利用高效的三磷酸腺苷（ATP）再生系统提高脱氧腺苷三磷酸（dATP）的合成：响应面分析的优化。

Improved Synthesis of Deoxyadenosine Triphosphate by Using an Efficient ATP Regeneration System: Optimization of Response Surface Analysis.

机构信息

School of Chemistry and Chemical Engineering, Henan University of Science and Technology, Luoyang 471023, China.

出版信息

Molecules. 2023 May 11;28(10):4029. doi: 10.3390/molecules28104029.

DOI:10.3390/molecules28104029

PMID:37241768

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10222888/

Abstract

Deoxyadenosine triphosphate (dATP) is an important biochemical molecule. In this paper, the synthesis of dATP from deoxyadenosine monophosphate (dAMP), catalyzed by was studied. By adding chemical effectors, an efficient ATP regeneration and coupling system was constructed to achieve efficient synthesis of dATP. Factorial and response surface designs were used to optimize process conditions. Optimal reaction conditions were as follows: dAMP 1.40 g/L, glucose 40.97 g/L, MgCl·6HO 4.00 g/L, KCl 2.00 g/L, NaHPO 31.20 g/L, yeast 300.00 g/L, ammonium chloride 0.67 g/L, acetaldehyde 11.64 mL/L, pH 7.0, temperature 29.6 °C. Under these conditions, the substrate conversion was 93.80% and the concentration of dATP in the reaction system was 2.10 g/L, which was 63.10% higher than before optimization, and the concentration of product was 4 times higher than before optimization. The effects of glucose, acetaldehyde, and temperature on the accumulation of dATP were analyzed.

摘要

脱氧腺苷三磷酸(dATP)是一种重要的生化分子。本文研究了在催化下，由脱氧腺苷一磷酸(dAMP)合成 dATP 的过程。通过添加化学效应物，构建了高效的 ATP 再生和偶联系统，实现了 dATP 的高效合成。利用析因设计和响应面设计对工艺条件进行了优化。最佳反应条件为：dAMP 1.40 g/L、葡萄糖 40.97 g/L、MgCl·6HO 4.00 g/L、KCl 2.00 g/L、NaHPO·12HO 31.20 g/L、酵母 300.00 g/L、氯化铵 0.67 g/L、乙醛 11.64 mL/L、pH 值 7.0、温度 29.6°C。在此条件下，底物转化率为 93.80%，反应体系中 dATP 的浓度为 2.10 g/L，比优化前提高了 63.10%，产物浓度比优化前提高了 4 倍。分析了葡萄糖、乙醛和温度对 dATP 积累的影响。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/e4a5/10222888/ec44fd997153/molecules-28-04029-g001.jpg

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利用高效的三磷酸腺苷（ATP）再生系统提高脱氧腺苷三磷酸（dATP）的合成：响应面分析的优化。

Improved Synthesis of Deoxyadenosine Triphosphate by Using an Efficient ATP Regeneration System: Optimization of Response Surface Analysis.

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