RT Journal Article SR Electronic T1 In situ estimates of iron-oxidation and accretion rates for iron-oxidizing bacterial mats at Lō’ihi Seamount JF bioRxiv FD Cold Spring Harbor Laboratory SP 095414 DO 10.1101/095414 A1 David Emerson A1 Jarrod J. Scott A1 Anna Leavitt A1 Emily Fleming A1 Craig Moyer YR 2016 UL http://biorxiv.org/content/early/2016/12/19/095414.abstract AB It is increasingly recognized that diffuse, hydrothermal venting is an important source of iron to the deep-sea that can influence oceanic iron dynamics and abundance. Lithotrophic Fe-oxidizing bacteria (FeOB) are dominant at diffuse hydrothermal vent sites, producing microbial iron mats that are often centimeters or more thick. At present, little is known about in situ Fe-oxidation rates, or accretion rates for iron mats. An in situ productivity chamber was developed that took advantage of the unique mineral morphotypes produced by FeOB to estimate rates of Fe-oxidation and accretion. Chambers were placed at two diffuse vents (1179 and 1300 mbsl) at Lō’ihi Seamount where they were colonized by FeOB for different amounts of time. From this analysis, it was estimated that Fe-oxidation rates could range from 8.2–51.9 × 10−6 mol · hr−1, and that iron mats could accrete at around 2.2 cm · yr−1. Molecular analysis indicated that the relative abundance of Zetaproteobacteria, a group of known FeOB, accounted for 80–90% of the bacteria colonizing the chambers. There was a distinct difference between populations at the 1179m site (Pohaku), and the 1300m site (North Hiolo Ridge). Microscope slides placed within the productivity chambers were colonized by different morphotypes of FeOB. The cells responsible for one common morphotype that produces a Y-shaped filament were identified as Zetaproteobacteria by use of a small subunit rRNA probe. This work confirms the importance of FeOB in the formation of chemosynthetic iron mats, and provides the first estimates for in situ Fe-oxidation rates and mat accretion rates.HighlightsAn in-situ productivity chamber was developed to estimate rates of Fe-oxidation and understand colonization patterns at chemosynthetic iron mats at Lō’ihi Seamount.Fe-oxidation rates ranged from 8.2–51.9 × 10−6 mol ˙ hr−1, and it was estimated that the iron mats could accrete at around 2.2 cm ˙ yr−1.The iron mat community was dominated by Zetaproteobacteria, whose relative abundance accounted for up to 89% of the microbial community.The community membership that grew during short-term incubations reflected the community composition of nearby microbial mats.