Attributes of Drying Define the Structure and Functioning of Microbial Communities in Temperate Riverbed Sediment

Schreckinger, José; Mutz, Michael; Mendoza‐Lera, Clara; Frossard, Aline

doi:10.3389/fmicb.2021.676615

Cited by 14 publications

(14 citation statements)

References 82 publications

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“…being the species with the highest deviation from the control (1.6-fold increased abundance). When looking at relative abundance, Dothideomycetes were initially the most dominant fungal group in dried sediments (in concordance with Schreckinger et al, 2021), but their relative abundance decreased with increasing recovery time (Supplementary Figure S5).…”

Section: Bacterial Fungal and Diatom Community Structuresupporting

confidence: 66%

“…To prepare the dried sediment, we sampled fully submerged and immobile (hereafter stationary) sandy sediment from the top 10 cm of the riverbed in June 2018 (Supplementary Figures S2A,B). The sediment was dried for 90 days under an outdoor translucent rooftop, exposed to natural sunlight radiation and temperature changes without shading and excluding precipitation (for details of the drying process see Schreckinger et al, 2021). Migrated and control sediments were sampled from the crest (≤1 cm) of migrating bedform and stationary sediment patches, respectively, at base flow in October 2018 (Supplementary Figure S2C).…”

Section: Experimental Designmentioning

confidence: 99%

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Long-term functional recovery and associated microbial community structure after sediment drying and bedform migration

et al. 2023

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Climate change and erosion from agricultural areas cause increased drying periods and bedform migration of riverbeds, respectively, worldwide. Both sediment drying and bedform migration can independently stress the microbial community residing in the riverbed. Here, we investigated the microbial response after exposure to these stressors with a focus on long-term recovery. We conducted an in situ experiment to investigate the long-term (8 months) functional and structural recovery of benthic microbial communities from either sediment drying (episodic severe stressor) or bedform migration (frequent moderate stressor). Stressed sediment associated communities were rewetted (dried sediments) and immobilized (migrated sediments) and exposed in the River Spree (north-eastern Germany) to initiate the recovery process. We then evaluated the microbial function (community respiration, net community production and extracellular enzymatic activities) as well as the bacterial, fungal and diatom community structure (16S rRNA gene and ITS region metabarcoding, and microscopic diatom morphotype classification). We observed different recovery times for community respiration (less than 7 days) and gross primary production (more than 5 months), implying a shift toward net heterotrophy in the first few months after stress exposure. Similarly, we observed a strong autotrophic community response (particularly associated with the diatoms Navicula and Fragilaria), especially in migrated sediments. The bacterial and fungal community response to sediment drying was stronger than to bedform migration (particularly associated with the bacterium Flavobacterium and the fungi Alternaria sp. and Aureobasidium pullulans). Our results show that sediment drying and bedform migration had a significant impact on the microbial community function and structure, which persisted for several months after the stress. Due to the surprising long period of recovery, successive stress events combined with seasonal effects will likely hamper the ongoing recovery process with severe alterations to the microbial function and structure. These findings extend the concept of ecosystem resilience and stability on the dimensions of timescale and seasonal environmental variations. Legacy effects are expected to play a key role when facing future stress.

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Section: Bacterial Fungal and Diatom Community Structuresupporting

confidence: 66%

Section: Experimental Designmentioning

confidence: 99%

Long-term functional recovery and associated microbial community structure after sediment drying and bedform migration

et al. 2023

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“…In the case of 'RGT-Reform' wheat cultivar, drought negatively affected xylosidase and glucosidase activities in the Chernozem soil but promoted glucosidase activities in Luvisol [22]. Drought impact on sediment revealed de-crease in esterase (0.5%/day) [61], β-glucosidase (>50%) [62], leucine aminopeptidase [63], phosphatase (>50%) [64], and phenol oxidase (PO) [63] activities. In the case of Mediterranean evergreen oak forests, a reduction of 10 and 21% of soil moisture in plots (by water runoff) decreased urease activity by 10-67% and 42-60%, protease activity by 15-66% and 35-45%, and β-glucosidase activity by 10-80% and 35-83% depending on the annual period (spring and autumn) and soil depth (0-15 and 15-30 cm).…”

