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U. Goodenough, J. Heuser (1985)
The Chlamydomonas cell wall and its constituent glycoproteins analyzed by the quick-freeze, deep-etch techniqueThe Journal of Cell Biology, 101
C. Lamelas, K. Wilkinson, V. Slaveykova (2005)
Influence of the composition of natural organic matter on Pb bioavailability to microalgae.Environmental science & technology, 39 16
Á. Zsolnay, E. Baigar, M. Jimenez, B. Steinweg, F. Saccomandi (1999)
Differentiating with fluorescence spectroscopy the sources of dissolved organic matter in soils subjected to dryingChemosphere, 38 1
A. Baker (2001)
Fluorescence excitation-emission matrix characterization of some sewage-impacted rivers.Environmental science & technology, 35 5
E. Harris (1989)
2 – Culture and Storage Methods
Isabelle Worms, K. Wilkinson (2007)
Ni uptake by a green alga. 2. Validation of equilibrium models for competition effects.Environmental science & technology, 41 12
F. Cantwell, J. Nielsen, S. Hrudey (1982)
Free nickel ion concentration in sewage by an ion exchange column-equilibration methodAnalytical Chemistry, 54
Isabelle Worms, Dana Simon, Dana Simon, Christel Hassler, Kevin Wilkinson (2006)
Bioavailability of trace metals to aquatic microorganisms: importance of chemical, biological and physical processes on biouptake.Biochimie, 88 11
H. Kola, K. Wilkinson (2005)
Cadmium uptake by a green alga can be predicted by equilibrium modelling.Environmental science & technology, 39 9
C. Jumarie, C. Fortin, M. Houde, P. Campbell, F. Denizeau (2001)
Cadmium uptake by Caco-2 cells: effects of Cd complexation by chloride, glutathione, and phytochelatins.Toxicology and applied pharmacology, 170 1
Maki Yamamoto, I. Kurihara, S. Kawano (2005)
Late type of daughter cell wall synthesis in one of the Chlorellaceae, Parachlorella kessleri (Chlorophyta, Trebouxiophyceae)Planta, 221
B. Vigneault, P. Campbell (2005)
UPTAKE OF CADMIUM BY FRESHWATER GREEN ALGAE: EFFECTS OF PH AND AQUATIC HUMIC SUBSTANCES 1Journal of Phycology, 41
(1989)
Culture and storage methods
K. Schamphelaere, C. Nys, Colin Janssen (2014)
Toxicity of lead (Pb) to freshwater green algae: development and validation of a bioavailability model and inter-species sensitivity comparison.Aquatic toxicology, 155
P. Sánchez-Marín, J. Lorenzo, R. Blust, R. Beiras (2007)
Humic acids increase dissolved lead bioavailability for marine invertebrates.Environmental science & technology, 41 16
(2011)
Paracentrotus lividus larvae
C. Hassler, V. Slaveykova, K. Wilkinson (2004)
Discriminating between intra‐ and extracellular metals using chemical extractionsLimnology and Oceanography: Methods, 2
R. Hajdu, V. Slaveykova (2012)
Cd and Pb removal from contaminated environment by metal resistant bacterium Cupriavidus metallidurans CH34: importance of the complexation and competition effectsEnvironmental Chemistry, 9
Y. Ge, S. Sauvé, W. Hendershot (2005)
Equilibrium Speciation of Cadmium, Copper, and Lead in Soil SolutionsCommunications in Soil Science and Plant Analysis, 36
A. Tessier, D. Turner (1995)
Metal speciation and bioavailability in aquatic systems
P. Sánchez-Marín, R. Beiras (2012)
Quantification of the increase in Pb bioavailability to marine organisms caused by different types of DOM from terrestrial and river origin.Aquatic toxicology, 110-111
B. Sulzberger, E. Durisch-Kaiser (2009)
Chemical characterization of dissolved organic matter (DOM): A prerequisite for understanding UV-induced changes of DOM absorption properties and bioavailabilityAquatic Sciences, 71
C. Lamelas, V. Slaveykova (2007)
Comparison of Cd(II), Cu(II), and Pb(II) biouptake by green algae in the presence of humic acid.Environmental science & technology, 41 11
V. Slaveykova, K. Wilkinson, A. Ceresa, E. Pretsch (2003)
Role of fulvic acid on lead bioaccumulation by Chlorella kesslerii.Environmental science & technology, 37 6
P. Sánchez-Marín, C. Fortin, P. Campbell (2013)
Copper and lead internalisation by freshwater microalgae at different carbonate concentrations.Environmental Chemistry, 10
