Seasonal Variations in Planktonic Community Structure and Production in an Atlantic Coastal Pond: The Importance of Nanoflagellates

Dupuy, Christine; Ryckaert, Mireille; Gall, Solange Le; Hartmann, Hans J.

doi:10.1007/s00248-006-9087-z

Cited by 11 publications

(7 citation statements)

References 40 publications

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“…given nanoplankton growth rate ranging from 7 h (Dupuy et al, 2007) to 20 h (Calbet et al 2008;Liu et al 2009). Thus, doubling of HNF concentration in the water column suggest that HNF concentration in eroded sediment during the survey was roughly 10 5 cell mL -1 , which is a hundred times greater than previously reported average values found in the first top cm of the BMO sediment (10 3 cell mL -1 , C. Dupuy personal communication).…”

Section: Decrease Of Resuspended Microorganisms By Grazing Predatorsmentioning

confidence: 62%

“…However, a total community change occurred with replacement of benthic diatoms by pelagic diatoms in proportion of water depth change during the rising tide. No significant primary production of diatoms was expected given the short duration of the Eulerian survey compared to the generation time for microphytoplankton (1 division d -1 , Calbet and Landry 2004 to 2 divisions d -1 , Dupuy et al 2007) and water turbidity (Struski and Bacher 2006;Bouman et al 2010). Thus, mixing was the most likely dominant process.…”

Section: Mixing With Offshore Watersmentioning

confidence: 99%

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Microorganism dynamics during a rising tide: Disentangling effects of resuspension and mixing with offshore waters above an intertidal mudflat

Guizien

Dupuy

Ory

et al. 2014

Journal of Marine Systems

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Resuspension of microphytobenthic biomass that builds up during low tide has been acknowledged as a major driver of the highly productive food web of intertidal mudflats. Yet, little is known about the contribution to pelagic food web of the resuspension of other microorganisms such as viruses, picoeukaryotes, cyanobacteria, bacteria, nanoflagellates, and ciliates, living in biofilms associated with microphytobenthos and surficial sediment. In the present study, a novel approach that involves simultaneous Lagrangian and Eulerian surveys enabled to disentangle the effects of resuspension and mixing with offshore waters on the dynamics of water column microorganisms during a rising tide in the presence of waves. Temporal changes in the concentration of microorganisms present in the water column were recorded along a 3 km cross-shore transect and at a fixed subtidal location. In both surveys, physical and biological processes were separated by comparing the time-evolution of sedimentary particles and microorganisms concentrations. During a rising tide, sediment erosion under waves action occurred over the lower and upper part of the mudflat, where erodibility was highest. Although erosion was expected to enrich the water column with the most abundant benthic microorganisms, such as diatoms, bacteria and viruses, enrichment was only observed for nanoflagellates and ciliates. Grazing probably overwhelmed erosion transfer for diatoms and bacteria, while adsorption on clayed particles may have masked the expected water column enrichment in free viruses due to resuspension. Ciliate enrichment could not be attributed to resuspension as those organisms were absent from the sediment. Wave agitation during the water flow on the mudflat likely dispersed gregarious ciliates over the entire water column. During the rising tide, offshore waters imported more autotrophic, mainly cyanobacteria genus Synechococcus sp. than heterotrophic microorganisms, but this import was also heavily grazed. Finally, the water column became a less heterotrophic structure in the subtidal part of the semi-enclosed bay, where mixing with offshore waters occurs (50% decrease), compared to the intertidal mudflat, when resuspension occurs. The 2 present study suggests that this differential evolution resulted predominantly from dilution with offshore waters less rich in heterotrophic microorganisms. Indeed, any input of microorganisms accompanying physical transfers due to bed erosion or offshore waters mixing was immediately buffered, probably to the benefit of grazers.

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Section: Decrease Of Resuspended Microorganisms By Grazing Predatorsmentioning

confidence: 62%

Section: Mixing With Offshore Watersmentioning

confidence: 99%

Microorganism dynamics during a rising tide: Disentangling effects of resuspension and mixing with offshore waters above an intertidal mudflat

Guizien

Dupuy

Ory

et al. 2014

Journal of Marine Systems

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“…In June 2013, higher AVFA decomposition rate was only observed in the unfiltered seawater, indicating that the larger-sized protists (>20 μm) were involved in the peptide decomposition. Higher temperature in summer 2013 than winter 2011 (Table 1) may have caused faster growth and larger cell volume of protists (Dupuy et al, 2007;Auer and Arndt, 2001). Alternatively, specific types of protists that can utilize peptides may differ between winter and summer.…”

Section: The Role Of Different-sized Microorganisms In Peptide Decompmentioning

confidence: 99%

Differentiating the role of different-sized microorganisms in peptide decomposition during incubations using size-fractioned coastal seawater

