Diversity of Arctic pelagic &amp;lt;i&amp;gt;Bacteria&amp;lt;/i&amp;gt; with an emphasis on photoheterotrophs: a review

Bœuf, Dominique Le; Humily, Florian; Jeanthon, Christian

doi:10.5194/bg-11-3309-2014

Cited by 21 publications

(17 citation statements)

References 137 publications

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“…In the upper ice horizons, increased permeability may have aided the bacteria to utilize the EPSs produced during the winter and/or other carbon sources frozen in ice during the autumn freeze‐up, as also discussed previously (Riedel et al, ; Deming, ). Another, yet very speculative, survival strategy of bacteria under nutrient limitation and salinity stress may be their ability to obtain supplementary energy from light via light‐harvesting pigments (e.g., proteo‐ and xanthorhodopsins; Feng et al ., ; Palovaara et al ., ) as well as bacteriochlorophyll a (Koh et al ., ; Boeuf et al ., ), which are found throughout the major sea‐ice bacterial classes, such as Flavobacteriia, Gammaproteobacteria and Alphaproteobacteria (Koh et al, ; Vollmers et al ., ). Bacterial genera from these classes, potentially possessing light harvesting pigments were also abundant at all three stations in our study.…”

Section: Resultsmentioning

confidence: 99%

Bacterial communities in Arctic first‐year drift ice during the winter/spring transition

Eronen-Rasimus

Piiparinen

Karkman

et al. 2016

Environ Microbiol Rep

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Horizontal and vertical variability of first-year drift-ice bacterial communities was investigated along a North-South transect in the Fram Strait during the winter/spring transition. Two different developmental stages were captured along the transect based on the prevailing environmental conditions and the differences in bacterial community composition. The differences in the bacterial communities were likely driven by the changes in sea-ice algal biomass (2.6-5.6 fold differences in chl-a concentrations). Copiotrophic genera common in late spring/summer sea ice, such as Polaribacter, Octadecabacter and Glaciecola, dominated the bacterial communities, supporting the conclusion that the increase in the sea-ice algal biomass was possibly reflected in the sea-ice bacterial communities. Of the dominating bacterial genera, Polaribacter seemed to benefit the most from the increase in algal biomass, since they covered approximately 39% of the total community at the southernmost stations with higher (>6 μg l(-1) ) chl-a concentrations and only 9% at the northernmost station with lower chl-a concentrations (<6 μg l(-1) ). The sea-ice bacterial communities also varied between the ice horizons at all three stations and thus we recommend that for future studies multiple ice horizons be sampled to cover the variability in sea-ice bacterial communities in spring.

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Section: Resultsmentioning

confidence: 99%

Bacterial communities in Arctic first‐year drift ice during the winter/spring transition

Eronen-Rasimus

Piiparinen

Karkman

et al. 2016

Environ Microbiol Rep

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“…AAP bacteria are abundant in various marine environments (Kolber et al, , Cottrell et al, , Sieracki et al, , Jiao et al, , Yutin et al, , Boeuf et al, ) and also in many freshwater lakes and rivers (Mašín et al, , Mašín et al, , Ruiz‐González et al, , Čuperová et al, , Caliz and Casamayor, , Fauteux et al, , Lew et al, ). Freshwater AAP bacteria seem to represent a diverse assemblage of species belonging exclusively to different subgroups of Alpha‐ and Betaproteobacteria (Waidner and Kirchman, , Shi et al, , Salka et al, , Čuperová et al, , Caliz and Casamayor, ).…”

Section: Introductionmentioning

confidence: 99%

High turnover rates of aerobic anoxygenic phototrophs in European freshwater lakes

