从化学合成到生物合成——天然产物全合成新趋势

张发光; 曲戈; 孙周通; 马军安

doi:10.12211/2096-8280.2021-039

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从化学合成到生物合成——天然产物全合成新趋势

特约评述 | 更新时间：2026-03-18

- 从化学合成到生物合成——天然产物全合成新趋势
  封面论文
- From chemical synthesis to biosynthesis: trends toward total synthesis of natural products
- 合成生物学 2021年2卷第5期页码：674-696
- 作者机构：
  
  1.天津大学理学院化学系，合成生物学前沿科学中心，天津 300072
  2.中国科学院天津工业生物技术研究所，天津 300308
- 作者简介：
  
  曲戈（1985—），男，博士，副研究员。研究方向为酶分子理性设计与生物催化。 E-mail：qug@tib.cas.cn
- 基金信息：
  
  国家重点研发计划(2019YFA0905100);广东省重点领域研发计划(2020B0303070002)
- DOI：10.12211/2096-8280.2021-039
  中图分类号： Q55;062
- 收稿：2021-04-01，
  
  修回：2021-06-19，
  
  纸质出版：2021-10-31
- 稿件说明：
移动端阅览
张发光，曲戈，孙周通，马军安. 从化学合成到生物合成——天然产物全合成新趋势［J］. 合成生物学， 2021， 2（5）： 674-696

ZHANG Faguang， QU Ge， SUN Zhoutong， MA Jun′an. From chemical synthesis to biosynthesis：trends toward total synthesis of natural products［J］. Synthetic Biology Journal， 2021， 2（5）： 674-696
张发光，曲戈，孙周通，马军安. 从化学合成到生物合成——天然产物全合成新趋势［J］. 合成生物学， 2021， 2（5）： 674-696 DOI： 10.12211/2096-8280.2021-039.

ZHANG Faguang， QU Ge， SUN Zhoutong， MA Jun′an. From chemical synthesis to biosynthesis：trends toward total synthesis of natural products［J］. Synthetic Biology Journal， 2021， 2（5）： 674-696 DOI： 10.12211/2096-8280.2021-039.

摘要

结构复杂而多样的天然产物是药物发现和创制的重要宝库。为了克服有限的自然资源，来自学术界和工业界的科学家近两个世纪一直不断尝试人工合成天然产物。化学全合成已经取得了巨大成就，众多高度复杂的天然产物已经被有机化学家成功制备；但本领域仍存在诸多挑战性问题，例如化学反应中涉及昂贵的化学试剂、苛刻的反应条件、难控的立体选择性、冗长的合成路线以及较低的总收率等。随着合成生物学的发展，越来越多天然产物可通过生物细胞工厂实现人工制备，从而提供全新而互补的全合成策略。本文简要概括天然产物化学全合成，围绕几种药物活性天然产物的生物合成介绍其相关进展，以青霉素、红霉素、阿维菌素为例分析总结了天然产物同源途径的改造与优化；以维生素B

、莨菪烷碱为例概括评述了天然产物的异源表达与生物制造；并以人源胰岛素、青蒿素、沙弗拉霉素、嗜氮酮、卡英酸、鬼臼毒素为例重点介绍了生物与化学交叉融合策略在天然产物全合成中的应用。尽管在类天然产物新分子、立体复杂天然产物等的全合成中仍面临诸多挑战，但生物全合成对这些天然产物分子的构建将发挥越来越显著的作用；通过化学合成与生物合成优势互补，并借助当今蓬勃发展的人工智能技术，实现生物全合成的智能化、自动化、高效化将是本领域发展的新趋势。

Abstract

The complexity and diversity of natural products have made them a rich source for drug and agrochemical discovery. To overcome the supplying limitation of natural resources

tremendous effort has been made by the academic and industrial communitie

s during the past two centuries for the total artificial synthesis of natural products. In this regard

total chemical synthesis has achieved significant progress

and numerous highly complex natural products have been synthesized through different chemical processes. Despite these great achievements in total chemical synthesis

there are still many challenges including expensive chemical reagents

harsh reaction conditions

difficult control on stereoselectivity

long synthetic route

and low product yield. Notably

the development of synthetic biology has allowed more and more natural products to be produced through biological cell factories

which provides a new and complementary strategy for the synthesis of natural products at a large scale. This review critically comments on the representative advances in total chemical synthesis of natural products (Section 1)

and then highlight major progress and trends in the biosynthesis of pharmaceutically important natural products (Sections 2 and 3). In Section 2.1

we selected the production of penicillin

erythromycin

and avermectin as examples to analyze the modification and optimization of natural product biosynthetic pathways. The discovery and utilization of secondary metabolites from microorganisms has been a continuous driving force in the field of natural products. Notably

significant progress has been made in the total biosynthesis of natural products from secondary metabolism via the genetic manipulation of microbial cells. In Section 2.2

we selected Vitamin B

and Tropane alkaloids as examples to demonstrate the use of heterologous expression and biological production for natural product synthesis. In recent years

on the basis of analyzing the structure of natural products in animals

plants

and microorganisms

great advances have emerged in exploring their biochemical reaction mechanisms and synthetic routes. More importantly

expressing and regulating the relative genes in heterologous microbial cells have enabled the complete biosynth

esis of many natural products. Furthermore

in Section 3

human insulin

artemisinin

saframycin

azaphilone

kainic acid

and podophyllotoxin were selected as examples to showcase the power of merging chemical and biological processes for the total synthesis of natural products. Although there are still many challenges in the total synthesis of new and complex natural products

biosynthesis will ultimately play a significant role in the construction of natural molecules and their relative analogues. By taking advantage of the merits with organic chemistry

synthetic biology

and artificial intelligence

the development of highly efficient and automatic biosynthesis could be a trend in this field.

关键词

Keywords

references

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