The photic‐aphotic divide is a strong ecological and evolutionary force determining the distribution of ciliates (Alveolata, Ciliophora) in the ocean

Santoferrara, Luciana F.; Qureshi, Aleena; Sher, Amina; Blanco-Bercial, Leocadio

doi:10.1111/jeu.12976

Cited by 3 publications

(3 citation statements)

References 90 publications

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“…For example, Syndiniales composition varied by season (PERMANOVA R 2 = 0.2 and 0.11; P -value < 0.001) at depths in the photic zone (e.g., 1 and 120 m), while seasonal changes were not significant at deeper depths (e.g., 600 and 1000 m). Other 18S rRNA gene metabarcoding studies at this site [ 33 , 34 ] and in the North Pacific [ 17 ] have noted significant variability in protist composition and diversity with depth compared with weaker seasonal signals. Seasonality in the Sargasso Sea is characterized by deep convective mixing (~150–300 m) between January and March and stratification of the water column (mixed layer depth < 20 m) as early as May [ 32 ], driving seasonal patterns in phytoplankton, heterotrophic bacteria, and viruses [ 39–41 ].…”

Section: Resultsmentioning

confidence: 77%

“…Recent 18S rRNA gene metabarcoding work at BATS revealed a high relative abundance of Syndiniales (~40%) throughout the water column [ 33 ] and their presence in sediment traps [ 20 ]. Moreover, several studies at BATS [ 33 , 34 ], and in other oligotrophic systems [ 17 ], have observed significant shifts in protist diversity and composition with depth, with communities varying less over seasonal cycles. We performed covariance network analysis of a 4-year (2016–19) 18S rRNA gene metabarcoding dataset [ 33 ], constructing networks for each of 12 discrete depths (1–1000 m).…”

Section: Introductionmentioning

confidence: 99%

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Role of Syndiniales parasites in depth-specific networks and carbon flux in the oligotrophic ocean

Anderson,

Blanco-Bercial,

Carlson

et al. 2024

ISME Communications

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Microbial associations that result in phytoplankton mortality are important for carbon transport in the ocean. This includes parasitism, which in microbial food webs is dominated by the marine alveolate group, Syndiniales. Parasites are expected to contribute to carbon recycling via host lysis; however, knowledge on host dynamics and correlation to carbon export remain unclear and limit the inclusion of parasitism in biogeochemical models. We analyzed a 4-year 18S rRNA gene metabarcoding dataset (2016–2019), performing network analysis for twelve discrete depths (1–1000 m) to determine Syndiniales-host associations in the seasonally oligotrophic Sargasso Sea. Analogous water column and sediment trap data were included to define environmental drivers of Syndiniales and their correlation with particulate carbon flux (150 m). Syndiniales accounted for 48–74% of network edges, most often associated with Dinophyceae and Arthropoda (mainly copepods) at the surface and Rhizaria (Polycystinea, Acantharea, and RAD-B) in the aphotic zone. Syndiniales were the only eukaryote group to be significantly (and negatively) correlated with particulate carbon flux, indicating their contribution to flux attenuation via remineralization. Examination of Syndiniales amplicons revealed a range of depth patterns, including specific ecological niches and vertical connection among a subset (19%) of the community, the latter implying sinking of parasites (infected hosts or spores) on particles. Our findings elevate the critical role of Syndiniales in marine microbial systems and reveal their potential use as biomarkers for carbon export.

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Section: Resultsmentioning

confidence: 77%

Section: Introductionmentioning

confidence: 99%

Role of Syndiniales parasites in depth-specific networks and carbon flux in the oligotrophic ocean

