Abstract
Microbial iron cycling influences the flux of major nutrients in the environment (e.g., through the adsorptive capacity of iron oxides) and includes biotically induced iron oxidation and reduction processes. The ecological extent of microbial iron cycling is not well understood, even with increased sequencing efforts, in part due to limitations in gene annotation pipelines and limitations in experimental studies linking phenotype to genotype. This is particularly true for the marine subseafloor, which remains undersampled, but represents the largest contiguous habitat on Earth. To address this limitation, we used FeGenie, a database and bioinformatics tool that identifies microbial iron cycling genes and enables the development of testable hypotheses on the biogeochemical cycling of iron. Herein, we survey the microbial iron cycle in diverse subseafloor habitats, including sediment-buried crustal aquifers, as well as surficial and deep sediments. We inferred the genetic potential for iron redox cycling in 32 of the 46 metagenomes included in our analysis, demonstrating the prevalence of these activities across underexplored subseafloor ecosystems. We show that while some processes (e.g., iron uptake and storage, siderophore transport potential, and iron gene regulation) are near-universal, others (e.g., iron reduction/oxidation, siderophore synthesis, and magnetosome formation) are dependent on local redox and nutrient status. Additionally, we detected niche-specific differences in strategies used for dissimilatory iron reduction, suggesting that geochemical constraints likely play an important role in dictating the dominant mechanisms for iron cycling. Overall, our survey advances the known distribution, magnitude, and potential ecological impact of microbe-mediated iron cycling and utilization in sub-benthic ecosystems.
Highlights
Iron is the dominant redox-active element in the Earth’s crust and an important nutrient for almost all known life
Et al (2018) reconstructed metagenomeassembled genomes (MAGs) affiliated with the iron-oxidizing Zetaproteobacteria, which are known to adapt to fluctuating O2 concentrations and advective flow regimes (Chiu et al, 2017; Blackwell et al, 2020), further solidifying the presence and significant contribution that iron-oxidizing bacteria make to the aquifer community
Our survey of 18 metagenome assemblies from the North Pond crustal aquifer (Tully et al, 2018) using the FeGenie library confirmed the presence of previously reported iron oxidases (Figure 1) (Tully et al, 2018; Seyler et al, 2020), which we phylogenetically linked to Zetaproteobacteria and Rhodospirillaceae (Supplementary File 2)
Summary
Iron is the dominant redox-active element in the Earth’s crust and an important nutrient for almost all known life. The extent of information that can be gained from metagenomes or metagenome-assembled genomes (MAGs), derived from shotgun sequencing, in relation to the potential for microbial iron redox cycling in the environment remains poorly constrained. This is true of the marine subsurface, an extremely remote and difficult to access/sample environment, that is significantly influenced by microbe-mineral interactions, those related to iron oxidation and reduction (Edwards et al, 2003a; Roden, 2012)
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