Mitsunobu carboxylic acids

Sulfonate esters also can be prepared under Mitsunobu conditions. Use of zinc tosylate in place of the carboxylic acid gives a tosylate of inverted configuration. 

Preparation of the donor 46 was started from 4,6-0-benzylidene protected thiomannoside 47 (Scheme 7.24). Alkylation with p-allyloxybenzyl chloride under phase transfer conditions78 was followed by 3-O-silylation and Pd(0)-mediated deallylation79 to give 48. The phenolic OH group was alkylated with ethyl 6-bromohexanoate and carboxylic acid, liberated by alkaline hydrolysis, was reacted with PEG monomethyl ether (MW -5000) under Mitsunobu conditions to afford 46. 

In a follow-up communication,26 similar chemistry was used for the production of 2-substituted benzofurans beginning not with an anthranilic acid derivative, but with a resin-bound ortho-hydroxy aryl iodide 3. In the solid-phase work, depicted in Scheme 5, the relevant carboxylic acid was linked to TentaGel via a Mitsunobu reaction, and after deprotection was seen to undergo smooth Heck coupling and cyclization, giving essentially pure compounds in 40-70% overall yield after cleavage. 

Bifunctional reagents have recently been used to facilitate separations in the Mitsunobu reaction.39 Mitsunobu products are often hard to separate from excess reagents and byproducts, including phosphines and phosphine oxides. The tagged phosphine 21 and azodicarboxylate 22 and the byproducts formed from these are converted to the carboxylic acid forms by treatment with trifluoroacetic acid (TFA) at the end of the reaction. The excess reagents and byproducts could then be captured on an ion exchange resin for convenient removal. 

Employing the Mitsunobu reaction with diisopropyl azodicarboxylate and triphenyl-phosphine, aminoacylserine (in contrast to aminoacylthreonine) is converted into (ami-noacyl)oxazolidine-2-carboxylic acid. 54 By the same procedure a/Zo-threonine peptides are converted into the oxazoline derivatives, whilst the threonine peptides are apparently converted into the aziridines in good yields. 86 ... 

Addition of the lithium acetylide of tetrahydropyranyl-protected but-3-yn-l-ol 156 provided the racemic alcohol 157 (Scheme 34). The nitrogen was introduced through a Mitsunobu reaction, followed by oxidation of the primary alcohol to the carboxylic acid and a change of the phthaloyl protecting group to Boc protection. The latter reaction was necessary because hydrazinolysis of the C-terminal amide analogue of 159 did result in deeply red-colored mixtures, indicating that phthaloyl removal by this method should occur prior to peptide synthesis. 131 ... 

Three different strategies are generally used for the attachment of carboxylic acids to resins as benzyl esters (a) acylation of resin-bound benzyl alcohols [38-40], (b) O-alkylation of carboxylates by resin-bound benzylic halides [4143], or (c) O-alkylation of carboxylic acids under Mitsunobu conditions [44,45] (Figure 3.3). These reactions are treated in detail in Section 13.4. 

As illustrated by the examples in Table 3.9, resin-bound 4-alkoxybenzylamides often require higher concentrations of TFA and longer reaction times than carboxylic acids esterified to Wang resin. For this reason, the more acid-sensitive di- or (trialkoxy-benzyl)amines [208] are generally preferred as backbone amide linkers. The required resin-bound, secondary benzylamines can readily be prepared by reductive amination of resin-bound benzaldehydes (Section 10.1.4 and Figure 3.17 [209]) or by A-alkyla-tion of primary amines with resin-bound benzyl halides or sulfonates (Section 10.1.1.1). Sufficiently acidic amides can also be A-alkylated by resin-bound benzyl alcohols under Mitsunobu conditions (see, e.g., [210] attachment to Sasrin of Fmoc cycloserine, an O-alkyl hydroxamic acid). 

Both aliphatic alcohols and phenols have been immobilized as esters of support-bound carboxylic acids. The esterification can be achieved by treatment of resin-bound acids with alcohols and a carbodiimide, under Mitsunobu conditions, or by acylation of alcohols with support-bound acyl halides (see Section 13.4). 

The p-sulfanyl amides 28 are synthesized from N-protected amino acids 24 via amino alcohols 25, which are converted into (5-acetylsulfanyl amides 26 by a Mitsunobu reaction. The (5-amine disulfide 27 is subsequently coupled with a variety of carboxylic acids, followed by reduction with tributylphosphine in aqueous THF in the presence of pyridine to produce the free thiol 28 (Scheme 5).1211 Detailed experimental procedures for these compounds have not been reported. 

