Is core bacterial community more vulnerable to environmental changes in dammed river?

Shijun Zhu; Chen Wen; Shanshan Xie; Xia Luo

doi:10.1088/1755-1315/742/1/012022

Collection of Environmental Variables and Bacterial Community Compositions in Marian Cove, Antarctica, during Summer 2018

Data ◽

10.3390/data6030027 ◽

2021 ◽

Vol 6 (3) ◽

pp. 27

Author(s):

Hyo-Ryeon Kim ◽

Jae-Hyun Lim ◽

Ju-Hyoung Kim ◽

Il-Nam Kim

Keyword(s):

Bacterial Community ◽

Community Composition ◽

Marine Bacteria ◽

Environmental Variables ◽

Environmental Changes ◽

Bacterial Community Composition ◽

Composition Data ◽

Decomposition Of Organic Matter ◽

Class Level ◽

Earth’S Climate

Marine bacteria, which are known as key drivers for marine biogeochemical cycles and Earth’s climate system, are mainly responsible for the decomposition of organic matter and production of climate-relevant gases (i.e., CO₂, N₂O, and CH₄). However, research is still required to fully understand the correlation between environmental variables and bacteria community composition. Marine bacteria living in the Marian Cove, where the inflow of freshwater has been rapidly increasing due to substantial glacial retreat, must be undergoing significant environmental changes. During the summer of 2018, we conducted a hydrographic survey to collect environmental variables and bacterial community composition data at three different layers (i.e., the seawater surface, middle, and bottom layers) from 15 stations. Of all the bacterial data, 17 different phylum level bacteria and 21 different class level bacteria were found and Proteobacteria occupy 50.3% at phylum level following Bacteroidetes. Gammaproteobacteria and Alphaproteobacteria, which belong to Proteobacteria, are the highest proportion at the class level. Gammaproteobacteria showed the highest relative abundance in all three seawater layers. The collection of environmental variables and bacterial composition data contributes to improving our understanding of the significant relationships between marine Antarctic regions and marine bacteria that lives in the Antarctic.

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Changes in Heterotrophic Picoplankton Community Structure after Induction of a Phytoplankton Bloom under Different Light Regimes

Diversity ◽

10.3390/d11100195 ◽

2019 ◽

Vol 11 (10) ◽

pp. 195 ◽

Cited By ~ 1

Author(s):

Karayanni ◽

Kormas ◽

Moustaka-Gouni ◽

Sommer

Keyword(s):

Community Structure ◽

Bacterial Community ◽

Relative Abundance ◽

Environmental Changes ◽

Phytoplankton Bloom ◽

Phytoplankton Growth ◽

Light Regimes ◽

Operational Taxonomic Units ◽

Abundant Otus

Bacterial and archaeal diversity and succession were studied during a mesocosm experiment that investigated whether changing light regimes could affect the onset of phytoplankton blooms. For this, 454-pyrosequencing of the bacterial V1-V3 and archaeal V3-V9 16S rRNA regions was performed in samples collected from four mesocosms receiving different light irradiances at the beginning and the end of the experiment and during phytoplankton growth. In total, 46 bacterial operational taxonomic units (OTUs) with ≥1% relative abundance occurred (22–34 OTUs per mesocosm). OTUs were affiliated mainly with Rhodobacteraceae, Flavobacteriaceae and Alteromonadaceae. The four mesocosms shared 11 abundant OTUs. Dominance increased at the beginning of phytoplankton growth in all treatments and decreased thereafter. Maximum dominance was found in the mesocosms with high irradiances. Overall, specific bacterial OTUs had different responses in terms of relative abundance under in situ and high light intensities, and an early phytoplankton bloom resulted in different bacterial community structures both at high (family) and low (OTU) taxonomic levels. Thus, bacterial community structure and succession are affected by light regime, both directly and indirectly, which may have implications for an ecosystem’s response to environmental changes.

