Ecotoxicological bioassays Klara Hilscherova, Ludek Blaha, Jakub Hofman & co. CHEMICAL ENTERS THE ENVIRONMENT Bioavailable fraction EXPOSURE acute chronic Toxikokinetics biotransformation bioactivation excretion / sequestration Target site EFFECT LEVELS, FATE, PROCESSES CHEMICAL ENTERS THE ORGANISM biomonitoring System of organs Organ Tissue Cell Organell Biomolecule Individual Population Community Ecosystem Biosphere Flexibility Ability to determine cause Specifity Sensitivity Ecological relevance Response duration Longer-term effects HIGHHIGH HIGHHIGH LOWLOW LOWLOW Effect of Chemicals Biotest Bioassay is a process where a test system (tissue,organism, population) is exposed under defined conditions to different known concentrations of tested compound or sample. In vivo effects? Ecotoxicity Tests Provide a direct measure of biological uptake of the toxicants Establish link between site contamination and adverse ecological effects May provide info on synergistic or antagonistic interactions among chemicals Direct extrapolation of lab to field should be carefully evaluated May do an in situ toxicity test under field conditions Bioassays - single / multiple species - acute / chronic effects - standardized (practical) vs. experimental (research) Simulation of the ecosystem - major trophic levels included - producers - consumers - destruents Microcosm & Mesocosm Studies Ecotoxicity Tests Toxicity tests can be used for both aquatic and terrestrial systems Aquatic tests are more developed Endpoints are mortality, growth and/or reproduction Vertebrates Rodents Fish Birds Invertebrates Insects Amphipods (crustacea related to shrimp and krill) Plankton Microbes Luminescent bacteria (Microtox) Plants Aquatic or terrestrial Vascular or non-vascular 1 Standardized methods Organizations associated with biotests and standardized guidelines OECD = Organization for Economic Cooperation Development ISO = International Standardization Organization US EPA = US Environmental Protection Agency SETAC = Society for Environmental Toxicology and Chemistry IOBC = International Organisation for Biological and Integrated Control of Noxious Animals and Plants EPPO = European and Mediterranean Plant Protection Organization ASTM = American Society of Testing and Materials ANSI = American National Standards Institute CEN = European Commitee for Standardization AFNOR = Association Francaise de Normalisation EEC = European Economic Community WHO = World Health Organisation BBA = Biologische Bundesanstalt für Land- und Forstwirtschaft OPPTS = The Office of Prevention, Pesticides and Toxic Substances (EPA) DIN = German Deutsches Institut für Normung OECD guidelines for the Testing of Chemicals Section 2: Effects on Biotic Systems http://www.oecd.org/document/40/0,3746,en_2649_34377_37051368_1_1_1_1,00.html 1 Test No. 201: Alga, Growth Inhibition Test 11 July 2006 Test No. 221: Lemna sp. Growth Inhabition Test 11 July 2006 Test No. 202: Daphnia sp. Acute Immobilisation Test 23 Nov 2004 Test No. 211: Daphnia magna Reproduction Test 16 Oct 2008 Test No. 203: Fish, Acute Toxicity Test 17 July 1992 Test No. 204: Fish, Prolonged Toxicity Test: 14-Day Study 04 Apr 1984 Test No. 210: Fish, Early-Life Stage Toxicity Test 17 July 1992 Test No. 212: Fish, Short-term Toxicity Test on Embryo and Sac-Fry Stages 21 Sep 1998 Test No. 215: Fish, Juvenile Growth Test 21 Jan 2000 Test No. 229: Fish Short Term Reproduction Assay 08 Sep 2009 Test No. 230: 21-day Fish Assay 08 Sep 2009 Test No. 231: Amphibian Metamorphosis Assay 08 Sep 2009 Aquatic organisms Test No. 218: Sediment-Water Chironomid Toxicity Using Spiked Sediment 23 Nov 2004 Test No. 219: Sediment-Water Chironomid Toxicity Using Spiked Water 23 Nov 2004 Test No. 233: Sediment-Water Chironomid Life-Cycle Toxicity Test Using Spiked Water or Spiked Sediment 23 July 2010 Test No. 225: Sediment-Water Lumbriculus Toxicity Test Using Spiked Sediment 15 Oct 2007 Tests with sediment OECD guidelines 1 Soil organisms Test No. 208: Terrestrial Plant Test: Seedling Emergence and Seedling Growth Test 17 Aug 2006 Test No. 227: Terrestrial Plant Test: Vegetative Vigour Test 17 Aug 2006 Test No. 207: Earthworm, Acute Toxicity Tests 04 Apr 1984 Test No. 220: Enchytraeid Reproduction Test 23 Nov 2004 Test No. 222: Earthworm Reproduction Test (Eisenia