Long‐term change of phytoplankton in Lake Kivu: The rise of the greens

Rugema, Edouard; Darchambeau, François; Sarmento, Hugo; Stoyneva-Gärtner, Maya; Leitão, Maria; Thiery, Wim; Latli, Adrien; Descy, Jean-Pierre

doi:10.1111/fwb.13383

Cited by 19 publications

(26 citation statements)

References 64 publications

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“…[e.g. 2 , 3 ], there are very limited data available on the water quality and ecological status of most lentic ecosystems in tropical Africa. From these data, it seems that growing eutrophication of these ecosystems [e.g.…”

Section: Introductionmentioning

confidence: 99%

Assessment of some key indicators of the ecological status of an African freshwater lagoon (Lagoon Aghien, Ivory Coast)

et al. 2021

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The supply of drinking water is a vital challenge for the people who live on the African continent, as this continent is experiencing strong demographic growth and therefore increasing water demands. To meet these needs, surface water resources are becoming increasingly mobilized because underground resources are not always available or have already been overexploited. This situation is the case in the region of Abidjan in the Ivory Coast, where the drinking water deficit is a growing problem and it is therefore necessary to mobilize new water resources to ensure the supply of drinking water. Among the potential resources, local managers have identified a freshwater lagoon, Lagoon Aghien, That is in close proximity to the city of Abidjan. With the aim of enhancing knowledge on the ecological functioning of the lagoon and contributing to the assessment of its ability to provide drinking water, several physical and chemical parameters of the water and the phytoplankton community of the lagoon were monitored for 17 months (December 2016-April 2018) at six sampling stations. Our findings show that the lagoon is eutrophic, as evidenced by the high concentrations of total phosphorus (>140 μg L-1), nitrogen (1.36 mg L-1) and average chlorophyll-a (26 to 167 μg L-1) concentrations. The phytoplankton community in the lagoon is dominated by genera typical of eutrophic environments including mixotrophic genera such as Peridinium and by cyanobacteria such as Cylindrospermopsis/Raphidiopsis, Microcystis and Dolichospermum that can potentially produce cyanotoxins. The two rainfall peaks that occur in June and October appeared to be major events in terms of nutrient flows entering the lagoon, and the dynamics of these flows are complex. Significant differences were also found in the nutrient concentrations and to a lesser extent in the phytoplankton communities among the different stations, especially during the rainfall peaks. Overall, these results reveal that the quality of the lagoon’s water is already severely degraded, and this degradation could increase in future years due to increasing urbanization in the watershed. These results therefore raise questions about the potential use of the lagoon as a source of drinking water if measures are not taken very quickly to protect this lagoon from increasing eutrophication and other pollution sources.

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Section: Introductionmentioning

confidence: 99%

Assessment of some key indicators of the ecological status of an African freshwater lagoon (Lagoon Aghien, Ivory Coast)

et al. 2021

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“…Vertical mixing in tropical lakes is very dynamic, and the depth of the actively mixing layer can range widely over 24 hr (e.g. Barbosa & Padisák, 2002;Rugema et al, 2019), as a function of water column heating due to solar radiation incidence, causing the actively mix layer depth to be shallower around noon (Amaral et al, 2018;MacIntyre & Melack, 1984). These daily vertical movements were shown to affect nutrients (Melack & Fisher, 1990) and greenhouse gases dynamics (Amaral et al, 2018(Amaral et al, , 2020Barbosa et al, 2020), but the impact to phytoplankton biomass and primary production on Amazon floodplain lakes are yet to be assessed.…”

Section: Discussionmentioning

confidence: 99%

“…Phytoplankton provides a substantial contribution to primary production in aquatic ecosystems (Zwart et al, 2015), sustaining a network of trophic interactions, with decisive consequences for ecosystem functioning (Abonyi et al, 2018). The role of bottom‐up factors influencing phytoplankton biomass has been studied for decades, but prevailing models developed in temperate zones may be inappropriate for tropical environments due to differences in food web configuration and varying amplitude of seasonal and interannual cycles (Huszar et al, 2006; Melack, 1976; Rugema et al., 2019; Sarmento, 2012). Phytoplankton biomass is regulated by both top‐down and bottom‐up effects in temperate lakes distributed over a wide productivity gradient (Mazumder, 1994).…”

Section: Introductionmentioning

confidence: 99%

Fisheries management influences phytoplankton biomass of Amazonian floodplain lakes

