Alkaloids lactone synthesis

The focus of this review is to discuss the role of Cinchona alkaloids as Brpnsted bases in organocatalytic asymmetric reactions. Cinchona alkaloids are Lewis basic when the quinuclidine nitrogen initiates a nucleophilic attack to the substrate in asymmetric reactions such as the Baylis-Hillman (Fig. 3), P-lactone synthesis, asymmetric a-halogenation, alkylations, carbocyanation of ketones, and Diels-Alder reactions 30-39] (Fig. 4). 

The above syntheses of the parent spiroamine system establish the skeleton of the aromatic alkaloids. A synthesis of a derivative of jS-erythroidine (III) with the intact spiro skeleton, achieved in Boekel-heide s laboratory (15), provides similar confirmation for the lactonic alkaloids. 

The influence of the functional groups of the substrate in the course of an allylsilane addition to a carbonyl group are exempHfied in the enantiodivergent synthesis of the Geissman-Waiss lactone [63]. The Geissman-Waiss [64] lactone 200 and 202 serves as a versatile intermediate for the synthesis of pyrroUzidine alkaloids. For this reason, there are a variety of different syntheses to this building block [65]. The Geissmann-Waiss lactone synthesis of Wistrand and coworkers not only provides a short access to one enantiomer but also enables the synthesis of both enantiomeric forms. The synthesis is depicted in Scheme 3.40. 

In the arena of (3-lactone synthesis, recent advances such as the use of NHC, phosphine, or isothiourea catalysts have expanded the founding work employing alkaloids for the asymmetric synthesis of these targets. Methodologies have incorporated both in situ generated monosubstituted and isolable disubstituted ketenes as well as recent studies from Romo accessing ammonium enolates by means of an in situ carboxylic acid activation strategy. These protocols allow access to (3-lactones, with the full complement of substitution, in routinely exquisite levels of diastereo- and enantioselectivity. 

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]. 

Chemoselective C-alkylation of the highly acidic and enolic triacetic acid lactone 104 (pAl, = 4.94) and tetronic acid (pA, = 3.76) is possible by use of DBU[68]. No 0-alkylation takes place. The same compound 105 is obtained by the regioslective allylation of copper-protected methyl 3,5-dioxohexano-ate[69]. It is known that base-catalyzed alkylation of nitro compounds affords 0-alkylation products, and the smooth Pd-catalyzed C-allylation of nitroalkanes[38.39], nitroacetate[70], and phenylstilfonylnitromethane[71] is possible. Chemoselective C-allylation of nitroethane (106) or the nitroacetate 107 has been applied to the synthesis of the skeleton of the ergoline alkaloid 108[70]. 

Node and Fuji have developed a new chiral synthesis of various alkaloids using chiral nitroalkene, fS -( - -3-methyl-3-( 3 -nitrovinyl -o-valerolactone Scheme 8 11 shows a total synthesis of f-i-physosdgmine, a principM alkriloid of the CMabar bean The key nitroalkene is prepared by asymmetric nitroolefinadon of ct-methyl-o-lactone using a chirM enamine fsee... 

The reaction is essentially that described by the submitters.8 The procedure illustrates a convenient method for the synthesis of a type of lactone which could serve as an important intermediate in the synthesis of isoquinolones, tetrahydroisoquinolines, and isoquinoline alkaloids Several analogous and closely related lactones have been reported. 

The nonaromatic lactones from cis-13, and trcyclohexaneacetic acid14 were important intermediates in the synthesis of indole alkaloids. 

In this chapter the proposed (5) division of secophthalideisoquinolines into the four subgroups and the nomenclature have been preserved. Since the publication of the most recent review (5), information about the synthesis of the missing ( )-narceine enol lactone (102) (87), the isolation of ( )-fumaramine (112) from Fumaria vailanti (88), and the discovery of a new seco alkaloid, coryrutine (118), from Corydalis rutifolia (89) has appeared. In the former plant fumaramine (111) (55) and in the latter N-methylhydrasteine... 

Secophthalideisoquinoline enol lactones of type 128 were used by Klotzer et al. (95,103-105) for the synthesis of benzazepine system 129 which was further transformed to alkaloids of rhoeadine type. 

The aza-tricyclic lactone 320 is an intermediate in the synthesis of the indolizidine 321, which is the indolizine analogue of the pyrrolizidine alkaloid platynecine <1995TL5109> (Scheme 84). 

