Synthesis stereochemistry

The bis-carbazole alkaloids typically contain previously known monomeric carbazoles as structural subunits. To date, bis-carbazole alkaloids have been isolated from plants of two genera of the family Rutaceae, Murraya and Clausena, and are linked either by a methylene unit, a bisbenzylic ether bridge, a bond joining one aromatic portion directly to an annotated dihydropyran unit, or by a biaryl bond. Many reviews have appeared on the monomeric carbazole alkaloids. However, in these articles only a few bis-carbazole alkaloids were listed (3,5-7). For the first time, in 1992, Furukawa et al. compiled all of the bis-carbazole alkaloids that were known to the end of 1992 (158). Taster and Bringmann summarized to the end of 2001, the occurrence, stereochemistry, synthesis, and biological activity of the bis-carbazoles linked through a biaryl bond (159). We compiled to the mid of 2002, the occurrence, stereochemistry, synthesis, and the biological activity of all classes of bis-carbazoles (8). In this section, we cover the total syntheses of the natural bis-carbazole alkaloids reported since 1990. 

S. M. Hansen, F. Rominger, M. Metz, and P. Hofmann, The First Grubbs-Type Metathesis Catalyst with cis Stereochemistry Synthesis of [(rf-dtbpm)Cl2Ru=CH—CH=CMe2] from a Novel, Coordinatively Unsaturated Dinuc-lear Ruthenium Dihydride, Chem. Eur. J. 5, 557-566 (1999). 

Compound Lactone size Stereochemistry Synthesis L121(f KB ... 

Absolute Configuration of (+)>Bottrospicatoi (10). To determine the stereochemistry, synthesis of (+)-bottrospicatol and isobottrospicatol (Cg-epimer) was carried out according to Figure 4. (-)-Carvone (1) was oxidized by m-chloroperbenzoic acid in dry ether to give the diastereomixture of 8,9-epoxycarvone (85%), colorless oil ... 

Lesnikowski, Z J, Jaworska, M., and Stec, W, J. (1990) Octa(thymidine methanephosphonates) of partially defined stereochemistry synthesis and effect of chirality at phosphorus on binding to pentadecadeoxynboadenylic acid. Nucl Acids Res, 18,2109-2115. 

Synthesis The ester must be a fumarate so that the stereochemistry of the final adduct is correct ... 

If you don t see why the stereochemistry should be as 1 have drawn it, 1 suggest you make a model of 332A and discover for yourself There is a simple synthesis of 332A (X = OTs) from the Robinson annelation (frame 117) product 332B. 

Note that no stereochemistry has been introduced so far. Reduction (sodium and liquid ammonia) selectively gives trans chrysanthemic alcohol which can be oxidised to the acid with CrOs. Draw out the whole synthesis as a chart. 

Strategy Problem 7 Synthesis of a single enantiomer. Many compounds such as pharmaceuticals, flavourings, and insect control chemicals must not only have the right relative stereochemistry but must be optically active too if tliey are to be of any use. Consider the strategy of synthesising one enantiomer ... 

The early Escherunoser-Stork results indicated, that stereoselective cyclizations may be achieved, if monocyclic olefins with 1,5-polyene side chains are used as substrates in acid treatment. This assumption has now been justified by many syntheses of polycyclic systems. A typical example synthesis is given with the last reaction. The cyclization of a trideca-3,7-dien-11-ynyl cyclopentenol leads in 70% yield to a 17-acetyl A-norsteroid with correct stereochemistry at all ring junctions. Ozonolysis of ring A and aldol condensation gave dl-progesterone (M.B. Gravestock, 1978 see p. 279f.). 

In his cephalosporin synthesis methyl levulinate was condensed with cysteine in acidic medium to give a bicyclic thiazolidine. One may rationalize the regioselective formation of this bicycle with the assumption that in the acidic reaction mixture the tMoI group is the only nucleophile present, which can add to the ketone. Intramolecular amide formation from the methyl ester and acid-catalyzed dehydration would then lead to the thiazolidine and y-lactam rings. The stereochemistry at the carboxylic acid a-... 

Diacetoxylation of various conjugated dienes including cyclic dienes has been extensively studied. 1,3-Cyclohexadiene was converted into a mixture of isomeric l,4-diacetoxy-2-cyclohexenes of unknown stereochemistry[303]. The stereoselective Pd-catalyzed 1,4-diacetoxylation of dienes is carried out in AcOH in the presence of LiOAc and /or LiCI and beiizoquinone[304.305]. In the presence of acetate ion and in the absence of chloride ion, /rau.v-diacetox-ylation occurs, whereas addition of a catalytic amount of LiCl changes the stereochemistry to cis addition. The coordination of a chloride ion to Pd makes the cis migration of the acetate from Pd impossible. From 1,3-cyclohexadiene, trans- and ci j-l,4-diacetoxy-2-cyclohexenes (346 and 347) can be prepared stereoselectively. For the 6-substituted 1,3-cycloheptadiene 348, a high diaster-eoselectivity is observed. The stereoselective cij-diacetoxylation of 5-carbo-methoxy-1,3-cyclohexadiene (349) has been applied to the synthesis of dl-shikimic acid (350). 

