Enantioselective allylic substitutions forms

The Ir-catalyzed enantioselective allylic substitution reaction can be used for the synthesis of -substituted a-amino acids . For example, the enantioselective Ir-catalyzed allylic substitution of 3-arylallyl diethyl phosphates 5.24 with pronucleophile diphenylimino gly-cinate 5.25 is achieved up to 98% ee by using bidentate chiral phosphite ligand 5.26. By changing the base, both diastereoisomeric substitution products 5.27a and 5.27b could be formed selectively. 

Allyl derivatives 11 with identical substituents at Cl and C3 are an important class of substrates for enantioselective allylic substitution (Scheme 10). Starting from either enantiomer (11 or ent-ll) the same allyl-palladium complex 12 is formed. Therefore, the first part of the catalytic cycle leading to this intermediate usually is irrelevant for the stereoselectivity of the overall reaction [31]. The two termini of the free allyl system are enantiotopic. If the catalyst is chiral, they become diasterotopic in the allyl-metal complex and, therefore, may exhibit different reactivities toward nucleophiles. Under the influence of a suitable chiral ligand attached to palladium, nucleophilic attack can be rendered regioselective leading preferentially either to product 13 or its enantiomer ent-l3. 

Four reviews on allylic substitution reactions have been published. The first deals with the enantioselective allylic substitutions by carbon nucleophiles, in the presence of both palladium and non-palladium catalysts. The second reviews stere- 0 oselective allylic substitution reactions forming asymmetric C-C, C-N, and C-O bonds. The third review covers new developments in metal-catalysed asymmetric 0 allylic substitution reactions with heteroatom-centred nucleophiles. Several applications of this new methodology are included. Finally, the catalytic 5 2 and 5 2 reactions of allylic alcohols, most of which occur with a very high ee, have been reviewed. ... 

Enantioselective allylic substitutions to form a stereocenter at one of the allylic carbons can take many forms, as summarized in Scheme 20.10. The diversity of methods by which... 

Enantioselective allylic substitutions of cyclic allylic esters have been more challenging to develop than enantioselective reactions of symmetrical, acyclic allylic esters. In one set of reactions, racemic allylic esters react to form non-racemic products by addition of carbon or nitrogen nucleophiles in the presence of palladium catalysts. In these cases, attack at the two termini of the allylic intermediate generates the two enantiomers. Only a handful of ligands have generated catalysts that form products from the substitution of aliphatic. 

A final approach to enantioselective allylic substitution is the reaction of prochiral nucleophiles with allylic esters. In this case, the stereocenter is not generated on the allyl unit it is generated at the nucleophilic carbon. This chemistry has been conducted with cyanoesters and related unsymmetrical stabilized carbon nucleophiles, including azlactones, which are a protected form of ammo acids. This generation of a stereocenter in the nucleophile is thought to be particularly challenging because the position at which the stereocenter is formed is further from the metal than it is in reactions that form a stereocenter at the allyl group. 

As a final set of examples, enantioselective allylic substitution of unstabilized eno-lates to form a new stereocenter at the enolate carbon have been developed through the decarboxylative reactions of allyl enol carbonates. - - These reactions are enantioselective versions of reactions closely related to those in Equation 20.18 and Scheme 20.4, and two examples are shown in Equations 20.60 and 20.61. In these cases, a new stereocenter is formed at the a-carbon of the enolate nucleophile. Most of these reactions have been conducted with allyl enol carbonates that generate cyclic ketone enolates, but enantioselective reactions of acyclic allyl enol carbonates have also been reported. Although allyl enol carbonates undergo decarboxylation faster than the 3-keto ester isomers, the 0-allyl p-keto esters are more difficult to prepare, and enantioselective allylations starting with p-ketoesters have been reported. - Decarboxylative reactions of amines and a-amino acids have been conducted to form allylic and homoallylic amines (Equation 20.62), respectively, and enantioselective decarboxylative allylations of amides have been reportedIridium-catalyzed enantioselective decarboxylative allylation of amides starting with 0-allyl imides has also been reported. ... 

The synthesis of lycorane (13) by Mori and Shiba-saki121 is breathtaking for its use of three consecutive Pd catalyzed C-C bond forming reactions. Thus, Pd-catalyzed asymmetric allylic substitution of a benzoate in meso 7 in the presence of the chiral bisphos-phine 8 leads to the regioselective formation of 10 in 40 % ee It is easy to overlook this low level of enantioselectivity when we are faced with the subsequent elegant Pd-catalyzed reactions Pd-catalyzed intramolecular animation is followed by a Pd-catalyzed Heck coupling to afford 12, which is then readily converted to the target molecule... 

The first enantioselective, iridium-catalyzed allylic substitution was reported by Helmchen and coworkers soon after the initial report by Takeuchi. Helmchen studied catalysts generated from phosphinooxazoline (PHOX) ligands and [Ir(COD)Cl]2 for the reactions of sodium dimethylmalonate with cinnamyl acetates (Scheme 2) [50]. The alkylation products were isolated in nearly quantitative yield and were formed with ratios of branched-to-Unear products up to 99 1 and with enantioselectivities up to 95% ee. In this and subsequent studies with PHOX ligands [51,52], Helmchen et al. demonstrated that the highest yields and selectivities were obtained with a PHOX ligand containing electron-withdrawing substituents and... 

