Amaryllidaceae

Minor Aklaloids of the Amaryllidaceas. The chief data recordf regarding these alkaloids are summarised in the accompanying tab (p. 411) —... 

Demethylvasconine (85) (9-methoxy-5-methyl-phenanthridin-8-olate) presented in Scheme 31 was found in Crinum kirkii (95P1291) (Amaryllidaceae). Although published as cation, no information about the anion of this alkaloid is given. Its relationship to other alkaloids of this class, however, makes a betainic structure more than likely and this is confirmed by a comparison of the NMR data of 85 with the cationic and betainic alkaloids presented in Table III. This betaine is isoconjugate with the 2-methylphenanthrene anion and thus defined the alkaloid as a member of class 1 (odd alternant hydrocarbon anions). Whereas substitution of the isoconjugate phenanthridinium moiety at the 1-position with an anionic fragment results in zwitterions (cf. Section III.D), the phenanthridinium-2-olate is a mesomeric betaine. 

O. R. Queckenberg and A. W. Eraham, Cliromatographic and specti oscopic coupling a powerful tool for the screening of wild amaryllidaceae, J. Planar Chromatogr. 6 55-61 (1993). 

Scheme 9.33 Synthetic strategy toward carba-sugars, Amaryllidaceae alkaloids, and undecenolides.

The photocyclization of enamides has been widely employed in the construction of heterocyclic systems the N-acryloyl-2-aminopyridines 37, for example, are converted on irradiation to the lactams 38.36 Numerous benzylisoquinoline alkaloids have been prepared using this approach, and in particular, the syntheses of benzo[c]phenanthridine alkaloids have been reviewed.37 Thus, irradiation of the [Z]-l-ethylidene-2-benzoyltetra-hydroisoquinoline 39 affords the corresponding 8-oxoberberine 4038 competing photoisomerization to the E-isomer is observed but cyclization occurs only via the Z-isomer. Examples of syntheses of Amaryllidaceae and indole alkaloids have also been reported. In this way, the precursor 41 of ( )-lycoran has been obtained by oxidative cyclization of the enamide 42.39... 

One of these products (49) was used as a key intermediate for the synthesis of the Amaryllidaceae alkaloids a- and /-lycorane (Scheme 12)53. A copper-catalyzed Grignard reaction with 49 afforded 50 via a selective y-anti displacement of the chloride. Hydrogenation followed by Bischler-Napieralski cyclization gave 51. Interestingly, reversal of the latter two steps gave the isomer 52 where an epimerization at the benzylic carbon had occurred in the cyclization step (>99% selectivity). Subsequent reduction of the amide in each case afforded the target molecules a- and y-lycorane, respectively. The purity of the final product was very high with respect to the opposite stereoisomer. Thus <0.2% of /-lycorane was present in a-lycorane and vice versa. 

Martin effected the synthesis of several 3,5-diarylated indoles by a tandem Stille-Suzuki sequence [131]. The latter reaction involves exposure of 3-(3-pyridyl)-5-bromo-l-(4-toluenesulfonyl)indole with arylboronic acids (aryl = 3-thienyl, 2-furyl, phenyl) under typical conditions to give the expected products in 86-98% yield [131], Carrera engaged 6- and 7-bromoindole in Pd-catalyzed couplings with 4-fluoro- and 4-methoxyphenylboronic acids to prepare 6- and 7-(4-fluorophenyl)indole (90% and 74% yield) and 6-(4-methoxyphenyl)indole (73% yield) [29]. Banwell and co-workers employed 7-bromoindole in a Suzuki coupling with 3,4-dioxygenated phenylboronic acids en route to the synthesis of Amaryllidaceae alkaloids [132], Yields of 7-arylated indoles are 93-99%. Moody successfully coupled 4-bromoindole... 

Amaryllidaceae, alkaloids in, 2 75 Amator, gold-based dental alloy, 8 307t Amator 2, gold-based dental alloy,... 

