Co-occurrence Networks Among Bacteria and Microbial Eukaryotes of Lake Baikal During a Spring Phytoplankton Bloom

Михайлов, И. С.; Zakharova, Yulia; Bukin, Yu. S.; Galachyants, Yuri P.; Petrova, Darya P.; Sakirko, M. V.; Likhoshway, Ye. V.

doi:10.1007/s00248-018-1212-2

Cited by 113 publications

(65 citation statements)

References 71 publications

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“…In December, Teleaulax and Dinobryon were other abundant genera after Aulacoseira and Thalassiosira, with an average relative abundance of 11.33% and 11.17%, respectively. Teleaulax belongs to Cryptophyta, which was also detected by Mikhailov et al [60] during spring algal blooms in Lake Baikal. It contributed the highest proportions of 15% for total eukaryotic reads, and was positively correlated with Cryptococcus.…”

Section: Microbial Eukaryotic Community Compositionsupporting

confidence: 65%

“…Among these correlations, 18 were negative and only one was positive (with Bromeliophrya), indicating that Penicillium negatively affected the growth of the majority of other genera, or that there might be an antagonistic and competitive [36], or saprophytic [14], association between Penicillium and these genera. Correlations from modules II and V-VII were all positive, and positive correlations from modules V-VII were especially significant, indicating that the eukaryotic genera from these modules might arise from similar niches or mutualism [60,61,66]. Additionally, in module II, Phanerochaete was observed to have the highest positive correlations with other eukaryotic genera (adegree of 20), followed closely by Pleiochaeta with a degree of 13.…”

Section: Relationships Between Phytoplankton and Eukaryotic Communitimentioning

confidence: 91%

“…Similarly, as the common dominant taxon, Ciliophora were also observed with a maximal relative abundance (10.93%) in November (at a depth of 2 m). Ciliophora and Cercozoa are widely distributed and ubiquitous in lakes [11,14,32,60,61] and reservoirs [15,62], and they are important consumers of algae and bacteria, which occupy a pivotal position in aquatic food webs by transferring nutrients to higher trophic levels [61]. Nematoda, Ciliophora, and Cercozoa are also affiliated with zooplankton, inducing a decrease of algal density by predation and altering the structure of phytoplankton communities by selecting specific algae [31].…”

Section: Microbial Eukaryotic Community Compositionmentioning

confidence: 99%

“…The authors also observed that rare and non-rare taxa exhibited synergistic effects that might contribute to maintaining the stability and resilience of eukaryotic communities and ecological function. Mikhailov et al [60] found that species from the microbial metacommunity occupied positive correlations and were highly interconnected with one another within a specific domain. Positive associations between bacteria and eukaryotes may be used as evidence of mutualistic interactions, whereas negative associations may indicate competition.…”

Section: Relationships Between Phytoplankton and Eukaryotic Communitimentioning

confidence: 99%

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Community Compositions of Phytoplankton and Eukaryotes during the Mixing Periods of a Drinking Water Reservoir: Dynamics and Interactions

Yan

Chen

Huang

et al. 2020

IJERPH

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In deep drinking water reservoir ecosystems, the dynamics and interactions of community compositions of phytoplankton and eukaryotes during the mixing periods are still unclear. Here, morphological characteristics combined with high-throughput DNA sequencing (HTS) were used to investigate the variations of phytoplankton and the eukaryotic community in a large canyon-shaped, stratified reservoir located at the Heihe River in Shaanxi Province for three months. The results showed that Bacillariophyta and Chlorophyta were the dominant taxa of the phytoplankton community, accounting for more than 97% of total phytoplankton abundance, which mainly consisted of Melosira sp., Cyclotella sp., and Chlorella sp., respectively. Illumina Miseq sequencing suggested that the biodiversity of eukaryotes increased over time and that species distribution was more even. Arthropoda (6.63% to 79.19%), Ochrophyta (5.60% to 35.16%), Ciliophora (1.81% to 10.93%) and Cryptomonadales (0.25% to 11.48%) were the keystone taxa in common, contributing over 50% of the total eukaryotic community. Cryptomycota as a unique fungus was observed to possess significant synchronization with algal density, reaching a maximum of 10.70% in December (when the algal density distinctly decreased) and suggesting that it might affect the growth of algae through parasitism. Co-occurrence network patterns revealed the complicated and diverse interactions between eukaryotes and phytoplankton, suggesting that eukaryotes respond to variations in dynamic structure of the phytoplankton community, although there might be antagonistic or mutualistic interactions between them. Redundancy analysis (RDA) results showed that environmental variables collectively explained a 96.7% variance of phytoplankton and 96.3% variance of eukaryotic microorganisms, indicating that the temporal variations of phytoplankton and eukaryotic microorganisms were significantly affected by environmental conditions. This study shows that potential interactions exist between phytoplankton and eukaryotic microorganism communities, andcould improve our understanding of the ecological roles of phytoplankton and eukaryotic microorganisms in changing aquatic ecosystems. However, long-term investigations are necessary in order to obtain comprehensive understandings of their complicated associations.

