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Alcohol Prelog

This synthesis came shortly after one by Prelog, Kohlberg, Cerkovnikov, Rezek and Piantanida (1937) based on a series of reactions which, with modifications and extensions. Prelog and his colleagues have applied to the syntheses of bridged heterocyclic nuclei, of which this is an example. 4-Hydroxymethyltetrahydropyran (VI R =. OH) is converted via the bromo-compound (VI R = Br) and the nitrile (VI R = CN) into tetrahydropyran-4-acetic acid of which the ethyl ester (VII) is reduced to 4-()3-hydroxyethyl)-tetrahydropyTan (VIII). This is converted by fuming hydrobromic acid into 3-(2-bromoethyl)-l 5-dibromopentane (IX) which with ammonia in methyl alcohol yields quinuclidine (V). [Pg.455]

Preeclampsia, Viagra and, 164 Prelog, Vladimir, 181 Prepolymer, epoxy resins and, 673 Priestley, Joseph, 245 Primary alcohol, 600 Primary amine, 916 Primary carbon. 84 Primary hydrogen, 85 Primary structure (protein), 1038 Primer strand (DNA), 1108 pro-R prochiralitv center, 316 pro-S prochirality center, 316 Problems, how to work, 27 Procaine, structure of, 32 Prochirality, 315-317 assignment of, 315-316 naturally occurring molecules and, 316-317... [Pg.1312]

Two interesting yeast carbonyl reductases, one from Candida magnoliae (CMCR) [33,54] and the other from Sporobolomyces salmonicolor (SSCR) [55], were found to catalyze the reduction of ethyl 4-chloro-3-oxobutanoate to give ethyl (5)-4-chloro-3-hydroxybutanoate, a useful chiral building block. In an effort to search for carbonyl reductases with anti-Prelog enantioselectivity, the activity and enantioselectivity of CMCR and SSCR have been evaluated toward the reduction of various ketones, including a- and /3-ketoesters, and their application potential in the synthesis of pharmaceutically important chiral alcohol intermediates have been explored [56-58]. [Pg.147]

The carbonyl reductase from Candida magnoliae catalyzed the enantioselective reduction of a diversity of ketones, including aliphatic and aromatic ketones and a- and /3-ketoesters (Figure 7.17), to anti-Prelog configurated alcohols in excellent optical purity (99% ee or higher) [56]. [Pg.147]

Zhu, D., Yang, Y. and Hua, L. (2006) Stereoselective enzymatic synthesis of chiral alcohols with the use of a carbonyl reductase from Candida magnoliae with anti-Prelog enantioselectivity. The Journal of Organic Chemistry, 71 (11), 4202-4205. [Pg.163]

It is always advisable to examine the complete molecular topology in the neighborhood of the chiral carbon atom and to confirm the results by employing another analytical method before the final assignment. In conclusion, Prelog s rule does predict the steric course of an asymmetric synthesis carried out with a chiral a-keto ester, and the predictions have been found to be correct in most cases. Indeed, this method has been widely used for determining the absolute configuration of secondary alcohols. [Pg.39]

Acetalization of oxo aldehydes is used to protect sensitive aldehyde products, especially in asymmetric hydroformylation preventing racemization of an a-chiral aldehyde product [18-22,27]. Acetal formation can also be applied to the synthesis of monocyclic or spirocyclic pyranes as potential precursors and building blocks for natural products such as pheromones or antibiotics. A representative example is the synthesis of the pyranone subunit of the Prelog-Djerassi lactone. For this purpose, various 1,2-disubstituted homoal-lylic alcohols were used (Scheme 3) [32],... [Pg.77]

Medici et al. have used a combined sequential oxidation-reduction to access a range of imsaturated secondary alcohols from their racemates [7] (Scheme 1). Here the S-alcohol 2 is oxidized by B. stereothermophilus which is displaying Prelog specificity leaving the l -enantiomer untouched. The other microorganism, Y. lipolytica contains an anti-Prelog dehydrogenase which is therefore able to reduce the ketone 1 to the l -alcohol 2. Thus the combination of the two steps effects a net deracemization of substrate 2. [Pg.59]

