Widespread occurrence of nitrate storage and denitrification among Foraminifera and<i>Gromiida</i>

Piña-Ochoa, Elisa; Høgslund, Signe; Geslin, Emmanuelle; Cedhagen, Tomas; Revsbech, Niels Peter; Nielsen, Lars Peter; Schweizer, Magali; Jorissen, Frans; Rysgaard, Søren; Risgaard-Petersen, Nils

doi:10.1073/pnas.0908440107

Cited by 246 publications

(284 citation statements)

References 40 publications

Supporting

Mentioning

258

Contrasting

Order By: Relevance

“…Similar intracellular nitrate concentrations (up to 500 mM) have also been observed in white sulphur bacteria belonging to the family Beggiatoaceae (Beggiatoa, Thioploca and Thiomargarita;Fossing et al 1995, McHatton et al 1996, Schulz et al 1999, Sayama 2001), corresponding to 4000-fold higher concentration levels than in the ambient environment. These findings suggest that nitrate accumulation is a universal property of vacuolated, filamentous sulphur bacteria, as well as Foraminifera and Gromiida (Piña-Ochoa et al 2010). High variability was measured in the intracellular nitrate pool within each treatment (Figs.…”

Section: Nitrate Storage In Foraminiferamentioning

confidence: 70%

“…Foraminifera were gently cleaned of sediment with a brush and rinsed in nitrate-free ASW. The specimens were then transferred to PCR tubes and analysed for nitrate content using the VCl 3 reduction method (Braman & Hendrix 1989) on a chemiluminescence detector (Model CLD 86, Eco Physics AG) as described by RisgaardPetersen et al (2006) and Høgslund et al (2008), with modification by Piña-Ochoa et al (2010). The analysis was carried out immediately when possible; alternatively, specimens were stored at -20°C until analysis within 1 wk of sampling.…”

Section: Methodsmentioning

confidence: 99%

“…Jorissen et al 1995, Fontanier et al 2003, Koho et al 2008a, which implies that they have either a fermentative or a respiratory metabolism based on electron acceptors other than oxygen. Recently, it has been demonstrated that many benthic foraminiferal species appear to be facultative anaerobes, allowing them to use both oxygen and nitrate for respiration (Risgaard-Petersen et al 2006, Høgslund et al 2008, Piña-Ochoa et al 2010. These species seem to respire nitrate through denitrification (i.e.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Survival and life strategy of the foraminiferan Globobulimina turgida through nitrate storage and denitrification

Piña-Ochoa¹,

Koho²,

Geslin³

et al. 2010

Mar. Ecol. Prog. Ser.

View full text Add to dashboard Cite

In a laboratory experiment, we examined the prolonged survival and behaviour of the benthic foraminiferan Globobulimina turgida under 3 simulated natural conditions: oxygenated with added nitrate, anoxic with added nitrate, and anoxic. The survival rates, adenosine triphosphate (ATP) reserve and intracellular nitrate pool of G. turgida were measured periodically under these conditions. Furthermore, to evaluate the efficiency and energy yield of the respiration system, denitrification rates of individual specimens were quantified using the acetylene inhibition and N 2 O microsensor technique at the start of the experiment. Our results demonstrate that the long-term (56 d) survival rate (64%) and ATP concentrations of G. turgida were not significantly different in oxygenated and anoxic, nitrate-containing conditions (Mann-Whitney test, p > 0.05). Thus, G. turgida can survive prolonged anoxia (3 mo) as long as nitrate is available to sustain its respiration. However, it remains unsure whether growth or reproduction can take place under anoxia. Short-term (21 to 35 d) survival rates were lower in nitrate-free, anoxic conditions (22% recovered alive compared to 62 to 82% in nitrate-oxic or nitrate-anoxic conditions), but foraminifera were observed to survive up to 56 d if respiring from their intra-cellular nitrate pool only. The foraminiferal nitrate pool appears very dynamic, as wide ranges of concentrations were measured in living specimens (0 to 463 mM ind.-1 ). We postulate that the scatter in the nitrate pool measurements highlights the ability of the foraminifera to actively collect and respire on nitrate, depending on individuals' history of exposure to oxygen and nitrate.

show abstract

Section: Nitrate Storage In Foraminiferamentioning

confidence: 70%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Survival and life strategy of the foraminiferan Globobulimina turgida through nitrate storage and denitrification

Piña-Ochoa¹,

Koho²,

Geslin³

et al. 2010

Mar. Ecol. Prog. Ser.

