Amines pyruvate esters

A similar conclusion can be drawn from an unexplained case of sonochemical switching (Fig. 29). The addition of primary aromatic amines to methyl pyruvate produces first the tautomeric imine-enamine condensation product. This step seems to be sonication independent. Under stirring at room temperature, the condensation goes on with the condensation of the enamine with the pyruvic ester to yield a lactone. In contrast, sonication under the same conditions... 

It has also been possible to confirm the presence of the reduction product of a Schiff base on the polymer by proton magnetic resonance. For this purpose we have used unmodified poly(ethylenimine), since it too catalyzes the decarboxylation of oxalacetate to its product, pyruvate. Unmodified polyethylenimine was mixed with oxalacetate-4-ethyl ester. One-half of this solution was treated with NaBH4 the second half was exposed to a similar environment but no NaBH4 was added. The borohydride-treated polymer exhibited a strong triplet in the nmr spectrum centered at 3.4 ppm upfield from the HOD resonance. This new feature would be expected from the terminal methyl protons of the oxalacetate ester attached to the polymer. Only a very weak triplet was found in the control sample not treated with borohydride. These observations are strong evidence for the formation of Schiff bases with the polymer primary amine groups. Evidently the mechanistic pathway for decarboxylation by the polymer catalyst is similar to that used enzymatically. 

The catalytic hydrogenation of the benzoylformic acid amides of optically active amino acid esters was carried out. When the (5)-amino acid ester was used, the resulting mandelic acid had the (R)-con-figuration. When pyruvic acid amides of optically active benzylic amines were hydrogenated over palladium, optically active lactic acid was obtained in relatively high enantiomeric excess (ee 60%). The... 

The first efforts to address this issue involved hydrazone ( ) 62 (Scheme 2.9), prepared as a mixture E/Z 92 8) and separated via flash chromatography as the pure ( ) isomer in 75% yield. In this preparation, the oxazolidinone N amination was accomplished using a solution of monochloramine in methyl tert butyl ether [45], furnishing a quantitative yield of the N amino 2 oxazolidinone, which in turn was condensed with methyl pyruvate to afford 62. Addition of ethyl iodide to ( ) 62 using the Mn mediated photolysis conditions as described above gave 66% yield ofthe ethyl adduct, with a modest diastereomer ratio of 70 30, while the correspond ing isopropyl addition was very effective (85% yield, dr 92 8). Variation in the stoichiometry indicated that amounts less than 2 equiv of Lewis acid proportionally lowered the diastereoselectivity, suggesting that, in this case, the ester may participate... 

Later, a modified version of the synthesis was reported, in which the important secodine precursor is a tetrahydro-jS-carboline derivative, such as 557-559, rather than an indoloazepine ester, as in 560. This led to a simpler synthesis, the tetrahydro-/3-carboline derivatives required for the preparation of 557-559 being obtained directly from the appropriate trypt-amine derivative and pyruvic acid ester. By this route, ( )-vincadifformine (76), ( )-minovine (A g-methylvincadifformine) and ( ) ervinceine (87) were synthesized in comparatively high yield, and in essentially two stages from the starting tryptamine (330). 

In the oxidative deamination reaction, the enzyme was active toward N-[l-D-(carboxyl)ethyl]-L-methionine, N-[l-D-(carboxyl)ethyl]-L-phenylalanine, etc. The substrate specificity for amino donors of ODH in the reductive secondary amine-forming reaction was examined with pyruvate as a fixed amino acceptor [15,24]. The enzyme utilized L-norvaline, L-2-aminobutyric acid, L-norleucine, P-chloro-L-alanine, o-acetyl-L-serine, L-methionine, L-isoleucine, L-valine, L-phenylalanine, L-homophenylalanine, L-leucine, L-alanine, etc. 3-Aminobutyric acid and L-phenylalaninol also acted as substrates for the enzyme. Other amino compounds, such as P-amino acids, amino acid esters and amides, amino alcohols, organic amines, hydroxylamines, and hydrazines, were inactive as substrates. Pyruvate, oxaloacetate, glyoxylate, and a-ketobutyrate were good amino acceptors. We named the enzyme as opine... 

Soon afterward, MacMillan s group properly explored this organocatalytic reductive amination, observing that the ortho-triphenylsilyl phosphoric acid 17n in the presence of 5-A MS facilitates the desired coupling of acetophenone and 4-OMe-aniline in high conversion and with excellent levels of enantiocontrol at 40 C (87% yield, 94% ee) [55]. Authors report also the reduction of the pyruvic acid-derived cyclic imino ester with excellent enantioselectivity. However, implementation of the corresponding ethyl-substituted imine resulted in a dramatic decrease in... 

At almost the same time, MacMillan and coworkers found that the reductive amination starting from aldehyde, amine, and Hantzsch ester 39 also proceeded smoothly by means of 1 in the presence of 5 A MS to afford benzylic amines 43 with 83-97% ee (Scheme 11.11) [22]. They proved that dialkyl ketones as well as alkyl aryl ketones were suitable substrates even methyl ethyl ketone was reduc-tively aminated with 83% ee. They also reported the asymmetric reduction of pyruvic-acid-derived cyclic imino ester 44. In this reaction, the structure of 44 exhibited a remarkable correlation to MM3 calculations in terms of both hydrogen bond orientation and specific architectural elements that dictate iminium enan-tiofacial discrimination. 

During the study on enantioselective organocatalytic reductive amination, MacMillan et al. found that the pyruvic acid-derived cyclic imino ester could be efficiently reduced to yield the corresponding alanine amino ester with 97% ee and 82% yield... 

By acylation of amines with active derivatives of a-keto acids pyruvic acid chloride (767), p-nitrophenyl pyruvate 167, 169), carbodimide method 86. 166, 178), mixed anhydrides with phosphorous acid dichloride 436) and by activation with the cyclic esters of oxalic acid with 4,6-diphenyl-thieno-[3,4-d]-[l,3]-dioxolone-dioxide (H. Schmidt and W. Steglich, 346A). 

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