Planktonic marine iron oxidizers drive iron mineralization under low-oxygen conditions

Observations of modern microbes have led to several hypotheses on how microbes precipitated the extensive iron formations in the geologic record, but we have yet to resolve the exact microbial contributions. An initial hypothesis was that cyanobacteria produced oxygen which oxidized iron abiotically...

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Published inGeobiology Vol. 14; no. 5; pp. 499 - 508
Main Authors Field, E. K., Kato, S., Findlay, A. J., MacDonald, D. J., Chiu, B. K., Luther III, G. W., Chan, C. S.
Format Journal Article
LanguageEnglish
Published England Blackwell Publishing Ltd 01.09.2016
Wiley Subscription Services, Inc
Subjects
Cyanobacteria - metabolism
Geologic Sediments - chemistry
Iron Compounds - metabolism
Oxidation-Reduction
Oxygen - metabolism
Plankton - metabolism
Proteobacteria - metabolism
Seawater - microbiology
ANW, USA, Chesapeake Bay
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Summary:Observations of modern microbes have led to several hypotheses on how microbes precipitated the extensive iron formations in the geologic record, but we have yet to resolve the exact microbial contributions. An initial hypothesis was that cyanobacteria produced oxygen which oxidized iron abiotically; however, in modern environments such as microbial mats, where Fe(II) and O2 coexist, we commonly find microaerophilic chemolithotrophic iron‐oxidizing bacteria producing Fe(III) oxyhydroxides. This suggests that such iron oxidizers could have inhabited niches in ancient coastal oceans where Fe(II) and O2 coexisted, and therefore contributed to banded iron formations (BIFs) and other ferruginous deposits. However, there is currently little evidence for planktonic marine iron oxidizers in modern analogs. Here, we demonstrate successful cultivation of planktonic microaerophilic iron‐oxidizing Zetaproteobacteria from the Chesapeake Bay during seasonal stratification. Iron oxidizers were associated with low oxygen concentrations and active iron redox cycling in the oxic–anoxic transition zone (<3 μm O2, <0.2 μm H2S). While cyanobacteria were also detected in this transition zone, oxygen concentrations were too low to support significant rates of abiotic iron oxidation. Cyanobacteria may be providing oxygen for microaerophilic iron oxidation through a symbiotic relationship; at high Fe(II) levels, cyanobacteria would gain protection against Fe(II) toxicity. A Zetaproteobacteria isolate from this site oxidized iron at rates sufficient to account for deposition of geologic iron formations. In sum, our results suggest that once oxygenic photosynthesis evolved, microaerophilic chemolithotrophic iron oxidizers were likely important drivers of iron mineralization in ancient oceans.
Bibliography:National Science Foundation CAREER - No. EAR-1151682; No. NSF OCE-1155385
ArticleID:GBI12189
ark:/67375/WNG-J643KXDT-R
Data S1 Supporting methods for iron oxidation rate calculations and supporting discussion for cultivation of microaerophilic iron oxidizers. Fig. S1 Full sampling profiles of redox stratification and physical characteristics of the Chesapeake Bay water column in Pump Casts (a) IS4 and (b) IS8. Fig. S2 Microaerophilic chemolithotrophic iron-oxidizing bacteria (FeOB) enrichment culture positive for growth (star) was inoculated with water from the oxic-anoxic interface of the water column in Pump Cast IS8 sampling profile. Fig. S3 Filters (0.2 μm pore size) show collected particulates of varying colors and amounts with water depth from sampling profiles (a) Pump Cast IS4 and (b) CTD12. Fig. S4 Positive growth in (a) IS4-9.3 inoculated microaerophilic chemolithotrophic ironoxidizer enrichment culture. Fig. S5 Pump Cast IS4 (a) total cell numbers and (b) bacterial community structure changed with depth corresponding with changes in geochemistry of the water column. Fig. S6 Zetaproteobacteria Strain CP-8 growth curve and biotic Fe oxidation in gradient tubes (1% O2, pH 7.1, FeCO3). Fig. S7 Fe(II) oxidation rate experiment with Zetaproteobacteria strain CP-8 grown in gradient tubes. Table S1 Physical and geochemical parameters for Pump Cast IS4, CTD12, and Pump Cast IS8 sampling profile samples. Table S2 Percent 16S rRNA gene sequences from aerobic iron-oxidizer enrichments (EN) and phototroph enrichments (PH_EN) classified at the class level. Table S3 Number of Zetaproteobacteria 16S rRNA gene sequences from microaerophilic ironoxidizer enrichment cultures (EN) and phototroph enrichments (PH_EN) classified at the operational taxonomic unit (OTU) level. Table S4 Bacterial community structure (class level) of 16S rRNA gene sequences from in situ water samples collected in Pump Cast IS4 and CTD12 sampling profiles. Table S5 Iron oxidation and depositional rates by Zetaproteobacteria Strain CP-8.
NASA Exobiology Program - No. NNX12AG20G
istex:D02B0254898B93BD3E8E54154992176347393C04
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:1472-4677
1472-4669
DOI:10.1111/gbi.12189