fetida/Eisenia andrei) 23 Nov 2004 Test No. 228: Determination of Developmental Toxicity of a Test Chemical to Dipteran Dung Flies(Scathophaga stercoraria L. (Scathophagidae), Musca autumnalis De Geer (Muscidae)) 16 Oct 2008 Test No. 232: Collembolan Reproduction Test in Soil 08 Sep 2009 Test No. 226: Predatory mite (Hypoaspis (Geolaelaps) aculeifer) reproduction test in soil 16 Oct 2008 Test No. 216: Soil Microorganisms: Nitrogen Transformation Test 21 Jan 2000 Test No. 217: Soil Microorganisms: Carbon Transformation Test 21 Jan 2000 Test No. 213: Honeybees, Acute Oral Toxicity Test 21 Sep 1998 Test No. 214: Honeybees, Acute Contact Toxicity Test 21 Sep 1998 Test No. 205: Avian Dietary Toxicity Test 04 Apr 1984 Test No. 206: Avian Reproduction Test 04 Apr 1984 Test No. 223: Avian Acute Oral Toxicity Test 23 July 2010 Other tests ISO guidelines Aquatic microorganisms ISO 10712:1995 Water quality -- Pseudomonas putida growth inhibition test (Pseudomonas cell multiplication inhibition test) ISO 11348-1:2007 Water quality -- Determination of the inhibitory effect of water samples on the light emission of Vibrio fischeri (Luminescent bacteria test) -- Part 1: Method using freshly prepared bacteria ISO 11348-2:2007 Water quality -- Determination of the inhibitory effect of water samples on the light emission of Vibrio fischeri (Luminescent bacteria test) -- Part 2: Method using liquid-dried bacteria ISO 11348-3:2007 Water quality -- Determination of the inhibitory effect of water samples on the light emission of Vibrio fischeri (Luminescent bacteria test) -- Part 3: Method using freeze-dried bacteria ISO 13641-1:2003 Water quality -- Determination of inhibition of gas production of anaerobic bacteria -- Part 1: General test ISO 13641-2:2003 Water quality -- Determination of inhibition of gas production of anaerobic bacteria -- Part 2: Test for low biomass concentrations ISO 13829:2000 Water quality -- Determination of the genotoxicity of water and waste water using the umu-test ISO 16240:2005 Water quality -- Determination of the genotoxicity of water and waste water -- Salmonella/microsome test (Ames test) ISO/DIS 11350 Water quality -- Determination of the genotoxicity of water and waste water -- Salmonella/microsome fluctuation test (Ames fluctuation test) ISO 15522:1999 Water quality -- Determination of the inhibitory effect of water constituents on the growth of activated sludge microorganisms ISO 21338:2010 Water quality -- Kinetic determination of the inhibitory effects of sediment, other solids and coloured samples on the light emission of Vibrio fischeri (kinetic luminescent bacteria test) ISO 8192:2007 Water quality -- Test for inhibition of oxygen consumption by activated sludge for carbonaceous and ammonium oxidation ISO 9509:2006 Water quality -- Toxicity test for assessing the inhibition of nitrification of activated sludge microorganisms ISO guidelines Aquatic plants ISO 20079:2005 Water quality -- Determination of the toxic effect of water constituents and waste water on duckweed (Lemna minor) -- Duckweed growth inhibition test ISO 8692:2004 Water quality -- Freshwater algal growth inhibition test with unicellular green algae ISO/CD 16191 Water quality - Determination of the toxic effect of sediment and soil on the growth behaviour of Myriophyllum aquaticum - Myriophyllum test ISO 10253:2006 Water quality -- Marine algal growth inhibition test with Skeletonema costatum and Phaeodactylum tricornutum ISO 10710:2010 Water quality -- Growth inhibition test with the marine and brackish water macroalga Ceramium tenuicorne ISO 14442:2006 Water quality -- Guidelines for algal growth inhibition tests with poorly soluble materials, volatile compounds, metals and waste water ISO/DIS 13308 Water quality -- Toxicity test based on reproduction inhibition of the green macroalga Ulva pertusa ISO/TR 11044:2008 Water quality -- Scientific and technical aspects of batch algae growth inhibition tests ISO guidelines Aquatic invertebrates ISO 6341:1996 Water quality -- Determination of the inhibition of the mobility of Daphnia magna Straus (Cladocera, Crustacea) -- Acute toxicity test ISO 10706:2000 Water quality -- Determination of long term toxicity of substances to Daphnia magna Straus (Cladocera, Crustacea) ISO/DIS 14380 Water quality -- Determination