Biogeochemical fluxes and fate of diazotroph-derived nitrogen in the food web after a phosphate enrichment: modeling of the VAHINE mesocosms experiment

Gimenez, Audrey; Baklouti, Mélika; Moutin, Thierry

doi:10.5194/bg-13-5103-2016

Cited by 13 publications

(28 citation statements)

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“…In a recent mesocosms experiment, large increases in N2 fixation rates, PP rates and carbon export were obtained after a DIP enrichment of WTSP waters (Berthelot et al, 2015). Nevertheless, several days were necessary to measure significant increases indicating that regular short term experiments to establish nutrient limitation as usually operated , may not be relevant in WTSP conditions (Gimenez et al, 2016). 5…”

Section: Iron and Phosphate Availabilities As Key Factors Controllingmentioning

confidence: 99%

Nutrient availability and the ultimate control of the biological carbon pump in the Western Tropical South Pacific Ocean

Moutin¹,

Wagener²,

Caffin³

et al. 2018

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15Surface waters (0-200 m) of the western tropical South Pacific (WTSP) were sampled along a longitudinal 4000 km transect (OUTPACE cruise, 18 Feb., 3 Apr. 2015) during the stratified period between the Melanesian Archipelago (MA) and the western part of the SP gyre (WGY). Two distinct areas were considered for the MA, the western MA (WMA) and the eastern MA (EMA). The main carbon (C), nitrogen (N), phosphorus (P) pools and fluxes allow for characterization of the expected trend from oligotrophy to ultra-oligotrophy, and to build first-order budgets at the daily and seasonal scales (using 20 climatology). Sea surface chlorophyll a reflected well the expected oligotrophic gradient with higher values obtained at WMA, lower values at WGY and intermediate values at EMA. As expected, the euphotic zone depth, the deep chlorophyll maximum and nitracline depth deepen from west to east. Nevertheless, phosphaclines and nitraclines did not match. The decoupling between phosphacline and nitracline depths in the MA allows excess P to be locally provided in the upper water by winter mixing. We found a significant biological "soft tissue" carbon pump in the MA sustained almost exclusively by N2 fixation 25 and essentially controlled by phosphate availability in this iron-replete environment. The MA appears to be a net sink for atmospheric CO2 while the WGY is in quasi steady state. We suggest that the necessary excess P, allowing the success of nitrogen fixers and subsequent carbon production and export, is mainly brought to the upper surface by local deep winter convection at an annual scale rather than by surface circulation. We also suggest that mesozooplankton diel vertical migration plays a dominant role in the transfer of carbon from the upper surface to deeper water in the MA. While the origin of the 30 decoupling between phosphacline and nitracline remains uncertain, the direct link between local P upper waters enrichment, N2 fixation, organic carbon production and export, offers a possible shorter time scale than previously thought between N input by N2 fixation and carbon export. The low iron availability in the SP gyre and P availability in the MA during the stratified period may appear as the ultimate control of N input by N2 fixation. Because of the huge volume of water to consider and because the SP Ocean is the place of intense denitrification in the east (N sink) and N2 fixation in the west (N source), precise 35 seasonal C, N, P budgets would be of prime interest to understand the efficiency, at the present time, and in the future, of the oceanic biological carbon pump.

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Section: Iron and Phosphate Availabilities As Key Factors Controllingmentioning

confidence: 99%

Nutrient availability and the ultimate control of the biological carbon pump in the Western Tropical South Pacific Ocean

Moutin¹,

Wagener²,

Caffin³

et al. 2018

Preprint

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“…As such, the activity of N 2 fixers is not sufficient to sustain all nitrogen needs of heterotrophic bacteria, whatever are the intermediary processes relating both fluxes, although it can reach a 520 Biogeosciences Discuss., https://doi.org/10.5194/bg-2017-556 Manuscript under review for journal Biogeosciences 15 N fixed by Trichodesmium reaches rapidly non-fixing diatoms (Foster et al, 2011;Bonnet et al, 2016).…”

Section: Nutrient Limitation and Relationships With Nitrogen Fixers 505mentioning

confidence: 99%

“…At sites LDA and LDB, the addition of the 3 elements NPG stimulated BP more than P alone or N alone, suggesting possible NP co-limitation of heterotrophic prokaryotes. Furthermore, if N was shown to be the first limiting nutrient during short time scale experiment, addition of P stimulates N 2 fix, PP and export at larger 555 time scales (Van Den Brock et al, 2004;Berthelot et al, 2015, Gimenez et al, 2016.…”

Section: Nutrient Limitation and Relationships With Nitrogen Fixers 505mentioning

confidence: 99%

“…The addition of selected organic molecules such as glucose (Dekaezemacker et al, 2013) or natural organic matter such as Transparent Expolymer Particles, can influence N 2 fix rates (Benavides et al, 2015). Finally, recent experiments based on incubation with 15 N-labeled N 2 coupled to nano-SIMS analyses also demonstrated that a rapid transfer, at the scale of 24 to 48 h, can occur between N 2 fixers, non-fixing phytoplankton and heterotrophic prokaryotes 90 (Bonnet et al, 2016).…”

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confidence: 94%

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Dynamics of phytoplankton and heterotrophic bacterioplankton in the western tropical South Pacific Ocean along a gradient of diversity and activity of diazotrophs

