Abstract
In recent years, finding alternatives for fossil fuels has become a major concern. One promising solution is microorganism-based bio-photo electrochemical cells (BPECs) that utilize photosynthetic solar energy conversion as an energy source while absorbing CO2 from the atmosphere. It was previously reported that in cyanobacterial-based BPECs, the major endogenous electron mediator that can transfer electrons from the thylakoid membrane photosynthetic complexes and external anodes is NADPH. However, the question of whether the same electron transfer mechanism is also valid for live eukaryotic microalgae, in which NADPH must cross both the chloroplast outer membrane and the cell wall to be secreted from the cell has remained elusive. In this work, we show that NADPH is also the major endogenous electron mediator in the microalgae Dunalliela salina (Ds). We show that the ability of Ds to tolerate high salinity enables the production of a photocurrent that is 5–6 times greater than previously reported for freshwater cyanobacterial-based BPECs in the presence or absence of exogenous electron mediators. Additionally, we show that the electron mediator Vitamin B1 can also function as an electron mediator enhancing photocurrent production. Finally, we show that the addition of both FeCN and NADP+ to Ds has a synergistic effect enhancing the photocurrent beyond the effect of adding each mediator separately.
Highlights
In recent years, the increase in global pollution and the concern from climate change has led to extensive efforts to develop green energy technologies that have the potential to replace the use of fossil fuels
A different external electron transport (ExET) mechanism is based on mediated electron transport (MET) [3,4,19], which is performed by secretion of small metabolites that function as electron mediators between bacteria and the anode of an electrochemical cell
We show that NADPH which is the major endogenous mediator in cyanobacterial cells based bio-photo electrochemical cells (BPECs) is the major endogenous mediator in the microalgae DS
Summary
The increase in global pollution and the concern from climate change has led to extensive efforts to develop green energy technologies that have the potential to replace the use of fossil fuels. Multiple sources of electrons are potentially possible, depending on the method of cell preparation and the BPEC composition Another way for enhancement of the current that does not involve internalization of components by the cells can be done by utilization of an electrolyte with high salinity, which increases the conductivity of the system [28]. The anode of the BPEC functions as a driving force that enables their release [36] This EET mechanism was reported for several cyanobacterial species, it was not clear whether NADPH is the major electron mediator in microalgae, especially concerning the fact that to exit the cells, NADPH must first cross the chloroplast membrane that does not exist in cyanobacteria. We show that vitamin B1, can perform MET while its performance is like NADPH
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