Heterotrophic Foraminifera Capable of Inorganic Nitrogen Assimilation

Emmanuelle Geslin, Charlotte Madeleine Nicole Lekieffre, Anders Meibom
FRONTIERS MEDIA SA, 2020
Article

Résumé

Nitrogen availability often limits biological productivity in marine systems, where inorganic nitrogen, such as ammonium is assimilated into the food web by bacteria and photoautotrophic eukaryotes. Recently, ammonium assimilation was observed in kleptoplast-containing protists of the phylum foraminifera, possibly via the glutamine synthetase/glutamate synthase (GS/GOGAT) assimilation pathway imported with the kleptoplasts. However, it is not known if the ubiquitous and diverse heterotrophic protists have an innate ability for ammonium assimilation. Using stable isotope incubations (N-15-ammonium and C-13-bicarbonate) and combining transmission electron microscopy (TEM) with quantitative nanoscale secondary ion mass spectrometry (NanoSIMS) imaging, we investigated the uptake and assimilation of dissolved inorganic ammonium by two heterotrophic foraminifera; a non-kleptoplastic benthic species, Ammonia sp., and a planktonic species, Globigerina bulloides. These species are heterotrophic and not capable of photosynthesis. Accordingly, they did not assimilate C-13-bicarbonate. However, both species assimilated dissolved N-15-ammonium and incorporated it into organelles of direct importance for ontogenetic growth and development of the cell. These observations demonstrate that at least some heterotrophic protists have an innate cellular mechanism for inorganic ammonium assimilation, highlighting a newly discovered pathway for dissolved inorganic nitrogen (DIN) assimilation within the marine microbial loop.

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https://infoscience.epfl.ch/record/282467?ln=fr

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Emmanuelle Geslin, Charlotte Madeleine Nicole Lekieffre, Anders Meibom
FRONTIERS MEDIA SA, 2020
Article

Résumé

Official source

https://infoscience.epfl.ch/record/282467?ln=fr

À propos de ce résultat

Concepts associés (16)

Concepts associés

Chargement

Publications associées (38)

Publications associées

Chargement

Ammonium is the preferred source of nitrogen for planktonic foraminifer and their dinoflagellate symbionts

Emmanuelle Geslin, Charlotte Madeleine Nicole Lekieffre, Anders Meibom

The symbiotic planktonic foraminiferaOrbulina universainhabits open ocean oligotrophic ecosystems where dissolved nutrients are scarce and often limit biological productivity. It has previously been proposed thatO. universameets its nitrogen (N) requirements by preying on zooplankton, and that its symbiotic dinoflagellates recycle metabolic 'waste ammonium' for their N pool. However, these conclusions were derived from bulk(15)N-enrichment experiments and model calculations, and our understanding of N assimilation and exchange between the foraminifer host cell and its symbiotic dinoflagellates remains poorly constrained. Here, we present data from pulse-chase experiments with(13)C-enriched inorganic carbon,N-15-nitrate, and(15)N-ammonium, as well as a(13)C- and(15)N- enriched heterotrophic food source, followed by TEM (transmission electron microscopy) coupled to NanoSIMS (nanoscale secondary ion mass spectrometry) isotopic imaging to visualize and quantify C and N assimilation and translocation in the symbiotic system. High levels of(15)N-labelling were observed in the dinoflagellates and in foraminiferal organelles and cytoplasm after incubation with(15)N-ammonium, indicating efficient ammonium assimilation. Only weak(15)N-assimilation was observed after incubation with(15)N-nitrate. Feeding foraminifers with(13)C- and(15)N-labelled food resulted in dinoflagellates that were labelled with(15)N, thereby confirming the transfer of(15)N-compounds from the digestive vacuoles of the foraminifer to the symbiotic dinoflagellates, likely through recycling of ammonium. These observations are important for N isotope-based palaeoceanographic reconstructions, as they show that delta N-15 values recorded in the organic matrix in symbiotic species likely reflect ammonium recycling rather than alternative N sources, such as nitrates.

