Zooplankton Diversity and Dispersal by Birds; Insights From Different Geographical Scales

Hessen, Dag O.; Jensen, Thomas Correll; Walseng, Bjørn

doi:10.3389/fevo.2019.00074

Cited by 25 publications

(25 citation statements)

References 61 publications

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“…For example, the lake on which we ran our experiment (Kenosee Lake) lacks stream connections except at high water levels (Vance et al, 1997), making direct dispersal unlikely during droughts. However, it may receive dispersers transported by terrestrial animals and waterfowl that travel among the dozens of prairie pothole lakes located within 5 km of its shoreline (Hessen et al, 2019;Vanschoenwinkel et al, 2008b;Frisch et al, 2007). We speculate that the level of dispersal among these types of prairie lakes are probably comparable to that among rock pools in Churchill,…”

Section: Discussionmentioning

confidence: 88%

“…When simulating dispersal during our enclosure experiments, we selected a dispersal rate of c. 1% of the resident community abundance per day based on studies of an interconnected pond system (Michels et al, 2001) and our desire to test our hypotheses within a reasonable time frame (6-week experiment). However, it may receive dispersers transported by terrestrial animals and waterfowl that travel among the dozens of prairie pothole lakes located within 5 km of its shoreline (Hessen et al, 2019;Vanschoenwinkel et al, 2008b;Frisch et al, 2007). For example, the lake on which we ran our experiment (Kenosee Lake) lacks stream connections except at high water levels (Vance et al, 1997), making direct dispersal unlikely during droughts.…”

Section: Discussionmentioning

confidence: 99%

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Can dispersal buffer against salinity‐driven zooplankton community change in Great Plains' lakes?

Huynh

Gray

2019

Freshwater Biology

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1. The North American Great Plains contains thousands of lakes that vary in salinity from freshwater to hypersaline. Paleolimnological studies show that salinity levels in these lakes are tightly linked with climate, and current projections point to a more arid future in the region due to natural and anthropogenic climate change, potentially influencing lake salinity.2. Many zooplankton species are sensitive to changes in salinity, and their position near the base of the aquatic food web makes it important to understand how they might respond to increasing salinity levels. Zooplankton communities in lakes with rising salinity levels may exhibit changes in structure, including a shift toward more salinity-tolerant species and a reduction in abundance, species richness, and diversity. However, it is possible that dispersal of zooplankton among lakes could mitigate such community changes when migrant populations replace sensitive zooplankton with those that are locally adapted to higher salinities.3. To test if dispersal could reduce salinity-induced changes in zooplankton communities, we ran a field enclosure experiment at a freshwater lake in southern Saskatchewan where we manipulated salinity levels and zooplankton dispersal.We evaluated how salinity and dispersal influenced species identities and relative abundances (community structure) using multivariate statistics and comparing taxonomic and functional compositions among the different treatments (richness, diversity, and evenness). 4. We found that increasing salinity levels in our enclosures above that in our study lake resulted in lower zooplankton abundances and species richness levels, primarily due to the loss of cladoceran species. However, patterns in our multivariate analyses suggested that cladocerans were maintained in enclosures with salinity levels of 2.5 and 5.0 g/L when those enclosures received immigration from nearby lakes.5. In contrast, our univariate analyses failed to find evidence that immigration affected community structure (richness, diversity, evenness). The lack of significant statistical differences could suggest that dispersal does not have an effect, or it may have been a problem with statistical power, as a power analysis suggested that fairly large effect sizes would have been required to achieve statistical significance.

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Section: Discussionmentioning

confidence: 88%

Section: Discussionmentioning

confidence: 99%

Can dispersal buffer against salinity‐driven zooplankton community change in Great Plains' lakes?

