Cyclization reactions intramolecular oxidative

R = H) undergoes a variety of enzyme-catalyzed free-radical intramolecular cyclization reactions, followed by late-stage oxidations, eliminations, rearrangements, and O- and N-alkylations. Working from this generalization as an organizing principle, the majority of known AmaryUidaceae alkaloids can be divided into eight stmctural classes (47). 

Interestingly, the nucleophilic addition of water in the sequence of events giving rise to 41 represents a relevant model system for investigating the mechanism of the generation of DNA-protein cross-links under radical-mediated oxidative conditions [80, 81]. Thus, it was shown that lysine tethered to dGuo via the 5 -hydroxyl group is able to participate in an intramolecular cyclization reaction with the purine base at C-8, subsequent to one electron oxidation [81]. 

Isoxazole derivatives have also been synthesized in variable yield by the palladium-catalyzed intramolecular oxidative cyclization of a,/i-unsaturated oximes (Scheme 110).174 Reactions of this type are reminiscent of procedures... 

Enyne metathesis is unique and interesting in synthetic organic chemistry. Since it is difficult to control intermolecular enyne metathesis, this reaction is used as intramolecular enyne metathesis. There are two types of enyne metathesis one is caused by [2+2] cycloaddition of a multiple bond and transition metal carbene complex, and the other is an oxidative cyclization reaction caused by low-valent transition metals. In these cases, the alkyli-dene part migrates from alkene to alkyne carbon. Thus, this reaction is called an alkylidene migration reaction or a skeletal reorganization reaction. Many cyclized products having a diene moiety were obtained using intramolecular enyne metathesis. Very recently, intermolecular enyne metathesis has been developed between alkyne and ethylene as novel diene synthesis. 

An unusual one-pot intramolecular sulfoxide alkylation-elimination reaction was found by Gibson et al. <2001SL712>. These authors found that treatment of 459 with potassium bis-trimethylsilylamide resulted in a ring closure to 460 in acceptable yield. Furthermore, Batori and Messmer found an effective method for preparation of [l,2,3]triazolo[l,5- ]pyrimidinium salts <1994JHC1041> oxidative cyclization of hydrazones 461 by 2,4,4,6-tetrabromo-2,5-cyclohexadienone gave rise to the quaternary salts 462. Under certain reaction conditions, the formation of 6-bromo-salts 462 (R6 = Br) was also experienced. As neither the starting compound nor the quaternary triazolopyridinium salt underwent bromination in this position, the authors assumed that this bromination process occurred on one of the intermediates in the course of the above-mentioned cyclization reaction. 

A large variety of metabolic cyclization reactions, counterparts to the reactions of hydrolytic ring opening discussed above, occur without any change in the degree of oxidation, and often nonenzymatically. Such reactions proceed by various mechanisms of intramolecular nucleophilic substitution, with elimination of amine, phenol, halide, or H20. 

In an effort to explore the factors that govern anodic C-C bond formation, Swenton and coworkers have also been exploring the intramolecular coupling of phenols and olefins (Scheme 28) [44]. In these reactions, initial oxidation of the phenol followed by loss of a proton and a second oxidation led to the formation of a cationic intermediate (26). This intermediate was trapped by the olefin to form a second cation that was in turn trapped by methanol to form the final product 28. When R2 was equal to methyl (25b) or phenyl (25c) the reaction led to a good yield of the cyclized product. Reactions where the R2 was equal to a hydrogen (25a and 25d) were not so successful. The cyclizations were compatible with the incorporation of the olefin into a third ring (25e). 

Finally, the intramolecular coupling reaction between an olefin and a pyrrole ring has been examined (Scheme 40). In this example, a 66% isolated yield of the six-membered ring product was obtained. A vinyl sulfide moiety was used as the olefin participant and the nitrogen protected as the pivaloyl amide in order to minimize the competition between substrate and product oxidation. Unlike the furan cyclizations, the anodic oxidation of the pyrrole-based substrate led mainly to the desired aromatic product without the need for subsequent treatment with acid. 

In all of the cyclization reactions, Moeller has found only a small difference between the use of alkyl and silyl enol ethers. Since both styrenes and enol ethers have similar oxidation potentials, even the styrene moiety could function as the initiator for oxidative cyclization reactions. The anodic oxidation of simple styrene type precursors leads to low yields of cyclized products so that enol ether moiety seems to be the more efficient initiator for intramolecular anodic coupling reactions [93]. 

The previous chapter covered radical cation cyclization reactions that were a consequence of single-electron oxidation. In the following section, radical anion cyclization reactions arising from single-electron reduction will be discussed. In contrast to the well documented cyclization reactions via carbon-centered free radicals [3, 4], the use of radical anions has received limited attention. There are only a few examples in the literature of intramolecular reductive cyclization reactions via radical anions other than ketyl. Photochemi-cally, electrochemically or chemically generated ketyl radical anions tethered to a multiple bond at a suitable distance, have been recognized as a promising entry for the formation of carbon-carbon bonds. 

Intramolecular addition of hydroxylamines and hydroxamic acids to the non-activated double bonds is possible through oxidative cyclization. Reaction of O-Acyl fi,y-unsaturated hydroxamates (e.g. 56, equation 38) with bromine provides 3,4-substituted iV-hydroxy -lactams such as 57 with high diastereoselectivity. Analogous reaction of O-benzyl hydroxylamine 58 (equation 39) with iodine results in five-membered cyclization with 2 1 ratio of diastereomers. ... 

