Functional and Structural Responses of Hyporheic Biofilms to Varying Sources of Dissolved Organic Matter

Overview

Journal Appl Environ Microbiol

Specialties Environmental Health
Microbiology

Date 2014 Jul 27

PMID 25063654

Citations 10

Authors

Karoline Wagner

Mia M Bengtsson

Katharina Besemer

Anna Sieczko

Nancy R Burns

Erik R Herberg

Tom J Battin

Affiliations

Soon will be listed here.

Abstract

Headwater streams are tightly connected with the terrestrial milieu from which they receive deliveries of organic matter, often through the hyporheic zone, the transition between groundwater and streamwater. Dissolved organic matter (DOM) from terrestrial sources (that is, allochthonous) enters the hyporheic zone, where it may mix with DOM from in situ production (that is, autochthonous) and where most of the microbial activity takes place. Allochthonous DOM is typically considered resistant to microbial metabolism compared to autochthonous DOM. The composition and functioning of microbial biofilm communities in the hyporheic zone may therefore be controlled by the relative availability of allochthonous and autochthonous DOM, which can have implications for organic matter processing in stream ecosystems. Experimenting with hyporheic biofilms exposed to model allochthonous and autochthonous DOM and using 454 pyrosequencing of the 16S rRNA (targeting the "active" community composition) and of the 16S rRNA gene (targeting the "bulk" community composition), we found that allochthonous DOM may drive shifts in community composition whereas autochthonous DOM seems to affect community composition only transiently. Our results suggest that priority effects based on resource-driven stochasticity shape the community composition in the hyporheic zone. Furthermore, measurements of extracellular enzymatic activities suggest that the additions of allochthonous and autochthonous DOM had no clear effect on the function of the hyporheic biofilms, indicative of functional redundancy. Our findings unravel possible microbial mechanisms that underlie the buffering capacity of the hyporheic zone and that may confer stability to stream ecosystems.

Citing Articles

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Priming of microcystin degradation in carbon-amended membrane biofilm communities is promoted by oxygen-limited conditions.

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Distinct responses from bacterial, archaeal and fungal streambed communities to severe hydrological disturbances.

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Multiple processes acting from local to large geographical scales shape bacterial communities associated with Phormidium (cyanobacteria) biofilms in French and New Zealand rivers.

Echenique-Subiabre I, Zancarini A, Heath M, Wood S, Quiblier C, Humbert J Sci Rep. 2018; 8(1):14416.

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Light availability impacts structure and function of phototrophic stream biofilms across domains and trophic levels.

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