of the acute toxicity to Thamnocephalus platyurus (Crustacea, Anostraca) ISO/CD 16303 Water quality -- Determination of toxicity of fresh water sediments using Hyalella azteca ISO 10872:2010 Water quality -- Determination of the toxic effect of sediment and soil samples on growth, fertility and reproduction of Caenorhabditis elegans (Nematoda) ISO 16712:2005 Water quality -- Determination of acute toxicity of marine or estuarine sediment to amphipods ISO 20665:2008 Water quality -- Determination of chronic toxicity to Ceriodaphnia dubia ISO 20666:2008 Water quality -- Determination of the chronic toxicity to Brachionus calyciflorus in 48 h ISO 14669:1999 Water quality -- Determination of acute lethal toxicity to marine copepods (Copepoda, Crustacea) ISO/DIS 14371 Water quality -- Determination of freshwater-sediment subchronic toxicity to Heterocypris incongruens (Crustacea, Ostracoda) ISO 7828:1985 Water quality -- Methods of biological sampling -- Guidance on handnet sampling of aquatic benthic macro- invertebrates ISO 8265:1988 Water quality -- Design and use of quantitative samplers for benthic macro-invertebrates on stony substrata in shallow freshwaters ISO 8689-1:2000 Water quality -- Biological classification of rivers -- Part 1: Guidance on the interpretation of biological quality data from surveys of benthic macroinvertebrates ISO 8689-2:2000 Water quality -- Biological classification of rivers -- Part 2: Guidance on the presentation of biological quality data from surveys of benthic macroinvertebrates ISO/DIS 10870 Water quality -- Guidelines for the selection of sampling methods and devices for benthic macroinvertebrates in fresh waters ISO/WD 16778 Water quality -- Calanoid copepod development test with Acartia tonsa ISO guidelines Aquatic vertebrates ISO 15088:2007 Water quality -- Determination of the acute toxicity of waste water to zebrafish eggs (Danio rerio) ISO 7346-1:1996 Water quality -- Determination of the acute lethal toxicity of substances to a freshwater fish [Brachydanio rerio Hamilton-Buchanan (Teleostei, Cyprinidae)] -- Part 1: Static method ISO 7346-2:1996 Water quality -- Determination of the acute lethal toxicity of substances to a freshwater fish [Brachydanio rerio Hamilton-Buchanan (Teleostei, Cyprinidae)] -- Part 2: Semi-static method ISO 7346-3:1996 Water quality -- Determination of the acute lethal toxicity of substances to a freshwater fish [Brachydanio rerio Hamilton-Buchanan (Teleostei, Cyprinidae)] -- Part 3: Flow-through method ISO 10229:1994 Water quality -- Determination of the prolonged toxicity of substances to freshwater fish -- Method for evaluating the effects of substances on the growth rate of rainbow trout (Oncorhynchus mykiss Walbaum (Teleostei, Salmonidae)) ISO 12890:1999 Water quality -- Determination of toxicity to embryos and larvae of freshwater fish -- Semi-static method ISO 21427-1:2006 Water quality -- Evaluation of genotoxicity by measurement of the induction of micronuclei -- Part 1: Evaluation of genotoxicity using amphibian larvae ISO 21427-2:2006 Water quality -- Evaluation of genotoxicity by measurement of the induction of micronuclei -- Part 2: Mixed population method using the cell line V79 ISO 23893-1:2007 Water quality -- Biochemical and physiological measurements on fish -- Part 1: Sampling of fish, handling and preservation of samples ISO/TS 23893-2:2007 Water quality -- Biochemical and physiological measurements on fish -- Part 2: Determination of ethoxyresorufin-O-deethylase (EROD) ISO/CD 23893-3 Water quality -- Biochemical and physiological measurements on fish -- Part 3: Determination of vitellogenin Application of bioassays in ecotoxicology Testing chemicals Traditional approach - bioassays developed to assess chemicals Standardized and validated approaches OECD Guideline methods - series 2 Effects on biota ISO methods E.g. Fish tests - OECD 203 / ISO 7346 E.g. D. magna - OECD 202 / ISO 6341 Other standard guidelines Limited ecological relevance often acute tests only, too standardized does not assess bioavailability, no consideration of mixtures no consideration of specific modes of action Testing toxicity of environmental matrices Relatively new in ecotoxicology many open challenges More complex and more complicated cause-effects often not clear (many confounding