Jin and Weinreb reported the enantioselective total synthesis of 5,11-methano-morphanthridine Amaryllidaceae alkaloids via ethynylation of a chiral aldehyde followed by allenylsilane cyclization (Scheme 4.6) [10]. Addition of ethynylmagnesium bromide to 27 produced a 2 1 mixture of (S)- and (R)-propargyl alcohols 28. Both of these isomers were separately converted into the desired same acetate 28 by acetylation or Mitsunobu inversion reaction. After the reaction of 28 with a silyl cuprate, the resulting allene 29 was then converted into (-)-coccinine 31 via an allenylsilane cyclization. 

The allenylsilane ene reaction is also well suited for the synthesis of cyclohexane rings. Jin and Weinreb have described the process of Eq. 13.55 in a synthesis of 5,11-methanomorphanthridine, an Amaryllidaceae alkaloid [64], Conversion of aldehyde 163 to imine 164 with piperonylamine took place in situ. Heating the solution of imine at reflux in mesitylene for 2 h led to cyclization through the conformer shown. The yield of 165 from aldehyde 163 was 66%. 

Lycorine is the most abundant alkaloid in plants of the Amaryllidaceae. Several syntheses of racemic lycorine had been reported prior to our initiation of studies directed at an asymmetric synthesis of the unnatural enantiomer 64. 2 a common theme in all of the syntheses of ( )-lycorine has been the utilization of either an intermolecular or intramolecular Diels-Alder construction of the key C-ring of the alkaloid. This six-membered ring presents a rather formidable synthetic challenge because of the four contiguous stereogenic centers, the trans 1,2-diol moiety, and the juxtaposition of the aromatic substituent and the carbon-carbon double bond. 

Kita et al. found that phenolic oxidative coupling in case of 272 provides seven-membered N heterocyclic compounds 274 and 275 by bond shift of the initially formed spiro intermediate 273 under suitable conditions. Besides 274 and 275, piperidino-spiroquinone 276 is also formed in this oxidation (Scheme 68). Of particular interest is the recently developed synthesis of amaryllidaceae alkaloids such as (+)-maritidine (Scheme 69) (96JOC5857). 

Galanthamine (10), an Amaryllidaceae-type alkaloid from Galanthus woronowii Losinsk and other species of this genus, has been approved in the last few years for the treatment of early-onset Alzheimer s disease. 

Galantamine and other amaryllidaceae alkaloids (refer to Structures 8)... 

Lopez S, Bastida J, Viladomat F, Acetylcholinesterase inhibitory activity of some Amaryllidaceae alkaloids and Narcissus extracts. Life Sciences 71 2521-2529, 2002. 

The Ley research group [76] developed a flow process for the multistep synthesis of ( )-oxomaritidine, an alkaloid found in the Amaryllidaceae family, known to have antineoplastic activity (Scheme 34) [77, 78]. The route does not involve intermediate purification of the products, which is necessary in the previously reported... 

Weniger B, Italiano L, Beck JP et al (1995) Cytotoxic activity of Amaryllidaceae alkaloids. Planta Med 61(l) 77-79... 

Iminium ion-vinylsilane cyclizations closely related to the one described here have been used to prepare indolizidine alkaloids of the pumiliotoxin A and elaeokanine families, indole alkaloids, amaryllidaceae alkaloids, and the antibiotic (+)-streptazolin. The ability of the silicon substituent to control the position, and in some cases stereochemistry, of the unsaturation in the product heterocycle was a key feature of each of these syntheses. 

Prabhakar and colleagues used ethyl propiolate (38, R = H, R = Et) to synthesize the Amaryllidaceae alkaloid Pratosine (43) (equation 13). On heating 42 in DMSO in the presence of water, a cascade of reactions is initiated, namely a [3,3]-sigmatropic rearrangement, ester hydrolysis, decarboxylation and cyclization, to afford Pratosine (43) in one step, albeit in modest yield. 

Amaryllidaceae Leucojum vernum Lycorine Homolycorine 2-O-acetyllycorine Leucovernine Acetylleucoverine N-demethylgalanthamine... 

L-proline L-serine L-threonine L-tryptophan Tryptophan-derived alkaloids Phenylethylamino alkaloids Phenylisoquinoline alkaloids Amaryllidaceae alkaloids True alkaloids... 

L-vatine Non-protein aminoacids PhenethyUsoquinoUne alkaloids Amaryllidaceae alkaloids Protoalkaloids Phenylethylamino alkaloids... 

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