Palladium-catalyzed reactions with nucleophilic substrates

5 Palladium-catalyzed reactions with nucleophilic substrates 

The complexes generated by oxidative addition of haloarenes and haloalkenes to palladium(O) are electrophilic at the metal-substituted center, and can therefore react with carbon nucleophiles other than alkenes, especially with enolate and homoenolate ions to form new C —C bonds [176, 177]. 

Given the tremendous variety of naturally occurring heterocyclic compounds, the development of elegant and efficient routes to the appropriately substituted ring systems is a formidable task. o-Amino- and o-hydroxy-substituted iodoarenes such as 121 can undergo a vast array of reactions with 1,2-. 0- and 1,4-dienes and ethenylcyclopropanes 

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Palladium-catalyzed reactions with nucleophilic substrates. 122... 

The Tsuji-Trost reaction is the palladium-catalyzed allylation of nucleophiles [110-113]. In an application to the formation of an A-glycosidic bond, the reaction of 2,3-unsaturated hexopyranoside 97 and imidazole afforded A-glycopyranoside 99 regiospecifically at the anomeric center with retention of configuration [114], Therefore, the oxidative addition of allylic substrate 97 to Pd(0) forms the rc-allyl complex 98 with inversion of configuration, then nucleophilic attack by imidazole proceeds with a second inversion of configuration to give 99. 

As mentioned earlier, Ding et al.15 captured a number of dichlorohetero-cyclic scaffolds where one chloro atom is prone to nucleophilic aromatic substitution onto resin-bound amine nucleophiles (Fig. 1). Even though it was demonstrated that in many cases the second chlorine may be substituted with SNAr reactions, it was pointed out that palladium-catalyzed reactions offer the most versatility in terms of substrate structure. When introducing amino, aryloxy, and aryl groups, Ding et al.15 reported Pd-catalyzed reactions as a way to overcome the lack of reactivity of chlorine at the purine C2 position and poorly reactive halides on other heterocycles (Fig. 10). 

This methodology has been used to provide efficient protocols for the asymmetric allylic alkylation of p-keto esters, ketone enolates, barbituric acid derivatives, and nitroalkanes. Several natural products and analogs have been accessed using asymmetric desymmetrization of substrates with carbon nucleophiles. The palladium-catalyzed reaction of a dibenzoate with a sulfonylsuccinimide gave an advanced intermediate in the synthesis of L-showdomycin (eq 3). ... 

A similar triarylphosphane was introduced by Leitner for the performance of transition metal catalyzed reactions in supercritical CO2 [24]. Recently, this phosphane was used for palladium catalyzed substitutions of allylic substrates in perfluorinated solvents under fluorous biphase conditions [25], Therefore, the reaction of cinnamyl methylcarbonate (36) with several nucleophiles (Nu-... 

Zinc enolates like 41 served as nucleophiles in a study aimed at a rhodium-catalyzed reaction with enantiomerically enriched allylic phosphates. Nonracemic products were obtained under efficient chirality transfer from the substrate and with remarkable diastereoselectivity [23]. Kazmaier enolates were used to manipulate the backbone of small peptides [27] by palladium-catalyzed allylations of a terminal glycine ester [28]. In the course of these studies, central glycine was also allylated in a diastereoselective manner through assumed chelated zinc enolates of glycine in a peptidic bond to proline or JV-alkyl amino acids [29]. Although this is, of course, not an asymmetric synthesis, the protocol is remarkable inasmuch as, in contrast to the palladium-mediated conversion, the noncatalyzed reaction of the enolate with the corresponding allylic bromide occurs in a more or less stereorandom manner. 

Diazonium salts react with various nucleophiles in water (Eq. 11.62).106 In acidic aqueous solution, p-pheny I e ncbis di azo ni um ion reacts with alcohols more rapidly than it does with water.107 In the presence of nucelophiles such as halides, the substitution products are obtained. Furthermore, diazonium salts of aromatic compounds are excellent substrates for palladium-catalyzed coupling reactions such as the Heck-type reactions in water. 

This trend is also observed in palladium chemistry where the general order for oxidative addition often correlates with that of nucleophilic substitution. Not only are 2-, 4- and 6-chloropyrimidines viable substrates for Pd-catalyzed reactions, but 4- and 6-chloropyrimidines react more readily than 2-chloropyrimidines. 

These peptide enolates could also be used as excellent nucleophiles in palladium-catalyzed allylic alkylations. Reactions of numerous dipeptides (e.g. 263) with different allylic substrates (e.g. 264) and [AllPdClja as catalyst delivered (S,/f)-configured peptides with y,5-unsaturated side chains (265), usually in high yields and diastereoselectivities (equation 69). 

Substitution reactions of allylic substrates with nucleophiles have been shown to be catalyzed by certain palladium complexes [2, 42], The catalytic cycle of the reactions involves Jt-allylpalladium as a key intermediate (Scheme 2-22). Oxidative addition of the allylic substrate to a palladium(o) species forms a rr-allylpal-ladium(n) complex, which undergoes attack of a nucleophile on the rr-allyl moiety to give an allylic substitution product. The substitution reactions proceed in an Sn or Sn- manner depending on catalysts, nucleophiles, and substituents on the substrates. Studies on the stereochemistry of the allylic substitution have revealed that soft carbon nucleophiles represented by sodium dimethyl malonate attack the TT-allyl carbon directly from the side opposite to the palladium (Scheme 2-23). 

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