Benzyl hydroxamates

Benzyl-oxygen bonds may be cleaved under conditions mild enough to leave an allylic hydroxy group (759) or an easily reduced N—OH bond intact (65,80). N-Hydroxyamino acids can be prepared in good yield by hydrogenolysis of benzyl hydroxamates as shown in the synthesis of N -hydroxylysine (6) from 5 (777). 

Later, ICrook and Miller found that /3-mesylates of benzyl hydroxamate of a-acylserine (149c X = OMs R = = H R = CHiPh) can be directly cyclized under... 

Palladium supported on barium sulfate is an efficient catalyst in the hydrogeno-lysis of benzyl hydroxamates to give the corresponding hydroxamic acids [Scheme 4.134].249 With palladium on charcoal, reduction of the N-O bond was observed. 

The Miller group [71] continued investigation on the cychzation of /3-hydroxy-O-benzyl hydroxamates in the presence of the Mitsimobu reagent leading to N-benzyloxy- -lactams. The Perrier rearrangement of o-glucal 91 followed by formation of hydroxamate and deacetylation provided a substrate 92 suitable for cychzation. hi the Mitsunobu reaction conditions 92 was converted into the -lactam 93, which was oxidized to the lactone 94 (Scheme 24). 

Shaw and McDowellhave prepared imidazolone derivatives by cyclization of a-acylamino amides. In a variation of this reaction the azlactone (30) was gradually converted to the hydroxamic acid (31) by methanolic hydroxylamine. Sodium methoxide and hydroxylamine readily gave the acyclic hydroxamic acid (32) which could be cyclized to 31 by dilute acid. Benzyloxyurea has been used in the sjrnthesis of pyrimidine hydroxamic acids (33) by reaction with /S-diketones followed by catalytic hydrogenation of the benzyl group. Protection... 

Cyclic hydroxamic acids and V-hydroxyimides are sufficiently acidic to be (9-methylated with diazomethane, although caution is necessary because complex secondary reactions may occur. N-Hydroxyisatin (105) reacted with diazomethane in acetone to give the products of ring expansion and further methylation (131, R = H or CH3). The benzalphthalimidine system (132) could not be methylated satisfactorily with diazomethane, but the V-methoxy compound was readil3 obtained by alkylation with methyl iodide and potassium carbonate in acetone. In the pyridine series, 1-benzyl-oxy and l-allyloxy-2-pyridones were formed by thermal isomeriza-tion of the corresponding 2-alkyloxypyridine V-oxides at 100°. 

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... 

The tris-hydroxamate encapsulating ligand (278) can be assembled by high dilution acylation of (279) with X = NHOBz by (279) with X = COCl, followed by removal of the benzyl protecting... 

Intramolecular addition of hydroxylamines and hydroxamic acids to the non-activated double bonds is possible through oxidative cyclization. Reaction of O-Acyl fi,y-unsaturated hydroxamates (e.g. 56, equation 38) with bromine provides 3,4-substituted iV-hydroxy -lactams such as 57 with high diastereoselectivity. Analogous reaction of O-benzyl hydroxylamine 58 (equation 39) with iodine results in five-membered cyclization with 2 1 ratio of diastereomers. ... 

In 2001, De Luca and GiacomeUi " reported a new simple and high-yielding one-flask synthesis of Weinreb amides from carboxylic acids and A-protected amino acids that uses different 1,3,5-triazine derivatives (such as 236) as the coupling agents (Scheme 104). The method allows the preparation of Weinreb amides 237 and hydroxamates as O-benzyl and 0-silyl hydroxamates that can be easily transformed into hydroxamic acids. 

Alkoxyl and acetoxyl protons in A-acetoxy-A-alkoxybenzamides give rise to sharp signals well below room temperature. In contrast, hydroxamic esters usually exhibit line broadened alkoxyl group resonances in their H NMR spectra at or even signihcantly above room temperature" . In toluene-rfg, the benzylic and acetoxyl methyl resonances of A-acetoxy-A-benzyloxybenzamide (100) showed signihcant line broadening below 250 K but remained isochronous down to 190 K. 

Photoexcited nitrobenzene may be used for benzylic hydroxylation (at C-9) of 17/3-acetoxy-3-methoxyoestra-l,3,5(10)-triene. The photochemistry of the 17/3-nitro-steroid (217) is markedly solvent dependent, the major products being in ether the 17-desnitro-compound (218), in propan-2-ol the hydroxylamine (219), and in EtOH-NaOEt the hydroxamic acid (220) and the cyclopropane (221). The hydroxamic acid (220) is probably formed through the oxaziridine (Scheme 7). Although there are analogies to this in the photochemistry of nitrones and oximes, the photoreduction of a nitroalkane in propan-2-ol to an alkyl-hydroxylamine appears to have no precedent. Further studies of photochemistry of conjugated... 

