A-iodolactone

Bis(5> m-collidine)iodine(I) tetrafluoroborate in DMSO has been found to be a convenient reagent for the conversion of alkanes to a-iodocarbonyl compounds. When dihydrofuran (305a) and dihydropyran (305b) are the substrates, this reaction affords the corresponding a-iodolactones 306 (Scheme 77). This method converts certain glycals such as 307 to their corresponding a-iodo-a,/3-unsaturated lactones 309, presumably because of elimination of a molecule of acetic acid from the initially formed lactone 308 (86S727) (Scheme 78). 

An enantioselective reduction of an a-iodolactone under radical conditions has been reported [95CC481]. Treatment of 207 with tin hydride, magnesium(II) iodide and in the presence of a chiral amine gave the 8-lactone 208 in good yield and moderate enantioselectivity. This is one of the first examples of chiral Lewis acid mediated enantioselective radical reactions. 

Hoshino et al. [33] reported the first example of an enantioselective radical reaction employing a chiral Lewis add complex. The enantioselective reduction of a-methoxy-methyl-a-iodolactone 41 with tributyltin hydride (BusSnH) in the presence of stoichiometric amounts of the chiral complex of a chiral diamine 42 and Mgl2, gave the reduced product 43 in 88 % yield with 62 % ee (Sch. 17). Reaction using Mg(C104)2, TiCU, Znl2,... 

The formation of a quaternary carbon center by the radical-mediated allylation of an a-iodolactone was examined for substrate 341 by Murakata, Jono, and Hos-hino [71]. Lewis acids for this reaction were prepared from a bis-sulfonamide and tri-methylaluminum in dichloromethane. Other aluminum compounds were employed in the preparation of the catalyst but all resulted in similar or lower asymmetric induction. The Lewis acid was complexed with the lactone and then the allylation procedure in Sch. 44 was performed. It was found that superior asymmetric induction could be achieved if the Lewis acid was prepared from the ligand with two equivalents of trimethylaluminum. It was also interesting that some turnover could be achieved, as indicated by the data obtained from use of 50 mol % catalyst. 

Radical reactions are also valuable strategies for the formation of quaternary carbon-based centers. An enantioselective variant of this has recently come to light utilizing aluminum as a Lewis acid complexed to chiral BINOL ligand 26 in the allylation of a-iodolactones 24 (Eq. 9, Table 1) [13]. 

A-Iodolactone has been identified in human thyroid tissue pretreated with high doses of iodine, it has also been isolated from porcine thyroid follicles ex vivo. It inhibits proliferation in micromolar concentrations and also induces apoptosis, thus it might be responsible for autoregulatory growth and thyroid involution induced by iodine. 

Synthesis of HeimiolA and Hopeahainol D Heimiol A and its epimer hopeahainol D are two unique resveratrol-derived dimers with a [3.2.2] bicycle system. The key step in their synthesis was a iodolactonization/intramolecular FC cascade reaction of the carboxylic acid 226 promoted by the iodonium source [(EtjSI)jClj]SbCl (IDSl) in MeCN at 25°C (Scheme 2.34) [37]. This reaction provided the entire [3.2.2] bicycle with the required all- yn... 

On the other hand, a-iodolactone was found as a nice substrate to realize the practical enantioselectivity [205]. In the presence of stoichiometric amount of chiral Lewis acid prepared by the 1 1 reaction of (S,S)-(157a) and Me3Al, the quaternary carbon formation through radical allylation with allyltributyltin resulted in the... 

It has been reported that the treatment of a hydroxytricycloundecenone derivative, which exists largely in the form of a hydroxyketone in solution (90%), with DIB-iodine in cyclohexane, followed by the photolysis resulted in the formation of a iodolactone arising from a 5-fragmentation in 76 to 82% yield (Scheme 61). 

Cyclopentene derivatives with carboxylic acid side-chains can be stereoselectively hydroxy-lated by the iodolactonization procedure (E.J. Corey, 1969, 1970). To the trisubstituted cyclopentene described on p. 210 a large iodine cation is added stereoselectively to the less hindered -side of the 9,10 double bond. Lactone formation occurs on the intermediate iod-onium ion specifically at C-9ot. Later the iodine is reductively removed with tri-n-butyltin hydride. The cyclopentane ring now bears all oxygen and carbon substituents in the right stereochemistry, and the carbon chains can be built starting from the C-8 and C-12 substit""" ... 