factors ) Testing strategy Battery of assays Fast screening tests (inhibition of Vibrio fisheri bioluminiscence, MICROTOX 30 min toxicity) Standardized acute toxicity tests Further studies with chronic assays Various purposes -> guidelines and recommendations REACH (EU - Registration, Evaluation and Authorisation of Chemicals) Plant protection products + biocides Veterinary and human pharmaceuticals Waste materials The most common set up for aquatic environment algae / D. magna / fish Basic principles of bioassays Reproducibility Standard design Possibility of data extrapolation on field conditions Cost and time feasibility Tested matrix Water Soil Air Sediment Waste Chemical compound Sample type Single compounds (hydrophobic, hydrophilic, volatile) Mixture of compounds (known and/or unknown) Environmental samples (usually unknown, mixtures of different compounds with different properties complicated interpretation) Used to develop Water Quality Criteria (WQC) for different uses Endpoints Lethal effects (mortality) sub lethal effects (immobilisation) Physiological activity (photosynthetic activity, enzymatic activity, biomass increase, resistance to diseases, pests and/or parasites) Reproductive activity, malformations Mutagenicity/genotoxicity (microbial, vascular plants, wildlife animals) Teratogenity (amphibian- Xenopus laevis) Embryotoxicity Reproduction bioassays Growth Factors influencing results of bioassays For reproducibility of results these main factors have to be standardized: Exposure duration Temperature Light:dark period Volume Oxygen content Composition of cultivation media Age of organism Parameters of the biological system Complexity / in vitro, in vivo, population, microcosm Population characteristics sex, age Aquatic vs. Terrestrial (soil) Exposure duration & effects Acute (often mortality), sub-acute, chronic (other endpoints) (4 days - algae / 4 generations, fish / acute toxicity) Exposure setup Static / with exchange of media / flow-through Depends on the compound stability (should be measured!) Bioassay endpoints Lethality, immobilization (Daphnia), growth, reproduction Abiotic factors in the experiment Validity criteria (pH, oxygen, temperature, humidity, water hardness ) Biotests to be considered 1) Prepare the organism § Culture media, standardized numbers, age, etc. 2) Prepare the sample § Dilution series § water/culture media direct organism exposure § Include BLANK (medium only) § solvent for organic compounds minimum to be added (1% vol) § Include SOLVENT CONTROL 3) Expose organisms § for appropriate time, number of repetitions, under specified conditions 4) Evaluate and report results § measure the endpoint / count organisms § statistical evaluation (means, ANOVA, dose-response ) Steps to conduct the biotest 1) Prepare organism 2) Prepare sample 3) Expose 4) Evaluate 50 100 LC50 [concentration] in mg/L or % effluent Parameters: No Observed Effect Concentration (NOEC) Dose-response curve Lowest Observed Effect Concentration (LOEC) ECx ( x % effects concentration) LCx ( x % lethal concentration) Laboratory ecotoxicology data and results Acute Aquatic Toxicity Tests Most frequently used (short = less expensive) Relates dose (Cw x time of exposure) to time of death for a particular test organism Produce concentration/response curve Ranges from 1 to 4 days for aquatic tests and up to 10 days for assessment of sediment toxicity Done in laboratory under controlled conditions Acute Aquatic Toxicity Tests n Growth inhibition assays with algae and macrophyta (72 h) (Scenedesmus quadricauda, Raphidocelis subcapitata, Selenastrum capricornutum, Lemna minor) n ISO 8692/2004 Water quality -- Freshwater algal growth inhibition test with unicellular green algae n OECD 201 Alga, Growth Inhibition Test n microplate miniaturization n Germination tests and root elongation with higher plants testing toxicity in the aquatic media (Lepidium sativum, Sinapis alba, Lactuca sativa) n OECD 208 Terrestrial Plant Test: Seedling Emergence and Seedling Growth Test AQUATIC BIOTESTS with PRODUCERS AQUATIC ASSAYS § Daphnia magna immobilisation (24 48h) ISO 6341/1996 Water quality - Determination of the inhibition of the mobility of Daphnia magna Straus (Cladocera, Crustacea) - Acute toxicity test OECD 202 Daphnia sp. Acute Immobilisation Test § crustacea Ceriodaphnia dubia § rotifer Brachionus calyciflorus §ToxKit assays §Thamnotoxkit (Thamnocephalus platyurus) §Artoxkit Artemia salina BIOTESTS with CONSUMERS - invertebrates BIOTESTS with CONSUMERS fish (acute 96h) Guppy, Poecilia reticulata Zebrafih, Danio rerio (syn. Brachydanio rerio) Carassius (Goldfish) Fathead minnow, Pimephales promelas (USA) (Rainbow) trout (Onchorhynchus sp.) Medaka, Oryzias latipes Nile tilapia, Oreochromis niloticus OECD 203 Fish, Acute Toxicity Test ISO 7346 Water quality - Determination of the acute lethal toxicity of substances to a freshwater fish Static/semi-static/flow through method prolonged tests embryolarval tests chronic tests reproduction, growth Specific endpoints genotoxicity, endocrine disruption BIOTESTS with CONSUMERS - amphibians FETAX Frog Embryo Teratogenicity Assay Xenopus (ASTM E1439-98 ) African clawed frog (Xenopus laevis) 96 h / egg and embryo exposure §Toxicity to luminescent bacteria Vibrio fisheri (MICROTOX®) §ISO 11348 Water quality - Determination of the inhibitory effect of water samples on the light emission of Vibrio fischeri § Growth inhibitions (Pseudomonas putida, Toxi-Chromotest, Toxi-ChromoPad) § Toxicity assays with SOIL BACTERIA BIOTESTS with DESTRUENTS - microorganisms Microtox EN ISO 11348-(1) - based on inhibition of bioluminiscence of marine bacteria Vibrio fischeri Chronic Aquatic Toxicity Tests Longer tests: 7 - 30 days Objective is to expose for at least 1/10th of lifetime Effect of different Cw on growth, reproduction, behavioral, physiological or other biological function Sub-chronic: only exposed during part of lifecycle (usually early stages) Life-cycle tests have been done for only a few contaminants Chronic Aquatic Toxicity Tests Chronic Aquatic Toxicity Tests Aquatic Toxicity Tests Sediment ecotoxicity tests n Toxicity of pore water/eluates (several ISO / OECD standards) : 100 g d.w./L water, 24h slow shake, filter, test V. fisheri (30 min), Algae, Invertebrates - D. magna (2 days) ? Aquatic eluate vs. Sediment n Recommended at least 2 different species (e.g., Hyalella, Chironomus, Daphnia, etc) and two different endpoints (e.g., growth, survival, reproduction, etc.) n Direct (contact) toxicity (only few standards ) : sediment+organisms & evaluate effects - worms, snails days-weeks Toxicity Test Species Freshwater Sediments Amphipods Hyalella azteca Midges Chironomus tentans Chironomus riparius Oligochaetes Tubifex tubifex Mayfly Hexagenia limbata Sediment toxicity Acute tests Pore water Sediment eluates 48-96 h exposure Preparation of eluates: 24h shaking, 100 g sediment/1L water Species: Daphnia magna, Daphnia pulex, Ceriodaphnia dubia, fathead minnow (Pimephales Promelas), rainbow trout (Oncorhynchus mykiss) Endpoints: survival, immobilization Contact tests - whole sediment 96h 10 day exposure Species: amphipod (Hyalella azteca), mayfly (Hexagenia limbata), chironomids (C.tentants/riparius) 10-day test with Hyalella azteca and Chironomus tentans Endpoint: survival Sediment toxicity Chronic tests Pore water Eluate from sediment 7-35 day exposure Species: Ceriodaphnia dubia, fathead minnow (Pimephales Promelas), rainbow trout (Oncorhynchus mykiss) Endpoints: survival, immobilization, growth, reproduction, time to the first reproduction, time of death, offspring survival Contact tests - whole sediment about 28 days exposure Species: Hyalella azteca, Chironomids (C.tentants/riparius) Endpoints: survival, immobilization, growth, reproduction, time to the first reproduction, time of death, offspring survival 28- and 42-day tests with H. azteca Sub-chronic and lifecycle tests with Chironomus tentans 10-day short term chronic test with amphibian larvae Tests for sediment toxicity - EPA www.epa.gov Tests for sediment toxicity - EPA www.epa.gov Tests for sediment toxicity - ASTM Sediment Toxicity - ASTM Sediment Toxicity Test confounding factors Potential Non-Contaminant Factors Sediment grain size Content and type of clay Organic carbon content and character Humic substances/organic matter structure and properties pH Oxygen content Ammonia / Sulfide toxicity Nutrition Changing sediment toxicity due to sampling and experimental procedures Mixing of more contaminated sediments with the thin layer at the sediment-water interface Oxidation and precipitation of