methyl (3a1S,10bR)-6-benzyl-2,3,3a1,6,11,12-hexahydro-1H-indolizino[8,1-cd]carbazole-5-carboxylate | 1320267-54-6

分子结构分类

有机化合物 - 生物碱及其衍生物 - 鸡蛋花型生物碱

中文名称

——

中文别名

——

英文名称

methyl (3a1S,10bR)-6-benzyl-2,3,3a1,6,11,12-hexahydro-1H-indolizino[8,1-cd]carbazole-5-carboxylate

英文别名

(+/-)-Na-benzyl-17,20-dehydrodesethylvincadifformine；(+/-)-N^a-benzyl-17,20-dehydrodesethylvincadifformine

methyl (3a1S,10bR)-6-benzyl-2,3,3a1,6,11,12-hexahydro-1H-indolizino[8,1-cd]carbazole-5-carboxylate化学式

CAS

1320267-54-6；98737-03-2

化学式

C₂₆H₂₆N₂O₂

mdl

——

分子量

398.505

InChiKey

VHDNPDKJWQRHND-JYFHCDHNSA-N

BEILSTEIN

——

EINECS

——

计算性质

辛醇/水分配系数(LogP)：

4.18
重原子数：

30.0
可旋转键数：

3.0
环数：

6.0
sp3杂化的碳原子比例：

0.35
拓扑面积：

32.78
氢给体数：

0.0
氢受体数：

4.0

上下游信息

下游产品

中文名称	英文名称	CAS号	化学式	分子量
蕊木宁	(+/-)-kopsinine	559-51-3	C₂₁H₂₆N₂O₂	338.45

反应信息

作为反应物：

描述：

methyl (3a1S,10bR)-6-benzyl-2,3,3a1,6,11,12-hexahydro-1H-indolizino[8,1-cd]carbazole-5-carboxylate 在 Raney Ni 作用下，以乙醇、苯为溶剂，生成蕊木宁

参考文献：

名称：

Collective synthesis of natural products by means of organocascade catalysis

摘要：

有机化学家现在能够在足够时间、资源和努力下合成几乎所有已知的天然产物的小量样本。但是，将全合成的学术成功转化为复杂天然产物的大规模构建和相关生物分子的大量集合开发，对合成化学家来说是一个巨大的挑战。在这里，我们展示了两种自然启发的技术，即有机级联催化（organocascade catalysis）和集体天然产物合成（collective natural product synthesis），它们可以促进使用常见分子支架来制备一系列具有不同结构的天然产物有用量。这个概念的强大之处已通过六种著名的生物碱天然产物的方便的、不对称的全合成得到证明：马钱子碱、阿部碱、长春碱、奥斯卡宁、可乐定和可普森宁。通过结合自然界中已经进化出的两种生物合成原理，David MacMillan和他在新泽西州普林斯顿大学的默克催化中心的同事们开发了一种能够广泛生产天然产物的有力策略。第一种技术是有机级联催化，其中连续的催化级联取代传统的停-来方法合成。第二种是集体合成，其使用通用的合成路线来达到一个常见的分子支架，而这个支架通过适当的微调，成为了同一家族的其他成员的通道。这种方法通过六种著名生物碱的不对称全合成得到展示：马钱子碱、阿部碱、长春碱、奥斯卡宁、可乐定和可普森宁。

DOI：

10.1038/nature10232
作为产物：

描述：

5-氯戊醛在硼酸、 sodium hydride 、间氯过氧苯甲酸、三苯基膦作用下，以二氯甲烷为溶剂，反应 10.5h，生成 methyl (3a1S,10bR)-6-benzyl-2,3,3a1,6,11,12-hexahydro-1H-indolizino[8,1-cd]carbazole-5-carboxylate

参考文献：

名称：

Studies in biomimetic alkaloid syntheses. 13. Total syntheses of racemic aspidofractine, pleiocarpine, pleiocarpinine, kopsinine, N-methylkopsanone, and kopsanone

