Acetoacetic acid, activation carboxylic acids

The alkylation of activated halogen compounds is one of several reactions of trialkylboranes developed by Brown (see also 15-16,15-25,18-31-18-40, etc.). These compounds are extremely versatile and can be used for the preparation of many types of compounds. In this reaction, for example, an alkene (through the BR3 prepared from it) can be coupled to a ketone, a nitrile, a carboxylic ester, or a sulfonyl derivative. Note that this is still another indirect way to alkylate a ketone (see 10-105) or a carboxylic acid (see 10-106), and provides an additional alternative to the malonic ester and acetoacetic ester syntheses (10-104). 

The synthesis of the representative compound of this series, 1,4-dihydro-l-ethyl-6-fluoro (or 6-H)-4-oxo-7-(piperazin-l-yl)thieno[2/,3/ 4,5]thieno[3,2-b]pyridine-3-carboxylic acid (81), follows the same procedure as that utilized for compound 76. Namely, the 3-thienylacrylic acid (77) reacts with thionyl chloride to form the thieno Sjthiophene -carboxyl chloride (78). Reaction of this compound with monomethyl malonate and n-butyllithium gives rise to the acetoacetate derivative (79). Transformation of compound 79 to the thieno[2 3f 4,5]thieno[3,2-b]pyhdone-3-carboxy ic acid derivative (80) proceeds in three steps in the same manner as that shown for compound 75 in Scheme 15. Complexation of compound 75 with boron trifluoride etherate, followed by reaction with piperazine and decomplexation, results in the formation of the target compound (81), as shown in Scheme 16. The 6-desfluoro derivative of 81 does not show antibacterial activity in vitro. 

The Pechmann and Knoevenagel reactions have been widely used to synthesise coumarins and developments in both have been reported. Activated phenols react rapidly with ethyl acetoacetate, propenoic acid and propynoic acid under microwave irradiation using cation-exchange resins as catalyst <99SL608>. Similarly, salicylaldehydes are converted into coumarin-3-carboxylic acids when the reaction with malonic acid is catalysed by the montmorillonite KSF <99JOC1033>. In both cases the use of a solid catalyst has environmentally friendly benefits. Methyl 3-(3-coumarinyl)propenoate 44, prepared from dimethyl glutaconate and salicylaldehyde, is a stable electron deficient diene which reacts with enamines to form benzo[c]coumarins. An inverse electron demand Diels-Alder reaction is followed by elimination of a secondary amine and aromatisation (Scheme 26) <99SL477>. 

One-electron oxidation systems can also generate radical species in non-chain processes. The manganese(III)-induced oxidation of C-H bonds of enolizable carbonyl compounds [74], which leads to the generation of electrophilic radicals, has found some applications in multicomponent reactions involving carbon monoxide. In the first transformation given in Scheme 6.49, a one-electron oxidation of ethyl acetoacetate by manganese triacetate, yields a radical, which then consecutively adds to 1-decene and CO to form an acyl radical [75]. The subsequent one-electron oxidation of an acyl radical to an acyl cation leads to a carboxylic acid. The formation of a y-lactone is due to the further oxidation of a carboxylic acid having an active C-H bond. As shown in the second equation, alkynes can also be used as substrates for similar three-component reactions, in which further oxidation is not observed [76]. 

The reaction of 2-amino-3-nitrosopyridines with compounds containing an activated methylene group permits unambiguous synthesis of various derivatives of pyrido[2,3-b]pyrazine. For example, the pyridine 58 reacts in the presence of sodium ethoxide with a variety of arylacetonitriles and cyanoacetic acid derivatives to provide various 2-substituted 3-amino compounds (59). " " Diethyl malonate reacts similarly to give the 2-carboxylic acid 60, its ester being presumably hydrolyzed in the alkaline reaction conditions. Ethyl acetoacetate yields the 2-acetyl-3-oxo compound 61, and acetylacetone ° provides the 2-acetyl-3-methyl compound 62. The latter condensation proceeds poorly in ethanolic sodium ethoxide, but heating the nitroso compound with acetylacetone under reflux in pyridine gives a 59% yield of the product 62. °... 

