Bacterial biogeography in the coastal waters of northern <scp>Z</scp>hejiang, <scp>E</scp>ast <scp>C</scp>hina <scp>S</scp>ea is highly controlled by spatially structured environmental gradients

Wang, Kai; Ye, Xiansen; Chen, Heping; Zhao, Qin; Hu, C.; He, Jiaying; Qian, Yue; Xiong, Jinbo; Zhu, Jiangfeng; Zhang, Demin

doi:10.1111/1462-2920.12884

Cited by 93 publications

(104 citation statements)

References 73 publications

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“…In addition, approximate 10 % variation of the BCCs was constrained by the interaction of geographic distance and seawater variables (Fig. 4), which is in concert with the notion that coastal BCCs is controlled by spatially structured environmental gradient (Wang et al 2015). However, there was still a large proportion (54.5 %) of the variation unexplained by the above selected biogeochemical variables (Fig.…”

Section: Resultsmentioning

confidence: 53%

Thermal discharge-created increasing temperatures alter the bacterioplankton composition and functional redundancy

Xiong

Peng

et al. 2016

AMB Expr

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Elevated seawater temperature has altered the coupling between coastal primary production and heterotrophic bacterioplankton respiration. This shift, in turn, could influence the feedback of ocean ecosystem to climate warming. However, little is known about how natural bacterioplankton community responds to increasing seawater temperature. To investigate warming effects on the bacterioplankton community, we collected water samples from temperature gradients (ranged from 15.0 to 18.6 °C) created by a thermal flume of a coal power plant. The results showed that increasing temperatures significantly stimulated bacterial abundance, grazing rate, and altered bacterioplankton community compositions (BCCs). The spatial distribution of bacterioplankton community followed a distance similarity decay relationship, with a turnover of 0.005. A variance partitioning analysis showed that temperature directly constrained 2.01 % variation in BCCs, while temperature-induced changes in water geochemical and grazing rate indirectly accounted for 4.03 and 12.8 % of the community variance, respectively. Furthermore, the relative abundances of 24 bacterial families were linearly increased or decreased (P < 0.05 in all cases) with increasing temperatures. Notably, the change pattern for a given bacterial family was in concert with its known functions. In addition, community functional redundancy consistently decreased along the temperature gradient. This study demonstrates that elevated temperature, combined with substrate supply and trophic interactions, dramatically alters BCCs, concomitant with decreases in functional redundancy. The responses of sensitive assemblages are temperature dependent, which could indicate temperature departures.Electronic supplementary materialThe online version of this article (doi:10.1186/s13568-016-0238-4) contains supplementary material, which is available to authorized users.

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Section: Resultsmentioning

confidence: 53%

Thermal discharge-created increasing temperatures alter the bacterioplankton composition and functional redundancy

Xiong

Peng

et al. 2016

AMB Expr

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“…We observed that Cyanobacteria were not dominant in the sediments, with a low average relative abundance (0.011%, data not shown). This could be partly explained by the limited light-permeability of the turbid waters containing a great amount of suspended particles in the study area overall27. Correspondingly, a number of previous works reported that Cyanobacteria were not dominant in the coastal marine sediments9115556.…”

Section: Discussionmentioning

confidence: 85%

“…The coastal area of northern Zhejiang is an interconnected marine ecosystem in the East China Sea that covers ~200 km, primarily comprising Hangzhou Bay, which is highly influenced by discharges from the Qiantang River and industry24; Xiangshan Harbor, a semi-enclosed bay, frequently perturbed by aquaculture25; Sanmen Bay, perturbed by booming fishery26; the Zhoushan Islands, located at the mouth of Hangzhou Bay and acting as barriers from the estuary to the ocean; coastal eastern Xiangshan, covered by fishery hot spots; and the Yushan Islands, serving as a reserve area27. In the present study, we used 16S rRNA gene sequencing and PICRUSt functional prediction to investigate regional variations in the diversity and metabolic functional potential of prokaryotic communities in the surface sediments from above coastal zones to answer three questions: (1) Does geographic distance overwhelm local environmental condition in shaping prokaryotic β-diversity?…”

