Pantolactone, reaction with

Silanes can react with acceptor-substituted carbene complexes to yield products resulting from Si-H bond insertion [695,1168-1171]. This reaction has not, however, been extensively used in organic synthesis. Transition metal-catalyzed decomposition of the 2-diazo-2-phenylacetic ester of pantolactone (3-hydroxy-4,4-dimethyltetrahydro-2-furanone) in the presence of dimethyl(phenyl)silane leads to the a-silylester with 80% de (67% yield [991]). Similarly, vinyldiazoacetic esters of pantolactone react with silanes in the presence of rhodium(II) acetate to yield a-silylesters with up to 70% de [956]. 

Numerous studies have been directed toward expanding the chemistry of the donor/ac-ceptor-substituted carbenoids to reactions that form new carbon-heteroatom bonds. It is well established that traditional carbenoids will react with heteroatoms to form ylide intermediates [5]. Similar reactions are possible in the rhodium-catalyzed reactions of methyl phenyldiazoacetate (Scheme 14.20). Several examples of O-H insertions to form ethers 158 [109, 110] and S-H insertions to form thioethers 159 [111] have been reported, while reactions with aldehydes and imines lead to the stereoselective formation of epoxides 160 [112, 113] and aziridines 161 [113]. The use of chiral catalysts and pantolactone as a chiral auxiliary has been explored in many of these reactions but overall the results have been rather moderate. Presumably after ylide formation, the rhodium complex disengages before product formation, causing degradation of any initial asymmetric induction. 

At Tokyo College of Pharmacy [284], esters of 2-(trifluoromethyl)propenoic acid were used to synthesise 16,16,16-trifluororetinal (Eq. 101). Intermolecular Lewis acid-catalysed Diels-Alder reaction with a pantolactone chiral auxiliary allowed the diastereoselective construction of the core cyclohexenone portion with the quaternary centre set in the desired absolute configuration. 

Reduction of ethyl 2 -ketopantothenate to ethyl 2 -d-pantothenate ((g) in Fig. 8). The rate of condensation of ketopantolactone or D-pantolactone with ethyl (3-alanine, yielding ethyl 2 -ketopantothenate (0 in Fig. 8) or ethyl D-panto-thenate, respectively, is quite fast compared to the condensation of ketopantolactone or D-pantolactone with (3-alanine, and the reaction with ethyl (3-alanine proceeds more stoichiometrically [117]. Since the enzymatic hydrolysis of ethyl D-pantothenate has been established [118], if the stereoselective reduction of ethyl 2 -ketopantothenate to ethyl D-pantothenate is possible, both the troublesome resolution and the incomplete condensation might be avoided at the same time. Carbonyl reductase of C. macedoniensis is used for this purpose. Washed cells of the yeast converted ethyl 2 -ketopantothenate (80 g/1) almost specifically to ethyl D-pantothenate (> 98% e.e.), with a molar yield of 97.2% [103]. In a similar manner, 2 -ketopantothenonitrile (50 g/1) was converted to D-pan-tothenonitrile (93.6% e.e.), with a molar yield of 95.6%, on incubation with Sporidiobolus salmonicolor cells as a catalyst [104],... 

An AD reaction with the cyclic silyl enol ether 28 provides rapid access to the natural product (+ )-pantolactone (29) (Scheme 3.27) [338]. In effect, these reactions are asymmetric a-hydroxylations of carbonyl compounds. 

The same reagent (/ )-(+) -pantolactone 112 gives good results with a-halo acids that are good precursors for many other compounds such as a-amino acids by nucleophilic displacement. The a-halo acid chlorides 115 are prepared directly from the simple acids 114 and treated with the same tertiary amine EtNMe2 used above to give the unstable ketenes 116 and hence the esters 117 by reaction with (R)-(+) -pantolactone22112. 

Diels-Alder reactions with Oppolzer s chiral sultam Diels-Alder reactions with pantolactone as chiral auxiliary Chiral auxiliaries attached to the diene Improved Oxazolidinones SuperQuats Asymmetric Michael (Conjugate) Additions... 

Diels-Alder reactions with pantolactone as chiral auxiliary... 

Chiral ( >2-cyanocinnamates 16 bearing ethyl (.S i-lactate and (7 )-pantolactone as the chiral auxiliary are very efficient dienophiles in the asymmetric Dicls-Alder reaction with cyclopentadiene, opening up a route to the synthesis of cycloaliphatic atnino acids96. 

Dipolar cycloadditions of nitrile imines with alkenes lead to 2-pyrazolines. Moderate select vities are observed in reactions with the acrylate of (/ )-pantolactone. 