This widely used general approach to pyrroles, utilizes two components one, the a-aminocarbonyl component, supplies the nitrogen and C-2 and C-3, and the second component supplies C-4 and C-5 and must possess a methylene group a to carbonyl. The Knorr synthesis works well only if the methylene group of the second component is further activated (e.g. as in acetoacetic ester) to enable the desired condensation leading to pyrrole to compete effectively with the self-condensation of the a-aminocarbonyl component. The synthesis of 4-methylpyrrole-3-carboxylic acid and therefrom, 3-methylpyrrole illustrates the process. 

Vinyl polymerization using metallocomplexes commonly proceeds by a radical pathway and rarely involves an ionic mechanism. For instance, metal chelates in combination with promoters (usually halogenated hydrocarbons) are known as initiators of homo- and copolymerization of vinylacetate. Similar polymer-bound systems are also known [3]. The polymerization mechanism is not well understood, but it is believed to be not exclusively radical or cationic (as polymerization proceeds in water). The macrochelate of Cu with a polymeric ether of acetoacetic acid effectively catalyzes acrylonitrile polymerization. Meanwhile, this monomer is used as an indicator for the radical mechanism of polymerization. Mixed-ligand manganese complexes bound to carboxylated (co)polymers have been used for emulsion polymerization of a series of vinyl monomers. Macromolecular complexes of Cu(N03)2 and Fe(N03)3 with diaminocellulose in combination with CCI4 are active in polymerization of MMA, etc. 

Acetoacetic acid, CHgCOCHgCOOH, is an aliphatic -keto acid. Derivatives are formed by reduction, activation of the carboxylic group, and decarboxylation. 

Protection as an ester overcomes this problem, but the resulting ester enolate is not particularly stable and its reactions can be low yielding. Addition of a second ester to the alpha carbon serves as an activating group and allows the formation of a stabilized enolate. As seen with the acetoacetic ester synthesis, this ester group can be eventually removed by a decarboxylation reaction. The malonic ester synthesis starts with commercially available diethyl malonate. Deprotonation, alkylation of the resulting enolate with an alkyl haUde, and hydrolysis followed by decarboxylation furnishes a carboxylic acid product. 

The first possibility is dubious, because there is no known biochemical oxidation reaction by which this would be accomplished. The other two possible pathways, acetone dicarboxylic acid or butyric acid, would both yield carboxyl-labeled acetoacetate, and thus 3,4-labeled glucose. The isolation of acetoacetate labeled only in the carboxyl group supports either possibility. An objection against the acetone dicarboxylic acid pathway is that acetoacetate, being a direct metabolic product of glutarate (see equation 6), should exhibit a higher specific activity than its resulting product, acetate. In the experiments of the above authors the specific... 

Hydroxy- 9-methylglutaryl CoA further yields acetyl CoA and acetoacetic acid, as was shown earlier by Coon et cU. (I48). In biotin deficiency the carboxylation reaction does not occur. It was shown by Lynen et al. that the actual carboxylation is preceded by the enzymic dehydration (rf jS-hydroxyisovaleryl CoA to /8-methylcrotonyl CoA, which is the true substrate for the entry of CO2. TTiis occurs at the expense of the hydrolysis of the terminal P04 of ATP. The unsaturated intermediate is then saturated by the addition of H2O to yield the final product. The critical step of this carboxylation is the conversion of CO2 to a reactive form. The analogy of the biochemical activation of other substances through an acyl adenylate type of compound did not fit CO2 activation. The final mechanism of the activation of CO2 was derived from the discovery that the carboxylase enzyme was a biotin-protein. This observation explains earlier work 149) which indicated that biotin is a cofactor of the fatty acid-synthesizing enzyme system. When the purified carboxylase was incubated with P and ATP an exchange reaction of phosphate occurred, which was inhibited by avidin, a protein which specifically binds biotin. This indicated that the primary reaction in CO2 fixation is the combination of ATP with the biotin-protein enzyme to yield ADP biotin-protein -f P. The active CO2 is then the product of an exchange reaction between ADP and C02 which is finally attached to the biotin-protein complex. 