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Section: Microbial Eukaryotic Community Compositionsupporting

confidence: 65%

Section: Relationships Between Phytoplankton and Eukaryotic Communitimentioning

confidence: 91%

Section: Microbial Eukaryotic Community Compositionmentioning

confidence: 99%

Section: Relationships Between Phytoplankton and Eukaryotic Communitimentioning

confidence: 99%

See 2 more Smart Citations

Community Compositions of Phytoplankton and Eukaryotes during the Mixing Periods of a Drinking Water Reservoir: Dynamics and Interactions

Yan

Chen

Huang

et al. 2020

IJERPH

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“…The first study [28] provided insights on the genetic diversity of protists from the southern basin of Lake Baikal (see Figure 1), pointing to novel diversity. Another study investigated co-occurrence networks of bacteria and microbial eukaryotes during the spring season [29], indicating positive correlations between specific Operational Taxonomic Units (OTUs) as well as the influence of geography on the microbial community structure. Despite the insights provided by these studies, more efforts are needed in order to understand protist diversity and evolution in Lake Baikal.…”

Section: Introductionmentioning

confidence: 99%

Tracing the Origin of Planktonic Protists in an Ancient Lake

2020

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Ancient lakes are among the most interesting models for evolution studies because their biodiversity is the result of a complex combination of migration and speciation. Here, we investigate the origin of single celled planktonic eukaryotes from the oldest lake in the world—Lake Baikal (Russia). By using 18S rDNA metabarcoding, we recovered 1414 Operational Taxonomic Units (OTUs) belonging to protists populating surface waters (1–50 m) and representing pico/nano-sized cells. The recovered communities resembled other lacustrine freshwater assemblages found elsewhere, especially the taxonomically unclassified protists. However, our results suggest that a fraction of Baikal protists could belong to glacial relicts and have close relationships with marine/brackish species. Moreover, our results suggest that rapid radiation may have occurred among some protist taxa, partially mirroring what was already shown for multicellular organisms in Lake Baikal. We found 16% of the OTUs belonging to potential species flocks in Stramenopiles, Alveolata, Opisthokonta, Archaeplastida, Rhizaria, and Hacrobia. Putative flocks predominated in Chrysophytes, which are highly diverse in Lake Baikal. Also, the 18S rDNA of a number of species (7% of the total) differed >10% from other known sequences. These taxa as well as those belonging to the flocks may be endemic to Lake Baikal. Overall, our study points to novel diversity of planktonic protists in Lake Baikal, some of which may have emerged in situ after evolutionary diversification.

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Rhizosphere bacterial community structure of three minor grain crops: A case‐study from paired field sites in northern China

et al. 2021

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Rhizosphere bacteria are critical to plant health and ecological functioning. However, our understanding of rhizosphere bacterial community turnover and co-occurrences with minor grain crops remains limited, especially at regional scales. Herein, we compared the turnover and networks of foxtail millet, proso millet, and sorghum rhizosphere bacterial communities across nine paired fields in northern China. Remarkable differences in community composition, diversity between three minor grain crops, and the influence of region on these indicators was greater than that of crop type.Community richness of foxtial millet, proso millet, and sorgum showed a unimodal curve with latitude increased. Compared to spatial factors, environmental variables had greater effects on the rhizosphere bacterial community turnover in three minor grain crops. Edaphic variables were more important than climatic variables for rhizosphere bacterial community composition in foxtail millet fields. In addition, soil organic matter (OM) and total nitrogen (TN) were the key factors influencing the turnover of rhizosphere communities in foxtail millet and sorghum. In contrast, pH and TN were important factors influencing the turnover of rhizosphere communities in proso millet. Rhizosphere bacterial networks were more closely interconnected in proso millet fields than in the other two crops, showing the lower average path length and diameter, greater average clustering, and graph density. In addition, Proteobacteria, Actinobacteria, and Acidobacteria played major roles in the rhizosphere bacterial network structures and were predicted to maintain generalist metabolic diversity. These findings provide new insights for expanding our knowledge of the biogeography and coexistence theory of minor grain crop ecosystems at a large scale.

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Co-occurrence Networks Among Bacteria and Microbial Eukaryotes of Lake Baikal During a Spring Phytoplankton Bloom

Cited by 113 publications

References 71 publications

Community Compositions of Phytoplankton and Eukaryotes during the Mixing Periods of a Drinking Water Reservoir: Dynamics and Interactions

Community Compositions of Phytoplankton and Eukaryotes during the Mixing Periods of a Drinking Water Reservoir: Dynamics and Interactions

Tracing the Origin of Planktonic Protists in an Ancient Lake

Rhizosphere bacterial community structure of three minor grain crops: A case‐study from paired field sites in northern China

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