Impact of interaction between Limnoperna fortunei and Roundup Max® on freshwater phytoplankton: An in situ approach in Salto Grande reservoir (Argentina)

Gattás, Florencia; Stefano, L.G. De; Vinocur, Alicia; Bordet, Facundo; Espinosa, Mariela Soledad; Pizarro, Haydée; Cataldo, Daniel

doi:10.1016/j.chemosphere.2018.06.129

Cited by 13 publications

(7 citation statements)

References 45 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…These organisms were frequently used in early studies on photosynthesis [ 72 ] and are distributed in both freshwater and marine environments [ 73 , 74 ]. In the present study, Chlamydomonadales X , consisting mainly of Spermatozopsis and Chlamydomonas , were largely distributed in freshwater environments, although Chlamydomonas could also be found in seawater environments [ 75 , 76 , 77 ]. The algae of Sphaeropleales X are common planktonic freshwater algae [ 78 ], and, in the current study, their members were mainly detected in samples taken from freshwater environments.…”

Section: Discussionmentioning

confidence: 68%

Changes of In Situ Prokaryotic and Eukaryotic Communities in the Upper Sanya River to the Sea over a Nine-Hour Period

Bai

Zhang

et al. 2023

Microorganisms

View full text Add to dashboard Cite

The transition areas of riverine, estuarine, and marine environments are particularly valuable for the research of microbial ecology, biogeochemical processes, and other physical–chemical studies. Although a large number of microbial-related studies have been conducted within such systems, the vast majority of sampling have been conducted over a large span of time and distance, which may lead to separate batches of samples receiving interference from different factors, thus increasing or decreasing the variability between samples to some extent. In this study, a new in situ filtration system was used to collect membrane samples from six different sampling sites along the Sanya River, from upstream freshwater to the sea, over a nine-hour period. We used high-throughput sequencing of 16S and 18S rRNA genes to analyze the diversity and composition of prokaryotic and eukaryotic communities. The results showed that the structures of these communities varied according to the different sampling sites. The α-diversity of the prokaryotic and eukaryotic communities both decreased gradually along the downstream course. The structural composition of prokaryotic and eukaryotic communities changed continuously with the direction of river flow; for example, the relative abundances of Rhodobacteraceae and Flavobacteriaceae increased with distance downstream, while Sporichthyaceae and Comamonadaceae decreased. Some prokaryotic taxa, such as Phycisphaeraceae and Chromobacteriaceae, were present nearly exclusively in pure freshwater environments, while some additional prokaryotic taxa, including the SAR86 clade, Clade I, AEGEAN-169 marine group, and Actinomarinaceae, were barely present in pure freshwater environments. The eukaryotic communities were mainly composed of the Chlorellales X, Chlamydomonadales X, Sphaeropleales X, Trebouxiophyceae XX, Annelida XX, and Heteroconchia. The prokaryotic and eukaryotic communities were split into abundant, common, and rare communities for NCM analysis, respectively, and the results showed that assembly of the rare community assembly was more impacted by stochastic processes and less restricted by species dispersal than that of abundant and common microbial communities for both prokaryotes and eukaryotes. Overall, this study provides a valuable reference and new perspectives on microbial ecology during the transition from freshwater rivers to estuaries and the sea.

show abstract

Section: Discussionmentioning

confidence: 68%

Changes of In Situ Prokaryotic and Eukaryotic Communities in the Upper Sanya River to the Sea over a Nine-Hour Period

Bai

Zhang

et al. 2023

Microorganisms

View full text Add to dashboard Cite

show abstract

“…In complement, Neury‐Ormanni et al (2020) suggested that a poor microalgae quality subsequent to diuron exposure (e.g., decreased content in essential fatty acids, see below) could trigger invertebrates to graze higher amounts of contaminated microalgae, to compensate for the decrease in nutrient supply (also see section Dissipation and mitigation of contaminants ). The impacts of glyphosate on phytoplankton were also shown to be altered in the presence of golden mussels ( Limnoperna fortunei ), the addition of which modified nutrient content in the water column and selected for phytoplankton species (De Stefano et al, 2018; Gattás et al, 2018). Such results contrast with those of Iummato et al (2017), who found no differences in periphyton exposed or not to glyphosate in the presence of L. fortunei , suggesting that the mussels attenuated the effects of glyphosate by contributing to its dissipation, and of López‐Doval et al (2010), who did not observe any significant interactions between diuron, biofilms, and grazers (freshwater snail Physella acuta ).…”

Section: Resultsmentioning

confidence: 99%

Twenty Years of Research in Ecosystem Functions in Aquatic Microbial Ecotoxicology