Because the Corey synthesis has been extensively used in prostaglandin research, improvements on the various steps in the procedure have been made. These variations include improved procedures for the preparation of norbomenone (24), alternative methods for the resolution of acid (26), stereoselective preparations of (26), improved procedures for the deiodination of iodolactone (27), alternative methods for the synthesis of Corey aldehyde (29) or its equivalent, and improved procedures for the stereoselective reduction of enone (30) (108—168). For example, a catalytic enantioselective Diels-Alder reaction has been used in a highly efficient synthesis of key intermediate (24) in 92% ee (169). 

PGF2a- The cyclopentane ring of the Corey lactone (9) is the host of four contiguous stereogenic centers. Retrosynthetic simplification of 9 provides 10, a construct which is more complex than 9 Nevertheless, intermediate 10 possesses structural features that satisfy the requirement for the iodolactonization transform. The iodolactone in 10 constitutes the retron for the iodolactonization transform.11 Cleavage of the indicated bonds in 10 sacrifices two of the five stereocenters and provides unsaturated carboxylic acid... 

Intermediate 8, the projected electrophile in a coupling reaction with intermediate 7, could conceivably be derived from iodolactone 16. In the synthetic direction, cleavage of the acetonide protecting group in 16 with concomitant intramolecular etherification could result in the formation of the functionalized tetrahydrofuran ring of... 

The adjacent iodine and lactone groupings in 16 constitute the structural prerequisite, or retron, for the iodolactonization transform.15 It was anticipated that the action of iodine on unsaturated carboxylic acid 17 would induce iodolactonization16 to give iodo-lactone 16. The cis C20-C21 double bond in 17 provides a convenient opportunity for molecular simplification. In the synthetic direction, a Wittig reaction17 between the nonstabilized phosphorous ylide derived from 19 and aldehyde 18 could result in the formation of cis alkene 17. Enantiomerically pure (/ )-citronellic acid (20) and (+)-/ -hydroxyisobutyric acid (11) are readily available sources of chirality that could be converted in a straightforward manner into optically active building blocks 18 and 19, respectively. 

A cursory inspection of key intermediate 8 (see Scheme 1) reveals that it possesses both vicinal and remote stereochemical relationships. To cope with the stereochemical challenge posed by this intermediate and to enhance overall efficiency, a convergent approach featuring the union of optically active intermediates 18 and 19 was adopted. Scheme 5a illustrates the synthesis of intermediate 18. Thus, oxidative cleavage of the trisubstituted olefin of (/ )-citronellic acid benzyl ester (28) with ozone, followed by oxidative workup with Jones reagent, affords a carboxylic acid which can be oxidatively decarboxylated to 29 with lead tetraacetate and copper(n) acetate. Saponification of the benzyl ester in 29 with potassium hydroxide provides an unsaturated carboxylic acid which undergoes smooth conversion to trans iodolactone 30 on treatment with iodine in acetonitrile at -15 °C (89% yield from 29).24 The diastereoselectivity of the thermodynamically controlled iodolacto-nization reaction is approximately 20 1 in favor of the more stable trans iodolactone 30. 

Unsaturated carboxylic acid 17 possesses the requisite structural features for an iodolactonization reaction.16 A source of electrophilic iodine could conceivably engage either diastereoface of the A20,21 double bond in 17. The diastereomeric iodonium ion inter-... 

Curran s synthesis of ( )-A9(l2)-capnellene [( )-2] is detailed in Schemes 30 and 31. This synthesis commences with the preparation of racemic bicyclic vinyl lactone 147 from ( )-norbomenone [( )-145] by a well-known route.61 Thus, Baeyer-Villiger oxidation of (+)-145 provides unsaturated bicyclic lactone 146, a compound that can be converted to the isomeric fused bicyclic lactone 147 by acid-catalyzed rearrangement. Reaction of 147 with methylmagne-sium bromide/CuBr SMe2 in THF at -20 °C takes the desired course and affords unsaturated carboxylic acid 148 in nearly quantitative yield. Iodolactonization of 148 to 149, followed by base-induced elimination, then provides the methyl-substituted bicyclic vinyl lactone 150 as a single regioisomer in 66% overall yield from 147. 

