Acetoacetate activation

Beinert and Stansley " have investigated the nature of the reactions leading to asymmetrically-labeled acetoacetate with a soluble enzyme system from pig heart, viz. the acetoacetate activation and cleavage enzyme system. This system carries out the condensation-cleavage reaction... 

The acetoacetic ester condensation (involving the acylation of an ester by an ester) is a special case of a more general reaction term the Claisen condensation. The latter is the condensation between a carboxylic ester and an ester (or ketone or nitrile) containing an a-hydrogen atom in the presence of a base (sodium, sodium alkoxide, sodamide, sodium triphenylmethide, etc.). If R—H is the compound containing the a- or active hydrogen atom, the Claisen condensation may be written ... 

Malonic ester, like acetoacetic ester (Section 111,151), when treated with an equivalent of sodium ethoxide, forms a mono-sodium derivative, which is of great value in synthetical work. The simplest formulation of the reaction is to r rd it as an attack of the basic ethoxide ion on a hydrogen atom in the CH, group the hydrogen atoms in the CHj group are activated by the presence of the two adjacent carbethoxyl groups ... 

The acetoacetate enolate ion (A in frame 54) is a reagent for the synthon B, the acetone anion. We shall discover how to add the COiEt activating group later. 

Another important reaction of diketene derivatives is the Hant2sch pyridine synthesis (101). This synthesis is the preparation of 1,4-dihydropyridines (14) starting either from two acetoacetic esters, which react with an aldehyde and ammonia or a primary amine or from 3-aminocrotonates and 2-alkyhdene acetoacetic esters, both diketene derivatives. Several such dihydropyridines such as nifedipine [21829-25-4] (102), nimodipine [66085-59-4] and nicardipine [55985-32-5] exhibit interesting pharmaceutical activity as vasodilators (blood vessel dilation) and antihypertensives (see Cardiovascularagents). 

Carbon is alkylated ia the form of enolates or as carbanions. The enolates are ambident ia activity and can react at an oxygen or a carbon. For example, refluxing equimolar amounts of dimethyl sulfate and ethyl acetoacetate with potassium carbonate gives a 36% yield of the 0-methylation product, ie, ethyl 3-methoxy-2-butenoate, and 30% of the C-methylation product, ie, ethyl 2-methyl-3-oxobutanoate (26). Generally, only one alkyl group of the sulfate reacts with beta-diketones, beta-ketoesters, or malonates (27). Factors affecting the 0 C alkylation ratio have been extensively studied (28). Reaction ia the presence of soHd Al O results mosdy ia C-alkylation of ethyl acetoacetate (29). 

The most convenient synthesis of 6-hydroxy-2-pyridones is by the condensation of a P-ketoester, eg, ethyl acetoacetate, with an active methylene compound, eg, malonic ester, cyanoacetic ester, and an amine. The amine can be omitted if an acetamide is used and in some cases this modification results in a higher yield. 

Similar pyrimidine-to-pyridine conversions were also reported for purine and 8-azapurine with C-H active acetonitriles, ethyl acetoacetate, acetylacetone with dimedone 8-azapurine is converted into triazolotetra-hydroquinoline (Scheme 15) (73JCS(P1)1620, S(Pl)1625, S(P1)1794). 

Although the antithyroid activity of compounds incorporating an enolizable thioamide function was discussed earlier, this activity was in fact first found in the pyrimidine series. The simplest compound to show this activity, methylthiouracil (80) (shown in both enol and keto forms), is prepared quite simply by condensation of ethyl acetoacetate with thiourea.Further work in this series shows that better activity was obtained by incorporation of a lipophilic side chain. Preparation of the required dicarbonyl compound starts with acylation of the magnesium enolate of the unsyrametrically esterified malonate, 81, with butyryl chlo-... 

Cyclization of the two pendant alkyl side chains on barbiturates to form a spiran is consistent with sedative-hypnotic activity. The synthesis of this most complex barbiturate starts by alkylation of ethyl acetoacetate with 2-chloropentan-3-one to give 152. Hydrolysis and decarboxylation under acidic conditions gives the diketone, 153. This intermediate is then reduced to the diol (154), and that is converted to the dibromide (155) by means of hydrogen bromide. Double Internal alkylation of ethyl... 

