Hydroxamic acid esters reactions with

The structures of the N-substitution products are reminiscent of the C-8 adduct that is the major product of the reaction of 2-fluorenyl-, 4-biphe-nylyl- and other N-arylhydroxylamine and hydroxamic acid esters with 2 -deoxyguanosine, (d-G) 2 deoxyguanosine-5 -phosphate (d-GMP), guano-sine, (G) or DNA in an aqueous environment." The mechanism of this reaction was not seriously investigated for many years because of the mistaken impression that the reaction was inefficient and could not compete with... 

Hydroxylamine is acylated by carboxylic esters, giving hydroxamic acids. The reaction often occurs in a few hours at room temperature if the components are mixed in alcoholic solution, preferably with addition of an equivalent of an alkoxide. In the latter case the hydroxamic acids are obtained as salts, but are easily liberated therefrom. 

The reaction of hydroxamoyl chlorides with the pyridine-S03 complex affords the salts of the hydroxamic acid ester chlorides XL ( ). 

R = CH3 and AR = C6H4NO2.) Actually Scheme XXV and Eq. (3-176) both take place, with some of the hydroxamic acid being formed directly and some via the intermediate. (Note that each of these reactions is itself complex, presumably occurring via a tetrahedral intermediate as shown in Scheme XXII for ester hydrolysis.)... 

A mixture of 3-hydroxy-4-phenylfurazan and 1,2,4-oxadiazole 243 was prepared from a-phenyl-a-hydroximino hydroxamic acid by acylation and subsequent treatment with 15% aqueous NaOH (Scheme 164) (25G201). The reaction of tetraacetate 244 with sodium acetate hydrate in glacial acetic acid at 70°C gives 3,4-dihydroxyfurazan (9%) (92URP1752734). a-Hydroximino ester 245 reacts with hydroxylamine to form furazan 246 in 25% yield (Scheme 164) (79JHC689). 

As in 10-55 hydrazides and hydroxamic acids can be prepared from carboxylic esters, with hydrazine and hydroxylamine, respectively. Both hydrazine and hydroxylamine react more rapidly than ammonia or primary amines (the alpha effect, p. 445). Imidates, RC(=NH)OR, give amidines, RC(=NH)NH2. Lactones, when treated with ammonia or primary amines, give lactams. Lactams are also produced from y- and 5-amino esters in an internal example of this reaction. 

As early as 1899, 8tieglitz proposed a tetrahedral intermediate for the hydrolysis of an imino ether to an amide. Thns it was clear qnite early that a complicated overall transformation, imino ether to amide, would make more sense as the result of a series of simple steps. The detailed mechanism proposed, althongh reasonable in terms of what was known and believed at the time, wonld no longer be accepted, but the idea of tetrahedral intermediates was clearly in the air. 8tieglitz stated of the aminolysis of an ester that it is now commonly snpposed that the reaction takes place with the formation of an intermediate prodnct as follows referring to work of Lossen. (Note that the favored tautomer of a hydroxamic acid was as yet unknown.)... 

Much more important than these reactions, however, are the reactions of CDI and its analogues with carboxylic acids, leading to AAacylazoles, from which (by acyl transfer) esters, amides, peptides, hydrazides, hydroxamic acids, as well as anhydrides and various C-acylation products may be obtained. The potential of these and other reactions will be shown in the following chapters. In most of these reactions it is not necessary to isolate the intermediate AAacylazoles. Instead, in the normal procedure the appropriate nucleophile reactant (an alcohol in the ester synthesis, or an amino acid in the peptide synthesis) is added to a solution of an AAacylimidazole, formed by reaction of a carboxylic acid with CDI. Thus, CDI and its analogues offer an especially convenient vehicle for activation of... 

The formation of the latter compounds can be attributed to the result of the direct attack of the nucleophile R on the a- or p-carbon atoms of SENAs after elimination of the corresponding protons. However, it is most likely that the reaction proceeds through nitrile oxides or conjugated nitrosoalkenes (see Scheme 3.93). This interpretation is evidenced by generation of silyl esters of hydroxamic acids R CONHOSi as by-products. The reactions with more saturated solutions give the latter compounds as the major products. 

As second example for the scale-up of solid-phase reactions directly on solid support, we chose an arylsulfonamido-substituted hydroxamic acid derivative stemming from the matrix metalloproteinase inhibitor library (MMP) of our research colleagues (Breitenstein et al. 2001). In this case, there was already a solution-phase synthesis available for comparison (see Scheme 4). The synthesis starts with the inline formation of a benzaldehyde 18 with the glycine methyl ester, which is then reduced to the benzylamine 20 using sodium borohydride in methanol/ THF (2 1). The sulfonamide formation is carried out in dioxane/H20 (2 1) with triethylamine as the base and after neutralisation and evaporation the product 21 can be crystallised from tert. butylmethyl ether. After deprotection with LiOH, the acid is activated by treatment with oxalyl chloride and finally converted into the hyroxamic acid 23 in 33.7% yield overall. 