The enzyme (16 inO Fig. 2.1) catalyzes the reversible transfer of the CoA moiety between an acyl-CoA and a carboxylic acid. The physiological reaction of the CoA-transferase, which is synthesized when cells enter the solventogenic phase, is to convert acetoacetyl-CoA into acetoacetate, with acetate or butyrate as the CoA-acceptor. Therefore, the activity of the CoA-transferase results in the reutilization of preformed acetate and butyrate, and the CoA-derivatives of the two acids enter the acid- or solvent-producing pathways. When butyrate is the CoA-acceptor, reaction 16 leads to the production of one acetone... 

Similar reactions are also possible with ethyl acetoacetate. The electrophiles that work well are primary and secondary alkyl halides and sulfonates. Tertiary halides do not react well— elimination is the main reaction. Acyl halides and unhindered epoxides also react well. An important aspect of these processes is that carboxylic acids with a carbonyl group at the p-position are readily decarboxylated (Figure 17.38). We will see in later chapters that we are using the ester as an activating group so that we can make the enolate more easily, but we can eliminate it later. Some examples of the use of this process in synthesis are given in Figure 17.39. 

Just like the aryl azides 2, the vinyl azides 11 are more reactive in their cycloadditions with active methylene compounds than are alkyl azides. In 1970, Alfred Hassner et al. developed a general synthetic approach to 1-vinyl-1,2,3-triazoles 12 and 14, (Scheme 4.4) [6] by the cycloaddition of active methylene compounds 10 or 13 with vinyl azides 11 (or their precursors, the P-haloalkyl azides), in the presence of 1 equiv. of an alkoxide (NaOMe). Decarboxylation of the l- dnyl-5-substituted l,2,3-triazole-4-carboxylic acids 14 synthesized from the reaction of ethyl acetoacetate or ethyl benzoylacetate with vinyl and P-haloalkyl azides led to 1-vinyl-5-substituted 1,2,3-triazoles in almost quantitative yield [6]. 

Biotin is a growth factor for many bacteria, protozoa, plants, and probably all higher animals. In the absence of biotin, oxalacetate decarboxylation, oxalosuccinate carboxylation, a-ketoglutarate decarboxylation, malate decarboxylation, acetoacetate synthesis, citrulline synthesis, and purine and pyrimidine syntheses, are greatly depressed or absent in cells (Mil, Tl). All of these reactions require either the removal or fixation of carbon dioxide. Together with coenzyme A, biotin participates in carboxylations such as those in fatty acid and sterol syntheses. Active C02 is thought to be a carbonic acid derivative of biotin involved in these carboxylations (L10, W10). Biotin has also been involved in... 

Schemes I-IV illustrate the syntheses of the pyrazole pyrethroids reported here. In scheme-I, condensation of ethyl ethoxy-methyl eneacetoacetate (3) (6) and ethyl ethoxymethylenetrifluoro-acetoacetate (4) (7) with phenyl hydrazine in glacial acetic acid initially at room temperature followed by heating at reflux gave the pyrazolecarboxylates 5 (8) and 6 in yields of 43 and 70%, respectively. Reduction with lithium aluminum hydride gave the alcohols 7 and 8 which were then allowed to react with the DV-acid chloride in Et3N/THF to give the pyrethroid isomer mixtures 9 (2) and 10 (4 3 trans/cis) in 80-85% yield from the carboxylates. Pyrethroid 10 was prepared to determine how the increased lipophilicity over 9 affected insecticidal activity.

Occasionally it is unnecessary to isolate the hydrazone since this is itself accessible by a coupling reaction. Numerous formazans can be obtained by treating compounds containing active methylene groups directly with 2 molar proportions of a diazonium salt. For example, pyruvic acid is converted into 3-oxalo-l,5-diphenylformazan (fi4formazylglyoxalic acid ) in 94% yield by benzenediazonium chloride in potassium hydroxide solution.351 Acyl groups (CH3CO or COOH) are often eliminated in such reactions 343,344,352 thus acetoacetic ester yields ethyl l,5-diphenylformazan-3-carboxylate almost... 

The finding that carboxyl groups of fatty acids tend to remain carboxyl groups in acetoacetate and that methyl groups tend to remain methyl groups supported speculation that two types of active acetate were formed, with different propensities for reaction, but both capable of entering either end of acetoacetate. More recent studies on the chemistry of fatty acid oxidation have found evidence for only one 2-carbon... 

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