Ecotoxicological tests with earthworms are widely used and are mandatory for the risk assessment of pesticides prior to registration and commercial use. The current model species for standardized tests is Eisenia fetida or Eisenia andrei. However, these species are absent from agricultural soils and often less sensitive to pesticides than other earthworm species found in mineral soils. To move towards a better assessment of pesticide effects on non-target organisms, there is a need to perform a posteriori tests using relevant species. The endogeic species Aporrectodea caliginosa (Savigny, 1826) is representative of cultivated fields in temperate regions and is suggested as a relevant model test species. After providing information on its taxonomy, biology, and ecology, we reviewed current knowledge concerning its sensitivity towards pesticides. Moreover, we highlighted research gaps and promising perspectives. Finally, advice and recommendations are given for the establishment of laboratory cultures and experiments using this soil-dwelling earthworm species.Electronic supplementary materialThe online version of this article (10.1007/s11356-018-2579-9) contains supplementary material, which is available to authorized users.
Current methods to
assess the impact of chemical mixtures on organisms
ignore the temporal dimension. The General Unified Threshold model
for Survival (GUTS) provides a framework for deriving toxicokinetic–toxicodynamic
(TKTD) models, which account for effects of toxicant exposure on survival
in time. Starting from the classic assumptions of independent action
and concentration addition, we derive equations for the GUTS reduced
(GUTS-RED) model corresponding to these mixture toxicity concepts
and go on to demonstrate their application. Using experimental binary
mixture studies with
Enchytraeus crypticus
and previously published data for
Daphnia magna
and
Apis mellifera
, we assessed the
predictive power of the extended GUTS-RED framework for mixture assessment.
The extended models accurately predicted the mixture effect. The GUTS
parameters on single exposure data, mixture model calibration, and
predictive power analyses on mixture exposure data offer novel diagnostic
tools to inform on the chemical mode of action, specifically whether
a similar or dissimilar form of damage is caused by mixture components.
Finally, observed deviations from model predictions can identify interactions,
e.g., synergism or antagonism, between chemicals in the mixture, which
are not accounted for by the models. TKTD models, such as GUTS-RED,
thus offer a framework to implement new mechanistic knowledge in mixture
hazard assessments.
Different criteria were compared for assessing bacterial wilt resistance in 13 tomato genotypes varying in disease susceptibility. Wilt severity and bacterial invasiveness at collar and midstem were compared in the field under cooler (March to May, 20–28°C) and warmer months (June to August, 23–29°C), which were unfavourable and favourable to wilt symptom expression, respectively. A model was proposed for determining resistance regardless of climatic conditions prevalent during field experimentation. This model was based on an estimate of bacterial invasiveness termed the colonization index. Using a qualitative imprint method we confirmed that the more resistant the genotype, the lower the bacterial colonization of the stem. The colonization index accounted both for wilted plants and for infected asymptomatic plants in which Pseudomonas solanacearum populations failed to produce wilt. The colonization index at midstem was the more useful indicator of resistance under favourable conditions. When environmental conditions were unfavourable to wilt, colonization index at collar level discerned resistant genotypes more clearly. The results formed the basis for a model for predicting the degree and stability of resistance in tomato.
Recent EFSA (European Food Safety Authority) reports highlighted that the ecological risk assessment of pesticides needed to go further by taking more into account the impacts of chemicals on biodiversity under field conditions. We assessed the effects of two commercial formulations of fungicides separately and in mixture, i.e., Cuprafor Micro® (containing 500 g kg -1 copper oxychloride) at 4 (C1, corresponding to 3.1 mg kg -1 dry soil of copper) and 40 kg ha -1 (C10), and Swing® Gold (50 g L -1 epoxiconazole EPX and 133 g L -1 dimoxystrobin DMX) at one (D1, 5.81 10 -2 and 1.55 10 -1 mg kg -1 dry soil of EPX and DMX, respectively) and ten times (D10) the recommended field rate, on earthworms at 1, 6, 12, 18 and 24 months after the application following the international ISO standard no. 11268-3 to determine the effects on earthworms in field situations. The D10 treatment significantly reduced the species diversity (Shannon diversity index, 54% of the control), anecic abundance (29% of the control), and total biomass (49% of the control) over the first 18 months of experiment. The Shannon diversity index also decreased in the mixture treatment (both fungicides at the recommended dose) at 1 and 6 months after the first application (68% of the control at both sampling dates), and in C10 (78% of the control) at 18 months compared with the control. Lumbricus terrestris, Aporrectodea caliginosa, Aporrectodea giardi, Aporrectodea longa, and Allolobophora chlorotica were (in decreasing order) the most sensitive species to the tested fungicides. This study not only addressed field ecotoxicological effects of fungicides at the community level and ecological recovery, but it also pinpointed some methodological weaknesses (e.g., regarding fungicide concentrations in soil and statistics) of the guideline to determine the effects on earthworms in field situations.
International audienceIt is becoming increasingly popular to use phytoremediation methods for the reclamation of mine sites containing metal(loid)s. This study aims to assess the phytostabilization ability of two willow species (Salix viminalis and Salix purpurea) on technosols from a former gold mining site presenting polymetallic contamination (As, Sb and Pb). Different reconstituted soils using a mixture of the litter and the technosol collected on this previously mined site and a non-contaminated control garden soil were investigated in a 2 laboratory mesocosm. The physico-chemical soil parameters and the total metal(loid)s content in pore water were determined. After 45 days of growth, roots, leaves and stems from the two willow species were harvested. The biomass, metal(loid) concentrations and the mineral mass were determined for the different plant organs. Both Salix species were able to develop root systems on the different reconstituted soils and a variable aboveground biomass according to the soil composition. As, Sb and Pb accumulated mainly in the Salix rhizosphere. S. purpurea was more efficient in accumulating As in the plant's upper parts than S. viminalis. S. viminalis showed an ability to transfer Pb and Sb to its shoots whereas S. purpurea did not translocate these elements
To
better understand nanoplastic effects, the potential for surface
functionalization and dissolve organic matter eco-corona formation
to modify the mechanisms of action and toxicity of different nanoplastics
needs to be established. Here, we assess how different surface charges
modifying functionalization (postive (+ve) aminated; neutral unfunctionalized;
negative (−ve) carboxylated) altered the toxicity of 50 and
60 nm polystyrene nanoplastics to the nematode Caenorhabditis
elegans. The potency for effects on survival, growth,
and reproduction reduced in the order +ve aminated > neutral unfunctionalized
≫ −ve carboxylated with toxicity >60-fold higher
for
the +ve than −ve charged forms. Toxicokinetic–toxicodynamic
modeling (DEBtox) showed that the charge-related potency was primarily
linked to differences in effect thresholds and dose-associated damage
parameters, rather than to toxicokinetic parameters. This suggests
that surface functionalization may change the nature of nanoplastic
interactions with membrane and organelles leading to variations in
toxicity. Eco-corona formation reduced the toxicity of all nanoplastics
indicating that organic molecule associations may passivate surfaces.
Between particles, eco-corona interactions resulting in more equivalent
effects; however, even despite these changes, the order of potency
of the charged forms was retained. These results have important implications
for the development of future grouping approaches.
New data were provided on the life cycle of Aporrectodea caliginosa. We showed that the maintenance costs were negligible during the growth period. The energy of adult individuals was entirely allocated to cocoon production. An energy-based model was calibrated for different feeding conditions.
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