Palladium-mediated oxidative cyclization

Hill et al. reported an efficient short synthesis of staurosporinone (293) using a palladium-mediated oxidative cyclization of the bisindolylmaleimide arcyriarubin A (349) as the key step (766). The key intermediate, arcyriarubin A (349), was prepared... 

Ohkubo et al. reported the synthesis of the arcyriaflavins B (346), C (347), and D (348) involving a base-induced indolylation of dibromo-Af-methylmaleimide 1420 and a palladium-mediated oxidative cyclization of the bisindolylmaleimides 1428, 1429, and 1430 as key steps (337). The reaction of 6-benzyloxyindole (1419) and... 

The first metal-mediated synthetic approach to coumestans was described by Kappe and Schmidt in the early 1970s, when they were able to prepare the disubstituted coumestans 71 through a palladium-mediated oxidative cyclization of the 4-hydroxy-2-phenyl-coumarins 70 (Scheme 30) [123]. The process involves the initial oxidative addition of the OH imit of 70 to Pd(0), followed by orf/zo-metalation of the neighboring phenyl ring, and final reductive elimination. 

The oxidative cyclization of Ar,Ar-diarylamines to carbazoles has been achieved by thermal or photolytic induction [7, 75]. However, the yields for this transformation are mostly moderate. Better results are obtained by the palladium(II)-mediated oxidative cyclization of Ar,Ar-diarylamines (Scheme 27). Oxidative cyclization by heating of the Ar,Ar-diarylamines 76 in the presence of a stoichiometric amount of palladium(II) acetate in acetic acid under reflux provides the corresponding 3-substituted carbazoles 77 in 70-80% yield [118]. The cou-... 

Scheme 27 Palladium(II)-mediated oxidative cyclization ofiSr,iST-diarylamines...

The palladium(II)-mediated oxidative cyclization of Ar,AT-diarylamines is useful for convergent total syntheses of a range of structurally different carbazole alkaloids. Goldberg coupling of 2,3-dimethoxyacetanilide 80 and 2-bromo-5-methylanisole 81 and subsequent alkaline hydrolysis affords the diarylamine 82... 

The Goldberg coupling between 5-acetylamino-2,2-dimethylchromene 84 and 5-bromo-2-methylanisole 85 followed by hydrolysis leads to the diarylamine 86, which on palladium(II)-mediated oxidative cyclization affords pyrayafoline A 87 [ 17] (Scheme 30). Starting from 7-acetylamino-2,2-dimethylchromene, the method has been applied to the synthesis of 0-methylpyrayafoline B [54]. 

The palladium(II)-mediated oxidative cyclization is also applied to the synthesis of carbazole-l,4-quinone alkaloids. The required arylamino-l,4-benzo-quinones are readily prepared by arylamine addition to the 1,4-benzoquinone and in situ reoxidation of the resulting hydroquinone [131]. 

Ether cleavage of 4-heptyl-3-methylveratrole 121 using boron tribromide affords 4-heptyl-3-methylcatechol 122 (Scheme 38). Oxidation of the catechol 122 with o-chloranil to 4-heptyl-3-methyl-l,2-benzoquinone 123 and subsequent immediate addition of aniline leads to 5-anilino-4-heptyl-3-methyl-l,2-benzo-quinone 124. Unlike the very labile disubstituted ort/zo-quinone 123, compound 124 is stable and can be isolated. Palladium(II)-mediated oxidative cyclization of the anilino-l,2-benzoquinone 124 provides carbazoquinocin C 51. 

Furukawa et al. reported the total synthesis of murrayaquinone A (107) by a palladium(II)-mediated oxidative cyclization of the corresponding 2-arylamino-5-methyl-l,4-benzoquinones. 2-Anilino-5-methyl-l,4-benzoquinone (842) was prepared starting from 2-methyl-l,4-benzoquinone 841 and aniline 839, along with the regio-isomeric 2-anilino-6-methyl-l,4-benzoquinone (844). The oxidative cyclization of 2-anilino-5-methyl-l,4-benzoquinone (842) with stoichiometric amounts of palla-dium(ll) acetate provided murrayaquinone A (107) in 64% yield. This method was also applied to the synthesis of 7-methoxy-3-methylcarbazole-l,4-quinone (113) starting from 3-methoxyaniline (840) (623). Seven years later, Chowdhury et al. reported the isolation of 7-methoxy-3-methylcarbazole-l,4-quinone (113) from the stem bark of Murraya koenigii and named it koeniginequinone A (113) (49) (Scheme 5.101). 