Mitsunobureaction.1 Two intermediates have been isolated from the Mitsunobu esterification of carboxylic acids with phenols. One is the betaine 1, which has been generally assumed to be involved the other is the phosphorane 2.2... 

When esterification is achieved under the Mitsunobu conditions (diethyl azodicarboxylate, Ph3P), only esters at positions 6 and 6 are produced, and isolation of the 6-monoester, which is formed faster is possible. Thus diesters can be efficiently prepared.97 99 In this type of reaction, when the carboxylic acid is... 

The Mitsunobu conditions, applied without any carboxylic acid, were shown to provide anhydro (3, 4 -epoxide)284 286 and dianhydro sucrose derivatives.331 Some of these compounds were further transformed by reduction (leading to dehydrosucroses) or ring-opening leading to sucrose epimers and dehydrohalo-or amino sucroses (see also Scheme 7).332... 

This potential mechanistic synergy made BSO an early candidate for conjugation to MGd. Thus, FMOC protection of the amine group of BSO 11 was carried out to give the corresponding carboxylic acid 12. Subsequent Mitsunobu coupling to MGd and deprotection afforded the desired conjugate 13 in 35% yield (Scheme 3). 

The O-alkylation of carboxylates is a useful alternative to the acid-catalyzed esterification of carboxylic acids with alcohols. Carboxylates are weak, hard nucleophiles which are alkylated quickly by carbocations and by highly reactive, carbocation-like electrophiles (e.g. trityl or some benzhydryl halides). Suitable procedures include treatment of carboxylic acids with alcohols under the conditions of the Mitsunobu reaction [122], or with diazoalkanes. With soft electrophiles, such as alkyl iodides, alkylation of carboxylic acid salts proceeds more slowly, but in polar aprotic solvents, such as DMF, or with non-coordinating cations acceptable rates can still be achieved. Alkylating agents with a high tendency to O-alkylate carboxylates include a-halo ketones [42], dimethyl sulfate [100,123], and benzyl halides (Scheme 6.31). 

Figure 2.34 shows the mechanism of this reaction. A key intermediate is the alkylated phosphine oxide A, with which the carboxylate ion reacts to displace the leaving group 0=PPh3. Figure 2.34 also shows that this carboxylate ion results from the deprotonation of the carboxylic acid used by the intermediate carbamate anion B. Nucleophiles that can be deproto-nated by B analogously, i.e., quantitatively, are also alkylated under Mitsunobu-like conditions (see Figure 2.36). In contrast, nucleophiles that are too weakly acidic cannot undergo Mitsunobu alkylation. Thus, for example, there are Mitsunobu etherifications of phenols, but not of alcohols.

Reliable clean S 2 reactions with secondary allylic alcohols can be achieved only with Mitsunobu chemistry. Here is a well-behaved example with a Z-alkene. The reagents have changed since your last encounter with a Mitsunobu-type reaction instead of DEAD and a carboxylic acid we have hexa-chloroacetone. 

An asymmetric synthesis of 2,3-disubstituted 1,4-benzodioxanes is based on the cyclisation of the protected diol 38, a Mitsunobu-derived substrate, which probably involves a quinone methide <03TA701>. An efficient resolution of 1,4-benzodioxane-2-carboxylic acid has been described <03TA3779>. 

Preparative Methods both enantiomers of dihydro-5-(hydroxymethyl)-2(3H) furanone and their trityl derivatives are commercially available but expensive. The simplest and by far most popular method for preparing (5)-dihydro-5-(hydroxymethyl)-2(3H)-furanone (2) consists of enantiospecific deamination of L-glutamic acid and subsequent selective reduction of the resulting carboxylic acid (13) (eq 1). Purification of the intermediate acid (13) by crystallization and not by distillation is recommended in order to secure an excellent optical yield (>98% ee). Likewise, (f )-dihydro-5-(hydroxymethyl)-2(3//)-furanone (1) (>98% ee) can be obtained from o-glutamic acid. As the latter is considerably more expensive than its natural antipode, an appealing option is to convert the (5)-lactone into its enantiomer (eq 2)P Also available and equally useful is an inversion route to (f )-dihydro-5-(trityloxymethyl)-2(3H)-furanone (5) by way of the Mitsunobu reaction (eq 3). ... 

---