The role of planktonic <i><scp>F</scp>lavobacteria</i> in processing algal organic matter in coastal <scp>E</scp>ast <scp>A</scp>ntarctica revealed using metagenomics and metaproteomics

Williams, Timothy J.; Wilkins, David E.; Long, Emilie; Evans, Flávia F.; DeMaere, Matthew Z.; Raftery, Mark J.; Cavicchioli, Ricardo

doi:10.1111/1462-2920.12017

Cited by 263 publications

(235 citation statements)

References 87 publications

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“…Consequently, Bacteroidetes and phytoplankton are often found in close association in polar waters (Grossart et al, 2005;Piquet et al, 2011;Williams et al, 2013) with the relative abundance of the former significantly correlated with the emergence of the late spring blooms (Alonso-Sáez et al, 2008). During May of 2014, the Flavobacteriaceae were notable by their prolific increase in relative abundance from negligible levels in March, congruent with the spike in chloroplast 16S rRNA abundance (Figure 5) and chl a maxima ( Table 1).…”

Section: Discussionmentioning

confidence: 74%

“…Recent whole genome analyses of various members of the Bacteroidetes have confirmed long-held assumptions of a preference for and selective advantage of the phylum when growing on complex organic matter (Abell and Bowman, 2005;Teeling et al, 2012;Fernández-Gómez et al, 2013;Williams et al, 2013), such as that typically produced by marine phytoplankton (Passow, 2002). Consequently, Bacteroidetes and phytoplankton are often found in close association in polar waters (Grossart et al, 2005;Piquet et al, 2011;Williams et al, 2013) with the relative abundance of the former significantly correlated with the emergence of the late spring blooms (Alonso-Sáez et al, 2008).…”

Section: Discussionmentioning

confidence: 86%

“…By late summer, this develops into a successional postbloom stage, comprising different phytoplankton populations (Sherr et al, 2003) and it follows, their different associated successional heterotrophic prokaryote consortia, in particular the Flavobacteriia and Gammaproteobacteria classes (AlonsoSáez et al, 2008;Teeling et al, 2012). This phenomenon of the polar phytoplankton blooms (Williams et al, 2013) followed by the heterotrophic bacterial populations also seemingly drives the annual disappearance of the chemolithoautotrophic marine Archaea from surface waters (Kalanetra et al, 2009;AlonsoSáez et al, 2012;Pedneault et al, 2014) and the subsequent seasonal fluctuations in prokaryote diversity (Murray et al, 1998;Ghiglione and Murray, 2012;Grzymski et al, 2012;Ladau et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

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Changes in Marine Prokaryote Composition with Season and Depth Over an Arctic Polar Year

et al. 2017

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As the global climate changes, the higher latitudes are seen to be warming significantly faster. It is likely that the Arctic biome will experience considerable shifts in ice melt season length, leading to changes in photoirradiance and in the freshwater inputs to the marine environment. The exchange of nutrients between Arctic surface and deep waters and their cycling throughout the water column is driven by seasonal change. The impacts, however, of the current global climate transition period on the biodiversity of the Arctic Ocean and its activity are not yet known. To determine seasonal variation in the microbial communities in the deep water column, samples were collected from a profile (1-1000 m depth) in the waters around the Svalbard archipelago throughout an annual cycle encompassing both the polar night and day. High-throughput sequencing of 16S rRNA gene amplicons was used to monitor prokaryote diversity. In epipelagic surface waters (<200 m depth), seasonal diversity varied significantly, with light and the corresponding annual phytoplankton bloom pattern being the primary drivers of change during the late spring and summer months. In the permanently dark mesopelagic ocean depths (>200 m), seasonality subsequently had much less effect on community composition. In summer, phytoplankton-associated Gammaproteobacteria and Flavobacteriia dominated surface waters, whilst in low light conditions (surface waters in winter months and deeper waters all year round), the Thaumarchaeota and Chloroflexi-type SAR202 predominated. Alpha-diversity generally increased in epipelagic waters as seasonal light availability decreased; OTU richness also consistently increased down through the water column, with the deepest darkest waters containing the greatest diversity. Beta-diversity analyses confirmed that seasonality and depth also primarily drove community composition. The relative abundance of the eleven predominant taxa showed significant changes in surface waters in summer months and varied with season depending on the phytoplankton bloom stage; corresponding populations in deeper waters however, remained relatively unchanged. Given the significance of the annual phytoplankton bloom pattern on prokaryote diversity in Arctic waters, any changes to bloom dynamics resulting from accelerated global warming will likely have major impacts on surface marine microbial communities, those impacts inevitably trickling down into deeper waters.

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Section: Discussionmentioning

confidence: 74%

Section: Discussionmentioning

confidence: 86%

Section: Introductionmentioning

confidence: 99%

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Changes in Marine Prokaryote Composition with Season and Depth Over an Arctic Polar Year

et al. 2017

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“…Surface waters (AZ, Polar Frontal Zone (PFZ) and SAMW) had high abundances of OTUs clustering with SILVA sequences from the Alphaproteobacteria, Bacteroidetes and Gammaproteobacteria. The higher abundance of Bacteroidetes at the surface reflects their association with phytoplankton, as many species in this lineage specialize in the degradation of high molecular weight products of primary production 20 . Alphaproteobacteria were represented primarily by the SAR11 clade, abundant in ocean surface communities 21 including the SO 22 , and Roseobacter clades, which have also been associated with degradation of phytoplankton products 15,20 (Supplementary Data 2).…”

Section: Resultsmentioning

confidence: 99%

“…The higher abundance of Bacteroidetes at the surface reflects their association with phytoplankton, as many species in this lineage specialize in the degradation of high molecular weight products of primary production 20 . Alphaproteobacteria were represented primarily by the SAR11 clade, abundant in ocean surface communities 21 including the SO 22 , and Roseobacter clades, which have also been associated with degradation of phytoplankton products 15,20 (Supplementary Data 2). The dominant Gammaproteobacterial orders were the Alteromonadales and Oceanospirillales, typical of SO surface waters 23 .…”

Section: Resultsmentioning

confidence: 99%

Advection shapes Southern Ocean microbial assemblages independent of distance and environment effects

et al. 2013

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Pleistocene glacial and interglacial ecosystems inferred from ancient DNA analyses of permafrost sediments from Batagay megaslump, East Siberia

et al. 2022

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The role of planktonic Flavobacteria in processing algal organic matter in coastal East Antarctica revealed using metagenomics and metaproteomics

Cited by 263 publications

References 87 publications

Changes in Marine Prokaryote Composition with Season and Depth Over an Arctic Polar Year

Changes in Marine Prokaryote Composition with Season and Depth Over an Arctic Polar Year

Advection shapes Southern Ocean microbial assemblages independent of distance and environment effects

Pleistocene glacial and interglacial ecosystems inferred from ancient DNA analyses of permafrost sediments from Batagay megaslump, East Siberia

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