ROYAL SOC2020

Chargement

, ,

Low-oxygenation events are more and more frequent and strong on continental shelves and in coastal areas where renewal of bottom waters is slow. Among the meiofauna living in such environments, foraminifera are among the most tolerant to the lack of oxygen. Some benthic foraminiferal species are able to survive hypoxia, and even anoxia, for weeks to months. Different species must have developed different mechanisms for survival - hypotheses include reduction of the metabolism, symbiosis with bacteria, or denitrification. Ammonia tepida, one of the most abundant species in intertidal environments, is able to survive up to 60 days in anoxia. Here we combined a 4 week feeding experiment using 13C-enriched microalgae (diatoms), with correlated transmission electron microscopy (TEM) and NanoSIMS (Secondary Ion Mass Spectrometry) imaging, and concentrations (GC/MS, GC/FFID), as well as bulk and compound specific carbon isotope ratios (13C/12C obtained by EA/IRMS and GC/C/IRMS) of individual fatty acids (FAs) to study the metabolic differences in intertidal Ammonia tepida exposed to oxic and anoxia conditions, respectively. Strongly contrasting cellular-level dynamics of integration and transfer of the ingested biofilm components were observed under the two conditions. Under oxic conditions, within a few days, intact diatoms (i.e. including the frustule) were ingested, assimilated and consumed, in part for biosynthesis of different cellular components: 13C-labeled lipid droplets formed over a timescale of a few days and were then partly lost through respiration. In contrast, in anoxia, fewer diatoms were initially ingested and these were not assimilated or metabolized further, but remained visible within the foraminiferal cytoplasm even after 4 weeks. The compound specific 13C/12C ratios indicated substantial de novo synthesis by the foraminifera of polyunsaturated FAs (PUFAs), such as 20:4(n-6), in oxic conditions; very limited PUFA synthesis was observed under anoxia. Together, our results indicate that anoxia induced a greatly reduced rate of heterotrophic metabolism in Ammonia tepida on a time scale of about 24 hours, which seems consistent with a state of dormancy.

2016

Chargement

Kleptoplastidic benthic foraminifera from aphotic habitats: Assimilation (or not) of inorganic C, N, and S studied at sub-cellular resolution

Emmanuelle Geslin, Charlotte Madeleine Nicole Lekieffre, Anders Meibom

The assimilation of inorganic compounds and their role in the foraminiferal metabolism compared to predation or organic matter assimilation is unknown. Here we investigate these processes with a study of the species Nonionellina labradorica (Dawson, 1860), a common kleptoplastic benthic foraminifer from Arctic and North Atlantic sublittoral regions, including aphotic zones of the Gullmar Fjord (Sweden). The objectives of this work were to (1) identify the origin of N. labradorica kleptoplasts, (2) assess their photosynthetic functionality for both oxygen production and conversion of inorganic carbon into photosynthates, and (3) investigate inorganic nitrogen and sulfate assimilation by N. labradorica. We used DNA barcoding to identify the origin of N. labradorica kleptoplasts and transmission electron microscope (TEM) imaging, correlated with nanometer-scale secondary ion mass spectrometry (NanoSIMS) isotopic imaging, to study 13C-bicarbonate, 15N-ammonium, and 34S-sulfate uptake. In addition, respiration rate measurements were determined to assess N. labradorica response to light. The partial 18S and 16S rDNA sequencing established that the kleptoplasts belonged to two species of Thalassiosira, a cosmopolitan planktonic diatom genus. TEM-NanoSIMS imaging revealed degraded cytoplasm in specimens exposed to light for 20 h and a complete absence of 13C assimilation. Oxygen measurements showed higher respiration rates under light than dark conditions, and no O2 production was detected. These combined results indicate that the photosynthetic pathways in N. labradorica are not functional. Under dark conditions, N. labradorica assimilated both 15N-ammonium and 34S-sulfate into its cytoplasm. Light exposure negatively impacted foraminiferal metabolism, ultimately causing specimen death. Our results suggest that foraminifera might have several ammonium or sulfate assimilation pathways, involving either the kleptoplasts or bona fide foraminiferal pathway(s) not yet identified.

2018

Chargement

Ammonium is the preferred source of nitrogen for planktonic foraminifer and their dinoflagellate symbionts

Emmanuelle Geslin, Charlotte Madeleine Nicole Lekieffre, Anders Meibom

ROYAL SOC2020

, ,

2016

Kleptoplastidic benthic foraminifera from aphotic habitats: Assimilation (or not) of inorganic C, N, and S studied at sub-cellular resolution

Emmanuelle Geslin, Charlotte Madeleine Nicole Lekieffre, Anders Meibom

2018