S. Mylon, B. Twining, N. Fisher, G. Benoit (2003)
Relating the Speciation of Cd, Cu, and Pb in Two Connecticut Rivers with Their Uptake in AlgaeEnvironmental Science & Technology, 37
P. Coble (1996)
Characterization of marine and terrestrial DOM in seawater using excitation-emission matrix spectroscopyMarine Chemistry, 51
H. Kola, L. Laglera, N. Parthasarathy, K. Wilkinson (2004)
Cadmium Adsorption by Chlamydomonas reinhardtii and its Interaction with the Cell Wall ProteinsEnvironmental Chemistry, 1
Olivier Errécalde, M. Seidl, P. Campbell (1998)
Influence of a low molecular weight metabolite (citrate) on the toxicity of cadmium and zinc to the unicellular green alga Selenastrum Capricornutum: An exception to the free-ion modelWater Research, 32
P. Campbell, M. Twiss, K. Wilkinson (1997)
Accumulation of natural organic matter on the surfaces of living cells: implications for the interaction of toxic solutes with aquatic biotaCanadian Journal of Fisheries and Aquatic Sciences, 54
(2000)
applications to complex aqueous media
W. Schecher, D. McAvoy (1992)
MINEQL+: A software environment for chemical equilibrium modelingComputers, Environment and Urban Systems, 16
Isabelle Worms, K. Wilkinson (2008)
Determination of Ni2+ using an equilibrium ion exchange technique: Important chemical factors and applicability to environmental samples.Analytica chimica acta, 616 1
C. Fortin, F. Caron (2000)
Complexing capacity of low-level radioactive waste leachates for 60Co and 109Cd using an ion-exchange techniqueAnalytica Chimica Acta, 410
J. McLean, M. Pabst, C. Miller, C. Dimkpa, A. Anderson (2013)
Effect of complexing ligands on the surface adsorption, internalization, and bioresponse of copper and cadmium in a soil bacterium, Pseudomonas putida.Chemosphere, 91 3
D. Simon, P. Descombes, W. Zerges, K. Wilkinson (2008)
Global expression profiling of Chlamydomonas reinhardtii exposed to trace levels of free cadmiumEnvironmental Toxicology and Chemistry, 27
D. Toro, H. Allen, H. Bergman, J. Meyer, P. Paquin, R. Santore (2001)
Biotic ligand model of the acute toxicity of metals. 1. Technical BasisEnvironmental Toxicology and Chemistry, 20
Isabelle Worms, J. Traber, David Kistler, L. Sigg, V. Slaveykova (2010)
Uptake of Cd(II) and Pb(II) by microalgae in presence of colloidal organic matter from wastewater treatment plant effluents.Environmental pollution, 158 2
V. Slaveykova, K. Wilkinson (2002)
Physicochemical aspects of lead bioaccumulation by Chlorella vulgaris.Environmental science & technology, 36 5
Brahim Koukal, C. Guéguen, M. Pardos, J. Dominik (2003)
Influence of humic substances on the toxic effects of cadmium and zinc to the green alga Pseudokirchneriella subcapitata.Chemosphere, 53 8
Isabelle Worms, N. Parthasarathy, K. Wilkinson (2007)
Ni uptake by a green alga. 1. Validation of equilibrium models for complexation effects.Environmental science & technology, 41 12
P. Porcal, A. Amirbahman, J. Kopáček, F. Novák, S. Norton (2009)
Photochemical release of humic and fulvic acid-bound metals from simulated soil and streamwater.Journal of environmental monitoring : JEM, 11 5
T. Brinkmann, P. Hörsch, Danielle Sartorius, F. Frimmel (2003)
Photoformation of low-molecular-weight organic acids from brown water dissolved organic matter.Environmental science & technology, 37 18
Régis Kottelat, D. Vignati, V. Chanudet, J. Dominik (2007)
Comparison of Small- and Large-scale Ultrafiltration Systems for Organic Carbon and Metals in Freshwater at Low Concentration FactorWater, Air, and Soil Pollution, 187
J. Spierings, Isabelle Worms, P. Miéville, V. Slaveykova (2011)
Effect of humic substance photoalteration on lead bioavailability to freshwater microalgae.Environmental science & technology, 45 8
D. McKnight, E. Boyer, P. Westerhoff, P. Doran, T. Kulbe, D. Andersen (2001)
Spectrofluorometric characterization of dissolved organic matter for indication of precursor organic material and aromaticityLimnology and Oceanography, 46
M. Waeber, S. Stoll, V. Slaveykova (2012)