Wu et al. reported the total synthesis of clausenaquinone A (112) using a palladium(ll)-mediated oxidative cyclization of the 2-arylamino-5-methoxy-l,4-benzoquinone 874 (107). This total synthesis was undertaken to establish the structure of natural clausenaquinone A (112). The key intermediate, 2-(3-hydroxy-4-methylanilino)-5-methoxy-l,4-benzoquinone (874), required for this synthesis, was obtained by the reaction of 5-amino-o-cresol (873) with 2-methoxy-l,4-benzoquinone (872) which was readily obtained by oxidation of methoxyhydroquinone (871). The palladium(ll)-mediated oxidative cyclization is non-regioselective. Thus, the cyclization of the 2-arylamino-5-methoxy-l,4-benzoquinone 874 with palladium(Il)... 

Following a synthetic pathway similar to the one reported for carbazoquinocin C (274) (see Scheme 5.127), the veratrole ( + )-818 was transformed to the arylamino-1,2-benzoquinone (+ )-954. By palladium(II)-mediated oxidative cyclization, compound... 

The oxidative cyclization of N,N-diarylamines represents a straightforward alternative route to the carbazole framework [55]. However, application of the classical thermally, photolytically or radical-induced process provides only moderate yields. Much higher yields are obtained for this transformation by palladium(II)-mediated oxidative cyclization, first reported by Akermark (Scheme 15.15) [56]. 

Scheme 15.15 Palladium(ll)-mediated oxidative cyclization of N,N-diarylamines to carbazoles.

In a palladium-mediated oxidative coupling reaction, alkenes such as methyl acrylate, acrylonitrile, or styrenes cyclize with 6- [(diinethylainino)methylene]amino -l,3-dimethyluracil to give the corresponding 6-substituted pyrido[2,3-[Pg.128]

Under the Wacker-type oxidation conditions, 4-trimethylsilyl-3-alkyn-l-ols 49 were converted to y-butyrolactones 50.40 Similarly, palladium(II)-mediated oxidative cyclization of Af-acyl aminoalkynes 51 provided a novel entry to y-lactams 52.4 ... 

A construction of the carbazole framework involving copper(ll)-catalyzed aryla-mine arylation and palladium(ll)-mediated oxidative cyclization has been reported by Menendez et al. (Scheme 41) [190, 191]. The diarylamines 95 were obtained by copper(ll) acetate-catalyzed N-arylation of arylamines 31 with phe-nyllead triacetate (183) using Barton s conditions [192]. Subsequent oxidative cyclization using palladium(ll) acetate under microwave irradiation afforded the carbazoles 32. This procedure was applied to the synthesis of murrayafoline A (188) [190]. 

Tamariz et al. developed an access to 1-methoxycarbazoles 225 via hydrolysis of 3-arylbenzoxazol-2-ones 223 and subsequent palladium(II)-mediated oxidative cyclization of the resulting diarylamines 224 (Scheme 54) [213, 214]. The required benzoxazol-2-ones 223 are obtained by regioselective Lewis acid-catalyzed Diels-Alder reaction of 4,5-dimethylene-3-aryl-l,3-oxazolidm-2-ones with alk-enes followed by aromatization using 2,3-dichloro-5,6-dicyano-l,4-benzoquinone (DDQ). 

Scheme 54 Synthesis of 1-methoxycarbazoles 225 by hydrolysis of the benzoxazol-2-ones 223 and subsequent palladium(II)-mediated oxidative cyclization of the diarylamines 224...

A number of studies on the palladium(n)-mediated oxidative cyclization of aniUno-quinones later appeared. Some of the compounds produced via this protocol are depicted in Figure 9.4. Bittner et al. [37b] and Furukawa and coworkers [37c] both described the application of the intramolecular cyclization chemistry toward the synthesis of analogues of the carbazole-l,4-quinone alkaloids. Furukawa and coworkers [37c] also reported the synthesis of murrayaquinone A (79) using this chemistry. Knolker and O Sullivan [37d,e] later demonstrated the utility of the palladium(ll)-mediated cycUzation in the synthesis of 83, which was initially anticipated to be a prekinamycin analogue precursor. In all... 

