Growth of non-phototrophic microorganisms using solar energy through mineral photocatalysis

Phototrophy and chemotrophy are two dominant modes of microbial metabolism. To date, non-phototrophic microorganisms have been excluded from the solar light-centered phototrophic metabolism. Here we report a pathway that demonstrates a role of light in non-phototrophic microbial activity. In lab sim...

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Bibliographic Details
Published in:Nature communications 2012-04, Vol.3 (1), p.768-768, Article 768
Main Authors: Lu, Anhuai, Li, Yan, Jin, Song, Wang, Xin, Wu, Xiao-Lei, Zeng, Cuiping, Ding, Hongrui, Hao, Ruixia, Lv, Ming, Wang, Changqiu, Tang, Yueqin, Dong, Hailiang
Format: Article
Language:English
Subjects:
631/326/41
639/638/439/890
Acidithiobacillus - growth & development
Acidithiobacillus - metabolism
Acidithiobacillus - radiation effects
Alcaligenes faecalis - growth & development
Alcaligenes faecalis - metabolism
Alcaligenes faecalis - radiation effects
Bacteria
Bacteria - growth & development
Bacteria - metabolism
Bacteria - radiation effects
Bioelectric Energy Sources
Biomass
Cell growth
Electrons
Geobiology
Humanities and Social Sciences
Light
Metabolism
Microorganisms
Minerals
Minerals - metabolism
multidisciplinary
Oxidation
Photocatalysis
Phototrophic Processes
Science
Science (multidisciplinary)
Solar Energy
Sunlight
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Summary:Phototrophy and chemotrophy are two dominant modes of microbial metabolism. To date, non-phototrophic microorganisms have been excluded from the solar light-centered phototrophic metabolism. Here we report a pathway that demonstrates a role of light in non-phototrophic microbial activity. In lab simulations, visible light-excited photoelectrons from metal oxide, metal sulfide, and iron oxide stimulated the growth of chemoautotrophic and heterotrophic bacteria. The measured bacterial growth was dependent on light wavelength and intensity, and the growth pattern matched the light absorption spectra of the minerals. The photon-to-biomass conversion efficiency was in the range of 0.13–1.90‰. Similar observations were obtained in a natural soil sample containing both bacteria and semiconducting minerals. Results from this study provide evidence for a newly identified, but possibly long-existing pathway, in which the metabolisms and growth of non-phototrophic bacteria can be stimulated by solar light through photocatalysis of semiconducting minerals. Microbial metabolism is usually considered to be phototrophic or chemotrophic. By showing that light-induced photoelectrons from metal oxide and metal sulfides can stimulate the growth of chemoautotrophic and heterotrophic bacteria, this study indicates that light may be involved in non-phototrophic microbial activity.
ISSN:2041-1723
2041-1723
DOI:10.1038/ncomms1768