Morin,

Artigas

2023

Enviro Toxic and Chemistry

View full text Add to dashboard Cite

One of the major threats to freshwater biodiversity is water pollution including excessive loads of nutrients, pesticides, industrial chemicals, and/or emerging contaminants. The widespread use of organic pesticides for agricultural and nonagricultural (industry, gardening, etc.) purposes has resulted in the presence of their residues in various environments, including surface waters. However, the contribution of pesticides to the deterioration of freshwater ecosystems (i.e., biodiversity decline and ecosystem functions impairment) remains uncertain. Once in the aquatic environment, pesticides and their metabolites can interact with microbial communities, causing undesirable effects. The existing legislation on ecological quality assessment of water bodies in Europe is based on water chemical quality and biological indicator species (Water Framework Directive, Pesticides Directive), while biological functions are not yet included in monitoring programs. In the present literature review, we analyze 20 years (2000–2020) of research on ecological functions provided by microorganisms in aquatic ecosystems. We describe the set of ecosystem functions investigated in these studies and the range of endpoints used to establish causal relationships between pesticide exposure and microbial responses. We focus on studies addressing the effects of pesticides at environmentally realistic concentrations and at the microbial community level to inform the ecological relevance of the ecotoxicological assessment. Our literature review highlights that most studies were performed using benthic freshwater organisms and that autotrophic and heterotrophic communities are most often studied separately, usually testing the pesticides that target the main microbial component (i.e., herbicides for autotrophs and fungicides for heterotrophs). Overall, most studies demonstrate deleterious impacts on the functions studied, but our review points to the following shortcomings: (1) the nonsystematic analysis of microbial functions supporting aquatic ecosystems functioning, (2) the study of ecosystem functions (i.e., nutrient cycling) via proxies (i.e., potential extracellular enzymatic activity measurements) which are sometimes disconnected from the current ecosystem functions, and (3) the lack of consideration of chronic exposures to assess the impact of, adaptations to, or recovery of aquatic microbial communities from pesticides. Environ Toxicol Chem 2023;00:1–22. © 2023 SETAC

show abstract

“…Eutrophication, accompanied by continued economic development, especially in densely populated areas of the world, constantly threatens the service functions of freshwater systems . High concentrations of herbicides may affect the growth of microalgae and cyanobacteria by altering their metabolic profile, , and they may even contribute to the formation of harmful cyanobacterial blooms (cyanoHABs). , Algae are sensitive to herbicides, and there is also great variability in species sensitivity. Studies show that the low sensitivity of cyanobacteria, a typical prokaryotic phytoplankton, to glyphosate-based herbicides and its ability to utilize phosphonates might be the key for its predominance. , Under the multiple challenges of climate warming and human activities, toxic cyanobacterial blooms tend to occur more frequently and for longer periods of time, further threatening future human health and ecosystem services. − Therefore, it is necessary to fill the knowledge gaps of the results of this interaction to support future lake management decisions or climate mitigation interventions to protect and restore freshwater ecosystems.…”

Section: Introductionmentioning

confidence: 99%

“…7 High concentrations of herbicides may affect the growth of microalgae and cyanobacteria by altering their metabolic profile, 8,9 and they may even contribute to the formation of harmful cyanobacterial blooms (cyanoHABs). 10,11 Algae are sensitive to herbicides, 12 and there is also great variability in species sensitivity. Studies show that the low sensitivity of cyanobacteria, a typical prokaryotic phytoplankton, to glyphosate-based herbicides and its ability to utilize phosphonates might be the key for its predominance.…”

Section: ■ Introductionmentioning

confidence: 99%

Chemodiversity of Cyanobacterial Toxins Driven by Future Scenarios of Climate Warming and Eutrophication

Yang

Wang

Yan

et al. 2023

Environ. Sci. Technol.

View full text Add to dashboard Cite

Climate change and eutrophication are two environmental threats that can alter the structure of freshwater ecosystems and their service functions, but we know little about how ecosystem structure and function will evolve in future scenarios of climate warming. Therefore, we created different experimental climate scenarios, including present-day conditions, a 3.0 °C increase in mean temperature, and a "heatwaves" scenario (i.e., an increase in temperature variability) to assess the effects of climate change on phytoplankton communities under simultaneous stress from eutrophication and herbicides. We show that the effects of climate warming, particularly heatwaves, are associated with elevated cyanobacterial abundances and toxin production, driven by a change from mainly nontoxic to toxic Microcystis spp. The reason for higher cyanobacterial toxin concentrations is likely an increase in abundances because under the dual pressures of climate warming and eutrophication individual Microcystis toxin-producing ability decreased. Eutrophication and higher temperatures significantly increased the biomass of Microcystis, leading to an increase in the cyanobacterial toxin concentrations. In contrast, warming alone did not produce higher cyanobacterial abundances or cyanobacterial toxin concentrations likely due to the depletion of the available nutrient pool. Similarly, the herbicide glyphosate alone did not affect abundances of any phytoplankton taxa. In the case of nutrient enrichment, cyanobacterial toxin concentrations were much higher than under warming alone due to a strong boost in biomass of potential cyanobacterial toxin producers. From a broader perspective our study shows that in a future warmer climate, nutrient loading has to be reduced if toxic cyanobacterial dominance is to be controlled.

show abstract

Impact of interaction between Limnoperna fortunei and Roundup Max® on freshwater phytoplankton: An in situ approach in Salto Grande reservoir (Argentina)

Cited by 13 publications

References 45 publications

Changes of In Situ Prokaryotic and Eukaryotic Communities in the Upper Sanya River to the Sea over a Nine-Hour Period

Changes of In Situ Prokaryotic and Eukaryotic Communities in the Upper Sanya River to the Sea over a Nine-Hour Period

Twenty Years of Research in Ecosystem Functions in Aquatic Microbial Ecotoxicology

Chemodiversity of Cyanobacterial Toxins Driven by Future Scenarios of Climate Warming and Eutrophication

Contact Info

Product

Resources

About