(27)24l). If esters of a-amino acids react with cyanates or thiocyanates, the products are hydantoins and 2-thiohydantoins, respectively. 

Recently, a new type of reaction - that is, aerobic oxidative cyanation of tertiary amines - was discovered. In this reaction, oxidation with molecular oxygen in place of peroxides, in addition to direct carbon-carbon bond formation by trapping of the iminium ion intermediates with a carbon nucleophile under oxidative conditions, is accomplished simultaneously. The ruthenium-catalyzed oxidation of tertiary amines with molecular oxygen (1 atom) in the presence of sodium cyanide gives the corresponding a-aminonitriles (Eq. 3.74) [132], which are useful for synthesis of a-amino acids and 1,2-diamines. 

Amino-5-imino-3-pyrazolidinones have been synthesized by reduction of the corresponding oximes.644,1339 Such amines form ureas and thioureas by reaction with potassium cyanate in acid solution and with phenyl isothiocyanate.644 4-Arylimino-5-imino-3-pyrazolidinones have been prepared by reaction of the 5-imino-3-pyrazolidinones with p-amino-A.-AT-diethylaniline in the presence of silver salts as oxidizing agents (eq. 172).244,519,1255,1538 4-Arylazo-5-imino-3-pyrazolidinones have most frequently been prepared by reaction of 5-imino-3-pyrazoli-dinones with aryldiazonium chlorides, as is usual for the preparation of similar compounds.591,594,920,1087,1255,1339,1539,1649 One such compound has been prepared by the Curtius rearrangement of the corresponding 4-arylazo azide.594... 

Stark, G. R., Stein, W. H., and Moore, S., Reactions of the cyanate present in aqueous urea with amino acids and proteins. J. Biol. Chem. 235, 3177-3181 (1960). 

The microwave-assisted one-pot three-step synthesis of thiohydantoins has been studied together with a polymer-supported catalyst and/or reagent [55]. Cyclization of a number of AT-substituted amino acids of type 50 and thioiso-cyanates 51 has given satisfactory yields within 5 min at 170 to 180 °C (see Scheme 29). Polymer-supported dimethylaminopyridine (PS-DMAP) 52 has been utilized as a supported base herein to catalyse the reaction however, in most cases the yield was comparatively lower to the use of triethylamine (TEA). PS-DMAP also assisted in simplifying the purification. 

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