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confidence: 99%

Regional variations in the diversity and predicted metabolic potential of benthic prokaryotes in coastal northern Zhejiang, East China Sea

Wang

Zhang

et al. 2016

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Knowledge about the drivers of benthic prokaryotic diversity and metabolic potential in interconnected coastal sediments at regional scales is limited. We collected surface sediments across six zones covering ~200 km in coastal northern Zhejiang, East China Sea and combined 16 S rRNA gene sequencing, community-level metabolic prediction, and sediment physicochemical measurements to investigate variations in prokaryotic diversity and metabolic gene composition with geographic distance and under local environmental conditions. Geographic distance was the most influential factor in prokaryotic β-diversity compared with major environmental drivers, including temperature, sediment texture, acid-volatile sulfide, and water depth, but a large unexplained variation in community composition suggested the potential effects of unmeasured abiotic/biotic factors and stochastic processes. Moreover, prokaryotic assemblages showed a biogeographic provincialism across the zones. The predicted metabolic gene composition similarly shifted as taxonomic composition did. Acid-volatile sulfide was strongly correlated with variation in metabolic gene composition. The enrichments in the relative abundance of sulfate-reducing bacteria and genes relevant with dissimilatory sulfate reduction were observed and predicted, respectively, in the Yushan area. These results provide insights into the relative importance of geographic distance and environmental condition in driving benthic prokaryotic diversity in coastal areas and predict specific biogeochemically-relevant genes for future studies.

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“…Pronounced spatial patterns of marine bacterial community composition have been described for estuarine areas that exhibit strong salinity gradients [8,46] as well as oceanic water masses with distinct gradients in salinity or temperature for instance [11,16]. However, as part of a semi-enclosed continental shelf sea the German Bight represents a unique, highly productive coastal environment that is strongly influenced by its intertidal flats, freshwater inflow of rivers and exhibits rather smallscale, highly variable hydrographic properties [3,42].…”

Section: Free-living and Particle-attached Bacterial Communities Are mentioning

confidence: 99%

“…Among these environmental factors, temperature and salinity seem to have largest influence on global bacterial community structure and richness [11,24]. On the other hand microbial communities on microscales [23], within estuaries [46] and along transects of up to 2000 km [8,16] varied in response to organic matter distribution, salinity, temperature, depth, nutrient concentrations and suspended particles for instance. Furthermore, the temporal variation has been extensively studied in various aquatic environments.…”

Section: Introductionmentioning

confidence: 99%

Spatiotemporal variation of the bacterioplankton community in the German Bight: from estuarine to offshore regions

2016

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Marine microbial biogeography has been studied intensively; however few studies address community variation across temporal and spatial scales simultaneously so far. Here we present a yearlong study investigating the dynamics of the free-living and particle-attached bacterioplankton community across a 100 km transect in the German Bight reaching from the Elbe estuary towards the open North Sea. Community composition was assessed using automated ribosomal intergenic spacer analysis and linked to environmental parameters applying multivariate statistical techniques. Results suggest that the spatial variation of the bacterioplankton community is defined by hydrographic current conditions, which separate the inner German Bight from the open North Sea and lead to pronounced differences in the coastal and offshore bacterioplankton community. However this spatial variation is overwhelmed by a strong temporal variation which is triggered by temperature as the main driving force throughout the whole transect. Variation in the free-living community was predominantly driven by temperature, whereas the particle-attached community exhibited stronger spatial variation patterns.

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Bacterial biogeography in the coastal waters of northern Zhejiang, East China Sea is highly controlled by spatially structured environmental gradients

Cited by 93 publications

References 73 publications

Thermal discharge-created increasing temperatures alter the bacterioplankton composition and functional redundancy

Thermal discharge-created increasing temperatures alter the bacterioplankton composition and functional redundancy

Regional variations in the diversity and predicted metabolic potential of benthic prokaryotes in coastal northern Zhejiang, East China Sea

Spatiotemporal variation of the bacterioplankton community in the German Bight: from estuarine to offshore regions

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