Section: Effect Of Drought On Soil Enzyme Activitiesmentioning

confidence: 99%

The Impact of Drought Stress on Soil Microbial Community, Enzyme Activities and Plants

2022

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Nowadays, the most significant consequence of climate change is drought stress. Drought is one of the important, alarming, and hazardous abiotic stresses responsible for the alterations in soil environment affecting soil organisms, including microorganisms and plants. It alters the activity and functional composition of soil microorganisms that are responsible for crucial ecosystem functions and services. These stress conditions decrease microbial abundance, disturb microbial structure, decline microbial activity, including enzyme production (e.g., such as oxidoreductases, hydrolases, dehydrogenase, catalase, urease, phosphatases, β-glucosidase) and nutrient cycling, leading to a decrease in soil fertility followed by lower plant productivity and loss in economy. Interestingly, the negative effects of drought on soil can be minimized by adding organic substances such as compost, sewage slugs, or municipal solid waste that increases the activity of soil enzymes. Drought directly affects plant morphology, anatomy, physiology, and biochemistry. Its effect on plants can also be observed by changes at the transcriptomic and metabolomic levels. However, in plants, it can be mitigated by rhizosphere microbial communities, especially by plant growth-promoting bacteria (PGPB) and fungi (PGPF) that adapt their structural and functional compositions to water scarcity. This review was undertaken to discuss the impacts of drought stress on soil microbial community abundance, structure and activity, and plant growth and development, including the role of soil microorganisms in this process. Microbial activity in the soil environment was considered in terms of soil enzyme activities, pools, fluxes, and processes of terrestrial carbon (C) and nitrogen (N) cycles. A deep understanding of many aspects is necessary to explore the impacts of these extreme climate change events. We also focus on addressing the possible ways such as genome editing, molecular analysis (metagenomics, transcriptomics, and metabolomics) towards finding better solutions for mitigating drought effects and managing agricultural practices under harsh condition in a profitable manner.

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“…Moreover, the relatively stronger land‐water connectivity in headwaters compared to the mainstem can supply terrestrially derived C inputs to stream under lotic conditions (Hotchkiss et al, 2015), and it may be an important source of C during drying events (Gómez‐Gener et al, 2020). The shading effects of riparian cover in headwaters also can buffer against the negative impacts of sediment desiccation on decomposer communities and associated GHG production (Schreckinger et al, 2021). However, the lower sediment temperature near the headwaters and coarser sediment texture may conversely limit CO 2 fluxes.…”

Section: Spatial and Temporal Patterns Of Drying And Damming At The N...mentioning

confidence: 99%

Greenhouse gas dynamics in river networks fragmented by drying and damming

Silverthorn,

López‐Rojo,

Foulquier

et al. 2023

Freshwater Biology

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River fragmentation by drying and damming is occurring more frequently in the Anthropocene era, yet there is limited knowledge of how this fragmentation influences greenhouse gas (GHG) fluxes in river networks. River networks have the potential to be important sources of GHGs to the atmosphere through both similar and dissimilar mechanisms associated with temporary (drying) and permanent (damming) fragmentation. We conducted a review of the literature and found 49, 43 and six studies about GHGs (CO2, CH4 and N2O) in rivers impacted by damming, drying and their interaction, respectively. We found research lacking in non‐arid climates and in small water‐retention structures for studies regarding drying and damming, respectively. The major factors directly influencing GHG fluxes in river networks impacted by drying were sediment moisture, temperature, organic matter content and texture. In networks impacted by damming, the most influential factors were water temperature, dissolved oxygen, and phytoplankton Chlorophyll‐a. Based on our literature review and meta‐ecosystem theory, we propose that the spatial distribution of fragmentation strongly influences GHG fluxes at the river‐network scale. The actionable future research directions identified here will help to improve our understanding of the effects of fragmentation by drying and damming on GHG fluxes, with the potential to inform river management and climate change mitigation strategies.

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Attributes of Drying Define the Structure and Functioning of Microbial Communities in Temperate Riverbed Sediment

Cited by 14 publications

References 82 publications

Long-term functional recovery and associated microbial community structure after sediment drying and bedform migration

Long-term functional recovery and associated microbial community structure after sediment drying and bedform migration

The Impact of Drought Stress on Soil Microbial Community, Enzyme Activities and Plants

Greenhouse gas dynamics in river networks fragmented by drying and damming

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