Common substructural motifs in polyketide natural products are six-membered ring lactones, lactols, and tetrahydropyrans. It was recognized by Wuts and co-workers that hydroformylation of readily available homoaUyhc alcohols would provide a direct and efficient entry into these ring systems. Such an approach was employed in a synthesis of Prelog-Djerassi lactone (Scheme 5.11) [13]. [Pg.98]

Figure 2.23 Enantioselective reduction of unsymmetricaUy substituted ketones by dehydrogenases yields secondary alcohols. The reaction may either follow Prelog s rule (addition of hydride from re-side) or they may not (anti-Prelog). Figure 2.23 Enantioselective reduction of unsymmetricaUy substituted ketones by dehydrogenases yields secondary alcohols. The reaction may either follow Prelog s rule (addition of hydride from re-side) or they may not (anti-Prelog).
Related examples are, for example, found in the area of catalyzed Diels-Alder reactions228. On reduction of carbonyl compounds by baker s yeast, in many cases hydrogen transfer occurs at the Re-face of the prostereogenic ketone 31 to yield alcohol 32 (Prelog s rule77). [Pg.456]

Recent examples where the Prelog rule makes the correct prediction are reduction of the cyclohexanedione 33 to give hydroxy ketone 34229, and reduction of the 1,l,1-trihalo-2-alka-nanes 35 and 37 to alcohols 36 and 38 respectively (Rs — CH3, CF3 RL — CC13, see also pp 403, 427, 435 and 446)78. [Pg.456]

However, it should be noted that caution should be exercised when Prelog s rule is applied to such complicated systems as intact cells (baker s yeast), which may contain oxidoreductases of different stereoselectivity230 231. For example, in the reduction of 39 to alcohol 40, Prelog s rule fails232. [Pg.457]

A rule, similar to Prelog s rule, has been proposed for the enzyme-mediated hydrolysis of the esters of secondary alcohols. Esters of the enantiomers 31 usually react faster. This rule correctly predicted the configuration of 14 out of 15 substrates when cholesterol esterase was used, 63 out of 64 substrates with a lipase from Pseudomonas cepacia, and of 51 out of 55 cyclic substrates using a lipase from Candida rugosa24°. [Pg.461]

The most representative results of these additive systems are (1) allyl alcohol seems to inhibit the Si-face attack of the hydride, and (2) allyl bromide inhibits the. Re-face attack. In this system, if it is assumed that CF3 is sterically less demanding than the CH2COCH3 substituent, Prelog s rule holds for the yeast-allyl bromide additive reduction system, whereas it is not followed when the additive is allyl alcohol [26]. [Pg.94]

Hydroformylation of 2,6-dimethyl-6-hepten-2-ol produces hydroxycitronellal (equation 12).22 Subjecting allyl alcohol to hydroformylation reaction conditions with HCo(CO>4 yields only propanal, isomerization taking place more rapidly than hydroformylation.2 Phosphine-modified rhodium catalysts will convert allyl alcohol to butane-1,4-diol under mild conditions in the presence of excess phosphine, however (equation 13).5 30 31 When isomerization is blocked, hydroformylation proceeds normally (equation 14). An elegant synthesis of the Prelog-Djerassi lactone has been accomplished starting with the hydroformylation of an allylic alcohol (equation IS).32... [Pg.923]

See other pages where Alcohol Prelog is mentioned: [Pg.152]    [Pg.152]    [Pg.348]    [Pg.457]    [Pg.549]    [Pg.570]    [Pg.571]    [Pg.663]    [Pg.666]    [Pg.99]    [Pg.96]    [Pg.384]    [Pg.147]    [Pg.153]    [Pg.155]    [Pg.155]    [Pg.39]    [Pg.40]    [Pg.282]    [Pg.147]    [Pg.284]    [Pg.59]    [Pg.66]    [Pg.267]    [Pg.96]    [Pg.111]    [Pg.118]    [Pg.53]    [Pg.450]    [Pg.451]    [Pg.143]   
See also in sourсe #XX -- [ Pg.290 ]



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