Cepáková

Hrouzek

Žišková

et al. 2016

Environmental Microbiology

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Aerobic Anoxygenic Phototrophic (AAP) bacteria are bacteriochlorophyll (BChl) a -containing organisms which use light energy to supplement their predominantly heterotrophic metabolism. Here, we investigated mortality and growth rates of AAP bacteria in three different freshwater lakes in Central Europe: the mountain lake Plešné, the oligo-mesotrophic Lake Stechlin and the forest pond Huntov. The mortality of AAP bacteria was estimated from diel changes of BChl a fluorescence. Net and gross growth rates were calculated from the increases in AAP cell numbers. The gross growth rates of AAP bacteria ranged from 0.38 to 5.6 d , with the highest values observed during summer months. Simultaneously, the rapidly growing AAP cells have to cope with an intense grazing pressure by both zooplankton and protists. The presented results document that during the day, gross growth usually surpased mortality. Our results indicate that AAP bacteria utilize light energy under natural conditions to maintain rapid growth rates, which are balanced by a generally intense grazing pressure.

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“…According to most previous studies carried out in the Arctic Ocean [12,71,79], as well as in Antarctic seas [80], Cyanobacteria seem to be practically absent from sea ice and surface SW. Initially we detected various sequences that were classified as Cyanobacteria, but these were later identified as chloroplasts.…”

Section: Are Cyanobacteria Absent?mentioning

confidence: 89%

“…Similarly, bacterial community composition in the SW of the Arctic shelf LMEs is quite variable at the class level [12,71]. The differences may partly be attributed to environmental variability on temporal (seasonal) or spatial (coastal vs. open ocean) scales, or if the sea was ice-covered or not, but often there does not seem to be any clear pattern.…”

Section: Community Structure-bacterial Classesmentioning

confidence: 99%

“…However, low temperature should not be a restriction for the occurrence of Cyanobacteria [82], e.g., coccoid picocyanobacteria have been reported in several studies from Arctic coastal regions [71,[83][84][85][86]. It has been argued that the Cyanobacteria reported from the Arctic Ocean represent allochthonous influences from land [87].…”

Section: Are Cyanobacteria Absent?mentioning

confidence: 99%

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Bacterial community structure in a sympagic habitat expanding with global warming: brackish ice brine at 85–90 °N

et al. 2018

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Larger volumes of sea ice have been thawing in the Central Arctic Ocean (CAO) during the last decades than during the past 800,000 years. Brackish brine (fed by meltwater inside the ice) is an expanding sympagic habitat in summer all over the CAO. We report for the first time the structure of bacterial communities in this brine. They are composed of psychrophilic extremophiles, many of them related to phylotypes known from Arctic and Antarctic regions. Community structure displayed strong habitat segregation between brackish ice brine (IB; salinity 2.4-9.6) and immediate sub-ice seawater (SW; salinity 33.3-34.9), expressed at all taxonomic levels (class to genus), by dominant phylotypes as well as by the rare biosphere, and with specialists dominating IB and generalists SW. The dominant phylotypes in IB were related to Candidatus Aquiluna and Flavobacterium, those in SW to Balneatrix and ZD0405, and those shared between the habitats to Halomonas, Polaribacter and Shewanella. A meta-analysis for the oligotrophic CAO showed a pattern with Flavobacteriia dominating in melt ponds, Flavobacteriia and Gammaproteobacteria in solid ice cores, Flavobacteriia, Gamma- and Betaproteobacteria, and Actinobacteria in brine, and Alphaproteobacteria in SW. Based on our results, we expect that the roles of Actinobacteria and Betaproteobacteria in the CAO will increase with global warming owing to the increased production of meltwater in summer. IB contained three times more phylotypes than SW and may act as an insurance reservoir for bacterial diversity that can act as a recruitment base when environmental conditions change.

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Diversity of Arctic pelagic <i>Bacteria</i> with an emphasis on photoheterotrophs: a review

Cited by 21 publications

References 137 publications

Bacterial communities in Arctic first‐year drift ice during the winter/spring transition

Bacterial communities in Arctic first‐year drift ice during the winter/spring transition

High turnover rates of aerobic anoxygenic phototrophs in European freshwater lakes

Bacterial community structure in a sympagic habitat expanding with global warming: brackish ice brine at 85–90 °N

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