View full text Add to dashboard Cite

show abstract

“…The consistent negative effect of foraminiferan biomass on benthic carbon remineralisation in both spring and summer raises questions on the metabolic mechanisms in this group. Recently, Piña-Ochoa et al (2010) have described use of denitrification processes by many foraminiferan species. This could imply the respiration of nitrate rather than oxygen from the water phase, but it is still unclear, whether foraminiferan denitrification is restricted to anaerobic conditions (Høgslund et al 2008;Piña-Ochoa et al 2010).…”

Section: Discussionmentioning

confidence: 99%

“…Recently, Piña-Ochoa et al (2010) have described use of denitrification processes by many foraminiferan species. This could imply the respiration of nitrate rather than oxygen from the water phase, but it is still unclear, whether foraminiferan denitrification is restricted to anaerobic conditions (Høgslund et al 2008;Piña-Ochoa et al 2010). Depending on the oxygen penetration of sediments, which is generally deeper in greater water depths, foraminifera can be abundant down to more than 5 cm sediment depth (Fontanier et al 2005).…”

Section: Discussionmentioning

confidence: 99%

Spring-to-summer changes and regional variability of benthic processes in the western Canadian Arctic

et al. 2011

View full text Add to dashboard Cite

Seasonal dynamics in the activity of Arctic shelf benthos have been the subject of few local studies, and the pronounced among-site variability characterizing their results makes it difficult to upscale and generalize their conclusions. In a regional study encompassing five sites at 100-595 m water depth in the southeastern Beaufort Sea, we found that total pigment concentrations in surficial sediments, used as proxies of general food supply to the benthos, rose significantly after the transition from ice-covered conditions in spring (March-June 2008) to open-water conditions in summer (June-August 2008), whereas sediment Chl a concentrations, typical markers of fresh food input, did not. Macrobenthic biomass (including agglutinated foraminifera [500 lm) varied significantly among sites (1.2-6.4 g C m -2 in spring, 1.1-12.6 g C m -2 in summer), whereas a general spring-to-summer increase was not detected. Benthic carbon remineralisation also ranged significantly among sites (11.9-33.2 mg C m -2 day -1 in spring, 11.6-44.4 mg C m -2 day -1 in summer) and did in addition exhibit a general significant increase from spring-to-summer. Multiple regression analysis suggests that in both spring and summer, sediment Chl a concentration is the prime determinant of benthic carbon remineralisation, but other factors have a significant secondary influence, such as foraminiferan biomass (negative in both seasons), water depth (in spring) and infaunal biomass (in summer). Our findings indicate the importance of the combined and dynamic effects of food supply and benthic community patterns on the carbon remineralisation of the polar shelf benthos in seasonally ice-covered seas.

show abstract

The interplay between the surface and bottom water environment within the Benguela Upwelling System over the last 70 ka

et al. 2016

View full text Add to dashboard Cite

The Benguela Upwelling System (BUS), located between 30 and 20°S, is one of the fundamental high-productivity systems of the world ocean. The BUS has previously been studied in terms of primary productivity and ecology over glacial-interglacial timescales; however, the response and coupling with the benthic environment have received little attention. Here, for the first time, we present a high-resolution reconstruction of the BUS highlighting the link between surface and benthic productivity and their response to climatic and oceanographic changes over the last 70 ka. The study is based on benthic foraminiferal faunal analysis together with analyses of diatom assemblages, grain size of the terrigenous fraction, and stable O and C isotopic and bulk biogenic components of core GeoB3606-1. We reveal significant shifts in benthic foraminiferal assemblage composition. Tight coupling existed between the surface and bottom water environment especially throughout marine isotope stages 4 and 3 (MIS4 and MIS3). Due to the high export production, the site has essentially experienced continuous low oxygen conditions; however, there are time periods where the hypoxic conditions were even more notable. Two of these severe hypoxic periods were during parts of MIS4 and MIS3 where we find an inverse relationship between diatom and benthic foraminifera accumulation, meaning that during times of extremely high phytodetritus export we note strongly suppressed benthic productivity. We also stress the importance of food source for the benthos throughout the record. Shifts in export productivity are attributed not only to upwelling intensity and filament front position, but also, regional-global climatic and oceanographic changes had significant impact on the BUS dynamics.

show abstract

Widespread occurrence of nitrate storage and denitrification among Foraminifera andGromiida

Cited by 246 publications

References 40 publications

Survival and life strategy of the foraminiferan Globobulimina turgida through nitrate storage and denitrification

Survival and life strategy of the foraminiferan Globobulimina turgida through nitrate storage and denitrification

Spring-to-summer changes and regional variability of benthic processes in the western Canadian Arctic

The interplay between the surface and bottom water environment within the Benguela Upwelling System over the last 70 ka

Contact Info

Product

Resources

About