Delving deeper: Metabolic processes in the metalimnion of stratified lakes

Giling, Darren P.; Stæhr, Peter A.; Grossart, Hans Peter; Andersen, Mikkel René; Boehrer, Bertram; Escot, C.; Evrendilek, Fatih; Gómez‐Gener, Lluís; Honti, Márk; Jones, Ian D.; Karakaya, Nusret; Laas, Alo; Moreno-Ostos, Enrique; Rinke, Karsten; Scharfenberger, Ulrike; Schmidt, Silke R.; Weber, Michael; Woolway, R. Iestyn; Zwart, Jacob A.; Obrador, Biel

doi:10.1002/lno.10504

Cited by 45 publications

(45 citation statements)

References 61 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Based on the microbial redox ‘tower’, aerobic respiration, denitrification, manganese(IV) reduction, Fe(III) reduction, sulfate reduction and methanogenesis are thought to proceed in a sequence, determined by thermodynamics, i.e., the energy yield of the different reactions (Richards, ; Froelich et al ., ; Orcutt et al ., ), creating typical geochemical gradients. However, in the environment, different metabolic processes were found to be co‐occurring in the same sediment zone (Chen et al ., a; Giling et al ., ). At our field sites, the vertical distribution of most active microbial groups correlated with measured geochemical gradients, while active Fe‐metabolizing bacteria were decoupled from these gradients, which was highly unexpected.…”

Section: Discussionmentioning

confidence: 97%

The distribution of active iron‐cycling bacteria in marine and freshwater sediments is decoupled from geochemical gradients

Otte

Harter

Laufer

et al. 2018

Environmental Microbiology

View full text Add to dashboard Cite

Summary Microaerophilic, phototrophic and nitrate‐reducing Fe(II)‐oxidizers co‐exist in coastal marine and littoral freshwater sediments. However, the in situ abundance, distribution and diversity of metabolically active Fe(II)‐oxidizers remained largely unexplored. Here, we characterized the microbial community composition at the oxic‐anoxic interface of littoral freshwater (Lake Constance, Germany) and coastal marine sediments (Kalø Vig and Norsminde Fjord, Denmark) using DNA‐/RNA‐based next‐generation 16S rRNA (gene) amplicon sequencing. All three physiological groups of neutrophilic Fe(II)‐oxidizing bacteria were found to be active in marine and freshwater sediments, revealing up to 0.2% anoxygenic photoferrotrophs (e.g., Rhodopseudomonas, Rhodobacter, Chlorobium), 0.1% microaerophilic Fe(II)‐oxidizers (e.g., Mariprofundus, Hyphomonas, Gallionella) and 0.3% nitrate‐reducing Fe(II)‐oxidizers (e.g., Thiobacillus, Pseudomonas, Denitromonas, Hoeflea). Active Fe(III)‐reducing bacteria (e.g., Shewanella, Geobacter) were most abundant (up to 2.8%) in marine sediments and co‐occurred with cable bacteria (up to 4.5%). Geochemical profiles of Fe(III), Fe(II), O2, light, nitrate and total organic carbon revealed a redox stratification of the sediments and explained 75%–85% of the vertical distribution of microbial taxa, while active Fe‐cycling bacteria were found to be decoupled from geochemical gradients. We suggest that metabolic flexibility, microniches in the sediments, or interrelationships with cable bacteria might explain the distribution patterns of active Fe‐cycling bacteria.

show abstract

Section: Discussionmentioning

confidence: 97%

The distribution of active iron‐cycling bacteria in marine and freshwater sediments is decoupled from geochemical gradients

Otte

Harter

Laufer

et al. 2018

Environmental Microbiology

View full text Add to dashboard Cite

show abstract

“…The surface waters were already well mixed and in equilibrium with the atmosphere, with a neutral balance of a likely low metabolism. In clearwater oligotrophic lakes, the metabolic rates are highest in metalimnetic instead of epilimnetic waters (Giling, Staehr, et al, 2017).…”

Section: Discussionmentioning

confidence: 99%

Storm impacts on alpine lakes: Antecedent weather conditions matter more than the event intensity