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Urbanization-induced environmental changes strongly affect wetland soil bacterial community composition and diversity

Environmental Research Letters ◽

10.1088/1748-9326/ac444f ◽

2021 ◽

Author(s):

Xinyu Yi ◽

Chen Ning ◽

Shuailong Feng ◽

Haiqiang Gao ◽

Jianlun Zhao ◽

...

Keyword(s):

Bacterial Community ◽

Bacterial Communities ◽

Environmental Changes ◽

Bacterial Community Composition ◽

Soil Microbial Communities ◽

Environmental Drivers ◽

Wetland Soil ◽

Rrna Gene ◽

Soil Microbial ◽

Soil Bacterial

Abstract Soil microbial communities potentially serve as indicators for their responses to changes in various ecosystems at scales from a region to the globe. However, changes in wetland soil bacterial communities and how they are related to urbanization intensities remains poorly understood. Here, we collected sixty soil samples along urbanization intensity gradients from twenty wetlands. We measured a range of environmental factors and characterized bacterial communities structure using 16S rRNA gene amplicon sequencing that targeted the V4-V5 region. Our results revealed the dominant soil microbial phyla included Proteobacteria (39.3%), Acidobacteria (21.4%) and Chloroflexi (12.3%) in the wetlands, and showed a significant divergence of composition in intensive urbanization area (UI_4) than other places. A critical "threshold" exists in the soil bacterial diversity, demonstrating different patterns: a gradual increase in the areas of low-to-intermediate disturbances but a significant decrease in highly urbanized areas where metabolic functions were significantly strong. Additionally, soil pH, total phosphorus (TP), available phosphorus (AP ) and ammonia nitrogen (NH4+-N) made a significant contribution to variations in bacterial communities, explaining 49.6%, 35.1%, 26.2% and 30.7% of the total variance, respectively. pH and NH4+-N were identified as the main environmental drivers to determine bacterial community structure and diversity in the urban wetlands. Our results highlight collective changes in multiple environmental variables induced by urbanization rather than by the proportion of impervious surface area (ISA), which were potentially attributed to the spatial heterogeneity along different urbanization gradients.

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Drivers on The Halophytes' Rhizosphere Bacteria Community and Functions in North China Salinized Areas

10.21203/rs.3.rs-215157/v1 ◽

2021 ◽

Author(s):

Fating Yin ◽

Fenghua Zhang ◽

Zhibo Cheng ◽

Haoran Wang

Keyword(s):

Bacterial Community ◽

North China ◽

High Throughput Sequencing ◽

Environmental Changes ◽

Rhizosphere Soil ◽

Ph Value ◽

Northern China ◽

Soil Bacterial Community ◽

Leymus Chinensis ◽

Soil Bacterial

Abstract Soil salinity is a serious environmental issue in arid China. Soil bacteria play a fundamental role in soil systems and respond rapidly to environmental changes. However, the responses of soil bacterial community to the different halophytes remains poorly understood. We investigated rhizosphere soil bacterial community changes under different halophytes in north China using high-throughput sequencing. Three typical halophytes were Leymus chinensis (LC), Puccinellia tenuiflora (PT), Suaeda glauca (SG). The dominant phyla were Proteobacteria, Actinobacteria, and Chloroflexi across three halophytic vegetation. These bacteria have important assistance for halophytes adapt to saline soil. PICRUSt forecasts demonstrated that energy metabolism, amino acid metabolism and carbohydrate metabolism are main bacterial functions in halophyte vegetation soil, and the abundance of metabolism these bacterial functions in SG was significantly higher than that in LC and PT. The pH value of different halophyte rhizosphere soils has a more significant effect on bacterial diversity than EC and soil trophic status, and soil water content (SWC) was important effect factors leading to differences in bacterial functions. These results give us a deeper understanding of the diversity and functional differences of rhizosphere soil bacterial communities in the typical halophytic vegetation of northern China.

