在L-茶氨酸生物催化中筛选高效ATP再生的多磷酸激酶突变体的高通量双系统。

Hui Gao, Mengxuan Li, Qing Wang, Tingting Liu, Xian Zhang, Taowei Yang, Meijuan Xu, Zhiming Rao
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引用次数: 1

摘要

ATP是一种重要的辅因子,参与了许多需要能量的生物催化反应。多磷酸激酶(PPK)由于其廉价且易于获得的底物多磷酸,可以为ATP消耗反应提供能量。我们测定了不同来源的PPK的催化性能,发现来自胡氏细胞吞噬菌(ChPPK)的PPK对底物ADP和polyP6具有最佳的催化活性。构建了细胞外-细胞内双系统,以高通量筛选ChPPK突变体的更好催化活性。最后,ChPPKD82N-K103E突变体的比活性提高了4.3倍。因此,我们将GMAS催化生产L-茶氨酸作为ATP再生的模型。GMAS酶能产生16.8 ± 来自100mM谷氨酸的1.3g/L L-茶氨酸。当加入5mM ATP和5U/mL ChPPKD82N-K103E时,L-茶氨酸的产率为16.6 ± 0.79g/L,转化率95.6 ± 4h时4.5%。随后,将该系统放大至200mM和400mM谷氨酸,导致L-茶氨酸的产率为32.3 ± 1.6 g/L和62.7 ± 1.1 g/L,转化率92.8 ± 4.6%和90.1 ± 分别为1.6%。此外,我们还构建了一个从谷氨酸到谷氨酰胺的高效ATP再生系统,13.8 ± 获得0.2 g/L谷氨酰胺,转化率为94.4 ± 添加6U/mL GS酶和5U/mL ChPPKD82N-K103E后4h内转化率为1.4%,为GGT酶催化谷氨酰胺转化L-茶氨酸奠定了基础。这证明了由突变酶驱动的有效ATP供应提高了底物向产物的转化率,并使底物值最大化。这是酶催化的高产率、高转化率和高经济价值的正组合。突变酶将进一步为消耗ATP的生物催化反应平台提供可持续的动力。
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A high-throughput dual system to screen polyphosphate kinase mutants for efficient ATP regeneration in L-theanine biocatalysis.

ATP, an important cofactor, is involved in many biocatalytic reactions that require energy. Polyphosphate kinases (PPK) can provide energy for ATP-consuming reactions due to their cheap and readily available substrate polyphosphate. We determined the catalytic properties of PPK from different sources and found that PPK from Cytophaga hutchinsonii (ChPPK) had the best catalytic activity for the substrates ADP and polyP6. An extracellular-intracellular dual system was constructed to high-throughput screen for better catalytic activity of ChPPK mutants. Finally, the specific activity of ChPPKD82N-K103E mutant was increased by 4.3 times. Therefore, we focused on the production of L-theanine catalyzed by GMAS as a model of ATP regeneration. Supplying 150 mM ATP, GMAS enzyme could produce 16.8 ± 1.3 g/L L-theanine from 100 mM glutamate. When 5 mM ATP and 5 U/mL ChPPKD82N-K103E were added, the yield of L-theanine was 16.6 ± 0.79 g/L with the conversion rate of 95.6 ± 4.5% at 4 h. Subsequently, this system was scaled up to 200 mM and 400 mM glutamate, resulting in the yields of L-theanine for 32.3 ± 1.6 g/L and 62.7 ± 1.1 g/L, with the conversion rate of 92.8 ± 4.6% and 90.1 ± 1.6%, respectively. In addition, we also constructed an efficient ATP regeneration system from glutamate to glutamine, and 13.8 ± 0.2 g/L glutamine was obtained with the conversion rate of 94.4 ± 1.4% in 4 h after adding 6 U/ mL GS enzyme and 5 U/ mL ChPPKD82N-K103E, which further laid the foundation from glutamine to L-theanine catalyzed by GGT enzyme. This proved that giving the reaction an efficient ATP supply driven by the mutant enzyme enhanced the conversion rate of substrate to product and maximized the substrate value. This is a positively combination of high yield, high conversion rate and high economic value of enzyme catalysis. The mutant enzyme will further power the ATP-consuming biocatalytic reaction platform sustainably.

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