Kinetics lactones

Hoye, T.R., Jeon, J., Kopel, L.C., Ryba, T.D., Teimakoon, M.A., and Wang, Y. (2010) Total synthesis of pelomside A through kinetic lactonization and relay ring-dosing metathesis cydization reactions. Angew. Chem. Int. Ed., 49, 6151-6155. 

The 9 — 15 fragment was prepared by a similar route. Once again Sharpless kinetic resolution method was applied, but in the opposite sense, i.e., at 29% conversion a mixture of the racemic olefin educt with the virtually pure epoxide stereoisomer was obtained. On acid-catalysed epoxide opening and lactonization the stereocentre C-12 was inverted, and the pure dihydroxy lactone was isolated. This was methylated, protected as the acetonide, reduced to the lactol, protected by Wittig olefination and silylation, and finally ozonolysed to give the desired aldehyde. 

CHMO is known to catalyze a number of enantioselective BV reactions, including the kinetic resolution of certain racemic ketones and desymmetrization of prochiral substrates [84—87]. An example is the desymmetrization of 4-methylcyclohexanone, which affords the (S)-configurated seven-membered lactone with 98% ee [84,87]. Of course, many ketones fail to react with acceptable levels of enantioselectivity, or are not even accepted by the enzyme. 

The identification of a novel BVMO from Mycobacterium tuberculosis (BVMOMtbs) complements this toolbox, as this particular biocatalyst performs a classical kinetic resolution instead of a regiodivergent oxidation vith complete consumption of substrate [140]. Notably, this enzyme accepts only one ketone enantiomer and converts it selectively to the abnormal lactone while the antipodal substrate remains unchanged (Scheme 9.24) [141]. 

A quantitative interpretation of aldonolactone inhibition in terms of an adaptation of the active site to a transition state approaching a planar, glycosyl oxocarbonium ion is made difficult for several reasons. Due to the interconversion between the 1,4- and 1,5-lactones, and their hydrolysis to the aldonic acids, their use is limited to kinetic studies with incubation times of 10 min or less. This was not realized by most investigators prior to 1970. In many cases, only the 1,4-lactone can be isolated its (partial) conversion into... 

On the other hand, the macrolides showed unusual enzymatic reactivity. Lipase PF-catalyzed polymerization of the macrolides proceeded much faster than that of 8-CL. The lipase-catalyzed polymerizability of lactones was quantitatively evaluated by Michaelis-Menten kinetics. For all monomers, linearity was observed in the Hanes-Woolf plot, indicating that the polymerization followed Michaehs-Menten kinetics. The V, (iaotone) and K,ax(iaotone)/ m(iaotone) values increased with the ring size of lactone, whereas the A (iactone) values scarcely changed. These data imply that the enzymatic polymerizability increased as a function of the ring size, and the large enzymatic polymerizability is governed mainly by the reachon rate hut not to the binding abilities, i.e., the reaction process of... 

Three types of coagulation were considered. The glucono(5)lactone (GDL)-induced coagulation system (GDL system) was prepared by acidification with 1.75 g/L GDL (Roquette, Lestrem, France). The rermet-induced coagulation system (rennet system) was prepared by the addition of calf rennet (SKW, Baupte, France) at 25.6/rg/L of milk. The GDL-I-rermet-induced coagulation system (mixed system) was prepared by acidification with 0.45 g/L GDL for 2h followed by the addition of rennet at 15.4/ig/L of milk. The experimental conditions for each system were selected in order to achieve gelation without syneresis. Coagulation kinetics were performed at 30°C. 

The stereochemistry of the C(3) hydroxy was established in Step D. The Baeyer-Villiger oxidation proceeds with retention of configuration of the migrating group (see Section 12.5.2), so the correct stereochemistry is established for the C—O bond. The final stereocenter for which configuration must be established is the methyl group at C(6) that was introduced by an enolate alkylation in Step E, but this reaction was not very stereoselective. However, since this center is adjacent to the lactone carbonyl, it can be epimerized through the enolate. The enolate was formed and quenched with acid. The kinetically preferred protonation from the axial direction provides the correct stereochemistry at C(6). 

Cyanide is not the only nucleophile to effect reactions as in Scheme 35, C, but of those studied so far only benzenesulfinate and phenoxide are similar (and also show second order kinetics) while others give simple substitution with no rearrangement (and show first order kinetics). No doubt ionization to a furylium ion plays an important part in some of these transformations, but it is harder to account for the behavior of 70 which yields a lactone (71) and almost no cyano products.198... 

Commercially available lipase PS has been used to obtain kinetic resolution of racemic 4-substituted oxetan-2-ones and 3- and 3,4-disubstituted oxetan-2-ones in organic solvents <00JCS(P1)71>. The enzyme appears to be relatively insensitive to the substituents on the lactone or to the nature of the ring opened products. 

In addition to the lactone-forming reaction (44), there has been in the last decade a substantial accumulation of accurate kinetic measurements for ring-closure reactions, parts of which have been discussed by Illuminati and Mandolini (1981) and by Winnik (1981a). 

The 1,3-dipolar cycloadditions of nitrones (551), (595), (614), (615) and their enantiomers (595 ent), (614 ent), (615 ent) (Fig. 2.40) to a.p-unsaturated y-lactones, such as achiral D7 g and D-glycero D7 h, provide an interesting example of double asymmetric inductions. The reactions are kinetically controlled. However, on heating and at longer reaction times, the reversibility of the cycloaddition (595 + D7 h) was observed, and the presence of a more stable thermodynamic product (620) was detected. Moreover, in the case of lactone D7 h, a... 

A toluene solution of the benzocyclobutene (327) was thermolyzed by heating in a sealed-tube at 180-200 °C for 48 hours to yield the lactone (328), via an intriguing epimerization pathway113), in which the initially formed kinetically controlled trans product was isomerized to the charged intermediate and then recyclized to furnish the thermodynamic m-isomer (328) u3). 

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. 

Bolm et al. (130) reported the asymmetric Baeyer-Villiger reaction catalyzed by Cu(II) complexes. Aerobic oxidation of racemic cyclic ketones in the presence of pivalaldehyde effects a kinetic resolution to afford lactones in moderate enan-tioselectivity. Aryloxide oxazolines are the most effective ligands among those examined. Sterically demanding substituents ortho to the phenoxide are necessary for high yields. Several neutral bis(oxazolines) provide poor selectivities and yields in this reaction. Cycloheptanones and cyclohexanones lacking an aryl group on the a carbon do not react under these conditions. 

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