Free‐living chemoautotrophic and particle‐attached heterotrophic prokaryotes dominate microbial assemblages along a pelagic redox gradient

Suter, Elizabeth A.; Pachiadaki, Maria; Taylor, Gordon T.; Astor, Yrene; Edgcomb, Virginia P.

doi:10.1111/1462-2920.13997

Cited by 46 publications

(114 citation statements)

References 113 publications

(180 reference statements)

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“…Most of the sulfide, ammonium, and methane input into the system (i.e., via diffusion or in situ production) can be attributed to diffusion from the bottom boundary (91%, 95%, and 97%, respectively), potentially produced near or in the underlying sediments. Our estimates suggest that some hydrogen sulfide is also produced within the water column (depths ∼600–900 m), consistent with the previous detection of sulfate‐reducing bacteria in sinking particles at anoxic depths (Suter et al, ), although some of the apparent sulfide sources may actually be sulfide diffusing out of the sediments on the basin's side walls. The contribution of in situ sulfide sources to overall sulfide fluxes into the redoxcline is relatively small (∼10%) and has decreased in the latter years, based on the estimated ratio of in situ produced versus in situ consumed sulfide.…”

Section: Resultssupporting

confidence: 90%

“…Given that sulfide oxidation spatially overlaps substantially with nitrate consumption (Figure c), it is probable that nitrate is at least partly used as a terminal electron acceptor for the oxidation of various sulfur compounds, a process observed in other oxygen‐depleted regions of the ocean (Canfield et al, ; Louca et al, ; Rogge et al, ; Schunck et al, ). Indeed, the Gammaproteobacterial clades BS‐GSO2 and SUP05, members of which are frequently implicated in sulfide oxidation and denitrification in oxygen‐poor marine systems (Fuchsman, Murray, & Staley, ; Glaubitz, Kießlich, Meeske, Labrenz, & Jürgens, ; Lavik et al, ; Rogge et al, ; Shah, Chang, & Morris, ; Walsh et al, ), have been observed at high relative abundances in the Cariaco Basin redoxcline (Rodriguez‐Mora et al, ; Suter et al, ; Taylor et al, ).…”

Section: Resultsmentioning

confidence: 99%

“…These data revealed the existence of a strong dynamic redox gradient over depth, along which upward diffusing reductants such as hydrogen sulfide are directly or indirectly oxidized by oxidants such as oxygen in a transition zone roughly spanning depths 200–400 m, sometimes referred to as “redoxcline” (Ho et al, ; Li, Taylor, Astor, Varela, & Scranton, ; Taylor et al, ). Concurrent molecular surveys revealed unique microbial communities that exhibit a clear spatial organization across depth, and elevated population densities within the redoxcline (Cernadas‐Martín, Suter, Scranton, Astor, & Taylor, ; Rodriguez‐Mora, Scranton, Taylor, & Chistoserdov, ; Suter, Pachiadaki, Taylor, Astor, & Edgcomb, ; Taylor et al, , ). However, chemical fluxes across space and microbial metabolic rates in Cariaco Basin and other anoxic regions remain poorly quantified and are largely temporally unresolved, thus making a mechanistic connection between chemical transitions and microbial ecological dynamics difficult (Taylor et al, ).…”

Section: Introductionmentioning

confidence: 99%

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Microbial metabolite fluxes in a model marine anoxic ecosystem

et al. 2019

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Permanently anoxic regions in the ocean are widespread and exhibit unique microbial metabolic activity exerting substantial influence on global elemental cycles and climate. Reconstructing microbial metabolic activity rates in these regions has been challenging, due to the technical difficulty of direct rate measurements. In Cariaco Basin, which is the largest permanently anoxic marine basin and an important model system for geobiology, long‐term monitoring has yielded time series for the concentrations of biologically important compounds; however, the underlying metabolite fluxes remain poorly quantified. Here, we present a computational approach for reconstructing vertical fluxes and in situ net production/consumption rates from chemical concentration data, based on a 1‐dimensional time‐dependent diffusive transport model that includes adaptive penalization of overfitting. We use this approach to estimate spatiotemporally resolved fluxes of oxygen, nitrate, hydrogen sulfide, ammonium, methane, and phosphate within the sub‐euphotic Cariaco Basin water column (depths 150–900 m, years 2001–2014) and to identify hotspots of microbial chemolithotrophic activity. Predictions of the fitted models are in excellent agreement with the data and substantially expand our knowledge of the geobiology in Cariaco Basin. In particular, we find that the diffusivity, and consequently fluxes of major reductants such as hydrogen sulfide, and methane, is about two orders of magnitude greater than previously estimated, thus resolving a long‐standing apparent conundrum between electron donor fluxes and measured dark carbon assimilation rates.

