Hydroxylamine reaction with esters

Formally, they can all be viewed as derivatives of hydroxylamine, H2N—OH indeed, oximes can be prepared by the addition of hydroxylamine to aldehydes and ketones (equations 1 and 2), and hydroxamic acids by its reactions with acetyl halides and esters (equations 3 and 4). ... 

Nowadays, the most economical way of preparing hydroxamic acid derivatives is the reaction of hydroxylamine with acid chlorides or esters . Unfortunately, the preparation of acid chlorides is often tedious. In addition, it is very difficult to avoid further acylation during the reaction with hydroxylamine. 

The syntheses of the methyl esters 116-118 from 115 and hydroxamic acids 119-121 were carried out via a typical alkylation of the hydroxy function of methyl 4-hydroxyben-zoate 116 followed by either reaction with hydroxylamine to provide bishydroxamic acids 119-121 containing an alkyl spacer between two aromatic rings. 

In 2003, Devocelle and colleagues reported a convenient two-step procedure for the parallel synthesis of hydroxamic acids (or O-protected hydroxamic acids 207) from carboxylic acids and hydroxylamine. It involves the formation of a polymer-bound HOBt active ester 206 from 204 and the acid 205 and subsequent reaction with O-protected or free hydroxylamine (Scheme 89). The use of free hydroxylamine leads to increased yields while maintaining high purities. Recycling of the exhausted resin 204 to prodnce the same or a different hydroxamic acid has been achieved by a three-step protocol, which is easily amenable to automation and cost-economical. 

The dibasic side chain at position 7 can be alternatively provided by a substituted amino alkyl pyrrolidine. Preparation of that diamine in chiral form starts with the extension of the ester function in pyrrolidone (46-1) by aldol condensation with ethyl acetate (46-2). Acid hydrolysis of the (3-ketoester leads to the free acid that then decarboxylates to form an acetyl group (46-3). The carbonyl group is next converted to an amine by sequential reaction with hydroxylamine to form the oxime, followed by catalytic hydrogenation. The desired isomer (46-4) is then separated... 

Mukund Sibi of North Dakota State University has developed (J. Am. Chem. Soc. 2004,126,718) a powerful three-component coupling, combining an a,(5-unsaturated amide 9, a hydroxylamine 10, and an aldehyde 11. The hydroxylamine condenses with the aldehyde to give the nitrone, which then adds in a dipolar sense to the unsaturated ester. The reaction proceeds with high diastereocontrol, and the absolute configuration is set by the chiral Cu catalyst. As the amide 9 can be prepared by condensation of a phosphonacetate with another aldehyde, the product 12 can be seen as the product of a four-component coupling, chirally-controlled aldol addition and Mannich condensation on a starting acetamide. 

Cleavage of enol estersEnol esters arc converted to oximes of the corresponding ketone by reaction with excess hydroxylamine in THF or pyridine. 

The teichoic acid which had not been subjected to ion-exchange chromatography contained D-alanine in characteristic, labile, ester linkage. It contained insufficient glucose to accommodate all of the alanine ester residues (alanine phosphorus ratio, 0.89 1), and the kinetics of the reaction with hydroxylamine indicated that all of the alanine is attached to the available hydroxyl groups at C-2 of glycerol residues. 

The teichoic acid shows an infrared absorption band at 1751 cm.-1, characteristic of carboxylic ester groups, which is not observed in samples from which the D-alanine residues have been removed. Removal of the u-alanine was readily effected with ammonia or hydroxylamine, when D-alaninamide or D-alanine hydroxamate were formed. The kinetics of the reaction with hydroxylamine reveal the high reactivity of its D-alanine ester linkages, which, like those in most other teichoic acids, are activated by the presence of a neighboring phosphate group. That the D-alanine residue is attached directly to the ribitol residues, instead of to the d-glucosyl substituents, was also shown by oxidation with periodate under controlled conditions of pH, when it was found that the D-alanine residues protect the ribitol residues from oxidation. Under the same conditions, all of the ribitol residues were oxidized in a sample of teichoic acid from which the D-alanine had been removed, and it is concluded that the ester groups are attached to C-2 or C-3 of the ribitol residues. 

The 3-ester group was transformed by transesterification,266 by hydra-zinolysis,131,133,136,137,26 1,307 and by reaction with hydroxylamine.74,75... 

The catalytic action of ChE s is, however, not limited to ester hydrolysis. Thus, these enzymes catalyze also the reverse reaction, i.e., esterification of acids with choline (14). They promote transesterification 15) and the condensation of hydroxylamine with acids 14) or esters 15). Anhydrides of carboxylic acids are also substrates of ChE s 16, 17) and can undergo all the reactions, mentioned with esters, i.e., hydrolysis, esterification, and hydroxamation. 

A great deal is known about the photochemistry of carbenes (Chapter 2) and in the cases of the diazirine precursors given here (Table 3.1) it can confidently be predicted that the adducts formed on irradiation with proteins will be stable under most of the conditions necessary for further study (Fig. 2.1). Of course common sense should be exercized, e.g. insertion into carboxyl groups will yield esters which are unstable to hydrolysis or to treatment with hydroxylamine (e.g. Ross et al., 1982), and the possibility of reaction with peptide bonds culminating in polypeptide chain cleavage has already been mentioned (Section 2.1, Fig. 2.2). 

This reaction was extended to other (i-dicarbonyl compounds containing a nitro group [474 176], The mechanism of the reaction of hydrazine with 1,3-dicarbonyl compounds is still largely unclear. Nevertheless, important evidence was obtained to indicate that a dihydroxypyrazolidine intermediate is formed in this reaction [477], If hydroxylamine is used instead of free hydrazine in the reaction with nitromalonaldehyde, the product is 4-nitroisoxazole [471], When a mixture of nitrocyanoacetic ester with one equivalent of hydrazine hydrate and a small amount of water is boiled, 5-amino-4-nitro-3-pyrazolone is formed [478],... 

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