Campos‐Silva

Peres

Amaral

et al. 2020

Journal of Applied Ecology

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1. Tropical floodplains secure the protein supply of millions of people, but only sound management can ensure the long-term continuity of such ecosystem services. Overfishing is a widespread threat to multitrophic systems, but how it affects ecosystem functioning is poorly understood, particularly in tropical freshwater food webs. Models based on temperate lakes frequently assume that primary producers are mostly bottom-up controlled by nutrient and light limitations, with negligible effects of top-down forces. Yet this assumption remains untested in complex tropical freshwater systems experiencing marked spatiotemporal variation. 2. We use consolidated community-based fisheries management practices and spatial zoning to test the relative importance of bottom-up versus top-down drivers of phytoplankton biomass, controlling for the influence of local to landscape heterogeneity. Our study focuses on 58 large Amazonian floodplain lakes under different management regimes that resulted in a gradient of apex-predator abundance. These lakes, distributed along ~600 km of a major tributary of the Amazon River, varied widely in size, structure, landscape context, and hydrological seasonality. 3. Using generalised linear models, we show that community-based fisheries management, which controls the density of apex predators, is the strongest predictor of phytoplankton biomass during the dry season, when lakes become discrete landscape units. Water transparency also emerges as an important bottom-up factor, but phosphorus, nitrogen and several lake and landscape metrics had minor or no effects on phytoplankton biomass. During the wet-season food pulse, when lakes become connected to adjacent water bodies and homogenise the landscape, only lake depth explained phytoplankton biomass. This is an open access article under the terms of the Creative Commons Attribution License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited.

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“…Since 2002, phytoplankton studies have been conducted in Lake Kivu (Sarmento et al 2012, Rugema et al 2019) using high performance liquid chromatography (HPLC) to determine phytoplankton marker pigments. This technique, which can estimate phytoplankton biomass at the class level, was developed in the marine environment (Wright and Jeffrey 2006) and applies as well to estuarine and fresh waters (Fietz and Nicklisch 2004, Descy et al 2005, Fietz et al 2005, review in Sarmento and Descy 2008.…”

Section: Introductionmentioning

confidence: 99%

“…This technique, which can estimate phytoplankton biomass at the class level, was developed in the marine environment (Wright and Jeffrey 2006) and applies as well to estuarine and fresh waters (Fietz and Nicklisch 2004, Descy et al 2005, Fietz et al 2005, review in Sarmento and Descy 2008. Monitoring phytoplankton biomass and composition in Lake Kivu, based on the use of specific marker pigments of these classes over 12 years, allowed Rugema et al (2019) to detect dramatic changes in phytoplankton community structure of Lake Kivu, which they attributed to a change in the water column mixing pattern, depending on large-scale climate variability. That study demonstrated the potential of using pigmentbased analysis of phytoplankton composition, complemented by data from microscopy, as a tool to monitor environmental changes in this tropical lake at different time scales.…”

Section: Introductionmentioning

confidence: 99%

Phytoplankton pigment analysis as a tool for monitoring a tropical great lake, Lake Kivu (East Africa)

et al. 2021

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Lake Kivu, East Africa, is a deep oligotrophic and meromictic lake containing high amounts of dissolved methane (∼55-60 km 3 ) and carbon dioxide (∼300 km 3 ) in its deep waters. Methane harvesting for energy production began in 2015, and a monitoring programme was set up to assess possible disturbance on the ecosystem. Phytoplankton biomass and composition was assessed twice per month or monthly at 2 monitoring sites between June 2005 and December 2019, based on HPLC analysis of chlorophyll a (Chl-a) and marker pigments. This long-term series shows that significant changes occurred around 2010 in the lake phytoplankton, with a notable increase of Chl-a and changes in the assemblage toward an increase in non-motile green algae and diatoms. To assess possible changes due to methane harvesting, we compared 2 periods, 2012-2014 and 2018-2019. Chl-a concentration decreased slightly in 2018-2019 compared to the reference period of 2012-2014, and significant changes occurred in composition of the phytoplankton assemblage. In terms of relative contribution to Chl-a, diatoms increased from 26% to 46%, whereas green algae decreased ∼2-fold, from 35% in 2012-2014 to 18% in 2018-2019. Multivariate analyses showed that phytoplankton composition was influenced by seasonal and interannual variations of limnological variables related to changes in meteorological factors. To assess possible future changes due to methane exploitation, we recommend increasing sampling frequency and taxonomic resolution, as well as improving environmental data acquisition.

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Long‐term change of phytoplankton in Lake Kivu: The rise of the greens

Cited by 19 publications

References 64 publications

Assessment of some key indicators of the ecological status of an African freshwater lagoon (Lagoon Aghien, Ivory Coast)

Assessment of some key indicators of the ecological status of an African freshwater lagoon (Lagoon Aghien, Ivory Coast)

Fisheries management influences phytoplankton biomass of Amazonian floodplain lakes

Phytoplankton pigment analysis as a tool for monitoring a tropical great lake, Lake Kivu (East Africa)

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