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Latitudinal Distributions and Controls of Bacterial Community Composition during the Summer of 2017 in Western Arctic Surface Waters (from the Bering Strait to the Chukchi Borderland)

Scientific Reports ◽

10.1038/s41598-019-53427-4 ◽

2019 ◽

Vol 9 (1) ◽

Author(s):

Jiyoung Lee ◽

Sung-Ho Kang ◽

Eun Jin Yang ◽

Alison M. Macdonald ◽

Hyoung Min Joo ◽

...

Keyword(s):

Bacterial Community ◽

Arctic Ocean ◽

Community Composition ◽

Surface Waters ◽

Bacterial Communities ◽

Environmental Changes ◽

Bacterial Community Composition ◽

Bering Strait ◽

Western Arctic ◽

Chukchi Borderland

AbstractThe western Arctic Ocean is experiencing some of the most rapid environmental changes in the Arctic. However, little is known about the microbial community response to these changes. Employing observations from the summer of 2017, this study investigated latitudinal variations in bacterial community composition in surface waters between the Bering Strait and Chukchi Borderland and the factors driving the changes. Results indicate three distinctive communities. Southern Chukchi bacterial communities are associated with nutrient rich conditions, including genera such as Sulfitobacter, whereas the northern Chukchi bacterial community is dominated by SAR clades, Flavobacterium, Paraglaciecola, and Polaribacter genera associated with low nutrients and sea ice conditions. The frontal region, located on the boundary between the southern and northern Chukchi, is a transition zone with intermediate physical and biogeochemical properties; however, bacterial communities differed markedly from those found to the north and south. In the transition zone, Sphingomonas, with as yet undetermined ecological characteristics, are relatively abundant. Latitudinal distributions in bacterial community composition are mainly attributed to physical and biogeochemical characteristics, suggesting that these communities are susceptible to Arctic environmental changes. These findings provide a foundation to improve understanding of bacterial community variations in response to a rapidly changing Arctic Ocean.

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Environmental changes affect the assembly of soil bacterial community primarily by mediating stochastic processes

Global Change Biology ◽

10.1111/gcb.13080 ◽

2015 ◽

Vol 22 (1) ◽

pp. 198-207 ◽

Cited By ~ 37

Author(s):

Ximei Zhang ◽

Eric R. Johnston ◽

Wei Liu ◽

Linghao Li ◽

Xingguo Han

Keyword(s):

Bacterial Community ◽

Stochastic Processes ◽

Environmental Changes ◽

Soil Bacterial Community ◽

Soil Bacterial

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Distribution and Control of Bacterial Community Composition in Marian Cove Surface Waters, King George Island, Antarctica during the Summer of 2018

Microorganisms ◽

10.3390/microorganisms8081115 ◽

2020 ◽

Vol 8 (8) ◽

pp. 1115

Author(s):

Soyeon Kim ◽

Ju-Hyoung Kim ◽

Jae-Hyun Lim ◽

Jin-Hyun Jeong ◽

Jang-Mu Heo ◽

...

Keyword(s):

Bacterial Community ◽

Spatial Variation ◽

Community Composition ◽

Surface Waters ◽

Bacterial Communities ◽

Environmental Changes ◽

Bacterial Community Composition ◽

Environmental Parameters ◽

And Control ◽

The Antarctic

Marian Cove is experiencing some of the most rapid environmental changes in the Antarctic region; however, little is known about the response of bacterial communities to these changes. The main purpose of this study was to investigate the spatial variation of physical–biogeochemical–bacterial community features in the Marian Cove surface waters and the environmental parameters governing the spatial variation in the bacterial community composition during the summer of 2018. The Marian Cove surface waters are largely composed of two different characteristics of water masses: relatively low-temperature, -salinity, and -nutrient surface glacier water (named SGW) and relatively high-temperature, -salinity, and -nutrient surface Maxwell Bay water (named SMBW). The SGW bacterial communities were dominated by unclassified Cryomorphaceae, Sedimenticola, and Salibacter genera, while the SMBW bacterial communities were dominated by Sulfitobacter, Arcobacter, and Odoribacter genera. Spatial variations in bacterial community composition were mainly attributed to physical and biogeochemical characteristics, suggesting that the bacterial community composition of the Marian Cove surface waters is mainly determined by environmental characteristics. These findings provide a foundation to improve the understanding of bacterial community variations in response to a rapidly changing Marian Cove in the Antarctic.