S Additional information <9, 15, 17, 18, 21, 24, 30, 33, 35> (<18> activity is regulated by light [28] <30> D-aspartate, L-glutamate and -alanine are inactive as substitutes for L-aspartate in the forward reaction, in the reverse reaction ADP cannot be replaced by AMP, UDP, GDP or IDP [1] <17> aspartokinase III, o-isomers of the derivatives of aspartic acid, including D-aspartate cr-benzyl ester and o-aspartate /)-hydroxamate are not substrates regardless of whether the a- or the -carboxyl group is derivatized, L-cysteine sulfinate and 2-methyl-DL-aspartate are no substrates... 

Recently Benkovic and Schrayl28b and Clark and Kirby,26c have investigated the hydrolysis of dibenzylphosphoenolpyruvic acid and mono-benzylphospho-enolpyruvic acid which proceed via stepwise loss of benzyl alcohol (90%) and the concomitant formation of minor amounts (10%) of dibenzylphosphate and monobenzylphosphate, respectively. The pH-rate profiles for release of benzyl alcohol reveal that the hydrolytically reactive species must involve a protonated carboxyl group or its kinetic equivalent. In the presence of hydroxylamine the course of the reaction for the dibenzyl ester is diverted to the formation of dibenzyl phosphate (98%) and pyruvic acid oxime hydroxamate but remains unchanged for the monobenzyl ester except for production of pyruvic acid oxime hydroxamate. The latter presumably arises from phosphoenolpyruvate hydroxamate. These facts were rationalized according to scheme (44) for the dibenzyl ester, viz. 

The hydrolytic products are benzyl alcohol and the corresponding enol phosphonate produced through carboxyl group participation. In the presence of hydroxylamine the products are diverted to benzyl phenylphosphonate and pyruvate oxime hydroxamate. These experimental results contrast markedly with those observed for the phosphoacetoin system. A simple explanation for the formation of benzyl phenylphosphonic acid is generation of the penta-covalent species (47)... 

The cyclic phosphonate may be intercepted with hydroxylamine to yield the corresponding hydroxamate. Importantly, the rate of hydroxylaminolysis is approximately the same as ethanol loss, thus it appears that the cyclic phosphonate and not a precursor pentacovalent species is being trapped. Insofar as the analogy is appropriate, hydroxylamine is trapping an acyclic acyl phosphate in the above case, albeit at a rate faster than benzyl alcohol loss. It is also noteworthy that for both the phosphonate and phosphate esters there is no net transfer of oxygen from the carboxyl to phosphorus during the entire course of hydrolysis, i.e. loss of two moles of alcohol. 

As illustrated by the examples in Table 3.9, resin-bound 4-alkoxybenzylamides often require higher concentrations of TFA and longer reaction times than carboxylic acids esterified to Wang resin. For this reason, the more acid-sensitive di- or (trialkoxy-benzyl)amines [208] are generally preferred as backbone amide linkers. The required resin-bound, secondary benzylamines can readily be prepared by reductive amination of resin-bound benzaldehydes (Section 10.1.4 and Figure 3.17 [209]) or by A-alkyla-tion of primary amines with resin-bound benzyl halides or sulfonates (Section 10.1.1.1). Sufficiently acidic amides can also be A-alkylated by resin-bound benzyl alcohols under Mitsunobu conditions (see, e.g., [210] attachment to Sasrin of Fmoc cycloserine, an O-alkyl hydroxamic acid). 

If the desired hydroxamic acids are sufficiently hydrophobic, workup is easily carried out using extraction and flash chromatography. However, many hydroxamic acids are soluble in polar solvents, which causes problems during isolation and purification. The structure of hydroxamic acid thermolysin inhibitors can be made more potent by the introduction of a malonyl moiety to match the specificity of thermolysin (Scheme 3). For example, in the synthesis of HONHCOCH(Bzl)CO-L-Ala-Gly-NH2 (4), O-benzylhydroxylamine was employed in the synthetic scheme to facilitate the isolation and purification of the intermediate 2.[101 The final precursor is a benzyl-protected hydroxamate 3 that can be deprotected by hydrogenolysis without byproducts contaminating the desired hydroxamic acid 4. 

The nitrone of piperidine reacts with phenyl vinyl ether to yield a 1,3-dipolar cycloaddition product. Benzylation led to a ring-opened product which was converted to a hydroxamic acid. This is desired functionality in medicinal chemistry because it is a metal-binding ligand <03S1221>. 

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