redox metals from the reaeration required for the sediment toxicity testing Microbioassay Saving of ØTime ØSpace ØWork ØChemicals 1. Batching 2. Inoculation 3. Exposure http://www.microbiotests.be/ Solid samples Water samples ToxichromoToxichromo--test ®test ® http://www.ebpi-kits.com/ ToxichromoToxichromo--Pad ®Pad ® MICROBIOTESTS Tests for specific in vivo effects embryotoxicity teratogenesis developmental disorders endocrine disruption reproductive disorders Aquatic tests or contact tests with sedimentdwelling invertebrates, amphipods, molluscs, fish, amphibian and mollusc eggs - Specific sublethal endpoints, histology In situ tests Caging bivalves, fish, molluscs Health status and specific biomarkers assessment in species collected on site Sublethal biomarkers, histology Test subject: water Test subject: sediment Determination of macrozoobenthos saprobic index functional feeding groups life form index evenness & diversity Bioassays toxicity, cytotoxicity endocrine disrupting potential genotoxicity, mutagenicity Chemical analyses organical analyses limnochemical parameters heavy metals Ecosystem native & concentrated surface water whole sediment, sediment pore water, elutriate and organic - extracts ... in vitro and in vivo bioassays Integrated assessment of aquatic ecosystems Terrestrial Toxicity Tests Direct exposure of test biota to media samples from a site Indirect exposure to filtered water exposed to soil or sediments samples Exposure to leachates from a site Controlled exposure to a specific contaminant using soil from the site Test biota soil microbes and fungi - critical role in C, N, S, P cycling, plus production of SOM and other organics invertebrates (earthworms and insects): provide essential ecosystem functions These tests are fast, simple and relatively inexpensive, with relevant results to evaluate effects on ecosystem biogeochemical functions Terrestrial Toxicity Tests Vertebrates: amphibian: survival, growth and reproductive success avian and small mammal: reproductive success and body burden Feeding studies (small mammal and avian toxicity tests) are useful to determine potential uptake and transfer within the food web - potential human exposure route Standard protocols have been derived from veterinary studies and FDA methods, but many are still under development Longer than invertebrate tests Earthworms: Eisenia fetida/andrei (OECD 222, 2000) Enchytraeids: Enchytraeus albidus, E.crypticus (OECD 220, 2000) Collembolans: Folsomia candida, F.fimetaria (ISO 11267, 1999) ØTest substrates: OECD artifical soil, real soils Ø10 adults (synchronized) in test vessel ØTest duration: 28 days 56 days ØEndpoints: survival, reproduction number of juveniles, weight changes ØPreliminary test => Final test Eisenia fetida Folsomia candida Enchytraeus crypticus Terrestrial bioassays - exposure in soil Terrestrial Toxicity Tests Vegetation mostly crops primary endpoints are: survival: seed germination test growth: seedling growth rate and root elongation test reproduction success: vascular plant toxicity photosynthesis rates: chlorophyll fluorescence assay can be applied in lab or in the field nutrient, water and light limitations can complicate analysis of results longer term studies Battery of bioassays Different Trophic level Sensitivity Target effect/organ Specific toxic effect (mutagenity, neurotoxicity, etc ) The negative response in test with one species does not mean that substance is not toxic. Toxicity can be observed after longer exposure and/or in different species. Simple battery: algae, zooplankton, fish, bacteria. Battery of bioassays Standard acute toxicity tests representing different ecology groups different levels of food chain microorganism, algae, invertebrates, fish Different guidelines: Vibrio fisheri, Thamnocephalus, Daphnia, Scenedesmus USEPA crustacean Ceriodaphnia dubia, algae Selenastrum capricornutum, fish Pimephales promelas Chronic toxicity crustaceans Daphnia magna, Ceriodaphnia dubia Specific endpoints: survival, reproduction, growth, activity, heartbeat, respiration, biochemical markers Micro and Mesocosm Controlled experiments in lab or field to study changes at any level: population community ecosystem Microcosm are small studies, usually in lab Mesocosm are large, containing many species, usually outdoors