Williams and coworkers [42] utilized a similar palladium(II)-mediated oxidative cyclization/w situ reduction protocol in the total synthesis of (+)-paraherquamide B (101, Scheme 9.14). Indole 99 was treated with 1.2 equiv of PdC and 2 equiv of AgBp4 to presumably form an alkylpalladium species, which was reduced with NaBH4 to ultimately provide 100 in good yield. This compound was further transformed to paraherquamide B in six steps. Williams et al. [43] later described the total synthesis of paraherquamide A utilizing the palladium(II)-mediated cyclization on a structurally similar compound. 

The intramolecular Heck reaction presented in Scheme 8 is also interesting and worthy of comment. Rawal s potentially general strategy for the stereocontrolled synthesis of the Strychnos alkaloids is predicated on the palladium-mediated intramolecular Heck reaction. In a concise synthesis of ( )-dehydrotubifoline [( )-40],22 Rawal et al. accomplished the conversion of compound 36 to the natural product under the conditions of Jeffery.23 In this ring-forming reaction, the a-alkenylpalladium(n) complex formed in the initial oxidative addition step engages the proximate cyclohexene double bond in a Heck cyclization, affording enamine 39 after syn /2-hydride elimination. The latter substance is a participant in a tautomeric equilibrium with imine ( )-40, which happens to be shifted substantially in favor of ( )-40. 

Addition of the arylamines 117 to 2-methoxy-3-methyl-l,4-benzoquinone 118 affords regioselectively the 5-arylamino-2-methoxy-3-methyl-l,4-benzo-quinones 119 (Scheme 37). Palladium(II)-catalyzed oxidative cyclization leads to the carbazole-l,4-quinones 28 [135,136],previously obtained by the iron-mediated approach (cf. Scheme 14). Regioselective addition of methyllithium to the quinones 28 provides carbazomycin G 29a and carbazomycin H 29b [96,135]. Reduction of 29a with lithium aluminum hydride followed by elimination of water on workup generates carbazomycin B 23a [135]. Addition of heptylmag-... 

Akermark et al. reported the palladium(II)-mediated intramolecular oxidative cyclization of diphenylamines 567 to carbazoles 568 (355). Many substituents are tolerated in this oxidative cyclization, which represents the best procedure for the cyclization of the diphenylamines to carbazole derivatives. However, stoichiometric amounts of palladium(II) acetate are required for the cyclization of diphenylamines containing electron-releasing or moderately electron-attracting substituents. For the cyclization of diphenylamines containing electron-attracting substituents an over-stoichiometric amount of palladium(II) acetate is required. Moreover, the cyclization is catalyzed by TFA or methanesulfonic acid (355). We demonstrated that this reaction becomes catalytic with palladium through a reoxidation of palladium(O) to palladium(II) using cupric acetate (10,544—547). Since then, several alternative palladium-catalyzed carbazole constructions have been reported (548-556) (Scheme 5.23). 

The arylamine 780b required for the total synthesis of carbazomycin B (261) was obtained by catalytic hydrogenation, using 10% palladium on activated carbon, of the nitroaryl derivative 784 which was obtained in six steps and 33% overall yield starting from 2,3-dimethylphenol 781 (see Scheme 5.85). Electrophilic substitution of the arylamine 780b with the iron-complex salt 602 provided the iron complex 787 in quantitative yield. The direct, one-pot transformation of the iron complex 787 to carbazomycin B 261 by an iron-mediated arylamine cyclization was unsuccessful, probably because the unprotected hydroxyarylamine moiety is too sensitive towards the oxidizing reaction conditions. However, the corresponding 0-acetyl derivative... 

Our palladium(II)-catalyzed approach for the carbazomycins G (269) and H (270) requires the carbazole-l,4-quinones 941 and 981 as precursors (compare the iron-mediated synthesis, see Scheme 5.137). These intermediates should result from oxidative cyclization of the arylamino-l,4-benzoquinones, which in turn are prepared from the arylamines 839 and 984 and 2-methoxy-3-methyl-l,4-benzoqui-none (939) (652) (Scheme 5.138). 

A domino palladium(II)-mediated rearrangement/oxidative cyclization of /3-aminocyclopropanoLs has been reported by Brandi and co-workers lead-... 

Chapter 3 by Jie Jack Li presents a collection of very interesting total syntheses of naturally occurring indole alkaloids where palladium chemistry plays a central role in the syntheses. Five different types of palladium-mediated reactions are treated (I) oxidative cyclization reactions promoted by palladium (II) species (2) transmetallation reactions with organoboranes, organoslannanes, and organozinc reagents (3) inter- and intramolecular Heck reactions (4) reactions with it-allylpalladium as the intermediate and (5) reactions using C-N bond formation as the key step for the synthesis. 

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