Mark6 and co-workers also have explored the use of chiral derivatives of 2-pyrones to induce asymmetry. Chiral pyrones 66-69 were studied in their reactions with ethyl vinyl ether. As the data in Table 9 indicate, the pantolactone auxiliary is the most useful of those studied. Most intriguing is the fact that catalysis with either antipode of the europium Lewis acid, or even an achiral europium Lewis acid, yields the same stereochemically impressive results. 

Formation of cyclic acetals was also observed in the MBH reaction of aliphatic aldehydes with pantolactone acrylate 28. The more stable cis isomers 29 are formed predominantly, and mixed products 30 can be isolated by sequential addition of two different aldehydes (Scheme 1.14). However, benzaldehyde failed to give the cyclic adduct on reaction with the pantolactone ester under the same conditions electronic effects rather than steric hindrance... 

The resulting 2-benzylthioethylamine could be debenzylated by treatment with sodium in liquid ammonia. However, when 2-benzylthioethylamine was treated with carbobenzyloxy-P-alanine azide (prepared from carbobenzyloxy-P-alanylhydrazide by nitrosation), 2-benzylthio-7V-(carbobenzyloxy-P-alanyl)ethyl-amine formed. Reduction with sodium in liquid ammonia was sufficient to remove both the benzyl and carbobenzyloxy protecting groups and, as noted above, reaction with pantolactone yielded pantetheine. Phosphorylation to the mono- and diphosphates of pantetheine has been effected with the corresponding dibenzylphospho-nates (vide supra, ATP). 

By employing chiral proton sources for the protonation of the intermediate samarium species 184/185, highly enantioenriched allenes were accessible in some cases [98]. Thus, in the reaction of propargylic phosphate 198, (R,Rj- 1,2-diphenyl-1,2-ethandiol (200) and (R)-pantolactone (201) were found to give the highest selec-tivities, affording allene 199 with up to 95% ee (Scheme 2.61). 

Brimble and coworkers176 studied the asymmetric Diels-Alder reactions of cyclopentadiene with chiral naphthoquinones 272 bearing different chiral auxiliaries. The highest endo and facial selectivities were obtained using zinc dichloride as the Lewis acid catalyst and (—)-pantolactone as the chiral auxiliary. Thus, the reaction between cyclopentadiene and 272 afforded a 98 2 mixture of 273 and 274 (equation 76). The chiral auxiliary was removed easily by lithium borohydride reduction. 

Hansen and colleagues177 used (+)-pantolactone as a chiral auxiliary to achieve asymmetric induction in the first step toward their synthesis of d.v-perhydroisoq uinol inc 278. The titanium tetrachloride catalyzed reaction between 1,3-cyclohexadiene (275) and chiral acrylate 276 proceeded with high diastereofacial selectivity to give 277 (94% de) in 75% yield (equation 77). 

Mark6 and colleagues178 studied the Eu(hfc)3 catalyzed inverse electron demand Diels-Alder reactions between (—)-pantolactone derived chiral a-pyrones 279 and vinyl ethers and thio ethers 280. This auxiliary proved superior to other auxiliaries in these reactions. The reactions generally proceeded with high yields, affording the endo adducts 281 with de values generally above 95%. The de proved independent of the chirality or achirality of the Lewis acid employed, as (+)-Eu(hfc)3, (—)-Eu(hfc)3 and Eu(fod)3 all afforded the same diastereomer with >95% de (equation 78, Table 13). 

The asymmetric [3 + 4] cycloaddition is readily achieved using chiral auxiliaries or catalysts [16]. The efficiency of the chiral auxiliary approach is illustrated in the [3-1-4] cycloaddition with cyclopentadiene. The vinyldiazoacetate 6, with (T)-pantolactone as the chiral auxiliary, generated the bicyclo[3.2.1]octadiene 75 in 87% yield and 76% dia-stereomeric excess (Eq. 10) [82]. Alternatively, the chiral rhodium prolinate Rh2(S-DOSP)4-catalyzed reaction of 4 generated the bicyclo[3.2.1]octadiene 76 in 77% yield and with 93% enantiomeric excess (Eq. 11) [83]. 

The reaction of vinylcarbenoids with vinyl ethers can lead to other types of [3 + 2] cycloadditions. The symmetric synthesis of 2,3-dihydrofurans is readily achieved by reaction of rhodium-stabilized vinylcarbenoids with vinyl ethers (Scheme 14.17) [107]. In this case, (J )-pantolactone is used as a chiral auxihary. The initial cyclopropanation proceeds with high asymmetric induction upon deprotection of the silyl enol ether 146, ring expansion occurs to furnish the dihydrofuran 147, with no significant epi-merization during the ring-expansion process. 

