Macrophytes moderate the taxonomic and functional composition of phytoplankton assemblages during a nutrient loading experiment

Barrow, Jennifer L.; Beisner, Beatrix E.; Giles, Rachel K.; Giani, Alessandra; Domaizon, Isabelle; Gregory‐Eaves, Irene

doi:10.1111/fwb.13311

Cited by 23 publications

(12 citation statements)

References 57 publications

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“…The submerged macrophyte H. verticillate , has been reported to produce and release allelochemicals that has inhibitory effects on Chlorella cell membrane ( Zhang et al., 2012 ) and cyanobacteria ( Wang et al., 2006 ; Gao et al., 2011 ). Over 32 days, SMs suppressed overall cyanobacteria biomass ( Table 2 ), concurring with findings from other experimental studies ( Lürling et al., 2006 ; Barrow et al., 2019 ; Amorim and Moura, 2020 ). Further, factors such as light and nutrient competition likely interacted with allelopathic controls in the mesocosms and led to the competitive exclusion of cyanobacteria.…”

Section: Discussionsupporting

confidence: 91%

“…In addition, SMs can facilitate nutrient uptake from the water column and sediment ( Sand-Jensen and Borum, 1991 ) and reduce sediment resuspension ( Horppila and Nurminen, 2003 ). Earlier studies involving small-scale experiments ( Barrow et al., 2019 ; Amorim and Moura, 2020 ) and natural aquatic ecosystems ( Chao et al., 2022 ; Peng et al., 2022 ) have repeatedly reported that the restoration of SMs decreases the phytoplankton abundance and increases water clarity. Thus, usage of SMs is a prospective tool for the elimination of algal blooms ( Jeppesen et al., 2007b ).…”

Section: Introductionmentioning

confidence: 99%

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The combined effects of filter-feeding bivalves (Cristaria plicata) and submerged macrophytes (Hydrilla verticillate) on phytoplankton assemblages in nutrient-enriched freshwater mesocosms

Song

Wang

et al. 2023

Front. Plant Sci.

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Freshwater ecosystems are threatened by eutrophication, which causes persistent and harmful algal blooms. Filter-feeding bivalve mollusks and submerged macrophytes (SMs) alleviate the eutrophication effects by inhibiting phytoplankton biomass blooms. However, very little is known about whether and how the combined manipulation of filter-feeding bivalves and SMs control eutrophication and influence phytoplankton assemblages. Here, we performed a nutrient-enriched freshwater mesocosm experiment to assess the combined effects of the filter-feeding bivalve Cristaria plicata, a cockscomb pearl mussel, and the macrophyte Hydrilla verticillate on the biomass and composition of phytoplankton assemblages. We found that addition of C. plicata and H. verticillate decreased the water nutrient concentrations and suppressed overall phytoplankton biomass. Further, distinct differences in taxa between restoration and control treatments were observed and noticeably competitive exclusion of cyanobacteria in the restoration treatments occurred. An antagonistic interaction between filter-feeding bivalves and SMs was only detected for total cyanobacteria biomass demonstrating that a larger magnitude of SM restoration may override the effect of filter-feeding bivalves. Our results suggest that manipulation, through the addition of bivalves as grazers, associated with the restoration of SMs, is an efficient approach for reducing cyanobacterial blooms and alleviating eutrophication.

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Section: Discussionsupporting

confidence: 91%

Section: Introductionmentioning

confidence: 99%

The combined effects of filter-feeding bivalves (Cristaria plicata) and submerged macrophytes (Hydrilla verticillate) on phytoplankton assemblages in nutrient-enriched freshwater mesocosms

Song

Wang

et al. 2023

Front. Plant Sci.