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Bacterial diversity in Himalayan glacial ice and its relationship to dust

Biogeosciences Discussions ◽

10.5194/bgd-5-3433-2008 ◽

2008 ◽

Vol 5 (4) ◽

pp. 3433-3456 ◽

Cited By ~ 2

Author(s):

S. Zhang ◽

S. Hou ◽

Y. Wu ◽

D. Qin

Keyword(s):

Bacterial Community ◽

Bacterial Diversity ◽

Environmental Changes ◽

Ice Core ◽

Community Diversity ◽

Glacial Ice ◽

Bacterial Community Diversity ◽

Index Analysis ◽

Two Parameters ◽

Epifluorescence Microscope

Abstract. Concentrations and community diversity of bacteria from 50 segments of a 108.83 m ice core drilled from the East Rongbuk (ER) Glacier (28.03° N, 86.96° E, 6518 m above sea level) on the northeast slope of Mt. Qomolangma (Everest), covering the period 950–1963 AD, were investigated by epifluorescence microscope, DGGE and Shannon-Weaver index analysis. There are four general periods of bacterial diversity, corresponding to four phases of dust abundance revealed by Ca2+ concentrations. It is indicated that higher bacterial community diversity is associated with warm periods, while lower bacterial community diversity with cold periods. However, a previously suggested positive correlation between bacterial and Ca2+ concentrations was not indicated by our observations. In fact, a weakly negative correlation was found between these two parameters. Our results suggest that bacterial community diversity, rather than concentrations, might be a suitable biological proxy for the reconstruction of past climatic and environmental changes preserved in glacial ice.

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Impact of Dinophysis acuminata Feeding Mesodinium rubrum on Nutrient Dynamics and Bacterial Composition in a Microcosm

Toxins ◽

10.3390/toxins10110443 ◽

2018 ◽

Vol 10 (11) ◽

pp. 443 ◽

Cited By ~ 3

Author(s):

Han Gao ◽

Chenfeng Hua ◽

Mengmeng Tong

Keyword(s):

Bacterial Community ◽

Nutrient Dynamics ◽

Environmental Changes ◽

Prey Availability ◽

Feeding Activity ◽

Nutrient Status ◽

Prey Cell ◽

Mesodinium Rubrum ◽

Dinophysis Acuminata ◽

Study Laboratory

The development of Dinophysis populations, producers of diarrhetic shellfish toxins, has been attributed to both abiotic (e.g., water column stratification) and biotic (prey availability) factors. An important process to consider is mixotrophy of the Dinophysis species, which is an intensive feeding of the Mesodinium species for nutrients and a benefit from kleptochloroplasts. During the feeding process, the nutritional status in the environment changes due to the preference of Mesodinium and/or Dinophysis for different nutrients, prey cell debris generated by sloppy feeding, and their degradation by micro-organisms changes. However, there is little knowledge about the role of the bacterial community during the co-occurrence of Mesodinium and Dinophysis and how they directly or indirectly interact with the mixotrophs. In this study, laboratory experiments were performed to characterize the environmental changes including those of the prey present, the bacterial communities, and the ambient dissolved nutrients during the co-occurrence of Mesodinium rubrum and Dinophysis acuminata. The results showed that, during the incubation of the ciliate prey Mesodinium with its predator Dinophysis, available dissolved nitrogen significantly shifted from nitrate to ammonium especially when the population of M. rubrum decayed. Growth phases of Dinophysis and Mesodinium greatly affected the structure and composition of the bacterial community. These changes could be mainly explained by both the changes of the nutrient status and the activity of Dinophysis cells. Dinophysis feeding activity also accelerated the decline of M. rubrum and contamination of cultures with okadaic acid, dinophysistoxin-1, and pectenotoxin-2, but their influence on the prokaryotic communities was limited to the rare taxa (<0.1%) fraction. This suggests that the interaction between D. acuminata and bacteria is species-specific and takes place intracellularly or in the phycosphere. Moreover, a majority of the dominant bacterial taxa in our cultures may also exhibit a metabolic flexibility and, thus, be unaffected taxonomically by changes within the Mesodinium-Dinophysis culture system.

