Isourea, O-acyl

The reaction of Ccf -ATPase with dicyclohexylcarbodiimide Carbodiimides readily react in aqueous solutions with protein amino, carboxyl and sulfhydryl groups slower reactions with tyrosine and serine have also been reported [369,370]. The primary reaction product of carboxyl groups with dicyclohexylcarbodiimide is dicyclohexyl-O-acyl isourea [370]. Dicyclohexyl-O-acyl isourea is susceptible to nucleophilic attack either by water or by endogenous or exogenous nucleophiles, yielding a complex series of reaction products [369-371]. 

In a related study by the same authors, the effect of microwave irradiation on car-bodiimide-mediated esterifications on a solid support was investigated, employing benzoic acid [29]. The carboxylic acid was activated using N,N -diisopropylcarbodi-imide (DIC) through the O-acyl isourea or the symmetrical anhydride protocol (Scheme 7.9). The isourea protocol was carried out in a dichloromethane/N,N-di-methylformamide mixture in sealed vessels, whereas the anhydride reactions were carried out in l-methyl-2-pyrrolidinone (NMP) at atmospheric pressure. 

Table VIII lists some commonly used activating groups. That most widely in use is dicyclohexylcarbodiimide (DCC), often in conjunction with additives such as A -hydroxysuccinimide (HONSu) or HOBt. These convert the O-acyl isourea intermediate 12 into the N-acyl derivative 13 (Scheme 14), which is less prone to racemization under the experimental conditions. But it must be emphasized that all such chemical methods involve some racemization of asymmetric centers, and the trick is to reduce this to an absolute minimum.

B, so-called O-acyl isoureas. To a certain extent, these constitute diaza analogs of the mixed anhydrides B of Figure 6.14. As can therefore be expected, O-acyl isoureas react with good nucleophiles with the same regioselectivity as their oxygen analogs at the carboxyl carbon of the carboxylic acid moiety. 

It seems to be reasonable to attribute some basic character to O-acyl-isoureas and therefore general base catalysis... 

The presence of a second nucleophile in the reaction mixture reduces the concentration of the O-acylisourea and thereby the extent of racemization. Also, HOBt, a weak acid, prevents proton abstraction from the chiral carbon atom and thus contributes to the conservation of chiral purity in a second manner as well. Last, but not least the availability of the auxiliary nucleophile (HOBt) efficiently shortens the lifetime of the overactivated O-acyl-isourea intermediate and thus diminishes the extent of O N acyl-migration leading to... 

A typical procedure calls for reaction of the hemiacetal donor with dicydohexyl carbodiimide and copper(I) chloride (0.1 equiv) at 80 °C, followed by an addition of the acceptor and continued heating. As an early demonstration of this protocol, oc-riboside 86 was prepared in moderate yield but with exclusive stereoselectivity [141]. Further measures were required for the glycosylation of monosaccharide acceptors, such as addition of p-toluenesulfonic add (0.1 equiv) to promote the formation of disaccharide 87 [144]. The method was more suitably applied to the synthesis of O-acyl glycopeptides, as evidenced by the formation of 88 in 60% yield [143,144]. Various peptides with non-nudeophilic side chains were found to be amenable to this stereoselective reaction. The [3-selectivity was suggested to arise from a preponderance of the a-isourea intermediate 85 in the activation step. 

All other carboxylic acid derivatives in Table 6.1, in which the leaving group is bound to the carboxyl carbon through an O atom, are increasingly better acylating agents than carboxylic acid alkyl esters (entry 3) in the order carboxylic acid phenyl ester (entry 4) < acyl isourea (entry 7) < mixed carboxylic acid/carbonic acid anhydride (entry 8) < carboxylic acid anhydride (entry 9) < mixed carboxylic acid anhydride (entry 10). 

Poor nucleophiles react with acyl isoureas B so slowly that the latter start to decompose. In some sense they acylate themselves. The N atom designated with the positional number 3 intramolecularly substitutes the O-bound leaving group that is attached to the carboxyl carbon Cl. A four-membered cyclic tetrahedral intermediate is formed. When the Cl -Ol bond in this intermediate opens up, the N-acyl urea E is produced. Because compound E is an amide derivative it is no longer an acylating agent (cf. Section 6.2). 

Isoquinudidine derivs. 2-azabicyclo[12.2]-octane derivs. retro-synthesis, 212-213 synthesis, 153, 291, 297 Isothioureas, 5-alkyl- thiols from, 168 Isoureas, O-acyl- = carbamimidic anhydrides reactive intermediates, 144-145, 234 —, O-alkyl- carbamimidic esters, 144-145 Isoxazoles, 307—308 —, 4,5-dihydro-, 153 Isoxazolidines, 153... 

The A-acyl-O-arylhydroxylamine 166 rearranges in the presence of trifluoroacetic acid to 168 by a [3,3]-sigmatropic shift. An isourea intermediate 167 was proposed to explain the observed transformation (equation 49). 

Acylation with potassium cyanate, phenylisocyanate and similar reagents gives ureides <8lHC(37)l. p. 102). According to experimental conditions, cyanogen affords the carboxamide (87). The anomalous reaction with o-anisylisocyanate results in the isourea (88). 

Carbodiimide method, a procedure for peptide bond formation using carbodi-imides, R-N=C=N-R, such as dicyclohexyl carbodiimide (DCC), diisopropyl carbodiimide (DIC) and water-soluble carbodi-imides. The carbodiimide reacts in a one-pot procedure with the carboxylate anion of the carboxy component to form a highly reactive O-acylisourea intermediate. The former reacts immediately with the amino function of the amino component to yield the desired peptide derivative and the urea byproduct. Indeed, a more complex mechanism must be taken into consideration. Unwanted side reactions are racemization via the oxazolone mechanism and formation of the unreactive N-acylurea by base-catalyzed acyl migration from the isourea oxygen to nitrogen. The side reactions can be diminished by preparing the O-acylisourea at 0 °C... 

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