Iodine is a very good electrophile for effecting intramolecular nucleophilic addition to alkenes, as exemplified by the iodolactonization reaction71 Reaction of iodine with carboxylic acids having carbon-carbon double bonds placed to permit intramolecular reaction results in formation of iodolactones. The reaction shows a preference for formation of five- over six-membered72 rings and is a stereospecific anti addition when carried out under basic conditions. 

Entries 15 to 18 are examples of use of iodocyclization in multistep syntheses. In Entry 15, iodolactonization was followed by elimination of HI from the bicyclic lactone. In Entry 16, a cyclic peroxide group remained unaffected by the standard iodolactonization and subsequent Bu3SnH reductive deiodination. (See Section 5.5 for... 

Reactants with internal nucleophiles are also subject to cyclization by electrophilic sulfur reagents, a reaction known as sulfenylcyclization.92 As for iodolactonization, unsaturated carboxylic acids give products that result from anti addition.93... 

On page 313, the effect of methyl substitution on the stereoselectivity of a,a-diallylcarboxylic acids under iodolactonization conditions was discussed. Consider the two compounds shown and construct a reaction energy profile for... 

It has been found that when 8,e-enolates bearing (3-siloxy substiments are subject to iodolactonization, the substituent directs the stereochemistry of cyclization in a manner opposite to an alkyl substituent. Suggest a TS structure that would account for this difference. 

Iodolactonization of anti,syn-1 could result in four iodolactones, two resulting from face selectivity, and two resulting from diastereotopic olefin selectivity. In practice only three lactones are formed in a 142 4.7 1 ratio, with 4 being essentially the only product. In fact this kinetic iodolactonization proceeds with 147 1 olefin selectivity and 30 1 face selectivity, considerably higher than the selectivity observed in previous iodolactonization of 3-methyl-4-pentenoic acid (8, 257). Lac-tonization of 1 also shows cis-C4,C5 selectivity. 

A very effective method for removal of the chiral auxiliary from cyclohexenones 34 involves treatment with I2 in THF-H2O to give the iodolactones 35 (Scheme 9). These highly functionalized chiral cyclohexanones have figured prominently in the asymmetric synthesis of natural products e.g. Scheme 15. Furthermore, selective cleavage of the cyclohexanone ring in 35... 

A different mode of fragmentation of the lactone ring in 35 occurred to give butyrolactone 38 when anhydrous lithium alkoxides were used in place of metal hydroxides under aqueous conditions (Scheme 10). It is noteworthy that 36, 37 and 38 (R = H) are all formed without racemization. Although we are only in the early stages of development of the chemistry of iodolactones 35, it is already clear that there is considerable potential for utilization of the butenolides derived from 35 as scaffolds for construction of carbocyclic and heterocyclic ring... 

Cyclohexenones 34 also undergo a highly diastereoselective dihydroxylation to give cii-diols 39 (Scheme 11).22 These diol amides are converted to hydroxylactones 40 by an acid-catalyzed process involving retro aldol-realdolization prior to transacylation. The enantiomers of hydroxylactones 40 are obtained from iodolactones 35 by iodide exchange with 2,2,6,6-tetramethylpiperidin-l-yloxy free radical (TEMPO) followed by reductive cleavage of the TEMPO derivative with Zn in ElOAc. The enantiomeric purity of the hydroxylactones prepared by either route is 95-98% ee. 

Birch reduction-alkylation of 5 with 2-bromoethyl acetate was carried out with complete facial selectivity to give 57. This tetrafunctional intermediate was converted to the bicyclic iodolactone 58 ( > 99% ee) from which the radical cyclization substrate 59 was prepared. The key radical cyclization occurred with complete regio- and facial-selectivity and subsequent stereoselective reduction of the resulting tertiary radical gave 60 with the required trans BC ring fusion.The allylic alcohol rmit of (+)-lycorine was obtained by a photochemical radical decarboxylation, 62 63. 

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