通过生物相容性羟醛缩合反应在细菌兼容条件下进行催化升级。

Catalytic Upgrading in Bacteria-Compatible Conditions via a Biocompatible Aldol Condensation.

作者信息

Domaille Dylan W, Hafenstine Glenn R, Greer Mattias A, Goodwin Andrew P, Cha Jennifer N

机构信息

Department of Chemical and Biological Engineering, University of Colorado, 3415 Colorado Ave., Boulder, Boulder, CO 80303.

Materials Science and Engineering Program, University of Colorado, 3415 Colorado Ave., Boulder, Boulder, CO 80303.

出版信息

ACS Sustain Chem Eng. 2016 Mar 7;4(3):671-675. doi: 10.1021/acssuschemeng.5b01590. Epub 2016 Feb 15.

DOI:10.1021/acssuschemeng.5b01590

PMID:28480149

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5417690/

Abstract

Integrating non-enzymatic chemistry with living systems has the potential to greatly expand the types and yields of chemicals that can be sourced from renewable feedstocks. The in situ conversion of microbial metabolites to higher order products will ensure their continuous generation starting from a given cellular reaction mixture. We present here a systematic study of different organocatalysts that enable aldol condensation in biological media under physiological conditions of neutral pH, moderate temperature, and ambient pressure. The relative toxicities of each catalyst were tested against bacteria, and the catalysts were found to provide good yields of homoaldol products in bacterial cultures containing aldehydes. Lastly, we demonstrate that a biocompatible oil can be used to selectively extract the upgraded products, which enabes facile isolation and decreases the product toxicity to microbes.

摘要

将非酶化学与生命系统相结合，有可能极大地扩展可从可再生原料中获取的化学品的类型和产量。将微生物代谢物原位转化为高阶产物将确保从给定的细胞反应混合物开始持续生成这些产物。我们在此展示了对不同有机催化剂的系统研究，这些催化剂能够在中性pH、适度温度和常压的生理条件下在生物介质中实现羟醛缩合反应。测试了每种催化剂对细菌的相对毒性，发现这些催化剂在含有醛的细菌培养物中能提供高产率的同羟醛产物。最后，我们证明了一种生物相容性油可用于选择性提取升级后的产物，这使得产物易于分离，并降低了产物对微生物的毒性。

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