A change in the pK of the molecule by elimination of the acidic enol function and inclusion of basic nitrogen leads to a marked change in biologic activity. That agent, chromonar (13) shows activity as a coronary vasodilator. Alkylation of ethyl acetoacetate with 2-chlorotriethylamine affords the substituted ketoester (10). Condensation with resorcinol in the presence of sulfuric acid affords directly the substituted coumarin (11). 

Activity is apparently retained when the ring nitrogen is alkylated as in flordipine (42). Aldol condensation of the benzaldehyde 39 with ethyl acetoacetate gives the unsaturated ester 40. The nitrogen containing reaction partner 41 is obtained by condensation of 32 with 2- morpholi-noethylamine. Reaction of 40 with 41 leads to flordipine (42) [12]. 

The methyl groups adjacent to the pyridine nitrogens can also be modified without changing calcium channel blocking activity. The most significant change involves replacement of methyl by a nitrile group. Hantsch type condensation of the nitrobenzaldehyde 43 with methyl acetoacetate and the vinyl amine 44 from isopropyl 3-cyano-3-ketopropionate leads directly to nilvadipine (45) [13]. 

Pyrimidinopyrazines related to folic acid have been investigated in some detail for their antimeta-bolic and antineoplastic activities. A related compound, which lacks one nitrogen atom, has been described as an antiproliferative agent, indicating it too has an effect on cell replication. Aldol condensation of the benzaldehyde 99 with ethyl acetoacetate gives the cinnamate 100. This is then reduced catalytically to the acetoacetate 101. Reaction of that keto ester with 2,4,6- triami-nopyrimidine gives the product 102 which is subsequently chlorinated (103) and subjected to hydrogenolysls. There is thus formed piritrexim (104) [17]. 

From Table 3, it can be seen that the reactivity of acyl acetanilide, such as BAA or AAA, is higher than that of the other reductant reported from our laboratory, i.e., acetanilide (AA), N-acetyl-p-methylaniline (p-APT), acetylacetone (AcAc), and ethyl acetoacetate (EAcAc). Moreover, the promoting activities of derivatives of acetoacetanilide were affected by the ortho substituent in benzene ring, and the relative rate of polymerization Rr) decreased with the increase of the bulky ortho substituent to the redox reaction between Ce(IV) ion and substituted acetoacetanilide. 

Condensation of 165 with chloroacetamide derivatives afforded (89JIC246) carbamoylhydrazino derivatives 168. Some are active against S. aureus and Escherichia coli. Condensation of 165 with ethyl cyanoace-tate, malononitrile, ethyl acetoacetate, or acetylacetone gave (87AP1191, 87PHA664 89JHC769) 169 and 170, whose bactericidal activity has been reported. 

A constant interest in the development of new rapid methodologies for the preparation of oxazole hbraries is motivated by their presence in numerous biologically active natural products. Janda and coworkers were hrst to show that oxazoles can be obtained by microwave-assisted treatment of polymer-bound a-acylamino-/f-ketoesters with Burgess reagent [68]. Hydroxybutyl-functionalized /anda/el resin was used for this investigation, with key steps being monitored by on-bead FT-IR. First, a resin-bound acetoacetate was pre-... 

The rate of mitochondrial oxidations and ATP synthesis is continually adjusted to the needs of the cell (see reviews by Brand and Murphy 1987 Brown, 1992). Physical activity and the nutritional and endocrine states determine which substrates are oxidized by skeletal muscle. Insulin increases the utilization of glucose by promoting its uptake by muscle and by decreasing the availability of free long-chain fatty acids, and of acetoacetate and 3-hydroxybutyrate formed by fatty acid oxidation in the liver, secondary to decreased lipolysis in adipose tissue. Product inhibition of pyruvate dehydrogenase by NADH and acetyl-CoA formed by fatty acid oxidation decreases glucose oxidation in muscle. 

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). 

