Bacterioplankton Metacommunity Processes across Thermal Gradients: Weaker Species Sorting but Stronger Niche Segregation in Summer than in Winter in a Subtropical Bay

Ren, Lijuan; Song, Xingyu; He, Dan; Wang, Jianjun; Tan, Meiting; Xia, Xiaomin; Li, Gang; Tan, Yehui; Wu, Qinglong L.

doi:10.1128/aem.02088-18

Cited by 27 publications

(17 citation statements)

References 64 publications

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“…Although mainly habitat filtering differentiated the assembly of bacterial communities, the compositional dissimilarities between the PBC and SBC were comparatively greater in summer than in winter. One possible explanation is that the relative importance of niche segregation triggered by competitive exclusion of bacterial taxa becomes stronger in summer (Ren et al., 2019). Within habitats, SBC had significantly lower variation in community composition than PBC in both seasons, implying that SBC is more stable in community structure than PBC (Zeng, Jiao, et al., 2019).…”

Section: Discussionmentioning

confidence: 99%

Habitats and seasons differentiate the assembly of bacterial communities along a trophic gradient of freshwater lakes

et al. 2021

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Section: Discussionmentioning

confidence: 99%

Habitats and seasons differentiate the assembly of bacterial communities along a trophic gradient of freshwater lakes

et al. 2021

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“…The complexity of these interactions is further compounded in coastal habitats, as these ecosystems are transitional zones between terrestrial and marine environments, where strong spatiotemporal heterogeneity in physicochemical and environmental conditions occur. Within these coastal environments, microbial communities have been shown to respond to spatial gradients of salinity, pollution, depth, nutrients, pH, bioturbation and dissolved oxygen, and temporal gradients of temperature and rainfall (Böer et al 2009, Fortunato et al 2012, 2013, Sun et al 2013, Wang et al 2015, Angly et al 2016, Jeffries et al 2016, Ren et al 2019. With a myriad of factors suggested to interact and potentially alter the composition and function of coastal microbial communities, a greater understanding is required in relation to how these communities respond to variable environmental conditions and the potential impacts these changes have on the critical ecosystem functions that these communities play.…”

Section: Open Pen Access Ccessmentioning

confidence: 99%

Nitrogen cycling in coastal sediment microbial communities with seasonally variable benthic nutrient fluxes

Marshall

Longmore

Phillips

et al. 2021

Aquat. Microb. Ecol.

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Benthic microbial communities contribute to nitrogen (N) cycling in coastal ecosystems through taxon-specific processes such as anammox, nitrification and N-fixation and community attributed pathways such as denitrification. By measuring the total (DNA-based) and active (RNA-based) surface sediment microbial community composition and the abundance and activity profiles of key N-cycling genes in a semi-enclosed embayment—Port Phillip Bay (PPB), Australia—we show that although the total relative abundance of N-cycling taxa is comparatively lower close to estuary inputs (Hobsons Bay [HB]), the capacity for this community to perform diverse Ncycling processes is comparatively higher than in sediments isolated from inputs (Central PPB [CPPB]). In HB, seasonal structuring of the sediment microbial community occurred between spring and summer, co-occurring with decreases in the activity profiles of anammox bacteria and organic carbon content. No changes were detected in the activity profiles of nitrifiers or the community-based pathway denitrification. Although no seasonal structuring of the sediment microbial community occurred in CPPB, the activity profiles of key N-cycling genes displayed comparatively higher within-site variability. These results show that despite N-cycling taxa representing a smaller fraction of the total community composition in estuary impacted sediments (HB) these microbial communities consistently engage in N-cycling processes and that seasonal instability in the composition of this community is not reflective of changes in its capacity to cycle N through coupled nitrification-denitrification but potentially via changes within the anammox community.

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“…The network topology may be an artifact of the shorter stream distance and catchment area in the Red Butte watershed, which affected clustering of co-occurrence networks in an Austrian catchment (Widder et al, 2014). The reduced network may also suggest higher rates of hydrologic disturbance (Widder et al, 2014) or species sorting (Ren et al, 2019) and imply changes in community function between watersheds (Fuhrman, 2009). The negligible effect of changes in land use at higher order streams suggests instream bacterial communities may not always be dramatically affected by land use changes or stream channelization in urban areas.…”

Section: Human Influence On Bacterioplankton Communitiesmentioning

confidence: 99%

Stream Microbial Community Structured by Trace Elements, Headwater Dispersal, and Large Reservoirs in Sub-Alpine and Urban Ecosystems

et al. 2020

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Stream bacterioplankton communities, a crucial component of aquatic ecosystems and surface water quality, are shaped by environmental selection (i.e., changes in taxa abundance associated with more or less favorable abiotic conditions) and passive dispersal (i.e., organisms’ abundance and distribution is a function of the movement of the water). These processes are a function of hydrologic conditions such as residence time and water chemistry, which are mediated by human infrastructure. To quantify the role of environmental conditions, dispersal, and human infrastructure (dams) on stream bacterioplankton, we measured bacterioplankton community composition in rivers from sub-alpine to urban environments in three watersheds (Utah, United States) across three seasons. Of the 53 environmental parameters measured (including physicochemical parameters, solute concentrations, and catchment characteristics), trace element concentrations explained the most variability in bacterioplankton community composition using Redundancy Analysis ordination. Trace elements may correlate with bacterioplankton due to the commonality in source of water and microorganisms, and/or environmental selection creating more or less favorable conditions for bacteria. Bacterioplankton community diversity decreased downstream along parts of the stream continuum but was disrupted where large reservoirs increased water residence time by orders of magnitude, potentially indicating a shift in the relative importance of environmental selection and dispersal at these sites. Reservoirs also had substantial effects on community composition, dissimilarity (Bray-Curtis distance) and species interactions as indicated by co-occurrence networks. Communities downstream of reservoirs were enriched with anaerobic Sporichthyaceae, methanotrophic Methylococcaceae, and iron-transforming Acidimicrobiales, suggesting alternative metabolic pathways became active in the hypolimnion of large reservoirs. Our results identify that human activity affects river microbial communities, with potential impacts on water quality through modified biogeochemical cycling.

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Bacterioplankton Metacommunity Processes across Thermal Gradients: Weaker Species Sorting but Stronger Niche Segregation in Summer than in Winter in a Subtropical Bay

Cited by 27 publications

References 64 publications

Habitats and seasons differentiate the assembly of bacterial communities along a trophic gradient of freshwater lakes

Habitats and seasons differentiate the assembly of bacterial communities along a trophic gradient of freshwater lakes

Nitrogen cycling in coastal sediment microbial communities with seasonally variable benthic nutrient fluxes

Stream Microbial Community Structured by Trace Elements, Headwater Dispersal, and Large Reservoirs in Sub-Alpine and Urban Ecosystems

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