Perga

Bruel

Rodríguez

et al. 2018

Global Change Biology

View full text Add to dashboard Cite

Extreme weather events may be just as important as gradual trends for the long-term trajectories of ecosystems. For alpine lakes, which are exposed to both exacerbated atmospheric warming and intense episodic weather events, future conditions might not be appropriately forecast by only climate change trends, i.e. warming, if extreme events have the potential to deflect their thermal and metabolic states from their seasonal ranges. We used high-frequency monitoring data over three open-water seasons with a one-dimensional hydrodynamic model of the high-altitude Lake Muzelle (France) to show that rainstorms or windstorms, notwithstanding their intensity, did not trigger long-lasting consequences to the lake characteristics when light penetration into the lake was not modified. In contrast, storms associated with high turbidity input from the watershed ("turbid storms") strongly modified the lacustrine hydrodynamics and metabolism for the rest of the open-water season through reduced light penetration. The long-lasting effects of turbid storms were related to the inputs and in-lake persistence of very light glacial suspensoids from the watershed. The occurrence of the observed turbid storms was not related to the wind or rain intensities during the events. Instead, the turbid storms occurred after dry and atypically warm spells, i.e. meteorological conditions expected to be more frequent in this alpine region in the upcoming decades. Consequently, storm events, notwithstanding their intensity, are expected to strongly imprint the future ecological status of alpine lakes under climate warming.

show abstract

“…lakes and oceans (Moll et al 1984;Weston et al 2005;Giling et al 2017) and influence nutrient cycling (Jamart et al 1977;Letelier et al 2004). DCMs create a vertical resource gradient for primary consumers and thus influence zooplankton vertical distributions and diel vertical migration (Williamson et al 1996a;Winder et al 2003), as well as predator aggregations (Tiselius et al 1993).…”

mentioning

confidence: 99%

Patterns and drivers of deep chlorophyll maxima structure in 100 lakes: The relative importance of light and thermal stratification

Leach

Beisner

Carey

et al. 2017

Limnology & Oceanography

132

139

View full text Add to dashboard Cite

The vertical distribution of chlorophyll in stratified lakes and reservoirs frequently exhibits a maximum peak deep in the water column, referred to as the deep chlorophyll maximum (DCM). DCMs are ecologically important hot spots of primary production and nutrient cycling, and their location can determine vertical habitat gradients for primary consumers. Consequently, the drivers of DCM structure regulate many characteristics of aquatic food webs and biogeochemistry. Previous studies have identified light and thermal stratification as important drivers of summer DCM depth, but their relative importance across a broad range of lakes is not well resolved. We analyzed profiles of chlorophyll fluorescence, temperature, and light during summer stratification from 100 lakes in the Global Lake Ecological Observatory Network (GLEON) and quantified two characteristics of DCM structure: depth and thickness. While DCMs do form in oligotrophic lakes, we found that they can also form in eutrophic to dystrophic lakes. Using a random forest algorithm, we assessed the relative importance of variables associated with light attenuation vs. thermal stratification for predicting DCM structure in lakes that spanned broad gradients of morphometry and transparency. Our analyses revealed that light attenuation was a more important predictor of DCM depth than thermal stratification and that DCMs deepen with increasing lake clarity. DCM thickness was best predicted by lake size with larger lakes having thicker DCMs. Additionally, our analysis demonstrates that the relative importance of light and thermal stratification on DCM structure is not uniform across a diversity of lake types.

show abstract

Delving deeper: Metabolic processes in the metalimnion of stratified lakes

Cited by 45 publications

References 61 publications

The distribution of active iron‐cycling bacteria in marine and freshwater sediments is decoupled from geochemical gradients

The distribution of active iron‐cycling bacteria in marine and freshwater sediments is decoupled from geochemical gradients

Storm impacts on alpine lakes: Antecedent weather conditions matter more than the event intensity

Patterns and drivers of deep chlorophyll maxima structure in 100 lakes: The relative importance of light and thermal stratification

Contact Info

Product

Resources

About