Propargyl esters, rearrangements with

The ester/alkyne rearrangement system can be extended by conjugation to involve a more distant site. The reaction of diethyl phosphorochloridate with 3-methylhex-4-yne-2-ene-l-ol leads to the vinylogous propargylic ester rearrangement as shown in Equation 4.39.176... 

A review of the rearrangement reaction of anthranilic acid esters, thioesters, or amides under acidic conditions to 2-aryl-3-substituted 4(l//)-quinolinone has been reported and summarizes limits and scope of the reaction in the synthesis of flavonoids. " Theoretical studies of the addition-cyclization-isomerization reaction of propargyl cyanamides with thiol and methanol have been reported to occur via five steps ... 

The treatment of propargylic alcohols with trialkyl orthoacetates gives 3-allenic esters (218), which rapidly rearrange in the presence of basic alumina, suspended in an aprotic solvent, to furnish (2 , 4Z)-dienoic esters (219). ... 

Rearrangement of acetylenic sulphenates to the allenic sulphoxides 151 was discovered when the synthesis of propargylic ester of trichloromethanesulphenic acid 152 was attempted (equation 86). This reaction is of general scope and gives very good yields of allenic sulphoxides (Table 14) from structurally diverse cohols and various sulphenyl chlorides Reaction of alkynols 153 with benzenesulphenyl chloride in the presence... 

The reaction is performed most simply by the addition of the propargylic alcohol to a solution of the phosphorus halide. Rearrangement of the phosphorus ester proceeds at ambient temperature or with mild heating. When phosphorus trihalides are used, the product can be isolated as the phosphonic dichloride.168169 Aqueous workup provides the phosphonic acid.162 In most instances, however, a dialkyl phosphorochloridite with only a single halogen on phosphorus available for reaction with alcohol has been used.165 170 174... 

The isomerization of the smallest alkynes 80 with halogens in a propargylic position has been described for chlorine [151, 152], bromine [153] and iodine [154] (Scheme 1.35), but often might proceed by an SN2 -type substitution rather than a prototropic rearrangement [155-159]. On the other hand, transformations such as 82 —> 83 [160] or 84 —> 85 [161] are clearly prototropic (Scheme 1.36). This is also true for propargylic halides such as 86 with its additional ester group assisting the prototropic isomerization [162,163] (Scheme 1.37). 

The acidity of the propargylic proton of the starting compound 18 allows the equilibration with the allene 19 induced by bases such as tertiary amines or alcoholates (Scheme 7.4). Such prototropic rearrangements furnish the title compounds 19 with at least one proton at the terminal carbon atom, often in good yields. The EWG group involves carboxylic acids [33], esters [34], ketones [35, 36], isonitriles [37], sul-fones [38], sulfoxides [39, 40] and phosphonates [41], The oxidation of easily accessi-... 

The first syntheses of a-allenic a-amino acids [131,133] took advantage of Steg-lich s [134] protocol for the oxazole-Claisen rearrangement of unsaturated N-ben-zoylamino acid esters (Scheme 18.46). Thus, treatment of the propargylic ester 143 with triphenylphosphine and tetrachlormethane furnished the allenic oxazolone 144, which was converted into the amino acid derivative 145 by methanolysis. Stepwise deprotection finally led to the allenic DOPA analog 146, which shows a much higher decarboxylase-inhibiting activity than a-vinyl- and a-ethynyl-DOPA [133],... 

Further variations of the Claisen rearrangement protocol were also utilized for the synthesis of allenic amino acid derivatives. Whereas the Ireland-Claisen rearrangement led to unsatisfactory results [133b], a number of variously substituted a-allenic a-amino acids were prepared by Kazmaier [135] by chelate-controlled Claisen rearrangement of ester enolates (Scheme 18.47). For example, deprotonation of the propargylic ester 147 with 2 equiv. of lithium diisopropylamide and transmetallation with zinc chloride furnished the chelate complex 148, which underwent a highly syn-stereoselective rearrangement to the amino acid derivative 149. 

In a similar way, propargyl esters of A -benzoyl-a-amino acids have been converted into a-allenyl-a-amino acid esters 113 by cyclization to oxazoles 111 followed by Claisen rearrangement to the 4-allenyl-2-phenyl-5(4//)-oxazolones 112. Oxazolone ring opening with methanol then afforded 113 (Scheme 7.32). ... 

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