Novel polycyclic heterocyclic systems including the isoxazoline ring were described. Thus, oximes 191 and 193 in the presence of sodium hypochlorite afforded heterocycles 192 or 194, respectively (equations 83 and 84). Intramolecular cycloaddition of nitrile oxide was used in the synthesis of the A-ring fragments of la,25-dihydrovitamin D3 and taxane diterpenoids, sulphur-containing isoxazoles, fluoro-substituted aminocyclopentanols and aminocyclopentitols . New gem- and vic-disubstituted effects in such cyclization reactions have been reviewed by Jung. ... 

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 intramolecular oxidative cyclization of the anilinobenzoquinone 940 with a catalytic amount of palladium(II) acetate in the presence of copper(II) acetate in air afforded the carbazole-l,4-quinone 941 in almost quantitative yield. The regioselective introduction of the heptyl side chain at C-1 of the carbazole-l,4-quinone 941 was achieved by a 1,2-addition of the corresponding Grignard reagent to give the carbazole-l,4-quinol 942 in 55% yield. However, 1,4-addition at C-3 and 1,2-addition at C-4 led to the regioisomeric products 943 and 944 as well. Finally, under acidic reaction conditions, the carbazole-l,4-quinol 942 was smoothly transformed to... 

The proposed mechanism is given in Scheme 15. Initially the dissociation of water, maybe trapped by the molecular sieve, initiates the catalytic cycle. The substrate binds to the palladium followed by intramolecular deprotonation of the alcohol. The alkoxide then reacts by /i-hydride elimination and sets the carbonyl product free. Reductive elimination of HOAc from the hydride species followed by reoxidation of the intermediate with dioxygen reforms the catalytically active species. The structure of 13 could be confirmed by a solid-state structure [90]. A similar system was used in the cyclization reaction of suitable phenols to dihydrobenzofuranes [92]. The mechanism of the aerobic alcohol oxidation with palladium catalyst systems was also studied theoretically [93-96]. 

A very large number of these systems with ring junction heteroatoms exists, and this number is constantly increasing. Only illustrative examples of the preparation of such systems can be given here. The synthetic methods for the formation of this type of heterocycle can be usefully classified as follows (i) various cyclocondensations between the corresponding heterocyclic derivatives and bifunctional units, (ii) intramolecular cyclizations of electrophilic, nucleophilic or (still rare) radical type, (iii) cycloadditions, (iv) intramolecular oxidative coupling, (v) intramolecular insertions, (vi) cyclization of open-chained predecessors, (vii) various reactions (quite often unusual) which are specific for each type of system. Examples given below illustrate all these cases. 

Morphine is biosynthesized from norreticuline through intramolecular oxidative coupling of the electron-rich aromatic rings, transformation that is difficult to achieve with chemical oxidizing agents. The most convenient synthesis, illustrated in Scheme 23, consists of partial saturation of the aromatic ring by the Birch reaction followed by an acid-Catalyzed Grewe-type cyclization to form the required tetracyclic skeleton (48). 

Not unrelated to the above syntheses is the intramolecular oxidative cyclization of ubiquinone (108) to ubichromenol (110) (63JA239). Catalyzed by bases, of which pyridine seems to be the choice example (65JCS5060), the reaction proceeds through the o-quinoneallide (109). Significantly, this process is also-brought about by irradiation with visible light <65LA(684)212>. 

In fact, the role of copper and oxygen in the Wacker Process is certainly more complicated than indicated in equations (151) and (152) and in Scheme 10, and could be similar to that previously discussed for the rhodium/copper-catalyzed ketonization of terminal alkenes. Hosokawa and coworkers have recently studied the Wacker-type asymmetric intramolecular oxidative cyclization of irons-2-(2-butenyl)phenol (132) by 02 in the presence of (+)-(3,2,10-i -pinene)palladium(II) acetate (133) and Cu(OAc)2 (equation 156).413 It has been shown that the chiral pinanyl ligand is retained by palladium throughout the reaction, and therefore it is suggested that the active catalyst consists of copper and palladium linked by an acetate bridge. The role of copper would be to act as an oxygen carrier capable of rapidly reoxidizing palladium hydride into a hydroperoxide species (equation 157).413 Such a process is also likely to occur in the palladium-catalyzed acetoxylation of alkenes (see Section 61.3.4.3). 

Cyclization of nitrile oxides with a four-atom intervening chain to the alkene always leads to 5,6-fused bicylic isoxazolines possessing a bridgehead C—N double bond. This is in contrast to nitrone cycliza-tions where competition to form bridged bicyclic isoxazolidines is observed. The alkenyl oximes (73) and (74) cyclize in typical fashion via nitrile oxide intermediates (Scheme 21).33a>36 The stereochemistry of cyclization here was studied both experimentally and by calculation. The higher stereoselectivity observed with the (Z)-alkene is typical. (Z)-Alkenes cycloadd much slower than ( >alkenes in intermole-cular reactions this is attributed to greater crowding in the transition state. Thus, intramolecular cycloaddition of (Z)-alkenes depends on a transition state that is heavily controlled by steric factors. 

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