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Acidification increases abundances ofVibrionalesandPlanctomycetiaassociated to a seaweed-grazer system: potential consequences for disease and prey digestion efficiency

PeerJ ◽

10.7717/peerj.4377 ◽

2018 ◽

Vol 6 ◽

pp. e4377 ◽

Cited By ~ 7

Author(s):

Tania Aires ◽

Alexandra Serebryakova ◽

Frédérique Viard ◽

Ester A. Serrão ◽

Aschwin H. Engelen

Keyword(s):

Bacterial Community ◽

Gut Microbiome ◽

Pathogenic Bacteria ◽

High Throughput Sequencing ◽

Environmental Changes ◽

Close Association ◽

Inorganic Compounds ◽

Brown Seaweed ◽

Microbial Composition ◽

Variable Regions

Ocean acidification significantly affects marine organisms in several ways, with complex interactions. Seaweeds might benefit from rising CO2through increased photosynthesis and carbon acquisition, with subsequent higher growth rates. However, changes in seaweed chemistry due to increased CO2may change the nutritional quality of tissue for grazers. In addition, organisms live in close association with a diverse microbiota, which can also be influenced by environmental changes, with feedback effects. As gut microbiomes are often linked to diet, changes in seaweed characteristics and associated microbiome can affect the gut microbiome of the grazer, with possible fitness consequences. In this study, we experimentally investigated the effects of acidification on the microbiome of the invasive brown seaweedSargassum muticumand a native isopod consumerSynisoma nadejda. Both were exposed to ambient CO2conditions (380 ppm, pH 8.16) and an acidification treatment (1,000 ppm, pH 7.86) for three weeks. Microbiome diversity and composition were determined using high-throughput sequencing of the variable regions V5-7 of 16S rRNA. We anticipated that as a result of acidification, the seaweed-associated bacterial community would change, leading to further changes in the gut microbiome of grazers. However, no significant effects of elevated CO2on the overall bacterial community structure and composition were revealed in the seaweed. In contrast, significant changes were observed in the bacterial community of the grazer gut. Although the bacterial community ofS. muticumas whole did not change,OceanospirillalesandVibrionales(mainlyPseudoalteromonas) significantly increased their abundance in acidified conditions. The former, which uses organic matter compounds as its main source, may have opportunistically taken advantage of the possible increase of the C/N ratio in the seaweed under acidified conditions.Pseudoalteromonas,commonly associated to diseased seaweeds, suggesting that acidification may facilitate opportunistic/pathogenic bacteria. In the gut ofS. nadejda,the bacterial genusPlanctomycetiaincreased abundance under elevated CO2. This shift might be associated to changes in food (S. muticum) quality under acidification.Planctomycetiaare slow-acting decomposers of algal polymers that could be providing the isopod with an elevated algal digestion and availability of inorganic compounds to compensate the shifted C/N ratio under acidification in their food.In conclusion, our results indicate that even after only three weeks of acidified conditions, bacterial communities associated to ungrazed seaweed and to an isopod grazer show specific, differential shifts in associated bacterial community. These have potential consequences for seaweed health (as shown in corals) and isopod food digestion. The observed changes in the gut microbiome of the grazer seem to reflect changes in the seaweed chemistry rather than its microbial composition.

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