AUTHOR=Jiang Jie , He Pengchen , Luo Ying , Peng Zhaofeng , Jiang Yongguang , Hu Yidan , Qi Lei , Dong Xiuzhu , Dong Yiran , Shi Liang 

TITLE=The varied roles of pilA-N, omcE, omcS, omcT, and omcZ in extracellular electron transfer by Geobacter sulfurreducens

JOURNAL=Frontiers in Microbiology

VOLUME=14

YEAR=2023

URL=https://www.frontiersin.org/journals/microbiology/articles/10.3389/fmicb.2023.1251346

DOI=10.3389/fmicb.2023.1251346

ISSN=1664-302X

ABSTRACT=<p><italic>Geobacter sulfurreducens</italic> mediates extracellular electron transfer (EET) reactions with different substrates, such as solid-phase Fe(III)-containing minerals, anodes and the cells of <italic>Geobacter metallireducens</italic>. To compare their roles in EET, the <italic>pilA-N, omcE</italic>, <italic>omcS</italic>, <italic>omcT</italic> and <italic>omcZ</italic> genes of <italic>G. sulfurreducens</italic> were systematically deleted. All mutants showed impaired and varied ability to form biofilms on nonconductive surface. Deletion of <italic>omcE</italic> also impaired bacterial ability to reduce ferrihydrite, but its impacts on the ability for anode reduction and the co-culture of <italic>G. metallireducens</italic>-<italic>G. sulfurreducens</italic> were minimal. The mutant without <italic>omcS</italic> showed diminished ability to reduce ferrihydrite and to form the co-culture, but was able to regain its ability to reduce anodes. Deletion of <italic>omcT</italic>, <italic>omcZ</italic> or <italic>pilA-N</italic> alone impaired bacterial ability to reduce ferrihydrite and anodes and to form the co-culture. Deletion of all tested genes abolished bacterial ability to reduce ferrihydrite and anodes. Triple-deletion of all <italic>omcS, omcT</italic> and <italic>omcZ</italic> abolished the ability of <italic>G. sulfurreducens</italic> to co-culture with <italic>G. metallireducens</italic>. However, deletion of only <italic>omcZ</italic> or <italic>pilA-N</italic> or both <italic>omcS</italic> and <italic>omcT</italic> abolished the ability of <italic>G. sulfurreducens</italic> without hydrogenase gene <italic>hybL</italic> to co-culture with <italic>G. metallireducens</italic>, which show their indispensable roles in direct electron transfer from <italic>G. metallireducens</italic> to <italic>G. sulfurreducens</italic>. Thus, the roles of <italic>pilA-N, omcE</italic>, <italic>omcS</italic>, <italic>omcT</italic> and <italic>omcZ</italic> for <italic>G. sulfurreducens</italic> in EET vary substantially, which also suggest that possession of PilA-N and multiple cytochromes of different structures enables <italic>G. sulfurreducens</italic> to mediate EET reactions efficiently with substrates of different properties.</p>