Structuring effects of climate-related environmental factors on Antarctic microbial mat communities

Verleyen, Elie; Sabbe, Koen; Hodgson, Dominic A.; Grubisic, Stana; Taton, Arnaud; Cousin, Sylvie; Wilmotte, Annick; Wever, Aaike De; Gucht, Kathleen Van der; Vyverman, Wim

doi:10.3354/ame01378

Cited by 29 publications

(25 citation statements)

References 66 publications

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“…S2). Other sequences assigned to this genus were detected in Antarctic lakes and sediment cores Powell et al 2005;Coolen et al 2008;Verleyen et al 2010), but the sequences from Beak Island were different from those observed previously (Fig. S2).…”

Section: Bk2-156 3050contrasting

confidence: 45%

“…In general, heterocystous cyanobacteria of the order Nostocales were more diverse in shallower Lake Beak-2 (four OTUs instead of two in Beak-1). These differences in community structure of cyanobacteria between the two lakes were likely related to differences in lake water depth, which has a profound influence on the light climate, which in turn is one of the major factors influencing the structure, diversity and formation of microbial mat communities in Antarctic lakes Verleyen et al 2005Verleyen et al , 2010. Many benthic cyanobacteria are adapted to high light levels, compared to, for instance, diatoms and mosses.…”

Section: Bk221d7a13mentioning

confidence: 99%

“…1). DGGE allows relatively rapid and inexpensive inventory of the most abundant taxa in microbial communities and was successfully used to study present-day cyanobacterial communities in Antarctic lakes (Taton et al 2003;Verleyen et al 2010). It separates PCR products of equal length, but different sequence (and thus melting temperature), on an acrylamide gel containing a gradient of chemical denaturants (Muyzer 1999).…”

Section: Introductionmentioning

confidence: 99%

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Late Holocene changes in cyanobacterial community structure in maritime Antarctic lakes

et al. 2013

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Despite the dominance of cyanobacteria in polar freshwater aquatic ecosystems, little is known about their past biodiversity and response to climate and environmental changes. We explored the use of light microscopy of microfossils, high performance liquid chromatography of the fossil pigment composition and denaturing gradient gel electrophoresis of fossil 16S rRNA genes to study past and present-day differences in cyanobacterial community structure in response to climate changes in two adjacent maritime Antarctic lakes with contrasting depths (4 and 26 m) and light climates. Light microscopy was of limited use because of degradation of cell structures. Fossil cyanobacterial pigment concentrations were below the detection limits of our method in several sediment samples in the deep lake, but abundant and diverse in the sediment core from the shallow pond, probably as a consequence of increased light availability and/or a more diverse and abundant benthic cyanobacterial flora. Total carotenoid and chlorophyll concentrations were highest in both lakes between ca. 2,950 and 1,800 cal yr BP, which coincides with the late Holocene climate optimum recognised elsewhere in maritime Antarctica. Cyanobacterial molecular diversity was higher in the top few centimeters of the sediments in both lakes. In deeper sediments, the taxonomic turnover of cyanobacteria appeared to be relatively small in response to past climate anomalies in both lakes, underscoring the broad tolerance of cyanobacteria to environmental variability. This, however, may in part be explained by the low taxonomic resolution obtained with the relatively conserved 16S rRNA gene and/or the preferential preservation of particular taxa. Our results highlight the potential of fossil DNA in lake sediments to study colonization and succession dynamics of lacustrine cyanobacteria and warrant further investigation of the factors that affect preservation of cyanobacterial DNA.Rafael Fernandez-Carazo and Elie Verleyen contributed equally to this work.Electronic supplementary material The online version of this article

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Section: Bk2-156 3050contrasting

confidence: 45%

Section: Bk221d7a13mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Late Holocene changes in cyanobacterial community structure in maritime Antarctic lakes

et al. 2013

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“…However Nodularia, described regularly for Antarctic microbial mats, in particular in the McMurdo Ice Shelf, McMurdo Dry Valleys and Larsemann and Vestfold Hills (Taton et al 2003a;Jungblut et al 2005;Taton et al 2006), was not found at any of the Arctic sites. These findings, as well as others (Papke et al 2003;Verleyen et al 2010;Bahl et al 2011), suggest that cyanobacteria follow biogeographic patterns more typical of macroscopic organisms, and that both dispersal and/ or settlement limitation likely play important roles in explaining the distribution of cyanobacterial genotypes. In fact, the high morphological diversification of Phormidum autumnale, thriving in the Antarctic from Paleozoic times, suggests the coevolution of lineages and formation of complex associations, resulting in a specific endemic Antarctic cyanobacterial flora (Strunecky´ et al 2012).…”