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Section: Resultssupporting

confidence: 90%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Microbial metabolite fluxes in a model marine anoxic ecosystem

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“…Putative γ‐proteobacteria S‐oxidizers (GSO) dominating the shallow anoxic and euxinic depths were represented by the SUP05 clade and a single OTU in the Ectothiorhodospiraceae family, closely matching an uncultured Thiorhodospira sp. (Suter et al, ). Related GSOs dominate redoxclines of other oxygen‐depleted environments, such as the Black Sea (Fuchsman et al, ), Baltic Sea (Glaubitz et al, ), shelf water on the Namibian coast (Lavik et al, ), Saanich Inlet (Walsh et al, ), and the Pacific Ocean OMZs (Stewart et al, ).…”

Section: Introductionmentioning

confidence: 99%

“…As in many other stratified oxygen-depleted water columns, chemoautotrophic assemblages across the Cariaco's redox transitional zone are comprised of ammonia-oxidizing, nitrite-oxidizing, anaerobic ammonia-oxidizing (anammox), and reduced sulfur-oxidizing microorganisms (Cernadas-Martin et al, 2017;Montes et al, 2013;Suter et al, 2018;Taylor et al, 2001;Wakeham et al, 2012). During the present study's timeframe (2013)(2014)(2015)(2016)(2017), ammonia-oxidizing archaea in marine group I, ammonia-oxidizing betaand γ-proteobacteria, and nitrite-oxidizing Nitrospina (δ-proteobacteria) have been observed across the oxycline (Cernadas-Martin et al, 2017;Suter et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Anomalous δ¹³C in Particulate Organic Carbon at the Chemoautotrophy Maximum in the Cariaco Basin

et al. 2020

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A chemoautotrophy maximum is present in many anoxic basins at the sulfidic layer's upper boundary, but the factors controlling this feature are poorly understood. In 13 of 31 cruises to the Cariaco Basin, particulate organic carbon (POC) was enriched in 13C (δ13CPOC as high as −16‰) within the oxic/sulfidic transition compared to photic zone values (−23 to −26‰). During “heavy” cruises, fluxes of O2 and [NO3− + NO2−] to the oxic/sulfidic interface were significantly lower than during “light” cruises. Cruises with isotopically heavy POC were more common between 2013 and 2015 when suspended particles below the photic zone tended to be nitrogen rich compared to later cruises. Within the chemoautotrophic layer, nitrogen‐rich particles (molar ratio C/N< 10) were more likely to be 13C‐enriched than nitrogen‐poor particles, implying that these inventories were dominated by living cells and fresh detritus rather than laterally transported or extensively decomposed detritus. During heavy cruises, 13C enrichments persisted to 1,300 m, providing the first evidence of downward transport of chemoautotrophically produced POC. Dissolved inorganic carbon assimilation during heavy cruises (n = 3) was faster and occurred deeper than during light cruises (n = 2). Metagenomics data from the chemoautotrophic layer during two cruises support prevalence of microorganisms carrying RuBisCO form II genes, which encode a carbon fixation enzyme that discriminates less against heavy isotopes than most other carbon fixation enzymes, and metatranscriptomics data indicate that higher expression of form II RuBisCO genes during the heavy cruises at depths where essential reactants coexist are responsible for the isotopically heavier POC.

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Patterns and processes of free‐living and particle‐associated bacterioplankton and archaeaplankton communities in a subtropical river‐bay system in South China

Wang

Pan

Yang

et al. 2019

Limnology & Oceanography

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Free‐living and particle‐associated microbial communities play critical roles in nutrient cycles in aquatic systems. However, little is known about their assembly process, function, and interactions. Here, by using 16S rRNA gene amplicon sequencing of size‐fractionated samples collected during the wet and dry seasons, we investigated the assembly processes and co‐occurrence patterns of bacterial and archaeal communities in the Shenzhen River‐Bay system, South China. The bacterial and archaeal communities showed specific distribution patterns according to the size fraction (free‐living vs. particle‐associated), habitat (river vs. estuary), and seasonality (wet vs. dry season). Neutral modeling revealed that the stochastic pattern was more pronounced for bacteria than archaea, although both deterministic and stochastic processes significantly influenced the assembly of bacterial and archaeal communities. Homogeneous selection had a relatively higher importance in structuring bacterioplankton in free‐living fractions, while this process was more important in structuring archaeaplankton in particle‐associated fractions. Aquatic microbial community composition and assembly processes were most strongly associated with salinity and water temperature. Network analysis for each size fraction of the plankton revealed higher connectivity in the particle‐associated communities than the free‐living communities for intra‐bacteria, inter‐bacteria/archaea, and intra‐archaea associations, accordingly, when nonlinear associations were considered. These findings expand the current understanding of the ecological mechanisms and Archaea‐Bacteria interactions, underlying the size‐fractionated plankton dynamics in the river‐bay system.

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Free‐living chemoautotrophic and particle‐attached heterotrophic prokaryotes dominate microbial assemblages along a pelagic redox gradient

Cited by 46 publications

References 113 publications

Microbial metabolite fluxes in a model marine anoxic ecosystem

Microbial metabolite fluxes in a model marine anoxic ecosystem

Anomalous δ¹³C in Particulate Organic Carbon at the Chemoautotrophy Maximum in the Cariaco Basin

Patterns and processes of free‐living and particle‐associated bacterioplankton and archaeaplankton communities in a subtropical river‐bay system in South China

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Free‐living chemoautotrophic and particle‐attached heterotrophic prokaryotes dominate microbial assemblages along a pelagic redox gradient

Cited by 46 publications

References 113 publications

Microbial metabolite fluxes in a model marine anoxic ecosystem

Microbial metabolite fluxes in a model marine anoxic ecosystem

Anomalous δ13C in Particulate Organic Carbon at the Chemoautotrophy Maximum in the Cariaco Basin

Patterns and processes of free‐living and particle‐associated bacterioplankton and archaeaplankton communities in a subtropical river‐bay system in South China

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Anomalous δ¹³C in Particulate Organic Carbon at the Chemoautotrophy Maximum in the Cariaco Basin