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“…H. verticillata has a competitive advantage in shading, as the light crowns form rapidly. It can also reproduce readily via fragmentation and tubers, which increases its ability to uptake nutrients [38][39][40]. Thus, it can control algal biomass by limiting the external conditions required for algal growth [7].…”

Section: Synergistic Effect Of Combined Submerged Macrophyte Plantingmentioning

confidence: 99%

Optimization of Combined Submerged Macrophyte Planting Conditions for Inhibiting Algae by Response Surface Methodology

Wang

Guo

et al. 2020

Water

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Combined planting of submerged macrophytes could be an effective way of controlling algal blooms in landscape waters. In this study, the algal inhibition of single and combined planting of Hydrilla verticillata (A) and Myriophyllum spicatum (B) were explored. The optimized combined planting conditions were investigated using the central composite design. The results showed that the combined planting had a synergistic algal-inhibiting effect. Its inhibition (I (K)) is about 10.8% higher than that of single planting with the same density. The synergism of the combined planting may be due to the different ways in which the two plants inhibit the algal growth. H. verticillata inhibited the algal biomass and M. spicatum inhibited the algal specific growth rate. When the density of H. verticillata and M. spicatum were 7.2 g/L and 6.7 g/L, the value of I (K) reached a maximum 92.2%. Although increasing planting density would improve the algal inhibition, high planting density was not beneficial for the growth of plants. Moreover, no further significant improvement was shown with the increasing planting density when the value of I(K) was higher than 90%. Therefore, the cost-effective combined macrophyte density was 11.6 g/L and the value of A/B ranged from 1.05 to 1.07, where the value of I (K) could achieve 90%. This study can provide a practical basis for using macrophytes to control algal blooms.

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“…The functional phytoplankton composition based on biovolume changed more than 200 km downstream in a tropical river, suggesting that damming can filter species by their traits Graco-Roza et al (2020). An experimental study (Barrow et al, 2019) showed the influence of the macrophyte abundance in shaping phytoplankton functional diversity, based on density/biovolume; it indicated that competition for light, grazing, and probably, allelochemicals were mechanisms through which macrophytes mediated changes in the phytoplankton community. A recent experimental study accessed the relative effects of spatial overlap, grazing, and the physical environment on multiple dimensions of phytoplankton diversity (functional and taxonomical).…”

Section: Introductionmentioning

confidence: 99%

Responses of Functional and Taxonomic Phytoplankton Diversity to Environmental Gradients in Subtropical and Tropical Reservoirs

Santos

Brasil²,

Huszar³

2022

Front. Environ. Sci.

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Understanding the influence of environmental conditions on biodiversity is a major task in ecology. We investigated how phytoplankton taxonomic (TD) and functional (FD) diversities vary with environmental factors in eight subtropical and tropical reservoirs. We hypothesized that i) environmental variables affect phytoplankton TD and FD; ii) FD provides better relationships to environmental changes than TD, and; iii) indices based on biomass are better related to the environment than those based on identities. The relationships between phytoplankton diversities and environmental drivers were assessed through generalized linear models. Our hypotheses were partly confirmed. TD and FD were, in fact, dependent on the environment, with higher values occurring in warmer, clearer, and more enriched systems, under lower zooplankton grazing pressure; but FD based on identities was not predicted better from environmental conditions than TD based on identities. As expected, indices based on biomass are better related to the environment than their counterpart based on identities.

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Macrophytes moderate the taxonomic and functional composition of phytoplankton assemblages during a nutrient loading experiment

Cited by 23 publications

References 57 publications

The combined effects of filter-feeding bivalves (Cristaria plicata) and submerged macrophytes (Hydrilla verticillate) on phytoplankton assemblages in nutrient-enriched freshwater mesocosms

The combined effects of filter-feeding bivalves (Cristaria plicata) and submerged macrophytes (Hydrilla verticillate) on phytoplankton assemblages in nutrient-enriched freshwater mesocosms

Optimization of Combined Submerged Macrophyte Planting Conditions for Inhibiting Algae by Response Surface Methodology

Responses of Functional and Taxonomic Phytoplankton Diversity to Environmental Gradients in Subtropical and Tropical Reservoirs

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