Advantages of microcosm studies: Better than single-species studies More space efficient Easier to maintain controlled conditions Replication and standardization easier Low chance of contaminating the environment Issues with Microcosm: Can t simulate certain processes (e.g. acid deposition from environment) small population sizes => extinctions? Extrapolation of results May leave out a critical and/or sensitive component of ecosystem endocrine disruption (compounds interfere with hormonal regulation in organism), (anti)estrogenicity ... reproductive failure, teratogenicity neurotoxicity immunosuppressions carcinogenicity (mutagenicity / tumor promotion) Chronic effects How to study chronic toxicity ? Chronic toxicity is difficult to study and predict time and cost consuming experiments limited number of species (laboratory vs. natural species) effect = combination of chemical exposure and life style, habits ... metabolites or derivatives (not parent compounds) are often the active substances Cl Cl Cl Cl Cl Cl Cl Cl Cl OH Cl Ecotoxicological bioassays for chronic endpoints In vitro studies (biochemical mechanisms) + easy to perform, short-term - ecotoxicological relevancy + highly controlled conditions - mostly with vertebrate cells + lower amounts of chemicals needed (new compounds screening) In vivo biotest testing + unique whole organisms - only few (ecologically + controlled conditions nonrelevant) organisms used + better ecological interpretation - mostly ACUTE assays - chronic: long exposures Field and in situ observations, epidemiological studies How to study (chronic) toxicity ? MECHANISMS of toxicity Various chronic effects have uniform biochemical basis principal studies with mechanistically based in vitro techniques estimation of in vitro effects of individual compounds understanding the mechanisms, prediction of hazard application for risk assessment or monitoring derivation of relative potencies ("toxic equivalents") HORMONE Biochemical effects TOXIN In vivo effectsRECEPTOR Estrogen receptor activation 1) female reproduction disorders 2) male feminisation 3) tumor promotion 4) immunomodulations 5) developmental toxicity SINGLE mechanism -> SEVERAL effects => understanding to mechanisms may predict effects Effects in vitro ? In vitro models Original or genetically modified prokaryotic or eukaryotic cells BACTERIAL, YEAST TESTSBACTERIAL, YEAST TESTS TESTS ON TISSUE CULTURETESTS ON TISSUE CULTURE CELL LINESCELL LINES In vitro bioassays Principle Mechanism of action based Mechanism related to toxic effects Ø Using biological system as if it was an instrumental detector and/or integrator Screening tests Toxicity: Bacterial models Vibrio fisheri (Microtox) 0.5 h Escherichia coli (Toxichromotest) 2 h Fish/mammalian cell lines Genotoxicity : SOS chromotest, umuC test Comet assay GFP test etc. Contact test Flash test with Vibrio Fisheri kinetic test Toxicity/genotoxicityToxicity/genotoxicity Yeast models Fish/mammalian cell lines Tests for presence of compounds with hormone-like effects : Anti/estrogenicity Anti/androgenicity Retinoid-like activity Dioxin-like potency Specific mode of actionSpecific mode of action In vitro assays for genotoxic effects GENOTOXICITY = toxic modification or alteration of the structure or function of genetic material Bacterial or yeast assays with reporter genes Eukaryotic cells GreenScreen® test for genotoxicity Experimental Design NUCLEAR RECEPTOR MEDIATED EFFECTS important mechanisms involved in chronic toxicity Dioxin-like activity: Aryl hydrocarbon receptor (AhR)-mediated effects PCDDs/Fs, PAHs, PCBs Xenoestrogenity / Antiestrogenity: Estrogen receptor (ER)mediated effects PCDDs/Fs, PAHs, PCBs, OH-PCBs, alkylphenols, natural and synthetic hormones ... Xenoandrogenity / Antiandrogenity: androgen receptor (AR) mediated effects pesticides Interactions with retinoic acid receptor (RAR) Receptor-mediated effects luciferase reporter assays LightLight Luciferase Nuclear Factors 1 P + AhR HSP90 HSP90 Src HSP90 HSP90 DRE-Luc AhR ARNT Modulation of Gene Expression ARNT Src Activated 2 P P Cytosolic Proteins Membrane Proteins Increased Protein Phosphorylation Ligand (TCDD) LightLight Luciferase Nuclear Factors 1 P + AhR HSP90 HSP90 SrcSrc HSP90 HSP90 DRE-Luc AhR ARNT Modulation of Gene Expression ARNT Src Activated 