Gimenez

Duhamel

Dupouy

et al. 2018

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Abstract. Heterotrophic prokaryotic production (BP) was studied in the Western Tropical South Pacific using the leucine technique. Integrated over the euphotic zone, BP ranged from 58-120 mg C m -2 d -1 within the 20 Melanesian Archipelago, and from 31-50 mg C m -2 d -1 within the subtropical gyre. Nitrogen was often one of the main factor controlling BP on short time scale as shown using enrichment experiments, followed by dissolved inorganic phosphate (DIP) near the surface and labile organic carbon deeper in the euphotic zone. WithN 2 fixation being one of the most important fluxes fueling new production, we explored relationships between BP, primary production (PP) and N 2 fixation rates. BP variability was better explained by the variability of N 2 25 fixation rates than by that of PP in surface waters of the Melanesian Archipelago, which were characterized by N depleted layers, and low DIP turnover times (T DIP < 100 h). However, BP was more significantly correlated with PP but not with N 2 fixation rates where DIP was more available (T DIP > 100 h), i.e. in a layer deeper than the euphotic zone -including the deep chlorophyll maximum depths-in the Melanesian Archipelago, or within the entire euphotic zone in the subtropical gyre. Bacterial growth efficiency (BGE) ranged from 6 -10 %. Applying 30 correcting factors to estimate gross primary production and correcting BP for Prochlorococcus assimilation of leucine, we showed a large variability in the contribution of gross primary production to bacterial C demand.Exploration of a bloom collapse at one site south of Vanuatu showed the importance of blooms, which can persist over extensive distance for long periods of time, and can maintaining net autotrophy where they occur.Using a Lagragian sampling strategy during 6 days, long duration sites allowed for the study of the rapid 35 changes including BP, primary production and BGE, that occurred during the bloom collapse.

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“…Since experimental studies highlighted the significant contribution of N 2 fixation as a new source of N for planktonic ecosystems in the surface layer (Martínez et al, 1983;Karl et al, 1997;Capone et al, 2005), the process of diazotrophy associated (or not) with explicitly-represented diazotroph organisms has been implemented in numerous biogeochemical models in the last decades. As a result, more and more modeling studies have 30 been investigating the role of diazotrophy at global scale (Moore et al, 2001(Moore et al, , 2004Monteiro et al, 2011), at regional scale (Coles and Hood, 2007;Zamora et al, 2010), at local scale (Fennel et al, 2001;Gimenez et al, 2016) or more specifically at population scale, such as the work on Trichodesmium sp. by Rabouille et al (2006).…”

Section: Introductionmentioning

confidence: 99%

Diazotrophy as the main driver of planktonic production and biogeochemical C, N, P cycles in theWestern Tropical South Pacific Ocean: results from a 1DV biogeochemical-physical coupled model

Gimenez

Baklouti

Moutin

2018

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Abstract. The Oligotrophy to UlTra-oligotrophy PACific Experiment (OUTPACE) cruise took place in the Western Tropical South Pacific (WTSP) during the austral summer (March-April 2015). The aim of the OUTPACE project is to investigate a longitudinal gradient of biological and biogeochemical features in the WTSP, and especially the role of N 2 fixation on the C, N, P cycles. Two contrasted regions were considered : the Western Melanesian Archipelago (WMA), characterized by high N 2 fixation rates, significant surface production and low dissolved inorganic phosphorus (DIP) concentrations, and the 5Western south Pacific GYre (WGY), characterized by very low N 2 fixation rates, low surface production rates and high DIP concentrations. A one-dimensional biogeochemical -physical coupled model was used to investigate the role of N 2 fixation in the WTSP by running two identical simulations, only differing by the presence or not of diazotrophs. We evidenced that the nitracline and the phosphacline had to be respectively deeper and shallower than the Mixed-Layer Depth (MLD) to bring Ndepleted and P-repleted waters to the surface during winter mixing, thereby creating favorable conditions for the development 10 of diazotrophs. We also concluded that a preferential regeneration of the detrital phosphorus (P) matter was necessary to obtain this gap between the nitracline and the phosphacline depths, as the nutricline depths significantly depend on the regeneration of organic matter in the water column. Moreover, the model enabled us to highlight the presence of seasonal variations in upper surface waters in the simulation standing for WMA, where diazotrophs provided a new source of nitrogen (N) to their ecosystem, whereas no seasonal variations were obtained in the simulation standing for WGY, in absence of diazotrophs. These 15 main results emphasized the fact that surface production dynamics in the WTSP is based on a complex and sensitive system which depends on N 2 fixation in a crucial way.

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Biogeochemical fluxes and fate of diazotroph-derived nitrogen in the food web after a phosphate enrichment: modeling of the VAHINE mesocosms experiment

Cited by 13 publications

References 72 publications

Nutrient availability and the ultimate control of the biological carbon pump in the Western Tropical South Pacific Ocean

Nutrient availability and the ultimate control of the biological carbon pump in the Western Tropical South Pacific Ocean

Dynamics of phytoplankton and heterotrophic bacterioplankton in the western tropical South Pacific Ocean along a gradient of diversity and activity of diazotrophs

Diazotrophy as the main driver of planktonic production and biogeochemical C, N, P cycles in theWestern Tropical South Pacific Ocean: results from a 1DV biogeochemical-physical coupled model

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