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Acyl-transfer, from amides

The direct reaction of indoles with carbon dioxide at atmospheric pressure to give the 3-carboxylated derivatives has been reported. The reaction occurs in dimethyl for-mamide in the presence of a large excess in lithium t-butoxide whose function is to deprotonate the indole. Although the N-H proton is more acidic, the C(3) anion yields the thermodynamically more stable carboxylated product. Acyl transfer from amides, such as A-(4-nitrophenyl)acetamide to benzene may occur in triflic acid. The mechanism is likely to involve diprotonation of the amide, as shown in (39), and dissociation of the C-N bond to give an acyl cation. The methodology allows the formation of aromatic ketones by inter- or intra-molecular reaction. The acylation of arenes may also be... [Pg.221]

LGA PROVIDED BY METAL IONS IN THE ACYL TRANSFER FROM AMIDES, UREAS, AND CARBAMATES TO SOLVENT ROH... [Pg.38]

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... [Pg.22]

Compound A is an ester but has within it an amine function. Acyl transfer from oxygen to nitrogen converts the ester to a more stable amide. [Pg.568]

Better for the lateral lithiation of phenols are the N,N-dialkylcarbamate derivatives 444. These may be lithiated with LDA, allowing complete selectivity for the lateral position, presumably because this is the thermodynamic product.192 With s-BuLi ortholithiation is the predominant reaction pathway. If the lateral organolithium 445 is warmed to room temperature, an acyl transfer from O to C takes place, analogous to the anionic ortho-Fries (see section 2.3.2.1.4), giving amide 446.365... [Pg.80]

The resolving agent must now be removed by hydrolysis of the amide. This is a risky business as enolisation would destroy the newly formed stereogenic centre, and a cunning method was devised to rearrange the amide 30 into a more easily hydrolysed ester by acyl transfer from N to O. The rest of the synthesis is as before. By this means the alcohol 28 was obtained almost optically pure, <0.4% of the other enantiomer being present. No further reactions occur at the newly formed stereogenic centre, so the absolute chirality of 22 is as shown. [Pg.441]

Tetrahedral intermediates vary enormonsly in stability relative to the corresponding carbonyl componnds, from extremes like hexaflnoroacetone hydrate where it is difflcnlt to remove the nncleophile from the addnct, to amide hydrates where the obligatory intermediate in acyl transfer is present at nndetectably low concentrations. Linear free-energy relations provide a route to calculating the eqnilibrinm constant... [Pg.39]

In 1982 Cardillo used a three-step sequence involving two supported reagent systems to convert /i-iodoamines into amino alcohols (Scheme 2.23) [45]. Polymer-supported acetate ions were used for the substitution of the iodide which immediately underwent acyl transfer to the amine. The resulting compound (10) was directly treated with hydrochloric acid to cleave the amide and the free base was subsequently obtained from the reaction by treatment with a resin-bound carbonate. This was of particularly synthetic value because of the high water solubiHty of these amino alcohol compounds that would have made aqueous work-up challenging. [Pg.69]

Since formamide is a weak nucleophile, the use of imidazole or 4-dimethylaminopyridine (DMAP) is necessary for acyl transfer to formamide via an activated amide (imidazolide) or acylpyridinium ion. As Scheme 22 illustrates, the reaction starts with the oxidative addition of aryl bromide 152 to Pd(0) species, followed by CO insertion to form acyl-Pd complex 154. Imidazole receives the aroyl group to form imidazolide 155 and liberates HPdBr species. Then, imidazolide 155 reacts with formamide to form imide 156. Finally, decarbonylation of imide 156 gives amide 157. In fact, the formations of imidazolide intermediate 155 and imide 156 as well as the subsequent slow transformation of imide 156 to amide 157 by releasing CO were observed. This mechanism can accommodate the CO pressure variations observed during the first few hours of aminocarbonylation. When the reaction temperature (120 °C) was reached, a fast drop of pressure occurred. This corresponds to the formation of the intermediary imide 156. Then, the increase of pressure after 3 h of reaction was observed. This phenomenon corresponds to the release of CO from imide 156 to form amide 157. ... [Pg.529]

An efficient synthesis of P-lactam with D-phenylglycine or its derivatives as a side chain can be accomplished only by using a kinetically controlled approach via acyl group transfer from an activated side chain donor, and D-phenylglycine can be used as ester, usually methyl (PGM) or ethyl (PGE), or as amide (PGA). As a... [Pg.294]

Earlier work in this field has been thoroughly reviewed [1,2]. However, to illustrate in a sensible and logical way the evolution from simple metal ion promotion of acyl transfer in supramolecular complexes to supramolecular catalysts capable of turnover catalysis, an account of earlier work is appropriate. The following sections present a brief overview of our earlier observations related to the influence of alkaline-earth metal ions and their complexes with crown ethers on the alcoholysis of esters and of activated amides under basic conditions. [Pg.113]

The formation of IAA conjugates is widely believed to be a means for removal of excess IAA produced during certain times of plant development and also in mutant plants where indolic precursors and IAA metabolites accumulate.32 In all higher and many lower plants, applied IAA is rapidly conjugated to form IAA—aspartate.33 The ability of plant tissues to make aspartate conjugates of a variety of active auxins is induced by pretreatment with auxin,34 and this induction was shown to be blocked by inhibitors of RNA and protein synthesis. After almost 50 years of study, an in vitro system from plants was described that accounts for the formation of IAA amide conjugates35 via a mechanism where the acidic auxin is adenylated followed by acyl transfer to the amino acid. The gene for this reaction had been discovered almost 20 years before, when GH3 from soybean was shown... [Pg.14]

See other pages where Acyl-transfer, from amides is mentioned: [Pg.89]    [Pg.38]    [Pg.89]    [Pg.38]    [Pg.238]    [Pg.610]    [Pg.637]    [Pg.1202]    [Pg.538]    [Pg.540]    [Pg.238]    [Pg.1986]    [Pg.637]    [Pg.289]    [Pg.1787]    [Pg.1789]    [Pg.268]    [Pg.441]    [Pg.538]    [Pg.540]    [Pg.248]    [Pg.172]    [Pg.148]    [Pg.92]    [Pg.97]    [Pg.32]    [Pg.94]    [Pg.187]    [Pg.235]    [Pg.429]    [Pg.1003]    [Pg.15]    [Pg.317]    [Pg.1272]    [Pg.23]    [Pg.370]    [Pg.171]   
See also in sourсe #XX -- [ Pg.267 ]



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Acyl amides

Acyl transfer

Amides acylation

From amides

Transfer from

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