重组蓝藻中异源生物技术反应速率极限的探讨。

Giovanni Davide Barone, Michal Hubáček, Lenny Malihan-Yap, Hanna C Grimm, Lauri Nikkanen, Catarina C Pacheco, Paula Tamagnini, Yagut Allahverdiyeva, Robert Kourist
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引用次数: 1

摘要

背景:蓝藻已经成为生产化学品和生物燃料的高效生物。然而,这种电池的生产效率在商业应用方面一直很低。蓝藻的光生物转化利用光合电子形成还原性等价物,如nadph来为生物催化反应提供燃料。这些光生物转化是一种测量,在多大程度上光合电子可以偏离异源生物技术过程,如生产生物燃料。通过将枯草芽孢杆菌中的氧化还原酶YqjM等表达到聚胞菌PCC 6803中,获得了较高的还原马来酰亚胺的比活性。在光照和黑暗条件下,我们研究了添加碳水化合物作为外源碳源(如d -葡萄糖)加速NAD(P) h消耗氧化还原反应的可能性。结果:以OD750 = 2.5 (DCW = 0.6 g L-1)加入d -葡萄糖后,2-甲基马来酰亚胺生物转化活性(150µmol min-1 gDCW-1)提高1.7倍。在光照和黑暗条件下较高的细胞密度以及其他底物的还原中也观察到d -葡萄糖的刺激作用。添加d -葡萄糖后,光系统II和光系统I的有效光合产量均未增加。然而,当补充d -葡萄糖时,我们观察到更高的NAD(P)H荧光,表明糖酵解活性增加。此外,该系统在内部照明的气泡柱反应器中放大(工作体积为200 mL),在光限制条件下显示出2.4倍的比活性增加。结论:结果表明,在比活性为90µmol min-1 gDCW-1的光自养条件下,Synechocystis sp. PCC 6803的酶还原酶YqjM未达到NAD(P)H饱和,这表明催化和生物燃料生产的异源电子消耗过程速率的增加将需要将光合链的进一步还原能量向异源过程聚集。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Towards the rate limit of heterologous biotechnological reactions in recombinant cyanobacteria.

Background: Cyanobacteria have emerged as highly efficient organisms for the production of chemicals and biofuels. Yet, the productivity of the cell has been low for commercial application. Cyanobacterial photobiotransformations utilize photosynthetic electrons to form reducing equivalents, such as NADPH-to-fuel biocatalytic reactions. These photobiotransformations are a measure to which extent photosynthetic electrons can be deviated toward heterologous biotechnological processes, such as the production of biofuels. By expressing oxidoreductases, such as YqjM from Bacillus subtilis in Synechocystis sp. PCC 6803, a high specific activity was obtained in the reduction of maleimides. Here, we investigated the possibility to accelerate the NAD(P)H-consuming redox reactions by addition of carbohydrates as exogenous carbon sources such as D-Glucose under light and darkness.

Results: A 1.7-fold increase of activity (150 µmol min-1 gDCW-1) was observed upon addition of D-Glucose at an OD750 = 2.5 (DCW = 0.6 g L-1) in the biotransformation of 2-methylmaleimide. The stimulating effect of D-Glucose was also observed at higher cell densities in light and dark conditions as well as in the reduction of other substrates. No increase in both effective photosynthetic yields of Photosystem II and Photosystem I was found upon D-Glucose addition. However, we observed higher NAD(P)H fluorescence when D-Glucose was supplemented, suggesting increased glycolytic activity. Moreover, the system was scaled-up (working volume of 200 mL) in an internally illuminated Bubble Column Reactor exhibiting a 2.4-fold increase of specific activity under light-limited conditions.

Conclusions: Results show that under photoautotrophic conditions at a specific activity of 90 µmol min-1 gDCW-1, the ene-reductase YqjM in Synechocystis sp. PCC 6803 is not NAD(P)H saturated, which is an indicator that an increase of the rates of heterologous electron consuming processes for catalysis and biofuel production will require funnelling further reducing power from the photosynthetic chain toward heterologous processes.

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