Keto forms 3-Ketoacids

Relatively acidic carbon acids such as malonic esters and jS-keto esters were the first class of carbanions for which reliable conditions for alkylation were developed. The reason being that these carbanions are formed using easily accessible alkoxide ions. The preparation of 2-substiuted /i-kcto esters (entries 1, 4, and 8) and 2-substituted derivatives of malonic ester (entries 2 and 7) by the methods illustrated in Scheme 1.5 are useful for the synthesis of ketones and carboxylic acids, since both /1-ketoacids and malonic acids undergo facile decarboxylation ... 

The complex is additionally stabilised by co-ordination of the phenoxide, and possibly the carboxylate, to the metal ion, illustrating the utility of chelating ligands in the study of metal-directed reactivity. We saw in the previous section the ways in which a metal ion may perturb keto-enol equilibria in carbonyl derivatives, and similar effects are observed with imines. The metal ion allows facile interconversion of the isomeric imines. The first step of the reaction is thus the tautomerisation of 5.28 to 5.29 (Fig. 5-56). Finally, the metal ion may direct the hydrolysis of the new imine (5.29) which has been formed, to yield pyridoxamine (5.30) and the a-ketoacid (Fig. 5-57). 

Regarding ozonation processes, the treatment with ozone leads to halogen-free oxygenated compounds (except when bromide is present), mostly aldehydes, carboxylic acids, ketoacids, ketones, etc. [189]. The evolution of analytical techniques and their combined use have allowed some researchers to identify new ozone by-products. This is the case of the work of Richardson et al. [189,190] who combined mass spectrometry and infrared spectroscopy together with derivatization methods. These authors found numerous aldehydes, ketones, dicarbonyl compounds, carboxylic acids, aldo and keto acids, and nitriles from the ozonation of Mississippi River water with 2.7-3 mg L 1 of TOC and pH about 7.5. They also identified by-products from ozonated-chlorinated (with chlorine and chloramine) water. In these cases, they found haloalkanes, haloalkenes, halo aldehydes, haloketones, haloacids, brominated compounds due to the presence of bromide ion, etc. They observed a lower formation of halocompounds formed after ozone-chlorine or chloramine oxidations than after single chlorination or chlorami-nation, showing the beneficial effect of preozonation. 

The first group is the dihydroxyacetone phosphate (DHAP)-dependent aldolases, which use DHAP as the donor to produce 2-keto-l, 3, 4-trihydroxy motifs. The second group, the pyruvate- or phosphoenol pyruvate (PEP)-dependent aldolases, uses pyruvate to form 4-hydroxy-2-ketoacids. The third... 

Keto counterparts. Name the a-ketoacid that is formed hy transamination of each of the following amino acids ... 

It was shown that an enol intermediate was initially formed in the decarboxylation of l -ketoacids and presumably in the decarboxylation of malonic acids. It was found that the rate of decarboxylation of a,a-dimethylacetoacetic acid equalled the rate of disappearance of added bromine or iodine. Yet the reaction was zero order in the halogen . Qualitative rate studies in bicyclic systems support the need for orbital overlap in the transition state between the developing p-orbital on the carbon atom bearing the carboxyl group and the p-orbital on the i -carbonyl carbon atom . It was also demonstrated that the keto, not the enol form, of p ketoacids is responsible for decarboxylation of the free acids from the observa-tion that the rate of decarboxylation of a,a-dimethylacetoacetic acid k cid = 12.1 xlO sec ) is greater than that of acetoacetic acid (fcacw = 2.68x10 sec ) in water at 18 °C. Enolization is not possible for the former acid, but is permissible for the latter. Presumably this conclusion can be extended to malonic acids. 

The enzymes described above that convert oxaloacetate to pyruvate and CO2 appear to use metal chelation to stabilize the enolate formed by decarboxylation. Many other /3-ketoacid decarboxylases use a similar mechanism. However, there are a few decarboxylations of /3-keto acids or their functional equivalents in which no metal ion is involved. One is the case of acetoacetate decarboxylase, which functions by means of a Schiif base mechanism. A few additional examples are described below. All these cases involve particularly stable enolates. 