The study of Fuji et al. shows that the addition of lithium enolate 75 to ni-troamine 74 is readily reversible quenching conditions are thus essential for getting a good yield of product 76. An equilibrium mixture of the adducts exists in the reaction mixture, and the elimination of either the prolinol or lactone moiety can take place depending on the workup condition (Scheme 2-34). A feature of this asymmetric synthesis is the direct one pot formation of the enantiomer with a high ee value. One application of this reaction is the asymmetric synthesis of a key intermediate for indole type Aspidosperma and Hun-teria alkaloids.68 Fuji69 has reviewed the asymmetric creation of quaternary carbon atoms. 

Besides sesquiterpene lactones, an alkaloid analyzed as CgH14N203 (45), was isolated from the leaves of Arnica montana L. (80). Distinction between the two possible structures 45 (amide-urethane) and 46 (ester + urea) was accomplished by a selective synthesis from prolinamide. 

Highly efficient and stereoselective addition of tertiary amines to electron-deficient alkenes is used by Pete et al. for the synthesis of necine bases [26,27], The photoinduced electron transfer of tertiary amines like Af-methylpyrrolidine to aromatic ketone sensitizers yield regiospecifically only one of the possible radical species which then adds diastereospecifically to (5I )-5-menthyloxy-2-(5//)-furanone as an electron-poor alkene. For the synthesis of pyrrazolidine alkaloids in approximately 30% overall yield, the group uses a second PET step for the oxidative demethylation of the pyrrolidine. The resulting secondary amine react spontaneously to the lactam by intramolecular aminolysis of the lactone (Scheme 20) [26,27]. 

Removal of the amide function is much easier if the reaction is intramolecular, and —CONEt2 amides (sometimes even —CONPr-i2 amides) may be converted to lactones, lactams and other heterocycles in this way . Addition of an aldehyde or ketone as an electrophile generates a hydroxyl group (in some cases, atroposelectively, as it happens —though this is usually irrelevant to the stereochemistry of the product) which cyclizes to give a lactone via a benzylic cation in acid. This reaction has found wide use in the synthesis of polycyclic aromatics, particularly alkaloids. 

Acid treatment of a 3 1 mixture of murrayafoline A (7) and koenoline (8) led to chrestifoline A (192) in 70% yield. Addition of murrayafoline A (7) to a mixture of 1057 and lithium aluminum hydride in ether and dichloromethane afforded bismurrayafoline-A (197) in 19% yield (662) (Scheme 5.166). In addition to the aforementioned methods, the same group also reported a stereoselective synthesis of axially chiral bis-carbazole alkaloids by application of their "lactone concept" (663) and a reductive biaryl coupling leading to 2,2 -bis-carbazoles (664). 

Other procedures using TPAP/NMO/PMS/CH Cl include steps in the synthesis of (+)-altholactone (lactol to lactone) [78] antheliolide A [168] the AChE inhibitor (+)-arisugacin A and B (primary alcohol to aldehyde step also) [83] the marine macrolide amphidinolide T1 [169] the alkaloid (+)-batzelladine D cf. mech. 

Distinctly more hindered than the dioncophyllinc A-lactone 1, but still axially prostereogenic, is 6 which is obtained by intramolecular coupling in 87 % yield (see Section 2.2.2.2) which is the corresponding precursor for the synthesis of the related naphthalenylisoquinoline alkaloid (+)-ancistrocladisine10. 

LDA was used in the cyclization of tosylate 9, an intermediate in the synthesis of the pyrrolizidine alkaloid (+)-retronecine, which was prepared from (+ )-(7 )-malic acid in nine steps. The tricyclic lactone 10 was isolated in 53% yield70. 

The chiral lactone (178) has been used for the synthesis of a variety of natural products, such as sugars, lignans, terpenes, alkaloids, and P-lactams as a chiral building block 182c,184). The use of (178) as a powerful inductor of asymmetry was mainly established by Takano et al. 181, 84> one can expect more highly interesting reports from this group. 

A recently published full account of another synthesis [69] of the same alkaloid starting from the /rans-cinnamic ester 264 represented a different approach (ACD -> ACDB) to ( )-lycorine (Scheme 42). An intramolecular Diels-Alder reaction of 264 in o-dichlorobenzene furnished the two diastereomeric lactones 265 (86%) and 266 (5%) involving the endo and exo modes of addition respectively. The transposition of the carbonyl group of 265 to 267 was achieved by reduction with lithium aluminium hydride, followed by treatment of the resulting diol with Fetizon s reagent, which selectively oxidised the less substituted alcohol to give isomeric 5-lactone 267. On exposure to iodine in alkaline medium 267 underwent iodolactonisation to afford the iodo-hydroxy y-lactone 268. The derived tetrahydropyranyl ether... 

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