Huynh

Gray

2019

Freshwater Biology

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“…For the comparison of faecal loading rate and the subsequent effects on water chemistry at a landscape scale, we report previously unpublished chlorophyll a values from a large-scale survey of lakes across Southampton Island (for sampling details, see Mariash et al, 2018; Table 3). Water samples from these lakes were filtered onto GF/F fil-H. L. Mariash et al: Experimental tests of water chemistry response to ornithological eutrophication ters (in duplicates), frozen at −80 • C, and later analyzed using a Cary Eclipse fluorescence spectrophotometer (Aglilent, Santa Clara, USA) using standardized extraction methods and calculations (Holm-Hansen and Riemann, 1978;Jeffrey et al, 1997).…”

Section: Laboratory Analysismentioning

confidence: 99%

“…Biovolume estimates were based on geometrical models and cell measurements using photography and the AxioVision software (Zeiss, Germany) and converted using carbon to volume relationships (Menden-Deuer and Lessard, 2000). Phytoplankton taxonomy relied on the following literature: Cox (1996), Hillebrand et al (1999); John et al (2002), Komárek and Anagnostidis (2000), Guiry and Guiry (2017), Taylor et al (2007), and Wehr et al (2015). Taxa were identified to the genus level when possible but later grouped by class for comparisons.…”

Section: Phytoplankton Biovolumes and Community Compositionmentioning

confidence: 99%

“…While it has been demonstrated that goose droppings are a significant source of total nitrogen (N) and phosphorus (P) for nearby ponds (Côté et al, 2010;Mariash et al, 2018;Olson et al, 2005), only a few studies have attempted to quantify the magnitude of ornithological nutrient loading (Liu et al, 2014;Post et al, 1998) and relate increased nutrients to broader limnological affects (Van Geest et al, 2007;MacDonald et al, 2015;Unckless and Makarewicz, 2007). Birds can also act as vectors for the dispersal of plants, phytoplankton, and zooplankton when propagules are spread through their faeces (Figuerola and Green, 2002;Hessen et al, 2019). Currently, almost no measurements of these broader ecosystem-level effects exist for Arctic ponds.…”

Section: Introductionmentioning

confidence: 99%

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Experimental tests of water chemistry response to ornithological eutrophication: biological implications in Arctic freshwaters

2019

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Abstract. Many populations of Arctic-breeding geese have increased in abundance in recent decades, and in the Canadian Arctic, snow geese (Chen caerulescens) and Ross's geese (Chen rossii) are formally considered overabundant by wildlife managers. The impacts of these overabundant geese on terrestrial habitats are well documented, and, more recently, studies have suggested impacts on freshwater ecosystems as well. The direct contribution of nutrients from goose faeces to water chemistry could have cascading effects on biological functioning, through changes in phytoplankton biovolumes and community composition. We demonstrated previously that goose faeces can enrich ponds with nutrients at a landscape scale. Here, we show experimentally that goose droppings rapidly released nitrogen and phosphorus when submerged in freshwater, increasing the dissolved nitrogen and phosphorus in the water. This resulted in both a decrease in the nitrogen:phosphorus ratio and an increase in cyanobacteria in the goose dropping treatment. In contrast, this pattern was not found when we submerged cut sedge (Carex sp.) leaves. These results demonstrate that geese act as bio-vectors, causing terrestrial nutrients to be bioavailable in freshwater systems. Collectively, the results demonstrate the direct ecological consequences of ornithological nutrient loading from hyper-abundant geese in Arctic freshwater ecosystems.

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Population connectivity, dispersal, and swimming behavior inDaphnia

Tesson

Sha

2021

Ecology and Evolution

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A paradox of the zooplankter Daphnia is its strong degree of provincialism (De Gelas & De Meester, 2005) and behavioral patterning (Ekvall et al., 2015) occurring simultaneously to its high capacity of moving (e.g., vertical diurnal migration) and dispersal (Hansson et al., 2016; Pinceel et al., 2016; Waterkeyn et al., 2010), as well as its ability to adapt to changing environments (e.g., plasticity (Kim et al., 2009; Miner & Kerr, 2011)) and revival (Hairston et al., 1995). Daphnia has a high potential of movement and dispersal. Propagules can be transported by flowing water (Havel &

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Zooplankton Diversity and Dispersal by Birds; Insights From Different Geographical Scales

Cited by 25 publications

References 61 publications

Can dispersal buffer against salinity‐driven zooplankton community change in Great Plains' lakes?

Can dispersal buffer against salinity‐driven zooplankton community change in Great Plains' lakes?

Experimental tests of water chemistry response to ornithological eutrophication: biological implications in Arctic freshwaters

Population connectivity, dispersal, and swimming behavior inDaphnia

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