Production and diversity of microorganisms associated with sinking particles in the subtropical North Pacific Ocean

Church, Matthew J.; Kyi, Eint; Hall, Robert O.; Karl, David M.; Lindh, Markus V.; Nelson, Alexa; Wear, Emma K.

doi:10.1002/lno.11877

Cited by 15 publications

(15 citation statements)

References 85 publications

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“…It captures regional and seasonal variability in observed PSD properties, and demonstrates the ability of statistical machine learning methods to extrapolate these quantities globally. These global PSD reconstructions can in turn shed light on processes that depend on, or are reflected by, particle abundance and size distribution, including sinking particle fluxes (Guidi et al., 2008), aggregation, disaggregation and degradation of organic particles (Briggs et al., 2020; Burd & Jackson, 2009), interactions with microbial communities (Church et al., 2021; DeLong et al., 1993) and migrating animals (Cram et al., 2022), and chemical exchange between particles and seawater, including element scavenging (Ohnemus et al., 2019).…”

Section: Discussionmentioning

confidence: 99%

“…Particles can be remineralized by microbial degradation and grazing by zooplankton (Karl et al., 1988; Giering et al., 2014; Steinberg et al., 2008), aggregate and disaggregate following physical and biological interactions (Briggs et al., 2020; Burd & Jackson, 2009; Dilling & Alldredge, 2000; Jackson, 1990; Kiørboe et al., 1990), and sink out of the surface layers to transfer carbon and nutrients to the ocean interior (Boyd et al., 2019; Buesseler et al., 2007; Turner, 2015). Marine particles are hotspots of microbial activity and diversity (Church et al., 2021; DeLong et al., 1993; Karl et al., 1984), provide the bulk of energy that sustain mesopelagic and abyssal ecosystems (Burd et al., 2010; Giering et al., 2014), and eventually supply materials to the ocean sediment, where burial sequesters them for geological timescales (Dunne et al., 2007; Sarmiento & Gruber, 2006).…”

Section: Introductionmentioning

confidence: 99%

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Constraining the Particle Size Distribution of Large Marine Particles in the Global Ocean With In Situ Optical Observations and Supervised Learning

Clements

Yang

Weber

et al. 2022

Global Biogeochemical Cycles

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Constraining the Particle Size Distribution of Large Marine Particles in the Global Ocean With In Situ Optical Observations and Supervised Learning

Clements

Yang

Weber

et al. 2022

Global Biogeochemical Cycles

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“…The Flavobacteriaceae alone could account for up to 7.74% of the total prokaryotic community at station C9. Similarly, studies in other areas also showed that many taxa in Gammaproteobacteria and Flavobacteriales were dominant in the sinking community (Baumas et al., 2021; Church et al., 2021). Systematic assessment of individual prokaryotic lineage's contribution in carbon export is also warranted.…”

Section: Discussionmentioning

confidence: 79%

Sediment Trap Study Reveals Dominant Contribution of Metazoans and Dinoflagellates to Carbon Export and Dynamic Impacts of Microbes in a Subtropical Marginal Sea

Yuan

et al. 2022

JGR Biogeosciences

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Flux and efficiency of carbon export in the ocean has been widely studied using sediment traps, but due to limitations of traditional methods, differential contribution of different organisms is poorly understood. Here, we used DNA metabarcoding to document taxonomic composition for sediment traps deployed at a continental shelf (C6) and a continental slope (C9) site in the South China Sea. The results indicated that metazoans (mainly copepods) and dinoflagellates were the most dominant contributors overall, while dinoflagellates, diatoms, and haptophytes dominated the photosynthetic assemblage. For prokaryotes, Gammaproteobacteria dominated all samples. Furthermore, comparing the trap flora to overlying plankton revealed that metazoans and Polycystinea from Eukaryota and Gammaproteobacteria and Bacteroidetes from Prokaryota were enriched in the trap at both stations whereas haptophytes and Dinophyceae were consistently attenuated during sinking. In addition, Oceanospirillaceae and Rhodobacteraceae exhibited negative correlations with dinoflagellates, and based on overlying plankton metatranscriptomes, were most transcriptionally active lineages for metabolizing labile and semi‐labile organic carbon, potentially contributing to the Martin's decay of sinking particulate organic carbon. Using DNA and RNA sequencing technologies, this study provides novel insights into the lineage‐specific contribution and dynamic impacts of microbes to carbon export in a subtropical marginal sea.

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“…However, these large-scale models have not explicitly included microbial ecological dynamics. This is problematic as many of the aforementioned physical and chemical mechanisms shown to impact the vertical flux of POC are controlled by microbial and grazer dynamics 22 – 25 , 30 . For example, lability as represented by these models is inherently related to microbial activity (as we demonstrate below).…”

Section: Introductionmentioning

confidence: 99%

“…These micro-scale observations suggest that the rate of POC consumption in the ocean is highly variable and can vary as a function of microbial processes, in contrast to the conventional representation in carbon cycle models 45 , 46 , 53 , 57 , 58 . Therefore, to mechanistically understand the vertical flux of carbon in the ocean and generate robust predictions of future changes, we must account for particle-associated microbial behavior 22 , 24 , 59 , in addition to other dynamics such as particle size distribution and zooplankton activity.…”

Section: Introductionmentioning

confidence: 99%

Microbes contribute to setting the ocean carbon flux by altering the fate of sinking particulates

et al. 2022

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Sinking particulate organic carbon out of the surface ocean sequesters carbon on decadal to millennial timescales. Predicting the particulate carbon flux is therefore critical for understanding both global carbon cycling and the future climate. Microbes play a crucial role in particulate organic carbon degradation, but the impact of depth-dependent microbial dynamics on ocean-scale particulate carbon fluxes is poorly understood. Here we scale-up essential features of particle-associated microbial dynamics to understand the large-scale vertical carbon flux in the ocean. Our model provides mechanistic insight into the microbial contribution to the particulate organic carbon flux profile. We show that the enhanced transfer of carbon to depth can result from populations struggling to establish colonies on sinking particles due to diffusive nutrient loss, cell detachment, and mortality. These dynamics are controlled by the interaction between multiple biotic and abiotic factors. Accurately capturing particle-microbe interactions is essential for predicting variability in large-scale carbon cycling.

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Production and diversity of microorganisms associated with sinking particles in the subtropical North Pacific Ocean

Cited by 15 publications

References 85 publications

Constraining the Particle Size Distribution of Large Marine Particles in the Global Ocean With In Situ Optical Observations and Supervised Learning

Constraining the Particle Size Distribution of Large Marine Particles in the Global Ocean With In Situ Optical Observations and Supervised Learning

Sediment Trap Study Reveals Dominant Contribution of Metazoans and Dinoflagellates to Carbon Export and Dynamic Impacts of Microbes in a Subtropical Marginal Sea

Microbes contribute to setting the ocean carbon flux by altering the fate of sinking particulates

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