Current issues in ecotoxicology research Luděk Bláha (blaha@sci.muni.cz) RECETOX PřF MU PHARMACEUTICALS Example 1 - DICLOFENAC Unexpected effects at NON-TARGET species - nephrotoxicity at vultures - Relevant also in EU (ESP, EL,CY) Example 2 – AVERMECTIN-like antiparasitics Ivermectin – antiparasitics in large herds  Used 2-times per season per sheep/cow  Kills 100% parasites in sheep  Released in dung - kills 80-90% larvae of dung flies  High concentrations in dung (released 2 days post application)  Persistent in the soil (half-life 30 days)  Can be washed into adjacent streams (highly toxic to water insects) Moxidectin – used e.g. in home „spot on” products ? MIXTURE EFFECTS … VERY LOW CONCENTRATIONS Main questions: Are current limits (for individual compounds) safe? Relevance of “Something from Nothing” phenomenon ? 3 samples  12 European laboratories – different bioassays  ČR – RECETOX: 11 bioassays Carvalho, R. et al. (2014) Mixtures of chemical pollutants at European legislation safety concentrations: how safe are they? Toxicol Sci 141(1): 218-233 International ring test (2012-13) Testing comparability of existing and innovative bioassays for water quality assessment EU WFD priority substances Different concentrations EQS = limit (Environmental Quality Standard) MIXTURE EFFECTS … VERY LOW CONCENTRATIONS Example: Effects of mixtures on D. rerio fish embryos Control Effects of RM 3 (i.e. safe) mixtures Carvalho, R. et al. (2014) Mixtures of chemical pollutants at European legislation safety concentrations: how safe are they? Toxicol Sci 141(1): 218-233 MIXTURE EFFECTS … VERY LOW CONCENTRATIONS Example: Effects of mixtures on X. laevis frog embryos Controls Effects of RM 3 (i.e. safe) mixtures Carvalho, R. et al. (2014) Mixtures of chemical pollutants at European legislation safety concentrations: how safe are they? Toxicol Sci 141(1): 218-233 MIXTURE EFFECTS … VERY LOW CONCENTRATIONS Biotest A B C Microtox 26and 36% stimulation of luminescence in 15and 30mins of exposure, respectively 18and 35% stimulation of luminescence in 15and 30mins of exposure, respectively 22and 39% stimulation of luminescence in 15and 30mins of exposure, respectively Algae growth inhibition test 96-h exposure 31% inhibition of growth compared to solvent control 20% inhibition of growth compared to solvent control 16% inhibition of growth compared to solvent control Acute immobilization test with D. magna 90% immobilization after 48hours of exposure; 25% immobilization occurred in 50% concentration - not statistically significant no effect observed no effect observed Reproduction test with D. magna (21-d exposure) 100% mortality after 3days of the test, no reproduction could be evaluated 31+/- 37% inhibition of reproduction, not statistically significant 23+/- 24% inhibition of reproduction, not statistically significant FETAX (96-h exposure) 62+/- 10% of malformed embryos; no effect on embryo length observed 43+/- 12% of malformed embryos; no effect on embryo length observed 34+/- 14% of malformed embryos; no effect on embryo length observed FET (120-h exposure) effects observed in number of defected embryos - absence of gas bladder, (head) deformities and underdeveloped embryos were observed the most often. no significant effects observed effects observed in number of defected embryos, number of underdeveloped embryos and length In vitro - cytotoxicity no effect observed compared to solvent control no effect observed compared to solvent control no effect observed compared to solvent control In vitro - estrogenicity effect under LOQ effect under LOQ effect under LOQ In vitro - dioxin-like toxicity effect under LOQ effect under LOQ effect under LOQ In vitro - androgenicity effect under LOQ effect under LOQ effect under LOQ In vitro - antiandrogenicity effect under LOQ effect under LOQ effect under LOQ Kde „tradiční“ ekotoxikologie nestačí Nano-eco-toxicology Nanoparticles - examples Ecotoxicity of nanoparticles … (Mostly unknown) Parameters may Affect ecotoxicity Composition (chemical) Surface (size, area) Charge Reactivity Interactions with ions, other chemicals…  Effects on environmental Fate and toxicity Ecotoxicity of nanoparticles – RECETOX example Comparison of toxicity - 4 „appeared to be the same“ particles (one producer – 4 different lots) (zerovalent iron – ZVI – Fe0) ?? Why is H16 so toxic ?? Mechanistic and Computational (ECO)TOXICOLOGY OrganismChemical Adverse Effects Death Altered Reproduction Inhibition of Growth Tumorigenicity Skin irritation … + Traditionally – Evaluation of adverse effects using the whole organism models Hazard assessment REGULATORY FOCUS (APICAL ENDPOINTS) Newly added aspects What are the mechanisms (MoA – mode of action)? Can mechanisms serve for predictions? Extrémní rozvoj analytických technologií  „OMICS“ A další „ómy“ • Lipidóm • Mikrobiom … Sběr omics podporují strategické dokumenty & projekty Toxicity Testing in the 21st Century: A Vision and a Strategy US National Academies of Sciences http://www.nap.edu/catalog/11970.html OrganismChemical Adverse Effects (EC50) Death Inhibition of Growth Altered Reproduction Tumor Skin irritation … + Traditionally – Evaluation of adverse effects using the whole organism models +10^4 Chemicals HTS Chemical-biological interactions, Mechanistic Toxicological Data Hazard assessment New – Ex vivo / in vitro / In chemico / In silico Methods Key task/question: How to link MECHANISTIC INFORMATION with APICAL ENDPOINTS ? Kvantitativní mechanistické modelování PLoS Comput Biol. 2016 Apr 20;12(4):e1004874. Fig 1. The HPOL signaling network in rainbow trout as formulated in our model. Arrows and symbols on graph follow CellDesigner vs. 4.4 notation (www.celldesigner.org). GnRH is secreted from the hypothalamus into the pituitary stimulating the production of mFSH and mLH, which then leads to formation of FSH and LH, respectively. FSH, which is being continuously secreted from the pituitary, travels to the ovaries to stimulate production of E2. E2 then travels to the liver to bind with E2 receptors (R; translated from mR) to form ER. ER then stimulates the production of mVTG, which produces VTGL. Secreted VTG then travels from the liver to the ovaries via the plasma (VTGP) where it is absorbed by follicles in stages 3 through 6 (the proportion of follicles in these stages are denoted by Sj, j = 3, 4, 5, and 6) during vitellogenesis, the rate of which is affected by FSHP, to promote oocyte growth (OAvg). Oocyte growth then progresses the oocytes through the stages using a Weibull distribution created from OAvg together with OVar. In the later stages LHP stimulates the oocytes to produce DHP. Finally, oocytes undergo final maturation (SFOM) and combined with DHP, determine when the fish ovulates PLoS Comput Biol. 2016 Apr 20;12(4):e1004874. Kvantitativní mechanistické modelování Fig 3. HPOL model predictions for (A) pituitary levels of FSHβ subunit mRNA, (B) pituitary levels of LHβ subunit mRNA, (C) Hepatic levels of E2 receptor mRNA and (D) Hepatic levels of VTG mRNA Observed data (dark grey circles; mean ±TG mRn = 3) PLoS Comput Biol. 2016 Apr 20;12(4):e1004874. Kvantitativní mechanistické modelování