Multifaceted aspects of synchrony between freshwater prokaryotes and protists

Obertegger, Ulrike; Pindo, Massimo; Flaim, Giovanna

doi:10.1111/mec.15228

Cited by 7 publications

(8 citation statements)

References 73 publications

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“…We attributed this year effect to a change in the lake’s hydrology. The years from 2014 to 2017 showed a decreasing gradient in precipitation (Obertegger et al, 2019). Furthermore during the year 2017, Lake Tovel experienced a shift from nival to pluvial origin of its waters, leading to whole lake warming and increased stability of the water column (Flaim et al 2019).…”

Section: Discussionmentioning

confidence: 99%

“…Temperature values taken with a multiparametric probe (Idronaut Ocean Seven 316 Plus) at 1‐m intervals were averaged within the respective profile for the littoral (0–4 m), pelagic (0–20 m), and deep hypolimnion (30–35 m). Precipitation (mm), provided from the onshore meteorological station, and water level change (cm) were averaged for the 10 days before sampling as in Obertegger et al (2019). Total yearly precipitation (mm) at Lake Tovel showed a decreasing gradient from 2014 to 2017 (2014: 1867 mm; 2015: 1027 mm; 2016: 1110 mm; 2017: 978 mm; Obertegger et al, 2018).…”

Section: Methodsmentioning

confidence: 99%

“…Furthermore, we focused on three distinct habitats within Lake Tovel that reflect a varying degree of hydrological stability, light climate, and community composition; the littoral is the most hydrologically unstable because it receives >80% of the lake’s water inflow through underground springs (Borsato & Ferretti, 2006) while the hypolimnion is considered the most stable because of its sheltered position from the in‐ and outflow, and the pelagic is intermediate (Obertegger et al, 2018). Furthermore, the littoral shows highest, the hypolimnion lowest, and the pelagic intermediate light transparency (Obertegger, Pindo, & Flaim, 2019), an important parameter for phytoplankton (Richardson, Beardall, & Raven, 1983). Planktonic communities respond to hydrological stability (Winder & Hunter, 2008; Shade, Jones, & McMahon, 2008; Obertegger et al, 2018) and changing light climate (Edwards, Thomas, Klausmeier, & Litchman, 2016), and varying community composition in different habitats should be equally indicated by microscopy and HTS data.…”

Section: Introductionmentioning

confidence: 99%

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Do inferences about freshwater phytoplankton communities change when based on microscopy or high‐throughput sequencing data?

2020

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Microscopy and high‐throughput sequencing (HTS) detect and quantify algae differently. It is not known if microscopy‐based abundance or biomass better compare to HTS data or how methodological differences affect ecological inferences about the phytoplankton communities studied. We investigated methodological (abundancemicroscopy vs. abundanceHTS, biomassmicroscopy vs. abundanceHTS), habitat (littoral, pelagic, deep hypolimnion), and year (2014 vs. 2017) differences for phytoplankton communities of Lake Tovel (Italy) using ANOVA. Specifically, we tested the hypothesis that depending on comparing abundancemicroscopy or biomassmicroscopy to abundanceHTS different effects would be indicated; we called this the metric effect. Furthermore, using samples from 2014 to 2017, we investigated environment–community relationships by a redundancy analysis based on abundancemicroscopy, biomassmicroscopy, and abundanceHTS, and compared the results. Approximately 9 times more operational taxonomic units were reported with HTS (n2014 = 819, n2017 = 891) than algal taxa with microscopy (n2014 = 90, n2017 = 109) in 2014 and 2017. While microscopically assessed algal taxa were evenly distributed among phyla, the vast majority of operational taxonomic units were attributed to Chrysophyta (2014 = 54%, 2017 = 62%) and Bacillariophyta (2014 = 19%, 2017 = 17%). A metric effect for method differences was generally observed comparing abundancemicroscopy to abundanceHTS with Chlorophyta, Cryptophyta, and Dinophyta showing higher % abundance with microscopy while richness and Chrysophyta showed higher values with HTS. Almost no metric effects were found in 2014, but they were common across phyla in 2017. Bacillariophyta and Eustigmatophyta showed the same habitat differences when comparing biomassmicroscopy to abundanceHTS. Dinophyta showed habitat differences only with microscopy, while Chyrsophyta showed habitat differences only with HTS; these results were probably related to technical bias and strengths of HTS, respectively. Habitat differences of phyla were reasonably related to their ecological niche and linked to factors such as temperature and feeding preferences; furthermore, phyla often showed a significant 2014‐versus‐2017 year effect. The year 2014 was very wet while 2017 had a dry winter, and we attributed the patterns found to allochthonous nutrient input by rain and decreased turbulence. Redundancy analyses based on phytoplankton communities assessed with microscopy and HTS, respectively, equally indicated the importance of hydrology, nutrients, and temperature for phytoplankton communities and discriminated the littoral from the deep hypolimnion. However, variance explained was higher with HTS, and the pelagic was similar to the deep hypolimnion with microscopy but to the littoral with HTS. Despite the different strengths of microscopy and HTS for biodiversity assessment, both datasets outlined similar large‐scale patterns linked to strong environmental control of phytoplankton communities as they related to habitat...

