Sinking Trichodesmium Fixes Nitrogen in the Dark Ocean

Overview

Journal ISME J

Publisher Oxford University Press

Specialties Environmental Health
Microbiology

Date 2022 Jul 14

PMID 35835942

Authors

Mar Benavides

Sophie Bonnet

Frederic A C Le Moigne

Gabrielle Armin

Keisuke Inomura

Soren Hallstrom

Lasse Riemann

Ilana Berman-Frank

Emilie Poletti

Marc Garel

Olivier Grosso

Karine Leblanc

Catherine Guigue

Marc Tedetti

Cecile Dupouy

Affiliations

Soon will be listed here.

Abstract

The photosynthetic cyanobacterium Trichodesmium is widely distributed in the surface low latitude ocean where it contributes significantly to N fixation and primary productivity. Previous studies found nifH genes and intact Trichodesmium colonies in the sunlight-deprived meso- and bathypelagic layers of the ocean (200-4000 m depth). Yet, the ability of Trichodesmium to fix N in the dark ocean has not been explored. We performed N incubations in sediment traps at 170, 270 and 1000 m at two locations in the South Pacific. Sinking Trichodesmium colonies fixed N at similar rates than previously observed in the surface ocean (36-214 fmol N cell d). This activity accounted for 40 ± 28% of the bulk N fixation rates measured in the traps, indicating that other diazotrophs were also active in the mesopelagic zone. Accordingly, cDNA nifH amplicon sequencing revealed that while Trichodesmium accounted for most of the expressed nifH genes in the traps, other diazotrophs such as Chlorobium and Deltaproteobacteria were also active. Laboratory experiments simulating mesopelagic conditions confirmed that increasing hydrostatic pressure and decreasing temperature reduced but did not completely inhibit N fixation in Trichodesmium. Finally, using a cell metabolism model we predict that Trichodesmium uses photosynthesis-derived stored carbon to sustain N fixation while sinking into the mesopelagic. We conclude that sinking Trichodesmium provides ammonium, dissolved organic matter and biomass to mesopelagic prokaryotes.

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