Section: Aquatic Habitatsmentioning

confidence: 87%

Ecology and biogeochemistry of cyanobacteria in soils, permafrost, aquatic and cryptic polar habitats

et al. 2015

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Polar Regions (continental Antarctica and the Arctic) are characterized by a range of extreme environmental conditions, which impose severe pressures on biological life. Polar cold-active cyanobacteria are uniquely adapted to withstand the environmental conditions of the high latitudes. These adaptations include high ultra-violet radiation and desiccation tolerance, and mechanisms to protect cells from freeze-thaw damage. As the most widely distributed photoautotrophs in these regions, cyanobacteria are likely the dominant contributors of critically essential ecosystem services, particularly carbon and nitrogen turnover in terrestrial polar habitats. These habitats include soils, permafrost, cryptic niches (including biological soil crusts, hypoliths and endoliths), ice and snow, and a range of aquatic habitats. Here we review current literature on the ecology, and the functional role played by cyanobacteria in various Arctic and Antarctic environments. We focus on the ecological importance of cyanobacterial communities in Polar Regions and assess what is known regarding the toxins they produce. We also review the responses and adaptations of cyanobacteria to extreme environments.

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“…Also, Langenheder et al (2004) showed an increase on bacterial richness by DGGE profile in batch cultures during the stationary growth phase of the bacteria. Different bands representing the same OTU in DGGE gel (Figure 2) may be due to ambiguities in the sequences (Verleyen et al, 2010), since differences less than 0.6% may result in different bands (Bondoso et al, 2014) and we defined OTUs at 97% identity threshold.…”

Section: Dynamics Of Bacterial Communitymentioning

confidence: 99%

Bacterial degradation of dissolved organic matter released by Planktothrix agardhii (Cyanobacteria)

et al. 2017

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Although Planktothrix agardhii often produces toxic blooms in eutrophic water bodies around the world, little is known about the fate of the organic matter released by these abundant Cyanobacteria. Thus, this study focused in estimating the bacterial consumption of the DOC and DON (dissolved organic carbon and dissolved organic nitrogen, respectively) produced by axenic P. agardhii cultures and identifying some of the bacterial OTUs (operational taxonomic units) involved in the process. Both P. agardhii and bacterial inocula were sampled from the eutrophic Barra Bonita Reservoir (SP, Brazil). Two distinct carbon degradation phases were observed: during the first three days, higher degradation coefficients were calculated, which were followed by a slower degradation phase. The maximum value observed for particulate bacterial carbon (POC) was 11.9 mg L -1 , which consisted of 62.5% of the total available DOC, and its mineralization coefficient was 0.477 day -1 (t½ = 1.45 days). A similar pattern of degradation was observed for DON, although the coefficients were slightly different. Changes in the OTUs patterns were observed during the different steps of the degradation. The main OTUs were related to the classes Alphaproteobacteria (8 OTUs), Betaproteobacteria (2 OTUs) and Gammaproteobacteria (3 OTUs). The genus Acinetobacter was the only identified organism that occurred during the whole process. Bacterial richness was higher at the slower degradation phase, which could be related to the small amounts of DOM (dissolved organic matter) available, particularly carbon. The kinetics of the bacterial degradation of P. agardhii-originated DOM suggests minimal loss of DOM from the Barra Bonita reservoir.Keywords: dissolved organic matter, bacterial community, DGGE, degradation. Degradação bacteriana da matéria orgânica dissolvida liberada porPlanktothrix agardhii (Cyanobacteria) ResumoEmbora Planktothrix agardhii frequentemente forme florações tóxicas em corpos d'água pelo mundo, pouco ainda se sabe sobre o destino da matéria orgânica liberada por essa abundante Cyanobacteria. Assim, este estudo foi focado na estimativa do consumo bacteriano do carbono orgânico dissolvido (DOC) e nitrogênio orgânico dissolvido (DON) produzido por culturas axênicas de P. agardhii e identificação de algumas das unidades taxonômicas operacionais (OTUs) bacterianas envolvidas no processo. Ambos a linhagem de P. agardhii e o inóculo bacteriano foram amostrados do reservatório eutrófico de Barra Bonita (SP, Brasil). Foram observadas duas fases distintas da degradação do DOC: durante os três primeiros dias, coeficientes mais altos de degradação foram calculados, que foram então seguidos por uma fase mais lenta da degradação do carbono. O valor máximo calculado para o carbono bacteriano particulado (POC) foi de 11,9 mgL -1 , o que equivale a aproximadamente 62,5% do DOC disponível para consumo, e o seu coeficiente de mineralização foi de 0,477 dia -1 (t 1/2 = 1,45 dias). Um padrão similar de degradação foi observado para DON, embora os c...

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Structuring effects of climate-related environmental factors on Antarctic microbial mat communities

Cited by 29 publications

References 66 publications

Late Holocene changes in cyanobacterial community structure in maritime Antarctic lakes

Late Holocene changes in cyanobacterial community structure in maritime Antarctic lakes

Ecology and biogeochemistry of cyanobacteria in soils, permafrost, aquatic and cryptic polar habitats

Bacterial degradation of dissolved organic matter released by Planktothrix agardhii (Cyanobacteria)

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