Mitsunobu reaction chemoselectivity

HSAB is particularly useful for assessing the reactivity of ambident nucleophiles or electrophiles, and numerous examples of chemoselective reactions given throughout this book can be explained with the HSAB principle. Hard electrophiles, for example alkyl triflates, alkyl sulfates, trialkyloxonium salts, electron-poor car-benes, or the intermediate alkoxyphosphonium salts formed from alcohols during the Mitsunobu reaction, tend to alkylate ambident nucleophiles at the hardest atom. Amides, enolates, or phenolates, for example, will often be alkylated at oxygen by hard electrophiles whereas softer electrophiles, such as alkyl iodides or electron-poor alkenes, will preferentially attack amides at nitrogen and enolates at carbon. 

The synthesis of lipstatin 122 is too complex to discuss here in detail but an early stage in one synthesis uses a clever piece of chemoselectivity.23 Kocienski planned to make the P-lactone by a cycloaddition with the ketene 124 and to add the amino acid side chain 123 by a Mitsunobu reaction involving inversion. They therefore needed Z,Z-125 to join these pieces together. This was to be made in turn by a Wittig reaction from 126. The problem now is that 126 is symmetrical and cannot carry stereochemistry and that aldehydes are needed at both ends. 

Phenols attached to insoluble supports can be etherified either by treatment with alkyl halides and a base (Williamson ether synthesis) or by treatment with primary or secondary aliphatic alcohols, a phosphine, and an oxidant (typically DEAD Mitsu-nobu reaction). The second methodology is generally preferred, because more alcohols than alkyl halides are commercially available, and because Mitsunobu etherifications proceed quickly at room temperature with high chemoselectivity, as illustrated by Entry 3 in Table 7.11. Thus, neither amines nor C,H-acidic compounds are usually alkylated under Mitsunobu conditions as efficiently as phenols. The reaction proceeds smoothly with both electron-rich and electron-poor phenols. Both primary and secondary aliphatic alcohols can be used to O-alkylate phenols, but variable results have been reported with 2-(Boc-amino)ethanols [146,147]. 

The Mitsunobu alkylation conditions of 48 also exhibit high chemoselectivity when subjected to reaction with diol 4731 In this example, judicious choice of phosphine and diazo compound dictate which alcohol is activated. Using h-Bu3P in combination with TMAD (TV,N,V, /V -tetramethylazodicarboxamide) gives primarily reaction with the primary alcohol yielding 49. Whereas, Me3P and ADDP (l,l -(azodicarbonyl)-dipiperidide) allow for reaction at the secondary alcohol with another equivalent of 48 giving a fully protected di-amine 50. 

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