Liu

Riesen

Liu

2015

Journal of Experimental Marine Biology and Ecology

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Peptide decomposition by different-sized microorganisms was compared by incubating tetrapeptide alanine-valine-phenylalanine-alanine (AVFA), a fragment of RuBisCO, in coastal seawater after size-fraction by filtration. The size-fractioned seawater included <0.8-µm filtered (free-living bacteria), <5-µm filtered (free-living bacteria + heterotrophic nanoflagellates), <20µm filtered (free-living and particle-attached bacteria + heterotrophic nanoflagellates + other small protists), and unfiltered whole water collected from Texas coast in the western Gulf of Mexico. Decomposition rates of AVFA in the <20-µm and unfiltered seawater were significantly higher than those in the <0.8-µm and <5-µm seawater in the December 2011 incubation. The higher decomposition rate in the large size fractions can be attributed to activities of particleattached bacteria and/or large-size microorganisms, such as osmotrophic protists. However, the role of particle-attached bacteria in explaining this decomposition difference might be limited, as bacterial abundance and community structure did not differ much among the 4 treatments. Consistently, the June 2013 incubation indicated that AVFA decomposed most rapidly in the unfiltered seawater with >20-μm microorganisms. This study provides insights into the relative role of different-sized microorganisms in regulating the recycling of labile organic matter in coastal waters.

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“…This excess of nutrients is considered to be one of the major pollution sources in aquatic ecosystems (ESTEVES, 1998). The result is a series of biological events including: an increase in the dominance of certain trophic levels, such as an increase in algal biomass; modification of microbial loop components (bacteria, flagellates and ciliates) and significant impacts to higher trophic levels (SAMUELSSON et al, 2002;AUER et al, 2004).In this sense, aquatic communities have been used as descriptors of environmental changes (HIGUTI et al, 2005); especially microorganismal assemblages because of their ability to act as bioindicators of aquatic pollution (FOISSNER, 1992).Due to their small body size, high metabolic rates and short life cycles (DUPUY et al, 2007), the organisms that constitute the microbial food chain respond rapidly to changes in environmental conditions (AUER et al, 2001). In addition, they play an essential role in fast nutrient cycling, the mineralization of organic compounds and the production and transfer of organic matter in aquatic environments (AZAM et al, 1983 Among these microorganisms, the flagellate protozoans are important components, having a significant role in aquatic system metabolism.…”

mentioning

confidence: 98%

Effects of Eutrophication on Flagellates Associated with Eichhornia crassipes: An Experimental Approach

Pereira

Silva

Camargo

et al. 2010

International Review of Hydrobiology

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The effects of nutrient enrichment on density, biomass and on the relative contribution of pigmented and heterotrophic flagellates to the total abundance of all flagellates associated with Eichhornia crassipes were evaluated through mesocosm experiments over 33 days. Two triplicate treatments (nitrogen and phosphorus addition and a control treatment) were colonized, producing six mesocosm systems. The only variable that showed significance was flagellate density. Density increased significantly with increased nutrient concentrations in both flagellate groups, suggesting the importance of bottom-up control mechanisms. However, the time lag and the low magnitude response to density, as well as the lack of significant variation in biomass with respect to fertilization, suggested that a complex relationship is responsible for influencing the structure of flagellate communities associated with vegetation during nutrient enrichment in these food webs. IntroductionThe deterioration of water bodies caused by eutrophication from anthropogenic activities represents a severe environmental problem (TUNDISI, 2003). This excess of nutrients is considered to be one of the major pollution sources in aquatic ecosystems (ESTEVES, 1998). The result is a series of biological events including: an increase in the dominance of certain trophic levels, such as an increase in algal biomass; modification of microbial loop components (bacteria, flagellates and ciliates) and significant impacts to higher trophic levels (SAMUELSSON et al., 2002;AUER et al., 2004).In this sense, aquatic communities have been used as descriptors of environmental changes (HIGUTI et al., 2005); especially microorganismal assemblages because of their ability to act as bioindicators of aquatic pollution (FOISSNER, 1992).Due to their small body size, high metabolic rates and short life cycles (DUPUY et al., 2007), the organisms that constitute the microbial food chain respond rapidly to changes in environmental conditions (AUER et al., 2001). In addition, they play an essential role in fast nutrient cycling, the mineralization of organic compounds and the production and transfer of organic matter in aquatic environments (AZAM et al., 1983 Among these microorganisms, the flagellate protozoans are important components, having a significant role in aquatic system metabolism. The pigmented flagellates (PF) may have important roles in primary production (SAFI and HALL, 1997), whereas heterotrophic flagellates (HF) are considered to be the main consumers of bacteria (SIMEK et al., 1999). When they are consumed by metazoans (SHERR et al., 1988), the role of flagellates is compound many times; they become the dominant trophic link as the productivity of the pico -and nanoplankton is transferred to higher trophic levels (HWANG and HEALTH, 1997).Studies of the planktonic zone have shown that the abundance of flagellates is frequently associated with environmental trophic conditions and, consequently, is influenced by the bottom-up control mechanisms that are related t...

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Seasonal Variations in Planktonic Community Structure and Production in an Atlantic Coastal Pond: The Importance of Nanoflagellates

Cited by 11 publications

References 40 publications

Microorganism dynamics during a rising tide: Disentangling effects of resuspension and mixing with offshore waters above an intertidal mudflat

Microorganism dynamics during a rising tide: Disentangling effects of resuspension and mixing with offshore waters above an intertidal mudflat

Differentiating the role of different-sized microorganisms in peptide decomposition during incubations using size-fractioned coastal seawater

Effects of Eutrophication on Flagellates Associated with Eichhornia crassipes: An Experimental Approach

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