Selective chemoattraction of the benthic diatom Seminavis robusta to phosphate but not to inorganic nitrogen sources contributes to biofilm structuring

Diatoms frequently dominate marine and freshwater biofilms as major primary producers. Nutrient resources in these biofilms are patchily distributed and fluctuate dynamically over time. We recently reported that this spatially and temporally structured environment can be exploited by motile diatoms...

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Bibliographic Details
Published in:MicrobiologyOpen (Weinheim) 2019-04, Vol.8 (4), p.e00694-n/a
Main Authors: V. Bondoc, Karen Grace, Lembke, Christine, Vyverman, Wim, Pohnert, Georg
Format: Article
Language:English
Subjects:
Algae
Ammonium
Ammonium Compounds - metabolism
Bacillariophyceae
biofilm biology
Biofilms
Cell growth
Chemotactic response
Chemotaxis
Diatoms - growth & development
Diatoms - physiology
Foraging behavior
growth and survival
microbial behavior
Microorganisms
Motility
Nitrates - metabolism
Nitrogen
Nitrogen - metabolism
Nitrogen sources
nutrient acquisition
Nutrients
Original
Pattern analysis
Pheromones
Phosphates
Phosphates - metabolism
Recovery
Seminavis robusta
Silicates - metabolism
Silicon
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Summary:Diatoms frequently dominate marine and freshwater biofilms as major primary producers. Nutrient resources in these biofilms are patchily distributed and fluctuate dynamically over time. We recently reported that this spatially and temporally structured environment can be exploited by motile diatoms that use chemoattraction to dissolved silicate (dSi) under Si starvation. Here, we show that the behavioral response of diatoms is more complex and selective as cells are also responding to gradients of dissolved phosphate (dP) when starved in this nutrient. In contrast, neither nitrate nor ammonium (dN) triggers an attractive response under nitrogen limitation. Video monitoring and movement pattern analysis of the model diatom Seminavis robusta revealed that dP attraction is mediated by a combined chemokinetic and chemotactic response. After locating nutrient hotspots, the microalgae slow down and recover from the limitation. The fastest recovery in terms of growth was observed after dSi limitation. In agreement with the lack of directional response, recovery from dN limitation was slowest, indicating that no short‐term benefit would be drawn by the algae from the location of transient hotspots of this resource. Our results highlight the ability of diatoms to adapt to nutrient limitation by active foraging and might explain their success in patchy benthic environments. We report on the chemoreception and chemoattraction of diatoms toward inorganic nutrients and identify directed diatom motility as an unexpected reason for biofilm patchiness. We develop a picture of cells that can find their way according to their needs within a complex environment structured by chemical signals.
ISSN:2045-8827
2045-8827
DOI:10.1002/mbo3.694