摘要：

DOI：

10.1021/jo00224a027

点击查看最新优质反应信息

文献信息

Collective synthesis of natural products by means of organocascade catalysis

作者：Spencer B. Jones、Bryon Simmons、Anthony Mastracchio、David W. C. MacMillan

DOI：10.1038/nature10232

日期：2011.7

Organic chemists are now able to synthesize small quantities of almost any known natural product, given sufficient time, resources and effort. However, translation of the academic successes in total synthesis to the large-scale construction of complex natural products and the development of large collections of biologically relevant molecules present significant challenges to synthetic chemists. Here we show that the application of two nature-inspired techniques, namely organocascade catalysis and collective natural product synthesis, can facilitate the preparation of useful quantities of a range of structurally diverse natural products from a common molecular scaffold. The power of this concept has been demonstrated through the expedient, asymmetric total syntheses of six well-known alkaloid natural products: strychnine, aspidospermidine, vincadifformine, akuammicine, kopsanone and kopsinine. By combining two biosynthetic principles that have evolved in the natural world, David MacMillan and colleagues at the Merck Center for Catalysis at Princeton University, New Jersey, have developed a powerful strategy for the production of a broad spectrum of natural products. The first technique is organocascade catalysis, in which a continuous catalytic cascade replaces the traditional stop-go method of synthesis. The second is collective synthesis, in which a general synthetic route is used to reach a common molecular scaffold that, with appropriate fine-tuning, serves as a conduit to other members of the same chemical family. The method is demonstrated with the asymmetric total syntheses of six high-profile alkaloids: strychnine, aspidospermidine, vincadifformine, akuammicine, kopsanone and kopsinine.

有机化学家现在能够在足够时间、资源和努力下合成几乎所有已知的天然产物的小量样本。但是，将全合成的学术成功转化为复杂天然产物的大规模构建和相关生物分子的大量集合开发，对合成化学家来说是一个巨大的挑战。在这里，我们展示了两种自然启发的技术，即有机级联催化（organocascade catalysis）和集体天然产物合成（collective natural product synthesis），它们可以促进使用常见分子支架来制备一系列具有不同结构的天然产物有用量。这个概念的强大之处已通过六种著名的生物碱天然产物的方便的、不对称的全合成得到证明：马钱子碱、阿部碱、长春碱、奥斯卡宁、可乐定和可普森宁。通过结合自然界中已经进化出的两种生物合成原理，David MacMillan和他在新泽西州普林斯顿大学的默克催化中心的同事们开发了一种能够广泛生产天然产物的有力策略。第一种技术是有机级联催化，其中连续的催化级联取代传统的停-来方法合成。第二种是集体合成，其使用通用的合成路线来达到一个常见的分子支架，而这个支架通过适当的微调，成为了同一家族的其他成员的通道。这种方法通过六种著名生物碱的不对称全合成得到展示：马钱子碱、阿部碱、长春碱、奥斯卡宁、可乐定和可普森宁。
Studies in biomimetic alkaloid syntheses. 13. Total syntheses of racemic aspidofractine, pleiocarpine, pleiocarpinine, kopsinine, N-methylkopsanone, and kopsanone