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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Do inferences about freshwater phytoplankton communities change when based on microscopy or high‐throughput sequencing data?

2020

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“…Phytoplankton and heterotrophic bacteria are linked in multiple ways such as competition for nutrients, use of algal exudates, decomposition of decaying algae, or mixotrophic predation of algae on bacteria (Bižić-Ionescu et al, 2014;Salcher, 2014;Unrein et al, 2014;Ivanova et al, 2018). While prokaryotes and protists are in temporal synchrony in Lake Tovel during the ice-free period (Obertegger et al, 2019), this study indicated temporal differences. Small environmental differences in under-ice conditions can have huge impacts on phytoplankton composition (Vehmaa & Salonen, 2009), and we suggest that year-to-year variability in under-ice environmental conditions and biotic interactions (e.g.…”

Section: Discussionmentioning

confidence: 59%

Multi-annual comparisons of summer and under-ice phytoplankton communities of a mountain lake

et al. 2022

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Little is known on the dynamics of under-ice phytoplankton communities. We investigated phytoplankton communities in the upper (0–20 m) and lower (30–35 m) layer of oligotrophic Lake Tovel, Brenta Dolomites (Italy) over 6 years during summer and under ice. Winter conditions were different from one year to another with respect to ice thickness and snow cover. Proxies for light transmission (Secchi disc transparency, light attenuation) were similar between seasons, even though the incident solar radiation was lower in winter. Algal richness and chlorophyll-a were not different between seasons while biomass was higher during summer. In four of the 6 years, Bacillariophyta dominated during summer and Miozoa (class Dinophyceae) under ice while in 2 years Bacillariophyta also dominated under ice. Generally, a shift to larger size classes from summer to under ice was observed for Bacillariophyta, Chlorophyta, and Ochrophyta (class Chrysophyceae) while Dinophyceae showed the opposite pattern. No strong links between phytoplankton community composition and abiotic factors (under-ice convective mixing, snow on ice, under-ice light) were found. We suggest that inter-species relationships and more precise indicators of under-ice light should be considered to better understand under-ice processes.

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“…However, longer term studies eventually reflecting seasonal patterns are still very rare (Gilbert et al, 2012; Karl & Church, 2014; Linz et al, 2017). Furthermore, most microbial diversity studies, including temporal surveys, focus on either archaeal, bacterial or eukaryotic communities, but an integrated view of how the two change with time, eventually revealing underlying biotic interactions, are extremely scarce and restricted to large environments such as oceans and lakes (Biller et al, 2018; Obertegger et al, 2019; Steele et al, 2011). Yet, differences in overall metabolic capabilities, physiology, trophic features, generation time and dispersal might be reflected in distinct temporal patterns of bacteria and archaea vs. microbial eukaryotes.…”

Section: Introductionmentioning

confidence: 99%

Small freshwater ecosystems with dissimilar microbial communities exhibit similar temporal patterns

et al. 2021

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Despite small freshwater ecosystems being biodiversity reservoirs and contributing significantly to greenhouse fluxes, their microbial communities remain largely understudied. Yet, microorganisms intervene in biogeochemical cycling and impact water quality. Because of their small size, these ecosystems are in principle more sensitive to disturbances, seasonal variation and pluri-annual climate change. However, how microbial community composition varies over space and time, and whether archaeal, bacterial and microbial eukaryote communities behave similarly remain unanswered.Here, we aim to unravel the composition and intra/interannual temporal dynamic patterns for archaea, bacteria and microbial eukaryotes in a set of small freshwater ecosystems. We monitored archaeal and bacterial community composition during 24 consecutive months in four ponds and one brook from northwestern France by 16S rRNA gene amplicon sequencing (microbial eukaryotes were previously investigated for the same systems). Unexpectedly for oxic environments, bacterial Candidate Phyla Radiation (CPR) were highly diverse and locally abundant. Our results suggest that microbial community structure is mainly driven by environmental conditions acting over space (ecosystems) and time (seasons). A low proportion of operational taxonomic units (OTUs) (<1%) was shared by the five ecosystems despite their geographical proximity (2-9 km away), making microbial communities almost unique in each ecosystem and highlighting the strong selective influence of local environmental conditions. Marked and similar seasonality patterns were observed for archaea, bacteria and microbial eukaryotes in all ecosystems despite strong turnovers of rare OTUs. Over the 2-year survey, microbial community composition varied despite relatively stable environmental parameters. This suggests that biotic associations play an important role in interannual community assembly.

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Multifaceted aspects of synchrony between freshwater prokaryotes and protists

Cited by 7 publications

References 73 publications

Do inferences about freshwater phytoplankton communities change when based on microscopy or high‐throughput sequencing data?

Do inferences about freshwater phytoplankton communities change when based on microscopy or high‐throughput sequencing data?

Multi-annual comparisons of summer and under-ice phytoplankton communities of a mountain lake

Small freshwater ecosystems with dissimilar microbial communities exhibit similar temporal patterns

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