Engineering a diaphorase via directed evolution for enzymatic biofuel cell application

Abstract: Background: Diaphorase (DI) has received wide attention as the key anodic enzyme mediating the electron transfer and electric energy generation in enzymatic biofuel cells (EBFCs). Lowering the anodic pH may be a useful strategy for constructing high-performance in EBFCs. However, most DI suffered from the poor activity at low pHs. Therefore, it is necessary to modify the activity and its acidic tolerance to further improve the performance of the EBFC. Results: This paper attempts to improve the enzyme activity… Show more

“…Further, various dyes used as the electron mediator can be reduced by DI to subsequently deliver electrons to the electrode . Such cascade catalysis of G6PDH and DI represents a significant electron generation and transfer process in the anodic reaction of EBFCs and has been found to be rate limiting. , In addition, our lab’s previous work had found suitable mutants for EBFCs. , Thus, we speculated that tuning the catalysis of these two enzymes may achieve control of the output in EBFCs.…”

“…26,27 In addition, our lab's previous work had found suitable mutants for EBFCs. 28,21 Thus, we speculated that tuning the catalysis of these two enzymes may achieve control of the output in EBFCs.…”

“…Specifically, the two groups have different charged amino acids in the Ncap, so they can bind with each other upon illumination and undesirable interactions such as nMag–nMag or pMag–pMag can be avoided . The mutated G6PDH from Z. mobilis and DI from G. stearothermophilus fused with nMag or pMag were chosen to perform the anodic reaction in the EBFC. Without blue light, the two enzymes are free in the solution, so the reaction limited by the slow mass transfer yields a low current output.…”

Photoswitchable Enzymatic Biofuel Cell Based on Fusion Protein with Natural Photoreceptor Vivid

“…Further, various dyes used as the electron mediator can be reduced by DI to subsequently deliver electrons to the electrode . Such cascade catalysis of G6PDH and DI represents a significant electron generation and transfer process in the anodic reaction of EBFCs and has been found to be rate limiting. , In addition, our lab’s previous work had found suitable mutants for EBFCs. , Thus, we speculated that tuning the catalysis of these two enzymes may achieve control of the output in EBFCs.…”

“…26,27 In addition, our lab's previous work had found suitable mutants for EBFCs. 28,21 Thus, we speculated that tuning the catalysis of these two enzymes may achieve control of the output in EBFCs.…”

“…Specifically, the two groups have different charged amino acids in the Ncap, so they can bind with each other upon illumination and undesirable interactions such as nMag–nMag or pMag–pMag can be avoided . The mutated G6PDH from Z. mobilis and DI from G. stearothermophilus fused with nMag or pMag were chosen to perform the anodic reaction in the EBFC. Without blue light, the two enzymes are free in the solution, so the reaction limited by the slow mass transfer yields a low current output.…”

Photoswitchable Enzymatic Biofuel Cell Based on Fusion Protein with Natural Photoreceptor Vivid

Wearable Biofuel Cells: Advances from Fabrication to Application

Biomanufacturing by In Vitro Biotransformation (ivBT) Using Purified Cascade Multi-enzymes