Microbial planktonic communities in the Red Sea: high levels of spatial and temporal variability shaped by nutrient availability and turbulence

Pearman, John K.; Ellis, Joanne I.; Irigoien, Xabier; Sarma, Y.V.B.; Jones, Burton H.; Carvalho, Susana

doi:10.1038/s41598-017-06928-z

Cited by 58 publications

(51 citation statements)

References 103 publications

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“…Further detail of the environmental conditions and microbial communities present at the Indian Ocean stations is given by Mazard and colleagues (), Bird and colleagues (), Zubkov and colleagues () and Wyman and colleagues (). For an overview of the conditions and the microbial communities characteristic of the mid‐Atlantic Ocean in late summer/autumn, see Schattenhofer and colleagues () and Rees and colleagues (), and for the Gulf of Aqaba and wider Red Sea, see Rahav and colleagues () and Pearman and colleagues ().…”

Section: Resultsmentioning

confidence: 99%

A denitrifying community associated with a major, marine nitrogen fixer

Coates

Wyman

2017

Environmental Microbiology

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SummaryThe diazotrophic cyanobacterium, Trichodesmium, is an integral component of the marine nitrogen cycle and contributes significant amounts of new nitrogen to oligotrophic, tropical/subtropical ocean surface waters. Trichodesmium forms macroscopic, fusiform (tufts), spherical (puffs) and raft-like colonies that provide a pseudobenthic habitat for a host of other organisms including marine invertebrates, microeukaryotes and numerous other microbes. The diversity and activity of denitrifying bacteria found in association with the colonies was interrogated using a series of molecular-based methodologies targeting the gene encoding the terminal step in the denitrification pathway, nitrous oxide reductase (nosZ). Trichodesmium spp. sampled from geographically isolated ocean provinces (the Atlantic Ocean, the Red Sea and the Indian Ocean) were shown to harbor highly similar, taxonomically related communities of denitrifiers whose members are affiliated with the Roseobacter clade within the Rhodobacteraceae (Alphaproteobacteria). These organisms were actively expressing nosZ in samples taken from the mid-Atlantic Ocean and Red Sea implying that Trichodesmium colonies are potential sites of nitrous oxide consumption and perhaps earlier steps in the denitrification pathway also. It is proposed that coupled nitrification of newly fixed N is the most likely source of nitrogen oxides supporting nitrous oxide cycling within Trichodesmium colonies.

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Section: Resultsmentioning

confidence: 99%

A denitrifying community associated with a major, marine nitrogen fixer

Coates

Wyman

2017

Environmental Microbiology

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“…The Red Sea presents a unique combination of environmental variables that have previously been shown to shape the planktonic community (Kürten et al, , ; Ngugi, Antunes, Brune, & Stingl, ; Pearman et al, ; Pearman, Kurten, Sarma, Jones, & Carvalho, ) and the metazoan component of the reef cryptobiome (Carvalho et al, ). However, knowledge of the factors structuring the composition and function of bacterial communities within coral reefs remains limited (Roik et al, ; Neave et al, ).…”

Section: Discussionmentioning

confidence: 99%

Disentangling the complex microbial community of coral reefs using standardized Autonomous Reef Monitoring Structures (ARMS)

et al. 2019

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Autonomous Reef Monitoring Structures (ARMS) have been applied worldwide to describe eukaryotic cryptic reef fauna. Conversely, bacterial communities, which are critical components of coral reef ecosystem functioning, remain largely overlooked. Here we deployed 56 ARMS across the 2,000‐km spread of the Red Sea to assay biodiversity, composition and inferred underlying functions of coral reef‐associated bacterial communities via 16S rRNA gene sequencing. We found that bacterial community structure and diversity aligned with environmental differences. Indeed, sea surface temperature and macroalgae cover were key in explaining bacterial relative abundance. Importantly, taxonomic and functional alpha diversity decreased under more extreme environmental conditions (e.g., higher temperatures) in the southern Red Sea. This may imply a link between bacterial community diversity and functional capabilities, with implications for conservation management. Our study demonstrates the utility of ARMS to investigate the response of coral reef‐associated bacterial communities to environmental change.

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“…Our results also revealed a consistent coupling between the diel dynamics of DOC sources and the changes in the size structure and composition of HP communities, at both the epipelagic and the mesopelagic layer of the sampled water column (0-700 m). As in its northern reaches, the central Red Sea is characterized by high salinity ($ 39.0) (Ngugi et al, 2012), low inorganic nutrients (Kürten et al, 2016) and relatively high water temperatures (24 C-32 C) in the epipelagic layer, and low oxygen concentrations in the mesopelagic layer (< 1 mg l −1 or < 9.2% AE 1.1% temperature corrected oxygen saturation) (Qian et al, 2011;Pearman et al, 2017). Similar to other oligotrophic regions, the Red Sea is frequently assumed to remain invariable for periods of weeks, however, it experiences its main seasonal phytoplankton bloom in epipelagic waters during winter (Calbet Although not yet explored for the Red Sea, phytoplankton temporal changes may affect HP distribution in the surface layer as reported elsewhere (Nagata, 2000;Lefort and Gasol, 2014).…”

Section: Discussionmentioning

confidence: 99%

“…There is evidence that the more active HP taxa are usually found in the HNA group (Schattenhofer et al, 2011;Vila-Costa et al, 2012) while LNA cells are known to include mostly oligotrophic taxa, such as the SAR11 clade (Hill et al, 2010;Schattenhofer et al, 2011;Vila-Costa et al, 2012). It has been reported that SAR11 represents the dominant HP group across the Red Sea, contributing approximating 60% to the HP community abundance at the surface (Ngugi et al, 2012, Pearman et al, 2017. Here, we found some evidences of a higher contribution of LNA cells in the epipelagic layer than in the mesopelagic layer, especially during day-time ( Fig.…”

Section: Discussionmentioning

confidence: 99%

Diel dynamics and coupling of heterotrophic prokaryotes and dissolved organic matter in epipelagic and mesopelagic waters of the central Red Sea

García

Calleja

Al-Otaibi

et al. 2018

Environmental Microbiology

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The ecological status of an ecosystem can be approached by the taxa present but also by the size of individual organisms. In aquatic ecosystems, flow cytometry (FC) allows to study the individual size spectra and broad community composition through the evaluation of cytometric categories. The Red Sea represents a warm oligotrophic environment with a strong diel signal of vertically migrating mesopelagic fish, which feed at night at the surface and release dissolved organic carbon (DOC) at depth during day-time. However, knowledge about how these conditions affect the dynamics of heterotrophic prokaryotes (HP) and their coupling with DOC is lacking. Here, we analyzed a high frequency sampling over 24 h to identify the community structure and compositional changes of HP in the epipelagic and mesopelagic layers of the central Red Sea. Our results show marked vertical and diel changes in HP communities in both layers. Specifically, the relative contribution of high nucleic acid content cells was remarkably linked to changes in DOC concentration and properties. The patterns observed were likely associated to the diel vertical migration of mesopelagic fish. These findings reveal that the structure of microbial communities in warm oligotrophic environments may be more dynamic than previously thought.

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Microbial planktonic communities in the Red Sea: high levels of spatial and temporal variability shaped by nutrient availability and turbulence

Cited by 58 publications

References 103 publications

A denitrifying community associated with a major, marine nitrogen fixer

A denitrifying community associated with a major, marine nitrogen fixer

Disentangling the complex microbial community of coral reefs using standardized Autonomous Reef Monitoring Structures (ARMS)

Diel dynamics and coupling of heterotrophic prokaryotes and dissolved organic matter in epipelagic and mesopelagic waters of the central Red Sea

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