2 P P Cytosolic Proteins Membrane Proteins Increased Protein Phosphorylation Dioxins Estrogens Androgens Retinoids Nuclear receptors (AhR, ER, AR, RAR/RXR) play an important role in toxic effects of many pollutants DIOXIN-like toxicity Anti / estro-, Anti / andro- -genicity Common mechanism - transcription factors: development of mechanistically based bioassays In vitro luciferase reporter bioassays studies of individual chemicals (toxicity identification, IEF calculation) complex environmental samples (estimation of toxic potential) NUCLEAR RECEPTORS IN TOXICITY BIOMARKERs Sublethal effects, studied in organisms from biotests or sampled in the environment Early warning signals of potential damage in organism and/or the whole population, early marker of toxicity (prior to any morphological alterations) Changes in cellular or biochemical components, structures or functions caused by xenobiotics Sensitive, fast responses, can show the mechanism of effect, precede any visible toxicity symptoms Most studied in vertebrates Possible to study also in plants and invertebrates from standard biotests (algae, macrophytes, invertebrates) Biotransformation enzymes (phase I&II) Induction of detoxification enzymes in plants and animals A. Enzymes of the 1st phase of biotransformation MFO enzymes (mixed function monooxygenases) induction of P450 cytochrome enzymes (EROD, MROD, PROD) B. Enzymes of the 2nd phase of biotransformation glutathione transferases (GST), uridinedifosfoglukuronosyl transferases, sulphotransferases Oxidative stress parameters Production of reactive oxygen species Activity of antioxidant enzymes glutathion peroxidase, glutathion reductase, superoxidase, catalase Concentration of nonenzymatic antioxidants Oxidative damage to macromolecules lipid peroxidation, oxidative DNA aducts, products of protein oxidation Protective proteins Stress proteins: heat shock proteins (HSP), glucoseregulated proteins (GRP) Metallothioneins (MT): metal binding Multi Xenobiotic Resistance (MXR): excretion of xenobiotics; induction or inhibition by chemisensitizers Hematological parameters Serum transaminases: Alanine transaminase (ALT), aspartate transaminase (AST); membrane disruption or organ damage Blood values: haematocrit, haemoglobin, blood sugars (glucose), plasma lipids and proteins (albumin) Immunological parameters White blood cell count Lymphocyte status Morphology of spleen, thymus and kidney Macrophage function Susceptibility to bacterial infections Reproductive & endocrine parameters Biochemical: Fish vitellogenin (VTG), Zona radiata Protein (ZRP), Cytochrome aromatase, spiggin (stickleback) Morphology of gonads; sperm condition Reproductive success (eggs, larvae) Intersex, Imposex Genotoxic parameters DNA adducts Comet assay Micronucleus assay, sister-chromatid exchange Flow cytometric screening (DNA, RNA, protein) Neurotoxic parameters Acetyl cholinesterase inhibition assay (ACHE) Neurotransmitter impairment (e.g. SERT) Behavioral studies BIOASSAYS are needed to test effects of 1) Individual chemicals Understanding toxicity + prospective studies for R.A. 2) Environmental samples Routine analytical data (PAHs, PCBs, OCPs) provide only partial information Biological experiments complement chemical analyses and may suggest elevated levels of unknown toxic chemicals (e.g. EDs) In vitro assays are screening tools that help to understand mechanisms (e.g. feminization / anti-androgenicity) In vivo assays ecologically relevant results SUMMARY BIOASSAYS Real ecotoxicology needed 1) Use non-standardized organisms n Laboratory - aquatic snails, chironomids, soil organisms n Natural sample natural organisms and test ecotoxicity immediately 2) Assess parameters important for populations n Reproduction n Life cycle effects (including early life stages) 3) Consider natural situations n Addapt test conditions (temperature?, water hardness? ) n Simulate real exposures (e.g. peaks during pesticide spraying) Summary Methods for assessing effect vary from single chemical/single species multiple stressors/multiple species short-term/long-term Ability to relate cause and effect varies accordingly (easier for simpler system) Need studies at all scales (temporal and spatial) to have better understanding Be critical of a standard developed with just one methodology!