Base-catalyzed, acylation equation

Another approach uses the reaction of 6-chloro-5-nitropyrimidines with a-phenyl-substituted amidines followed by base-catalyzed cyclization to pteridine 5-oxides, which can be reduced further by sodium dithionite to the heteroaromatic analogues (equation 97) (79JOC1700). Acylation of 6-amino-5-nitropyrimidines with cyanoacetyl chloride yields 6-(2-cyanoacetamino)-5-nitropyrimidines (276), which can be cyclized by base to 5-hydroxypteridine-6,7-diones (27S) or 6-cyano-7-oxo-7,8-dihydropteridine 5-oxides (277), precursors of pteridine-6,7-diones (278 equation 98) (75CC819). 

In 1887, Claisen and Lowman reported that the condensation of 2 mol of an ester, such as ethyl acetate, in the presence of base gave the p-keto ester, ethyl acetoacetate (ethyl 3-oxobutanoate equation 1). The intramolecular equivalent was recognized by Dieckmann in 1894. He found that heating an adipic acid ester with sodium and a trace of alcohol led to cyclization, with the formation of a cyclopentanone (equation 2). The reaction was, at an early stage, extended to the acylation of ketones. Claisen himself reported the base-catalyzed reaction of acetophenone and ethyl benzoate to give dibenzoylmethane in 1887. This reaction, too, has an intramolecular parallel. The acylation of ketones with esters and other acid derivatives is sometimes called a Claisen condensation, although this usage is criticized by some writers and avoided by others. A widely used example of ketone acylation is the synthesis of a-formyl (hydroxymethylene) ketones (equation 3). Intramolecular variants of this reaction include the classical synthesis of dimedone (Scheme 1). 

Such reactions are normally base catalyzed. Scheme 76 illustrates the use of this reaction to provide both fused and bridged rings. Other techniques for synthesizing the keto ester from trimethylsilyl ethers are shown in Scheme 77. The diketones shown were usually isolated as a mixture of enols or enol ethers. Acid-catalyzed acylation also provides a route to diketones not readily obtained by other routes (Scheme 78). The acid catalysts included polyphosphoric acid and naphthalene-2-sulfonic acid. In the latter example continuous removal of water facilitated the reaction. A related reaction involved treatment of an acid chloride with silver perchlorate in nitromethane (equation 41), although the yield of diketone was low. ° ... 

Reactions of alkynyl esters with nucleophilic reagents usually involve the attack of the nucleophile on the electrophilic acyl moiety (i.e. C==0, P=0, SO2) but not the triple bond. A typical example of such a process is the formation of lithium ynolates in the reaction of alkynyl tosylates with methyl lithium (see equation 10 in Section II.B.l). Similarly, the base-catalyzed hydrolysis of alkynyl esters most likely proceeds via OH attack on the acyl moiety and the subsequent standard mechanistic steps. 

The currently accepted mechanism for the hydrolysis of amides and esters catalyzed by the archetypal serine protease chymotrypsin involves the initial formation of a Michaelis complex followed by the acylation of Ser-195 to give an acylenzyme (Chapter 1) (equation 7.1). Much of the kinetic work with the enzyme has been directed toward detecting the acylenzyme. This work can be used to illustrate the available methods that are based on pre-steady state and steady state kinetics. The acylenzyme accumulates in the hydrolysis of activated or specific ester substrates (k2 > k3), so that the detection is relatively straightforward. Accumulation does not occur with the physiologically relevant peptides (k2 < k3), and detection is difficult. 

It is clear that this mechanistic interpretation is not unique, because there is no direct evidence for the proposed intermediates. For example, alternative possible explanations are (1) The amino group in the aminoenzyme may not be covalently bound, but may merely be activated by the enzyme and (2) similarly, the acyl transfer reaction of equation 16.31 could occur by the direct attack of Leu-Tyr-Leu on the enzyme-bound Leu-Tyr-Leu. However, M. S. Silver and S, L. T. James169,170 have proposed a further interpretation, based on the observation that small peptides stimulate the pepsin-catalyzed hydrolysis of other peptides by being first synthesized into larger peptides in a condensation reaction that is the reverse of the hydrolytic step e.g., equations 16.33. The idea of the condensation of two small peptides to give a larger peptide at a rate that is relatively fast compared with hydrolysis of the small peptides is quite reasonable... 

New syntheses, based on the condensation of a-haloketones with acid chlorides or anhydrides catalyzed by Sml2,51 or C-acylation of enoxysilanes catalyzed by a mixture of BiCl3/NaI or BiCl3/ Znl2, have been proposed (Equation (6)) 52... 

N-(l-Alkoxyalkyl)-aniides or -carbamates (2 X = OR), most frequently used as stable precursors for A -acyliminium ions, are usually prepared by one of the following routes (equations 7-13). For five- or six-membered cyclic cases a simple acid-catalyzed solvolysis of the hydroxy compound provides the alk-oxy derivative (equation 7). A silicon-assisted approach involves the TMSOTf-catalyzed reaction of bis(trimethylsilyl)formamide with aldehydes (equation 8). /V-(l-Trimethylsilyloxyalkyl)formamides are thus formed in good yields, which on TMSOTf-catalyzed solvolysis lead to the /V-( 1-alkoxyalkyl)form-amides. A third method is based on the NaBH4 reduction of imidates (equation 9), and has proved useful for a total synthesis of the insect poison pederine. Addition of reactive acid derivatives to imines constitutes another method (equations 10 and 11). Acylation with acid chlorides followed by treatment with ethanol in the presence of base leads to N-(l-alkoxyalkyl)amides. A one-step protocol using diethyl dicarbonate provides the corresponding carbamates. 2... 

Examples of the formylation of aryl halides with synthesis gas catalyzed by palladium complexes are summarized in Equation 19.90. These reactions relied upon the development of ligands with particular steric and electronic properties. The dia-damantyl-n-butyl phosphine shown in the equation, in combination with palladium acetate, leads to the formation of aromatic aldehydes in high yields from electron-rich and electron-poor aryl bromides. Reactions of nitroarenes and 2-bromopyridine provided the aldehydes in low yield, but other examples occurred in satisfactor) yield with only 0.1-0.75 mol % catalyst. The identity of the base is important in this process, and TMEDA was the most effective base. The mechanism of this process was not proposed in the initial work, but is likely to occur by oxidative addition of the aryl halide, insertion of the carbon monoxide into the palladium-aryl bond, and a combination of hydrogenolysis of the acyl intermediate and elimination of hydrogen halide to regenerate palladium(O). The base would then be involved in the hydrogenol5 sis and consumption of hydrogen halide. 

Table 19.2 gives examples of two reactions of acetic anhydride. In the first, the anhydride carbonyl is converted to the more stabilized carbonyl group of an ester in the second, a more stabilized amide carbonyl results. Hydrolysis under neutral or acid-catalyzed conditions yields two moles of a carboxylic acid per mole of anhydride, but, like hydrolysis of acyl chlorides is of little preparative value and is not included in the table. Likewise, hydrolysis in aqueous base according to the following equation is omitted from the table. 

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