Abstract. The evolution of eutrophication parameters (i.e., nutrients and phytoplankton
biomass) during recent decades was examined in coastal waters of the Vilaine
Bay (VB, France) in relation to changes in the Loire and Vilaine rivers.
Dynamic linear models were used to study long-term trends and seasonality of
dissolved inorganic nutrient and chlorophyll a concentrations (Chl a) in
rivers and coastal waters. For the period 1997–2013, the reduction in
dissolved riverine inorganic phosphorus (DIP) concentrations led to the
decrease in their Chl a levels. However, while dissolved inorganic nitrogen (DIN) concentrations decreased only slightly in the Vilaine, they increased
in the Loire, specifically in summer. Simultaneously, phytoplankton in the VB
underwent profound changes with increase in biomass and change in the timing
of the annual peak from spring to summer. The increase in phytoplankton
biomass in the VB, manifested particularly by increased summer diatom
abundances, was due to enhanced summer DIN loads from the Loire, sustained by
internal regeneration of DIP and dissolved silicate (DSi) from sediments. The
long-term trajectories of this case study evidence that significant reduction
of P inputs without simultaneous N abatement was not yet sufficient to
control eutrophication all along the Loire–Vilaine–VB continuum. Upstream
rivers reveal indices of recoveries following the significant diminution of
P, while eutrophication continues to increase downstream, especially when N
is the limiting factor. More N input reduction, paying particular attention
to diffuse N sources, is required to control eutrophication in receiving VB
coastal waters. Internal benthic DIP and DSi recycling appears to have
contributed to the worsening of summer VB water quality, augmenting the
effects of anthropogenic DIN inputs. For this coastal ecosystem, nutrient
management strategies should consider the role played by internal nutrient
loads to tackle eutrophication processes.
Diatom blooms in Thau lagoon are always related to rain events leading to inputs of inorganic nutrients such as phosphate, ammonium and nitrate through the watershed with time lags of about 1 week. In contrast, blooms of Alexandrium catenella/tamarense can occur following periods of 3 weeks without precipitation and no significant input of conventional nutrients such as nitrate and phosphate. Field results also indicate a significant drop (from 22-25 to 15-16 μM over 3 days) in dissolved organic nitrogen (DON) at the bloom peak, as well as a significant inverse relationship between A. catenella/tamarense cell density and DON concentrations that is not apparent for diatom blooms. Such dinoflagellate blooms are also associated with elevated (6-9 μM) ammonium concentrations, a curious feature also observed by other investigators, possibly the results of ammonium excretion by this organism during urea or other organic nitrogen assimilation. The potential use of DON by this organism represents short cuts in the nitrogen cycle between plants and nutrients and requires a new model for phytoplankton growth that is different from the classical diatom bloom model. In contrast to such diatom blooms that are due to conventional (nitrate, phosphate) nutrient pulses, Alexandrium catenella/tamarense blooms on the monthly time scale are due to organic nutrient enrichment, a feature that allows net growth rates of about 1.3 d −1 , a value higher than that generally attributed to such organisms.
<p><strong>Abstract.</strong> The evolution of eutrophication (i.e., phytoplankton biomass) during recent decades was examined in the coastal waters of Vilaine Bay (VB, France) in relation to those in their main external nutrient sources, the Loire and Vilaine Rivers. Dynamic Linear Models, corroborated by the Mann-Kendall test, were used to study long-term trends and seasonality of dissolved inorganic nutrient and chlorophyll <i>a</i> concentrations (Chl <i>a</i>) in rivers and coastal waters between 1980 and 2013. The reduction in dissolved riverine inorganic phosphorus concentrations (DIP) from the early 1990s led to the decrease in their Chl <i>a</i> levels. However, dissolved inorganic nitrogen concentrations (DIN) decreased only slightly in the Vilaine and actually increased in the Loire, especially during summer. Simultaneously, phytoplankton in the VB has undergone profound changes with: (1) increase in biomass, (2) change in the position of the annual peak from spring to summer, and (3) increase in diatom:dinoflagellate ratios, especially in summer. The increase in phytoplankton biomass in VB, particularly in summer, was probably due to increased DIN loads from the Loire, sustained by internal regeneration of DIP and dissolved silicate from sediments. This long-term ecosystem-scale analysis reports the consequence of nutrient management scenarios focused solely on P reduction. Freshwater ecosystems upstream reveal successful recoveries through the control of P alone, while eutrophication continues to increase downstream, especially during the period of N limitation. Therefore, nutrient management strategies, paying particular attention to diffuse N-sources, are required to control eutrophication in receiving coastal waters.</p>
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