作者：Martin E. Kuehne、Pamela J. Seaton

DOI：10.1021/jo00224a027

日期：1985.11

同类化合物

长春立辛长春新碱M1 脱乙酰基文多灵罗西定碱温都罗新文多灵它波宁盐酸盐它勃宁 Ervamycine; 11-甲氧基水甘草碱 4',5'-二去氢-4'-脱氧-2',19'-二氧代-2',19'-仲长春碱 11-羟基他波宁 (-)-14,15-didehydroaspidospermidine 4-deacetyl-4-propoxylvindoline hydroxyvinamidine 4-deacetyl-4-butoxylvindoline 4-deacetyl-4-(cyclohexanecarbonyl)oxyvindoline vinamidine jerantinine A acetate N-[[(1R,9R,12R,14S,19R)-14-ethyl-8,16-diazapentacyclo[10.6.1.01,9.02,7.016,19]nonadeca-2,4,6-trien-11-ylidene]amino]-4-methylbenzenesulfonamide 16-methoxy-1-methyl-6,7-didehydro-aspidospermidin-4-one (+)-20R-1,2-dehydro-Ψ-aspidospermidine methyl (1R,9R,10S,12S,19S)-12-ethenyl-8,16-diazahexacyclo[10.6.1.01,9.02,7.08,10.016,19]nonadeca-2,4,6,13-tetraene-10-carboxylate (1R,9R,12R,19R)-8,16-diazapentacyclo[10.6.1.01,9.02,7.016,19]nonadeca-2,4,6-triene-11,17-dione methyl (1R,9R,10S,12R,19S)-12-ethyl-8,16-diazahexacyclo[10.6.1.01,9.02,7.08,10.016,19]nonadeca-2,4,6,13-tetraene-10-carboxylate 3-Oxo-11-methoxytabersonine Aspidospermidine-3-carboxylic acid, 4-(acetyloxy)-6,7-didehydro-3-hydroxy-16-methoxy-1-methyl-, methyl ester, (2beta,3beta,4beta,5alpha,12beta,19alpha)- melodinine P N-methyltabersonine 14,15-didehydro-16-hydroxy-<3H>indole ent-N(1)-methyl-14,15-didehydroaspidospermidine vindoline hydrochloride Mbid (3aS,5R,10bR,12bS)-5-Chloro-3a-ethyl-12-oxo-2,3,3a,4,5,11,12,12b-octahydro-1H-6,12a-diaza-indeno[7,1-cd]fluorene-5-carboxylic acid methyl ester (3aS,5R,10bR,12R,12bS)-5-Chloro-12-cyano-3a-ethyl-2,3,3a,4,5,11,12,12b-octahydro-1H-6,12a-diaza-indeno[7,1-cd]fluorene-5-carboxylic acid methyl ester (3aS,5aR,10bR,12bR)-6-Ethyl-2,3,3a,5a,6,12b-hexahydro-1H,5H-6,12a-diaza-indeno[7,1-cd]fluorene-4,12-dione jerantinine A jerantinine C 10-O-methyljerantinine A baloxine 2βH,3αH-tubersonine methyl 15-bromo-2,3,6,7-tetrahydro-(5α,12β,19α)-aspidospermidine-3-carboxylate methyl 15-bromo-6,7-didehydro-(2β,5α,12β,19α)-aspidospermidine-3α-carboxylate 2,3-didehydro-20,21-dinor-aspidospermidine-3-carboxylic acid methyl ester methyl (1R,9R,10S,11R,12R,19R)-11-acetyloxy-12-ethyl-4-[(1R,3S,14R)-18-ethyl-3-methoxycarbonyl-14-[[(2S)-2-methoxycarbonylpyrrolidin-1-yl]methyl]-5,16-diazatetracyclo[14.3.1.04,12.06,11]icosa-4(12),6,8,10,18-pentaen-3-yl]-10-hydroxy-5-methoxy-8-methyl-8,16-diazapentacyclo[10.6.1.01,9.02,7.016,19]nonadeca-2,4,6,13-tetraene-10-carboxylate 20-deethyl-17-ethoxy-1-(p-tolylsulfonyl)-2,16,17,20-tetradehydroaspidospermidine 3α-acetonyl-tabersonine 20-desethyl-17-formyl-5-oxo-16,17-dehydroaspidospermidine Alkaloid XC-99 16-Chloro-1-dehydrovincadifformine Methyl 11-acetyloxy-12-ethyl-4-[(Z)-1-(16-ethyl-16-hydroxy-3,13-diazatetracyclo[11.2.2.02,10.04,9]heptadeca-2(10),4,6,8-tetraen-15-yl)-3-methoxy-3-oxoprop-1-en-2-yl]-10-hydroxy-5-methoxy-8-methyl-8,16-diazapentacyclo[10.6.1.01,9.02,7.016,19]nonadeca-2(7),3,5,13-tetraene-10-carboxylate