Reaction of a-ketoacid chlorides (374 Y = Cl) with amidrazones (356) leads preferentially to l,2,4-triazin-6-ones (379) (Equation (45)) <86S635,92JHC1161,92LA1271>. In this case the more reactive hydrazono group of the amidrazone reacts with the carbonyl chloride instead of the keto group. N-Aroyl-Y -ethoxalylphenylhydrazines react with amidrazones to form the 5-hydrazino-l,2,4-triazin-6-ones (380) (Equation (46)) <87S128>. 

Because the resolution with acylase gave a theoretical maximum yield of only 50% and required separation of the desired product from the unreacted enantiomer at the end of the reaction, we next tried to prepare the amino acid by reductive amination of the corresponding ketoacid, a process with a theoretical maximum yield of 100%. A variety of ketoacids can be converted to L-amino acids by treatment with ammonia, reduced nicotinamide adenine dinucleotide (NADH), and a suitable amino acid dehydrogenase. 2-Keto-6-hydroxyhexanoic acid (in equilibrium with its cyclic hemiketal form) was prepared by chemical synthesis starting from 4-chloro-l-butanol, which was... 

The a-ketoglutarate dehydrogenase complex is one of a three-member family of similar a-keto acid dehydrogenase complexes. The other members of this family are the pyruvate dehydrogenase complex, and the branched chain amino acid a-keto acid dehydrogenase complex. Each of these complexes is specific for a different a-keto acid structure. In the seqnence of reactions catalyzed by the complexes, the a-ketoacid is decarboxylated (i.e., releases the carboxyl gronp as CO2) (Fig.20.8). The keto gronp is oxidized to the level of a carboxylic acid, and then combined with CoASH to form an acyl CoA thioester (e.g., succinyl CoA). 

The (reversible) transformation of an a-ketocarboxyhc acid in presence of ammonia and one equivalent of NAD(P)H furnishes the corresponding a-amino acid and is catalyzed by amino acid dehydrogenases [EC 1.4.1.X] [962]. Despite major differences in its mechanism, this reaction bears a strong resemblance to carbonyl group reduction and it formally respresents a reductive amination (Scheme 2.133). As deduced for L-Leu-dehydrogenase [963], the a-ketoacid substrate is positioned in the active site between two Lys-residues. Nucleophihc attack by NH3 leads to a hemiaminal intermediate, which eliminates H2O to form an iminium species. The latter is reduced by a hydride from nicotinamide forming the L-amino acid. Since this mechanism is highly tuned for a-keto/a-amino acids, it is clear that a neutral Schiff base cannot be accepted as substrate. 

The use of an amine donor, which forms an unstable keto coproduct. For instance, cysteinesulfinic acid was used in transamination to furnish the p-sulfinic acid analog of pyruvate, which spontaneously decomposes into SO2 and pymvate [1732]. In a related fashion, a,co-diamino acids, such as ornithine or leucine yield amino-ketoacids, which (nonenzymatically) cyclize to the corresponding A -pyrroline-5-carboxylate and A -piperidine-2-carboxylate, respectively, as dead-end products [1733, 1734],... 

Decarboxylation, or loss of CO2, is not a typical reaction of carboxylic acids under ordinary conditions. However, j8-ketoacids are unusually prone to decarboxylation for two reasons. First, the Lewis basic oxygen of the 3-keto function is ideally positioned to bond with the carboxy hydrogen by means of a cyclic six-atom transition state. Second, this transition state has aromatic character (Section 15-3), because three electron pairs shift around the cyclic six-atom array. The species formed in decarboxylation are CO2 and an enol, which tautomerizes rapidly to the final ketone product. 

For some other enzymes, the mechanism of catalysis involving ThDP is very similar to the umpolung mechanism already described in the case of BAL, except that the reaction begins with an a-ketoacid 21. The ylide primarily formed from ThDP attacks the keto function to form an intermediate carboxylate ion 22. The reactive carbanion 23 is only formed after decarboxylation (Scheme 28.11). 

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