33 research outputs found
Dust inputs and bacteria influence dissolved organic matter in clear alpine lakes
Remote lakes are usually unaffected by direct human influence, yet they receive inputs of atmospheric pollutants, dust, and other aerosols, both inorganic and organic. In remote, alpine lakes, these atmospheric inputs may influence the pool of dissolved organic matter, a critical constituent for the biogeochemical functioning of aquatic ecosystems. Here, to assess this influence, we evaluate factors related to aerosol deposition, climate, catchment properties, and microbial constituents in a global dataset of 86 alpine and polar lakes. We show significant latitudinal trends in dissolved organic matter quantity and quality, and uncover new evidence that this geographic pattern is influenced by dust deposition, flux of incident ultraviolet radiation, and bacterial processing. Our results suggest that changes in land use and climate that result in increasing dust flux, ultraviolet radiation, and air temperature may act to shift the optical quality of dissolved organic matter in clear, alpine lakes
Differential Response of High-Elevation Planktonic Bacterial Community Structure and Metabolism to Experimental Nutrient Enrichment
Nutrient enrichment of high-elevation freshwater ecosystems by atmospheric deposition is increasing worldwide, and bacteria are a key conduit for the metabolism of organic matter in these oligotrophic environments. We conducted two distinct in situ microcosm experiments in a high-elevation lake (Emerald Lake, Sierra Nevada, California, USA) to evaluate responses in bacterioplankton growth, carbon utilization, and community structure to short-term enrichment by nitrate and phosphate. The first experiment, conducted just following ice-off, employed dark dilution culture to directly assess the impact of nutrients on bacterioplankton growth and consumption of terrigenous dissolved organic matter during snowmelt. The second experiment, conducted in transparent microcosms during autumn overturn, examined how bacterioplankton in unmanipulated microbial communities responded to nutrients concomitant with increasing phytoplankton-derived organic matter. In both experiments, phosphate enrichment (but not nitrate) caused significant increases in bacterioplankton growth, changed particulate organic stoichiometry, and induced shifts in bacterial community composition, including consistent declines in the relative abundance of Actinobacteria. The dark dilution culture showed a significant increase in dissolved organic carbon removal in response to phosphate enrichment. In transparent microcosms nutrient enrichment had no effect on concentrations of chlorophyll, carbon, or the fluorescence characteristics of dissolved organic matter, suggesting that bacterioplankton responses were independent of phytoplankton responses. These results demonstrate that bacterioplankton communities in unproductive high-elevation habitats can rapidly alter their taxonomic composition and metabolism in response to short-term phosphate enrichment. Our results reinforce the key role that phosphorus plays in oligotrophic lake ecosystems, clarify the nature of bacterioplankton nutrient limitation, and emphasize that evaluation of eutrophication in these habitats should incorporate heterotrophic microbial communities and processes
Climate change and Saharan dust drive recent cladoceran and primary production changes in remote alpine lakes of Sierra Nevada, Spain
Recent anthropogenic climate change and the exponential increase over the past
few decades of Saharan dust deposition, containing ecologically important inputs of
phosphorus (P) and calcium (Ca), are potentially affecting remote aquatic ecosystems.
In this study, we examine changes in cladoceran assemblage composition and
chlorophyll-a concentrations over the past ~150 years from high-resolution, welldated
sediment cores retrieved from six remote high mountain lakes in the Sierra
Nevada Mountains of Southern Spain, a region affected by Saharan dust deposition.
In each lake, marked shifts in cladoceran assemblages and chlorophyll-a concentrations
in recent decades indicate a regional-scale response to climate and Saharan
dust deposition. Chlorophyll-a concentrations have increased since the 1970s, consistent
with a response to rising air temperatures and the intensification of atmospheric
deposition of Saharan P. Similar shifts in cladoceran taxa across lakes began
over a century ago, but have intensified over the past ~50 years, concurrent with
trends in regional air temperature, precipitation, and increased Saharan dust deposition.
An abrupt increase in the relative abundance of the benthic cladoceran Alona
quadrangularis at the expense of Chydorus sphaericus, and a significant increase in
Daphnia pulex gr. was a common trend in these softwater lakes. Differences in the
magnitude and timing of these changes are likely due to catchment and lake-specific
differences. In contrast with other alpine lakes that are often affected by acid
deposition, atmospheric Ca deposition appears to be a significant explanatory factor,
among others, for the changes in the lake biota of Sierra Nevada that has not been
previously considered. The effects observed in Sierra Nevada are likely occurring in
other Mediterranean lake districts, especially in softwater, oligotrophic lakes. The
predicted increases in global temperature and Saharan dust deposition in the future
will further impact the ecological condition of these ecosystemsMinisterio de Educación y Ciencia (MEC), Grant/Award Number: AP2007-00352; Programa Nacional de Movilidad de Recursos Humanos de Investigaci on (MICINN); Ministerio de Medio Ambiente (MMA), Grant/Award Number: 87/2007; Ministerio de Econom ıa, Industria y Competitividad (MINECO), Grant/Award Number: CGL2011-23483; Natural Sciences and Engineering Research Council of Canad
20th Century Atmospheric Deposition and Acidification Trends in Lakes of the Sierra Nevada, California, USA
We investigated multiple lines of evidence to determine if observed and paleo-reconstructed changes in acid neutralizing capacity (ANC) in Sierra Nevada lakes were the result of changes in 20th century atmospheric deposition. Spheroidal carbonaceous particles (SCPs) (indicator of anthropogenic atmospheric deposition) and biogenic silica and δ(13)C (productivity proxies) in lake sediments, nitrogen and sulfur emission inventories, climate variables, and long-term hydrochemistry records were compared to reconstructed ANC trends in Moat Lake. The initial decline in ANC at Moat Lake occurred between 1920 and 1930, when hydrogen ion deposition was approximately 74 eq ha(-1) yr(-1), and ANC recovered between 1970 and 2005. Reconstructed ANC in Moat Lake was negatively correlated with SCPs and sulfur dioxide emissions (p = 0.031 and p = 0.009). Reconstructed ANC patterns were not correlated with climate, productivity, or nitrogen oxide emissions. Late 20th century recovery of ANC at Moat Lake is supported by increasing ANC and decreasing sulfate in Emerald Lake between 1983 and 2011 (p < 0.0001). We conclude that ANC depletion at Moat and Emerald lakes was principally caused by acid deposition, and recovery in ANC after 1970 can be attributed to the United States Clean Air Act
Trends in the water chemistry of high mountain lakes in Europe
15 páginas, 5 figuras,3 tablas.Here we present the chemical trends of seven high altitude lakes, analysed within the
AL:PE and MOLAR Projects of the EU (1999) and selected on the basis of the availability of
complete and reliable data for the period 1984–1999. The lakes are representative of the Scandinavian
Alps, the Cairngorm Mountains in Scotland, the Alps and the Pyrenees. Significant trends
were identified for some indicators of acidification, for instance pH and alkalinity, but not all lakes
reacted similarly to decreasing depositions of sulphate and base cations. Differences in lake response
are discussed in relation to recent variations of atmospheric deposition chemistry and associated
changes in climatic conditions. Beside individual variations of the studied lakes, depending, among
other things, on altitude and morphology, catchment characteristics and climate trends play a major
role for the reaction of high altitude lakes on changes in atmospheric depositions.The MOLAR project is funded within the European Commission Framework Programme
IV: Environment and Climate with assistance from INCO. Contract No.:
ENV4-CT95-0007/IC20-CT96-0021.Peer reviewe