Reduction of ketopantolactone to D-pantolactone (0 in Fig. 8). This reaction is catalyzed by conjugated polyketone reductase. About 50 or 90 g/1 of D-panto-lactone (98 or 94% e.e., respectively) was produced with a molar yield of nearly 100% on incubation with washed cells of R. minuta or C. parapsilosis, respectively [115, 116]. 

The principle of the optical resolution of racemic pantolactone is shown in Fig. 13. If racemic pantolactone is used as a substrate for the hydrolysis reaction by the stereospecific lactonase, only the d- or L-pantolactone might be converted to d- or L-pantoic acid and the l- or D-enantiomer might remain intact, respectively. Consequently, the racemic mixture could be resolved into D-pan-toic acid and L-pantolactone, or D-pantolactone and L-pantoic acid. In the case of L-pantolactone-specific lactonase, the optical purity of the remaining d-pantolactone might be low, except when the hydrolysis of L-pantolactone is complete. On the other hand, using the D-pantolactone-specific lactonase, d-pantoic acid with high optical purity could be constantly obtained independently of the hydrolysis yield. Therefore, the enzymatic resolution of racemic pantolactone with D-pantolactone-specific lactonase was investigated [138 140]. 

The reaction of (R)-pantolactone with calcium 3-aminopropionate (synthesized from acrylonitrile, see Fig. 8.20) affords calcium pantothenate [111]. 

Analogous to epoxides, aziridines can be prepared by the methylenation of imines. In this case, ethyl diazoacetate is the most common source of carbenes. For example, the imine derived from p-chlorobenzaldehyde 148 is converted to the c/j-aziridinyl ester 149 upon treatment with ethyl diazoacetate in the presence of lithium perchlorate <03TL5275>. These conditions have also been applied to a reaction medium of the ionic liquid l-n-butyl-3-methylimidazolium hexafluorophosphate (bmimPFe) with excellent results <03TL2409>. An interesting enantioselective twist to this protocol has been reported, in which a diazoacetate derived from (TJ)-pantolactone 150 is used. This system was applied to the aziridination of trifluoromethyl-substituted aldimines, which were prepared in situ from the corresponding aminals under the catalysis of boron trifluoride etherate <03TL4011>. 

In the hydroxyamination reactions performed with cyclohexene, low diastereoselectivity was induced by both ( + )-2-hydroxyheptahelicene ( )-A and ( —)-dihydroquinine (—)-B. Excellent diastereoselectivity was obtained in the reactions performed on (E)-, 2-diphenylethylene, especially by using the auxiliaries ( + )-A and (—)-B. The new stereogenic centers were formed with the same (S,S) configuration using either (—)-B or ( —)-pantolactone ( )-H, but unsatisfactory diastereoselectivity was achieved with the latter auxiliary. 

Ketene Additions. Reaction of the ketene derived from ibuprofen (Ar=p-isobutylphenyl) with (R)-pantolactone in the presence of simple tertiary amine bases in apolar solvents yielded >99% de favoring the (R,R)-ester (eq 9). The reaction is first order in each component and possesses a pronounced deuterium isotope effect knlko 4). The ketene from naproxen (Ar=2-(6-methoxynaphthyl)) affords a de of 80% under similar conditions. 

Interestingly, the Diels-Alder reaction of the acrylate of o-pantolactone and cyclopentadiene in the presence of 2 equiv. MAD results in high diastereoselectivity which is the opposite of that encountered with ordinary Lewis acids. The low-temperature NMR spectrum of the Lewis acid complex of the acrylate of D-pantolactone showed that an ordinary Lewis acid such as SnCU forms the chelate complex [O] (Sch. 132). In the 1 1 acrylate-MAD complex, structure [P], although predominant, seems to be in equilibrium with the minor complex [Q] with s-cis conformation this... 

Control of the stereochemistry of the Diels-Alder reaction by means of a chiral center in the substrate is a versatile means of synthesizing cychc systems stereoselec-tively [347]. For preparation of ring systems with multi-stereogenic centers, in particular, the diastereoselective Diels-Alder reaction is, apparently, one of the most dependable methods. The cyclization of optically active substrates has enabled asymmetric synthesis. Equation (147) shows a simple and very efficient asymmetric Diels-Alder reaction, starting from commercially available pantolactone [364,365], in which one chlorine atom sticking out in front efficiently blocks one side of the enone plane. A fumarate with two chiral auxiliaries afforded virtually complete stereocontrol in a titanium-promoted Diels-Alder reaction to give an optically active cyclohexane derivative (Eq. 148) [366,367]. A variety of diastereoselective Diels-Alder reactions mediated by a titanium salt are summarized in Table 13. 

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