Evolutionary patterns and physicochemical properties explain macroinvertebrate sensitivity to heavy metals

Ecological risk assessment depends strongly on species sensitivity data. Typically, sensitivity data are based on laboratory toxicity bioassays, which for practical constraints cannot be exhaustively performed for all species and chemicals available. Bilinear models integrating phylogenetic informat...

Full description

Saved in:
Bibliographic Details
Published in:Ecological applications 2016-06, Vol.26 (4), p.1249-1259
Main Authors: Malaj, Egina, Guillaume Guénard, Ralf B. Schäfer, Peter C. von der Ohe
Format: Article
Language:English
Subjects:
acute toxicity
Animals
aquatic invertebrates
aquatic organisms
bioassays
Biological Evolution
data collection
DNA
DNA - genetics
ecotoxicology
environmental assessment
Environmental Pollutants - toxicity
evolutionary biology
heavy metals
interspecific variation
Invertebrates - drug effects
LC50
macroinvertebrates
Metals, Heavy - toxicity
Models, Biological
molecular data
nucleotide sequences
phylogenetic modeling
phylogenetic tree
phylogeny
physicochemical properties
statistical models
toxicity
variance
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Ecological risk assessment depends strongly on species sensitivity data. Typically, sensitivity data are based on laboratory toxicity bioassays, which for practical constraints cannot be exhaustively performed for all species and chemicals available. Bilinear models integrating phylogenetic information of species and physicochemical properties of compounds allow to predict species sensitivity to chemicals. Combining the molecular information (DNA sequences) of 31 invertebrate species with the physicochemical properties of six bivalent metals, we built bilinear models that explained 70–80% of the variability in species sensitivity to heavy metals. Phylogeny was the most important component of the bilinear models, as it explained the major part of the explained variance (>40%). Predicted values from bilinear modeling were in agreement with experimental values (>50%); therefore, this approach is a good starting point to build statistical models which can potentially predict heavy metal toxicity for untested invertebrate species based on empirical values for similar species. Despite their good performance, development of the presented bilinear models would benefit from improved phylogenetic and toxicological datasets. Our analysis is an example for linking evolutionary biology with applied ecotoxicology. Its future applications may encompass other stress factors or traits influencing the survival of aquatic organisms in polluted environments.
ISSN:1051-0761
1939-5582
DOI:10.1890/15-0346