A closely related reaction has been performed with other aldehydes and even with ketones without a catalyst, but with heat. The aldehydes and ketones here are active ones, such as chloral and acetoacetic ester. The product in these cases is a 3-hydroxy alkene, and the mechanism is pericyclic ... 

The diazo transfer reaction between p-toluenesulfonyl azide and active methylene compounds is a useful synthetic method for the preparation of a-diazo carbonyl compounds. However, the reaction of di-tert-butyl malonate and p-toluenesulfonyl azide to form di-tert-butyl diazomalonate proceeded to the extent of only 47% after 4 weeks with the usual procedure." The present procedure, which utilizes a two-phase medium and methyltri-n-octylammonium chloride (Aliquat 336) as phase-transfer catalyst, effects this same diazo transfer in 2 hours and has the additional advantage of avoiding the use of anhydrous solvents. This procedure has been employed for the preparation of diazoacetoacetates, diazoacetates, and diazomalonates (Table I). Ethyl and ten-butyl acetoacetate are converted to the corresponding a-diazoacetoacetates with saturated sodium carbonate as the aqueous phase. When aqueous sodium hydroxide is used with the acetoace-tates, the initially formed a-diazoacetoacetates undergo deacylation to the diazoacetates. Methyl esters are not suitable substrates, since they are too easily saponified under these conditions. 

Reaction of 1,2-glycol systems, such as in the hemiacetal sesquiterpene 1751, with Me3SiCl/NaI in acetonitrile for 5 min at ambient temperature affords more than 80% of the corresponding olefin 1752 [15, 16] (Scheme 12.4). On reacting active methylene groups such as in ethyl acetoacetate or acetylacetone with benzal-dehyde in the presence of TCS14/Nal in acetonitrile, the intermediate unsaturated ketones 1753 and 1755 are reduced to ethyl 2-benzylacetoacetate 1754 [17] or 2-benzylacetylacetone 1756 [18] in 82% and 80% yield, respectively. 

While an active enzymatic mechanism produces acetoacetate from acetoacetyl-CoA in the liver, acetoacetate once formed cannot be reactivated directly except in the cytosol, where it is used in a much less active pathway as a precursor in cholesterol synthesis. This accounts for the net production of ketone bodies by the liver. 

In extrahepatic tissues, acetoacetate is activated to acetoacetyl-CoA by succinyl-CoA-acetoacetate CoA transferase. CoA is transferred from succinyl-CoA to form acetoacetyl-CoA (Figure 22-8). The acetoacetyl-CoA is split to acetyl-CoA by thiolase and oxidized in the citric acid cycle. If the blood level is raised, oxidation of ketone bodies increases until, at a concentration of approximately 12 mmol/L, they saturate the oxidative machinery. When this occurs, a large proportion of the oxygen consumption may be accounted for by the oxidation of ketone bodies. 

Diazonium salts add to active methylene compounds, for example ethyl acetoacetate, to form an intermediate azo compound (22), followed by the addition of a second diazonium salt (under more alkaline conditions) to yield the tetrazene (23) which then forms a 3-substituted formazan (24)10... 

Three compounds acetoacetate, P-hydroxybutyrate, and acetone, are known as ketone bodies. They are suboxidized metabolic intermediates, chiefly those of fatty acids and of the carbon skeletons of the so-called ketogenic amino acids (leucine, isoleucine, lysine, phenylalanine, tyrosine, and tryptophan). The ketone body production, or ketogenesis, is effected in the hepatic mitochondria (in other tissues, ketogenesis is inoperative). Two pathways are possible for ketogenesis. The more active of the two is the hydroxymethyl glutarate cycle which is named after the key intermediate involved in this cycle. The other one is the deacylase cycle. In activity, this cycle is inferior to the former one. Acetyl-CoA is the starting compound for the biosynthesis of ketone bodies. 

Nothing seems to be known as yet of the metabolic regulation of enzymes of poly(3HB) producing bacteria that catalyze the last step of the poly(3HB) cycle, i. e., the activation of acetoacetate (Fig. 1, steps 9,10). Since both enzymes are involved in a catabolic sequence, it may be speculated that they are inhibited, for... 

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