Trace metal behavior in surface waters: emphasis on dynamic speciation, sorption processes and bioavailabilityArchives Des Sciences, 65
P. Sánchez-Marín, J. Bellas, V. Mubiana, J. Lorenzo, R. Blust, R. Beiras (2011)
Pb uptake by the marine mussel Mytilus sp. Interactions with dissolved organic matter.Aquatic toxicology, 102 1-2
M. Gonsior, B. Peake, W. Cooper, D. Podgorski, J. D’Andrilli, W. Cooper (2009)
Photochemically induced changes in dissolved organic matter identified by ultrahigh resolution fourier transform ion cyclotron resonance mass spectrometry.Environmental science & technology, 43 3
H. Leeuwen, R. Town, J. Buffle, R. Cleven, W. Davison, J. Puy, W. Riemsdijk, L. Sigg (2005)
Dynamic speciation analysis and bioavailability of metals in aquatic systems.Environmental science & technology, 39 22
B. Vigneault, A. Percot, M. Lafleur, P. Campbell (2000)
Permeability changes in model and phytoplankton membranes in the presence of aquatic humic substancesEnvironmental Science & Technology, 34
J. Ritchie, E. Perdue (2003)
Proton-binding study of standard and reference fulvic acids, humic acids, and natural organic matterGeochimica et Cosmochimica Acta, 67
P. Sánchez-Marín, V. Slaveykova, R. Beiras (2010)
Cu and Pb accumulation by the marine diatom Thalassiosira weissflogii in the presence of humic acidsEnvironmental Chemistry, 7
P. Sánchez-Marín, J. Santos-Echeandía, M. Nieto‐Cid, X. Álvarez‐Salgado, R. Beiras (2010)
Effect of dissolved organic matter (DOM) of contrasting origins on Cu and Pb speciation and toxicity to Paracentrotus lividus larvae.Aquatic toxicology, 96 2
S. Bayen, Isabelle Worms, N. Parthasarathy, K. Wilkinson, J. Buffle (2006)
Cadmium bioavailability and speciation using the permeation liquid membrane.Analytica chimica acta, 575 2
H. Leeuwen (1999)
Metal Speciation Dynamics and Bioavailability: Inert and Labile ComplexesEnvironmental Science & Technology, 33
P. Campbel (1995)
Interactions between trace metals and aquatic organisms : A critique of the Free-ion Activity Model
Isabelle Worms, David Adenmatten, P. Miéville, J. Traber, V. Slaveykova (2015)
Photo-transformation of pedogenic humic acid and consequences for Cd(II), Cu(II) and Pb(II) speciation and bioavailability to green microalga.Chemosphere, 138
C. Fortin, P. Campbell (1998)
An Ion-Exchange Technique for Free-Metal Ion Measurements (Cd2+ Zn2+): Applications to Complex Aqueous MediaInternational Journal of Environmental Analytical Chemistry, 72
C. Lamelas, J. Pinheiro, V. Slaveykova (2009)
Effect of humic acid on Cd(II), Cu(II), and Pb(II) uptake by freshwater algae: kinetic and cell wall speciation considerations.Environmental science & technology, 43 3
Years of experimentation in well-defined media has demonstrated that trace metal bioavailability should be best predicted by the concentration (or activity) of the free cation (free ion activity model, FIAM). In the particular case of lead, uptake of Pb by Chlorella kessleri has been, however, shown to be higher in the presence of the Suwannee River fulvic acid and Suwannee River humic acid as compared to what was predicted by the free ion concentrations [Pb2+]. In order to estimate whether such exceptions of the FIAM can be extended to other freshwater phytoplankton, we measured the biouptake of Pb by C. reinhardtii another model phytoplankton, in solution containing these two model humic substances and for which free Pb2+ concentrations were evaluated using an ion-exchange technique. Our results showed that Pb internalization by C. reinhardtii can be directly related to the [Pb2+] but that the deviation from the FIAM when using C. kessleri was still observed under the present experimental conditions. Indeed, when using freshly isolated colloidal fraction (>3 kDa) of a marsh water and its photoaltered products, [Pb2+] measurements are shown to poorly predict Pb uptake by C. kessleri and surprisingly Pb uptake by C. reinhardtii.
Aquatic Geochemistry – Springer Journals
Published: Mar 10, 2015
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