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对超自然产物的追求:全合成对复杂天然产物药物化学的影响。

The quest for supernatural products: the impact of total synthesis in complex natural products medicinal chemistry.

机构信息

Department of Chemistry, The Skaggs Institute for Chemical Biology, The Scripps Research Institute, 10550 N. Torrey Pines Road, La Jolla, CA 92037, USA.

出版信息

Nat Prod Rep. 2020 Nov 1;37(11):1511-1531. doi: 10.1039/d0np00060d. Epub 2020 Nov 10.

DOI:10.1039/d0np00060d
PMID:33169762
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7678878/
Abstract

Covering: 2000 up to 2020This review presents select recent advances in the medicinal chemistry of complex natural products that are prepared by total synthesis. The underlying studies highlight enabling divergent synthetic strategies and methods that permit the systematic medicinal chemistry studies of key analogues bearing deep-seated structural changes not readily accessible by semisynthetic or biosynthetic means. Select and recent examples are detailed where the key structural changes are designed to improve defined properties or to overcome an intrinsic limitation of the natural product itself. In the examples presented, the synthetic efforts provided supernatural products, a term first introduced by our colleague Ryan Shenvi (Synlett, 2016, 27, 1145-1164), with properties superseding the parent natural product. The design principles and approaches for creating the supernatural products are highlighted with an emphasis on the properties addressed that include those that improve activity or potency, increase selectivity, enhance durability, broaden the spectrum of activity, improve chemical or metabolic stability, overcome limiting physical properties, add mechanisms of action, enhance PK properties, overcome drug resistance, and/or improve in vivo efficacy. Some such improvements may be regarded by some as iterative enhancements whereas others, we believe, truly live up to their characterization as supernatural products. Most such efforts are also accompanied by advances in synthetic organic chemistry, inspiring the development of new synthetic methodology and providing supernatural products with improved synthetic accessibility.

摘要

涵盖时间

2000 年至 2020 年

本篇综述介绍了通过全合成制备的复杂天然产物的药物化学的一些最新进展。这些基础研究强调了不同的合成策略和方法,这些策略和方法允许对具有深层次结构变化的关键类似物进行系统的药物化学研究,而这些结构变化通过半合成或生物合成手段不易获得。详细介绍了一些具有代表性的近期示例,其中关键结构变化旨在改善定义明确的特性或克服天然产物本身固有的局限性。在所呈现的示例中,合成工作提供了超自然产物,这是我们的同事 Ryan Shenvi(Synlett,2016,27,1145-1164)首次引入的一个术语,其性质超越了母体天然产物。创建超自然产物的设计原则和方法被强调,重点是解决的性质,包括那些提高活性或效力、增加选择性、增强耐用性、拓宽活性谱、提高化学或代谢稳定性、克服限制物理性质、增加作用机制、增强 PK 性质、克服耐药性和/或提高体内疗效的性质。其中一些改进可能被一些人认为是迭代增强,而我们认为,其他改进确实名副其实地成为超自然产物。这些努力大多还伴随着合成有机化学的进步,激发了新合成方法的发展,并为超自然产物提供了更好的合成可及性。

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