The wM-diacetate 363 can be transformed into either enantiomer of the 4-substituted 2-cyclohexen-l-ol 364 via the enzymatic hydrolysis. By changing the relative reactivity of the allylic leaving groups (acetate and the more reactive carbonate), either enantiomer of 4-substituted cyclohexenyl acetate is accessible by choice. Then the enantioselective synthesis of (7 )- and (S)-5-substituted 1,3-cyclohexadienes 365 and 367 can be achieved. The Pd(II)-cat-alyzed acetoxylactonization of the diene acids affords the lactones 366 and 368 of different stereochemistry[310]. The tropane alkaloid skeletons 370 and 371 have been constructed based on this chemoselective Pd-catalyzed reactions of 6-benzyloxy-l,3-cycloheptadiene (369)[311]. 

Zinc acetylides, prepared in situ by the treatment of lithium acetylides with ZnCF, are widely used. The zinc acetylide 311, prepared in situ, reacts with (Z)-3-iodo-2-buten-l-ol (312) with nearly complete retention of stereochemistry to afford an important intermediate 313 for carotenoid synthesis[227]. 

Sorbitol is a sweetener often substituted for cane sugar because it is better tolerated by dia betics It IS also an intermediate in the commercial synthesis of vitamin C Sorbitol is prepared by high pressure hydrogenation of glucose over a nickel catalyst What is the structure (including stereochemistry) of sorbitoP... 

After the stmcture and absolute stereochemistry of cleavamine (111), C22H24N2, was estabUshed, its synthesis was shortly completed and impetus to unravel the stmcture of the dimeric bases (22) was bolstered (77). Again, the fragment, now only slightly modified from that originally present in secologanin (102), is readily seen in catharanthine (107). 

An asymmetric synthesis of estrone begins with an asymmetric Michael addition of lithium enolate (178) to the scalemic sulfoxide (179). Direct treatment of the cmde Michael adduct with y /i7-chloroperbenzoic acid to oxidize the sulfoxide to a sulfone, followed by reductive removal of the bromine affords (180, X = a and PH R = H) in over 90% yield. Similarly to the conversion of (175) to (176), base-catalyzed epimerization of (180) produces an 85% isolated yield of (181, X = /5H R = H). C8 and C14 of (181) have the same relative and absolute stereochemistry as that of the naturally occurring steroids. Methylation of (181) provides (182). A (CH2)2CuLi-induced reductive cleavage of sulfone (182) followed by stereoselective alkylation of the resultant enolate with an allyl bromide yields (183). Ozonolysis of (183) produces (184) (wherein the aldehydric oxygen is by isopropyUdene) in 68% yield. Compound (184) is the optically active form of Ziegler s intermediate (176), and is converted to (+)-estrone in 6.3% overall yield and >95% enantiomeric excess (200). 

Catalytic hydrogenation of the 14—15 double bond from the face opposite to the C18 substituent yields (196). Compound (196) contains the natural steroid stereochemistry around the D-ring. A metal-ammonia reduction of (196) forms the most stable product (197) thermodynamically. When R is equal to methyl, this process comprises an efficient total synthesis of estradiol methyl ester. Birch reduction of the A-ring of (197) followed by acid hydrolysis of the resultant enol ether allows access into the 19-norsteroids (198) (204). 

The poly(vinyl alcohol) made for commercial acetalization processes is atactic and a mixture of cis- and /n j -l,3-dioxane stereoisomers is formed during acetalization. The precise cis/trans ratio depends strongly on process kinetics (16,17) and small quantities of other system components (23). During formylation of poly(vinyl alcohol), for example, i j -acetalization is more rapid than /ra/ j -acetalization (24). In addition, the rate of hydrolysis of the trans-2iQ. -A is faster than for the <7 -acetal (25). Because hydrolysis competes with acetalization during acetal synthesis, a high cis/trans ratio is favored. The stereochemistry of PVF and PVB resins has been studied by proton and carbon nmr spectroscopy (26—29). 

Although not of industrial importance, many organometallic approaches have been developed (38). A one-pot synthesis of vitamin has been described and is based on the anionic [4 + 2] cycloaddition of three-substituted isoben2ofuranones to l-phytyl-l-(phenylsulfonyl)propene. Owing to the rather mild chemical conditions, the (H)-stereochemistry is retained (39). 

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