Epimers Epoxides

The A-D-ring analog 30a,b (mixture of epimers) has been prepared from the epoxide 3a,b by base catalyzed epoxide cleavage, hydroxymethylenation, and O-alkylation of the butenolide unit using standard conditions. Hydroxymethylenation of keto-ester 7 followed by butenolide addition provided the A-D-ring analog 31. 

The endo-spiro-OZT could be prepared through a reaction sequence similar to that applied for the exo-epimer, with spiro-aziridine intermediates replacing the key spiro-epoxides (Scheme 18). Cyanohydrin formation from ketones was tried under kinetic or thermodynamic conditions, and only reaction with the d-gluco derived keto sugar offered efficient stereoselectivity, while no selectivity was observed for reaction with the keto sugar obtained from protected D-fructose. The (R) -cyanohydrin was prepared in excellent yield under kinetic conditions (KCN, NaHC03, 0 °C, 10 min) a modified thermodynamic procedure was applied to produce the (S)-epimer in 85% yield (Scheme 18). 

Conversion of the resulting separate D-seco D-E trans i-vincadiffor-mine diols 198-201 to their primary tosylates and tertiary trimethylsilyl-oxy derivatives 202-205 and coupling to vindoline by the chlorination-silver tetrafluoroborate-potassium borohydride sequence provided amino tosylates 206-209, which could be directly subjected to cyclization or, alternatively, converted to the C-20 -C-21 epoxides 178, 181, 210, and 211 by reaction with tetrabutylammonium fluoride (Scheme 53). While cyclization of the tosylates 206-209 led essentially only to quaternary salts which could be debenzylated to provide the lower energy atropi-somer of vinblastine (1), leurosidine (56), vincovaline (184), and its C-20 epimer (212) respectively, cyclization of the epoxides 178, 181, 210, and... 

As mentioned, the relative configuration of isoschizandrin (6) was uncertain, and structure (S)-17 or structure (R)-17 were proposed for this lignan (see Fig. 2) [14]. Addition of MeLi to ketone (S)-16 yielded compound (R)-17 as a single isomer (96%, dr>100 l). Epimer (S)-17 was obtained in three steps by olefination (CH2Br2, Zn, TiCl4), epoxidation (MCPBA), and... 

Aromatic Compounds.—A number of 2,3-dihydroxyoestra-l,3,5(10)-trienes have been prepared from the corresponding 2-amino-3-hydroxy-compounds using a novel inverse oxidation procedure followed by reduction with KI. Addition of the substrate to sodium metaperiodate in high dilution ensures no coupling with the intermediate quinonimines. 2-Bromo-oestradiol was readily converted into 2-methoxyoestradiol by treatment with NaOMe-MeOH-DMF-CuI. Novel preparations of the biologically interesting 11/3-methyl- and 11/3-ethyl-oestradiol have been reported in full. The key intermediates were the 11-oxo-oestradiol 3-benzyl ether (82) and its 9/3-epimer (83). The latter was derived from the 9,H-epoxides (81) by treatment with KOH followed by benzylation. The thermodynamically unstable 9a-epimer (82) was prepared from the 9j8-epimer (83) by... 

This reaction was used to introduce the final two skeletal carbons in a total synthesis of maytansine (4).2 The reaction of the 2,/ -unsaturated aldehyde (2) with I (R = C6H5) gives the desired 4,5-unsaturated 3-hydroxy ester 3 in 80% yield. The ratio of the desired (S)-alcohol to the epimer is 93 7. The resulting amino acid was cyclized to the lactam in 80% yield with mesitylenesulfonyl chloride (8, 318-319). Epoxidation by the Sharpless procedure (9, 78 79) was also highly stereoselective, giving the desired epoxide and the undesired epimer in the ratio > 200 1. 

A cationic cyclization inspired by a biogenetic postulate (Scheme 44) (73TL3963) results in formation of equal amounts of the C-15 epimers (189) from the vinyl epoxide (188). 

Epimerization of sugar, mechanisms 778 Epimers, definition of 163 Epinephrine (adrenaline) 542,553, 553s Episomes. See plasmid Epithelial cells 29 Epitheliocytes 25 Epoxides, alkyation by 254 Epoxide hydrolases 591 EPR (electron paramagnetic resonance) spectroscopy 398, 399 of glutamate mutase 873 in study of phosphotransferases 639 EPSP (enolpyruvoylshikimate-3-phosphate) 687s... 

The construction of the C2-C3 bond of the 1-hydroxyethylene moiety by the addition of a two-carbon fragment to aminoalkyl epoxides, amino ketones, p-amino-a-hydroxy aldehydes, or 4-amino-3-oxo phosphonates was also studied. As summarized in Scheme 14, Evans et al.[28] added a malonate to an aminoalkyl epoxide and the product spontaneously cyclized, leading to a lactone.— Then, the second side chain was incorporated into the a-carbon of the lactone, providing a mixture of C2 epimers. The final compound was obtained by hydrolysis and decarboxylation. The lack of diastereoselectivity of this method is offset by the small number of steps and the accessibility to all eight possible stereoisomers. Biihlmayer et al.[30] also used a similar method, but they transformed the epoxide into the apparently more reactive iodide. Then, the iodide compound was treated with an enolate. 

Reduction of the carbonyl in the r >[CO-CH2-NH] link 7 (R1 = H) results in the (hy-droxy)ethyleneamino or r >[CH(OH)-CH2-NH] link 8 (R1 = H), which has proved to be a very potent analogue of the tetrahedral hydrated intermediate of the scissile amide bond. It has been widely used for the design of various inhibitors of HIV protease 141,142 14 154 and ACE, 155-157 and to synthesize angiotensin II, III, and IV analogues. 158,159 Indeed, the chirality of the hydroxylated carbon is critical for HIV protease inhibition, but separation of the epimers may be difficult. Therefore, the stereoselective synthesis from epoxides has been actively investigated. An example of a C-methylated tp[CMe(OH)-CH2-NH] link, obtained from an epoxide with chromatographic separation of the epimers, has also been described. 157 Most of the [(hydroxy)ethyleneamino] peptides have been prepared by solution procedures, but two examples of solid-phase synthesis have been reported. A theoretical study of the (hydroxy)ethyleneamino replacement for the amide bond has been carried out on a HIV protease inhibitor. 160 ... 

By Ferrier glycosylation of di-O-acetyl-L-rhamnal (28) with the epoxide derivative 117 the disaccharide 118 is obtained. This is trans-opened by lithium iodide according to Fiirst-Plattner s rule. Upon different ways, two interesting products are obtained, either the original C-B disaccharide of aclacinomycin A 120 or its C-5 epimer 119 which contains one sugar in the D-configuration [69]. 

The Mitsunobu conditions, applied without any carboxylic acid, were shown to provide anhydro (3, 4 -epoxide)284 286 and dianhydro sucrose derivatives.331 Some of these compounds were further transformed by reduction (leading to dehydrosucroses) or ring-opening leading to sucrose epimers and dehydrohalo-or amino sucroses (see also Scheme 7).332... 

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