Anderson,

Blanco-Bercial,

Carlson

et al. 2024

ISME Communications

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“…Surface water in the ECS is mainly mixed by the CDW, KSW, and TCWW, while the deeper layer is influenced by KSSW, Shelf Mixing Water (SMW), and TCWW by the Optimum Multiparameter analysis (Zhou et al, 2018). Ciliate community composition and diversity reported differ markedly with depth (Countway et al, 2010;Grattepanche et al, 2016a, b;Santoferrara et al, 2023;Tucker et al, 2017;Zhao et al, 2017;Wang et al, 2021a), water masses (Sun et al, 2020;Yang et al, 2020;Gu et al, 2021), and geographical position (inshore/offshore) (Grattepanche et al, 2015;Santoferrara et al, 2016;Grattepanche et al, 2016b). While Yang et al (2020) indicated that planktonic ciliates were potentially reliable indicators of water masses in the ECS, this was not universally consistent, possibly due to methodological differences in definitions of water masses or ciliate analysis approaches (Zhang et al, 2015).…”

Section: Hydrographic Conditions Shape Small-sized Ciliate Community ...mentioning

confidence: 99%

Diversity and distribution of small-sized planktonic ciliate communities in the East China Sea

Chen,

Lin,

Tsai

et al. 2024

Front. Mar. Sci.

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Ciliates are an important ecological component in the microbial food web, but few studies have been conducted on the spatial distribution of small-sized planktonic ciliate communities in the East China Sea (ECS). Investigating ciliate communities using conventional morphological approaches is particularly difficult for the small, fragile, and naked species. Therefore, we applied DNA metabarcoding analysis to explore the spatial pattern of small-sized planktonic ciliate community structure within the surface, deep chlorophyll maximum (DCM), and bottom layers. Results showed the cosmopolitan species, Leegaardiella sp., was dominant and widespread in the ECS. The relative abundance of the mixotrophic family Tontonnidae decreased in the deeper layer. We characterized water masses of the ECS using environmental variables. In nano-sized ciliate communities, non-metric multidimensional scaling (NMDS) plots revealed a correlation with temperature, salinity, density, and depth. The circulation patterns were similar to cluster analysis results, suggesting that hydrographic conditions shaped small-sized ciliate community composition.

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Syndiniales parasites drive species networks and are a biomarker for carbon export in the oligotrophic ocean

Anderson

Blanco-Bercial

Carlson

et al. 2023

Preprint

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Microbial associations that result in phytoplankton mortality are important for carbon transport in the ocean. This includes parasitism, which in microbial food webs, is dominated by the marine alveolate group, Syndiniales. Parasites are expected to contribute to carbon recycling via host lysis; however, knowledge on host dynamics and correlation to carbon export remain unclear and limit the inclusion of parasitism in biogeochemical models. We analyzed a 4-year 18S rRNA metabarcoding dataset (2016-2019), performing network analysis for twelve discrete depths (1-1000 m) to determine Syndiniales-host associations in the seasonally oligotrophic Sargasso Sea. Analogous water column and sediment trap data were included to define environmental drivers of Syndiniales and their correlation with particulate carbon flux (150 m). Syndiniales accounted for 48-74% of network edges, most often associated with Dinophyceae and Arthropoda (mainly copepods) at the surface and Rhizaria (Polycystinea, Acantharea, and RAD-B) in the aphotic zone. Unlike other major groups, Syndiniales were significantly (and negatively) correlated with particulate carbon flux, suggesting parasites may drive flux attenuation through remineralization. Examination of Syndiniales amplicons revealed a range of depth patterns, including specific ecological niches and vertical connection among a subset (19%) of the community, the latter implying sinking of parasites (infected hosts or spores) on particles. Our findings point to the use of Syndiniales as biomarkers of carbon export, highlighting their importance for marine food webs and biogeochemistry.

show abstract

The photic‐aphotic divide is a strong ecological and evolutionary force determining the distribution of ciliates (Alveolata, Ciliophora) in the ocean

Cited by 3 publications

References 90 publications

Role of Syndiniales parasites in depth-specific networks and carbon flux in the oligotrophic ocean

Role of Syndiniales parasites in depth-specific networks and carbon flux in the oligotrophic ocean

Diversity and distribution of small-sized planktonic ciliate communities in the East China Sea

Syndiniales parasites drive species networks and are a biomarker for carbon export in the oligotrophic ocean

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