Photoelectron Shaping Marine Microbial Compositional and Metabolic Variation in the Photic Zone Around Estuary and Offshore Area of Yellow Sea, China,Geomicrobiology Journal

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Photoelectron Shaping Marine Microbial Compositional and Metabolic Variation in the Photic Zone Around Estuary and Offshore Area of Yellow Sea, China
Geomicrobiology Journal ( IF 2.2 ) Pub Date : 2020-05-19 , DOI: 10.1080/01490451.2020.1764673
Ying Liu ₁ , Yuan Sun ₁ , Hongrui Ding ₁ , Guiping Ren ₁ , Anhuai Lu ₁ , Yan Li ₁

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Abstract The photoelectrochemical characteristic of semiconducting minerals plays an imperative role in supporting the growth of many electroactive microorganisms. In order to study the effects of photoelectrons triggered from semiconducting mineral by solar energy on the marine microbial growth, metabolism, and community structure, a dual-chamber electrochemical system was established by incubating seawater microbial community with varying simulated electrochemical conditions. The absolute quantifications of 16S rRNA and 18S rRNA genes suggested that photoelectrons could support the growth and reproduction of bacteria with an increase of two magnitudes from 1.34 ± 0.76 × 1012 to 1.41 ± 0.93 × 1014, and archaea with a slight increase from 0.50–8.74 × 1011 to 2.37–14.80 × 1011, whereas not for the growth of eukaryote in consideration of the complicated regulating mechanism of eukaryotic cells. The bacterial and archaeal communities were shaped by the supplement of photoelectron, also not for the eukaryotic community. Proteobacteria, Bacteroidetes, Firmicutes, and Actinobacteria accounted for over 80% of the total bacterial community. Photoelectrons with appropriate energy could stimulate the diversity and maintain the community structure of bacteria and archaea while lower or higher electric potential caused lower diversity and more divergent microbial assemblages. The abundance of genes related to the electron transport chain was significantly higher in photoelectron regulated setups than that in open circuit ones, indicating that the extracellular photoelectrons experienced the transmembrane transition and entered the bacterial electron transport chain coupling cell anabolism and catabolism. This study proposed the potential impact of photoelectrons produced by semiconducting minerals on marine microorganisms and the putative electron flow under sunlight in the natural environments.

更新日期：2020-05-19

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