AI Article Synopsis
- Aldehydes and carboxylic acids are effective catalysts for racemizing amino acids, but the exact mechanisms are not fully understood.
- The study focuses on aspartic acid racemization, utilizing salicylaldehyde and acetic acid, employing computational methods to analyze the reaction pathways.
- Findings reveal that the dehydration step presents the highest energy barrier in the process, while the presence of water significantly lowers the energy required for this step, facilitating racemization.
Article Abstract
Aldehydes and carboxylic acids are widely used as catalysts for efficient racemization process of amino acids. However, the detailed reaction mechanism remains unclear. This work aims to clarify the racemization mechanism of aspartic acid (Asp) catalyzed by salicylaldehyde and acetic acid by using computational approaches. Density functional theory was used to obtain the structures and relative energies of 10 intermediates and five transition states, thus characterizing the main stages of the reaction. The calculated energy diagram shows that the dehydration step has the highest energy barrier, followed by the reaction step to change the chirality of Asp, which is a crucial process for racemization. In the dehydration reaction, water molecules can induce a remarkable decrease in the required energy.
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| http://dx.doi.org/10.1002/chir.23573 | DOI Listing |
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