乙醛酸生成甘氨酸的新机制：氮杂坎尼扎罗反应。

A New Mechanism for Formation of Glycine from Glyoxylic Acid: the Aza-Cannizzaro Reaction.

作者信息

Jarois Dean R, Schimmelpfennig Lars E, Gellman Samuel H

机构信息

Department of Chemistry, University of Wisconsin - Madison, 1101 University Ave, Madison, WI 53706, United States.

出版信息

Chemistry. 2024 Dec 18;30(71):e202403202. doi: 10.1002/chem.202403202. Epub 2024 Nov 6.

DOI:10.1002/chem.202403202

PMID:39349361

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11653230/

Abstract

Glyoxylic acid and glycine are widely considered to have been important prebiotic building blocks. Several mechanistic routes have been previously examined for conversion of glyoxylic acid to glycine. Here we provide evidence for a new mechanistic path. Glycine is spontaneously formed from glyoxylic acid in ammonium-rich aqueous solutions at neutral pH; oxamic acid is generated as well. Hydride transfer from the glyoxylate-derived hemiaminal to the corresponding iminium ion appears to underlie this transformation. This proposed mechanism parallels the well-known Cannizzaro reaction mechanism, which leads us to suggest the designation "aza-Cannizzaro reaction." This discovery offers a new perspective on prebiotic nitrogen incorporation because glycine can be a source of nitrogen for more complex molecules, including other α-amino acids.

摘要

乙醛酸和甘氨酸被广泛认为是重要的前体生物分子构建模块。此前已经研究了几条将乙醛酸转化为甘氨酸的反应机理途径。在此，我们提供了一条新反应机理途径的证据。在中性pH值的富铵水溶液中，乙醛酸能自发形成甘氨酸，同时还会生成草氨酸。从乙醛酸衍生的半缩醛胺向相应的亚胺离子的氢化物转移似乎是这一转化过程的基础。这一提出的反应机理与著名的坎尼扎罗反应机理相似，这使我们建议将其命名为“氮杂坎尼扎罗反应”。这一发现为前体生物氮的掺入提供了新的视角，因为甘氨酸可以作为包括其他α-氨基酸在内的更复杂分子的氮源。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e04f/11653230/46e1876236b0/CHEM-30-e202403202-g004.jpg

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乙醛酸生成甘氨酸的新机制：氮杂坎尼扎罗反应。

A New Mechanism for Formation of Glycine from Glyoxylic Acid: the Aza-Cannizzaro Reaction.

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