The configuration of the chiral BlNOLate backbone of the phosphoramidite ligand affects the rates and enantioselectivities of allylic substitution reactions. Hartwig and coworkers found that allylic substitution conducted with a catalyst derived from the simplified ligand (5a,/ )-L4 occurred more slowly than that conducted with a catalyst derived from (/ a,/ )-L4 [74]. Complexes of the mismatched (5a,/ )-L4 undergo cyclometalation slowly. The products formed from reactions catalyzed by complexes of (5a,/ )-L4 and (/ a,/ )-L4 have the opposite absolute configuration. 

As previously discussed, activation of the iridium-phosphoramidite catalyst before addition of the reagents allows less basic nitrogen nucleophiles to be used in iridium-catalyzed allylic substitution reactions [70, 88]. Arylamines, which do not react with allylic carbonates in the presence of the combination of LI and [Ir(COD)Cl]2 as catalyst, form allylic amination products in excellent yields and selectivities when catalyzed by complex la generated in sim (Scheme 15). The scope of the reactions of aromatic amines is broad. Electron-rich and electron-neutral aromatic amines react with allylic carbonates to form allylic amines in high yields and excellent regio- and enantioselectivities as do hindered orlAo-substituted aromatic amines. Electron-poor aromatic amines require higher catalyst loadings, and the products from reactions of these substrates are formed with lower yields and selectivities. 

Allylic substitution reactions catalyzed by metalacyclic iridium-phosphoramidite complexes form branched products from linear allylic esters with high regioselec-tivity. However, reactions with racemic, branched allylic esters would be particularly valuable because they are readily accessible from a wide array of aldehydes and vinylmagnesium halides. However, iridium-catalyzed allylic substitution reactions of branched allylic esters have so far occurred with low enantioselectivities [45, 75]. 

Allylic substitution using hard nucleophiles proceeds through a different mechanism. Instead of attacking the allyl group of the 71 allyl-metal complex, hard nucleophiles attack the metal first and the product is subsequently formed by reductive elimination. Nickel(O) complexes have often been used for this purpose. Reports of good enantioselectivities in this type of reaction are limited. 

S)-l is obtained from the bis(methyl carbonate) of (Z)-2-butene-l,4-diol and l,2-bis(tosyl-amino)ethane through a tandem pa]ladium(0)-catalyzed allylic substitution in the presence of (R)-BINAP (I) as chiral ligand79. Equilibration of the 7t-allylpalladium intermediates formed before the intramolecular nucleophilic attack is necessary for high enantioselectivity. Thus, only a racemic piperazine is produced in the reaction of the more nucleophilic l,2-bis(benzyl-amino)ethane with the diacetate of (Z)- or ( )-2-butene-l,4-diol. 

Catalysis by palladium complexes was actively developed during this decade. Allylic substitution gave excellent results in some cases, thanks to a good fit between the structures of catalyst and substrate. There were significant improvements in the enantioselectivities of the reactions and understanding to some extent of various mechanistic details (for example see [64,65,66]. Most of the time the product was formed with one or several asymmetric centers. In rare cases axial chirality may be created, too [67]. 

Enantioselective metal-catalysed allylic substitution reactions have attracted considerable attention, especially over recent years. The metal that has been most widely investigated for allylic substitution reactions is palladium. The mechanism of palladium-catalysed allylic substitution typically involves a double inversion, resulting in overall retention of relative stereochemistry. So, if the stereochemistry of the product is simply based on the stereochemistry of the starting material, how can an asymmetric synthesis be possible The answer lies in the choice of substrate for the enantioselective version of the palladium-catalysed allylic substitution reaction. For example, the substrate (10.40) proceeds via a meso intermediate complex (10.41). Which end of the allyl group the nucleophile adds to dictates which enantiomer of product will be formed, (10.42) or e r-(10.42). 

Another approach to create diverse C—H bond functionalization is to combine one C—H bond activation with a subsequent transformation which greatly enriches the diversity of the initial C—H bond functionalization products. Bearing this concept in mind, Sharma and Hartwig recently developed a one-pot process involving the linear selective Pd-catalyzed allylic C—H bond oxidation and subsequent enantioselective branched Ir-catalyzed allylic substitution to form products with new C—O, C—N, C—C, and C—S bonds (Scheme 5.67). The utility of this process was further demonstrated by an iterative sequence of C—H bond functionalization and homologations to prepare enantioenriched (l,n)-functionalized alkenes. 

In 2010, Wang and co-workers [142] introduced phosphine oxides as nucleophiles to the asymmetric allylic substitution of BH carbonates. With quinidine as catalyst, the reaction proceeded smoothly to approach optically active allylic diaryl phosphine oxides in modest to good yields and enantioselectivities. A subsequent study showed that an additive was cmcial to the reaction with dialkyl phosphine oxides for example, excellent enantioselectivity was afforded with Na2C03 as the additive while a racemic product formed with NaOH as the additive [143]. 

Much effort has been devoted to developing catalysts that control the enantioselectiv-ity of these substitution reactions, as well as the regioselectivity of reactions that proceed through unsymmetrical allylic intermediates. A majority of this effort has been spent on developing palladium complexes as catalysts. Increasingly, however, complexes of molybdenum, tungsten, ruthenium, rhodium, and iridium have been studied as catalysts for enantioselective and regioselective processes. In parallel with these studies of allylic substitution catalyzed by complexes of transition metals, studies on allylic substitution catalyzed by complexes of copper have been conducted. These reactions often occur to form products of Sj 2 substitution. As catalylic allylic substitution has been developed, this process has been applied in many different ways to the synthesis of natural products. ... 

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