Aldehyde 54 and the hydroxamic acids 55 were generated together in an acid-catalysed elimination reaction (Scheme 7 pathway (ii)). A crossover experiment indicated that esters are formed in a concerted rearrangement concomitant with the likely formation of the hydroxynitrene 57 (Scheme 7 pathway (iii)) while there is no evidence to date for the formation of hydroxynitrene, joint solvolysis of equimolar quantities of /V-acetoxy-/V-butoxy-/>-chlorobenzamide 26e and N- acetoxy-/V-benzyloxybenzamide 27a afforded significant quantities of butyl p-chlorobenzo-ate (36%) and benzyl benzoate (54%) as the only esters. This is an example of a HERON reaction, which has been identified in these laboratories as a characteristic rearrangement of bisheteroatom-substituted amides.32,33,42 43 155 158 Since ester formation was shown to prevail in neutral or low acid concentrations, it could involve the conjugate anion of the hydroxamic acid (vide infra).158... 

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. 

Very recently, Mordini and coworkers" have overcome the problems associated with the long reaction times that are normally required for the synthesis of hydroxamic acids from esters by performing these transformations under MW irradiation. The protective groups are also well tolerated under these reaction conditions, though a partial deprotection of the feri-butoxycarbonyl (Boc) group was observed in the reaction with Boc-proline ester. Amidic bonds and ketals also survive without any detectable decomposition. All the reactions go to completion in about six minutes, except in the case of the conversion of Boc-protected phenylalanine methyl ester, which required longer reaction times (12 min). 

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. 

Dioxazoles 146 are readily prepared by transketalization of 2,2-diethoxypropane, where both the NH and OH moieties are protected in a non-protic form (Scheme 68). The dioxazoles 146 are stable to a wide variety of reaction conditions and readily revert back to the hydroxamic acids 145 and isopropyl ester 147 (145/147 50/1) by treatment with Nafion-H in 2-propanol. The method is applicable to primary, secondary, tertiary and aromatic hydroxamic acids, and the acidity of the protons adjacent to the dioxazole allows R-functionalization. 

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. 

Opening of the dithiazole ring of the imidazolo[4,5-r7 [l,2,3]dithiazole 107 was employed as a key step in a multistep synthesis leading to hydroxamic acid derivatives 108 and 109 which are under investigation as matrix metalloproteinase inhibitors. Following initial reaction of 107 with NaOH treatment with 2-bromo-3-(4-chlorophenyl)propionic acid tert-butyl ester lead to the thioethers 108 from which 109 could be obtained (Scheme 10). <2000W0063197>. 

In 1984 Gassman and Granrud, and Novak and co-workers, published their results on reactions of similar esters of hydroxamic acids. Gassman and Granrud showed that the rearrangement of the methanesulfonate esters 45a-g in CDCI3 (Scheme 23) occurred in a first-order fashion and that kobs correlated with with a slope,, of -9.2. Novak and co-workers showed that the pH-independent first-order rate constants for hydrolysis in 5 vol%... 

Since differences were often reported in product yields from photochemical and thermal reactions, it was not clear that the same intermediate was generated in both cases. This issue was complicated by the fact that the temperatures under whieh the two experiments were run were usually quite different. The acid-base chemistry of nitrenium ions was largely unexplored so it was not known under what conditions these species could be protonated or deprotonated. It had also not been demonstrated that nitrenium ions played any role in the biological activity of mutagenic and carcinogenic esters of N-arylhydroxylamines or hydroxamic acids, particularly in their reactions with the DNA bases. Over the next decade these issues would be resolved but many questions about nitrenium ion chemistry would remain unanswered. 

The first term of the rate law requires acid-catalyzed decomposition of the conjugated acid of the ester. This term predominates only under strongly acidic conditions. It has not been investigated in detail, but the major product of the acid catalyzed reaction is the corresponding hydroxylamine. The second term predominates under neutral to mildly acidic conditions. This term is consistent with uncatalyzed heterolysis of the N—O bond of the neutral ester to generate a heteroaryinitrenium ion. " The rate law is more complicated than that for reactive esters of carbocyclic hydroxylamines or hydroxamic acids that show pH-independent decomposition over a wide pH range. The kinetic behavior of the heterocyclic esters is caused by protonation of a pyridyl or imidazolyl N under mildly acidic conditions. The protonated substrates are not subject to spontaneous uncatalyzed decomposition, so decreases under acidic conditions until acid-catalyzed... 

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