Project description:Titanium dioxide (TiO2) based nanomaterials (NMs) are among the most produced NMs worldwide. When irradiated with light, particularly UV, TiO2 is photoactive, a property that is explored for several purposes. There is an increasingly number of reports on the negative effects of photoactivated TiO2 to non-target organisms. We have here studied the effect of a suite of reference type TiO2 NMs i.e. NM103, NM104, NM105 and compared these to the Bulk) with and without UV radiation to the oligochaete Enchytraeus crypticus. High-throughput gene expression was used to assess the molecular mechanisms, while also anchoring it to known effects at organism level (i.e., reproduction). Results showed that the photoactivity of TiO2 (UV exposed) played a major role in enhancing TiO2 toxicity, activating transcription of oxidative stress, lysosome damage and apoptosis mechanisms. For non-UV activated TiO2, where toxicity at organism level (reproduction) was lower, results showed the potential for long-term effects (i.e., mutagenic and epigenetic). NM specific mechanisms were identified: NM103 affected transcription and translation, NM104_UV negatively affected reproductive system/organs; and NM105_UV activated superoxide anion response. Results provided mechanistic information for UV-related phototoxicity of TiO2 materials and evidences of the potential long-term effects.
Project description:Mechanisms of (photo)toxicity of TiO2 nanomaterials (NM103, NM104, NM105): using high-throughput gene expression in Enchytraeus crypticus
Project description:The transcriptome of the ecotoxicological model Enchytraeus crypticus is well studied but the downstream changes at the protein level remained a gap. Changes in the protein regulation following exposure to CuO nanomaterial (NM) and Cu salt (CuCl2) were investigated. High performance liquid chromatography with tandem mass spectrometry using tandem mass tags was used. CuO NM elicited higher number of differentially expressed proteins compared to CuCl2 with little to no overlap of proteins. CuO NM caused more stress response mechanisms, with good agreement between differentially expressed proteins, genes and metabolites. CuCl2 caused higher impact in shorter time periods, but organisms have conserved mechanisms (constitutive genes) that allow Cu handling and detoxification. CuO NM caused higher impact after a longer exposure period, inducing regulation of facultative genes with a whole differentiated paradigm and cascade. This could be due to different issues: 1) the cell uptake route is different for Cu NM and Cu ions 2) internalized Cu NM can result in a “Trojan- horse” effect 3) the cascade of events occurs in a different time order 4) the organism uptake is different between life stages, i.e., cocoons thickened surface protects the entry of NM and juveniles have facilitated entry via tegument. Protein responses are of key importance when trying to understand the link between exposure and the related adverse biological effects. We here used advanced proteomic profiling techniques to describe how the protein responses differ when an organism is exposed to Copper (Cu) nanomaterial compared to when it is exposure to Cu ions. We observed that when organisms are exposed to the nano-form they have longer-term changes in protein patterns, patterns that are different from the responses following exposure to the ionic form. On the level of individual proteins we identified nano-specific mechanisms.
Project description:Polycyclic Aromatic Hydrocarbons (PAHs) continue to cause environmental challenges due to their release in the environment by a great variety of anthropogenic activities and their accumulation in soil ecosystems. Here we studied the toxicological effect of the model PAH phenanthrene (Phe) on the soil invertebrate model Enchytraeus crypticus at the individual, tissue and molecular level. Organisms were exposed to Phe for 2 and 21 days to the (previously estimated) EC10 and EC50 (population reproduction over 3 weeks). Gene expression profiling did not reveal a typical Phe-induced biotransfor-mation signature, as it usually does in arthropods and vertebrates. Instead, we observed only general metabolic processes to be affected after 2 days of exposure, such as translation and ATP synthesis-coupled electron transport. Histological sections of tissues of 2-day exposed animals did not show any deviations from the control situation. In contrast, prolonged exposure up to 21 days showed histopathological effects: chloragogenous cells were highly vacuolated and hypertrophic. This was corroborated by differential expression of genes related to immune response and oxidative stress at the transcriptomic level. The data exemplify the complexity and species-specific features of PAH toxicity among soil invertebrate communities, which restricts read-across and extrapolation in the context of soil ecological risk assessment. The data presented in our manuscript is an exposure experiment where E. cryticus is exposed to phenanthrene EC10 and EC50 on reproduction for 2 and 21 days. A single channel, interwoven loop design was used to test animals. 4 biological replicates per condition were used containing 25 grams of soil and 5 - 7, adult old animals per replicate. The platform is a 4*180k Agilent platform containing some 86k E. crypticus probes in duplicate. However, only a subset of the probes (23k) was used for the analysis. To see which probes were used in the analysis see the raw data files control type column, only probes which are denoted with a 0 were used.
Project description:Negatives effects induced by exposure to ultra-violet (UV) radiation are well known. Nevertheless the modes of action of UV radiation are not well understood, in particular in soil invertebrates. In the present work, the effects of two UV doses (mimicking worst case scenarios in earth crust) on gene expression profile of Enchytraeus crypticus (Enchytraeidae, Oligochaeta) were investigated using the high-throughput 4 x 44K microarray developed for the species.
Project description:The soil worm Enchytraeus crypticus (oligochaete) is an ecotoxicology model species although without genome or transcriptome sequence information. The present research aimed at studying, via high-throughput pyrosequencing, the transcriptome of Enchytraeus crypticus, sampled from multiple test conditions, and the construction of a high-density microarray for functional genomic studies. A pyrosequencing run retrieved approximately 1.5 million reads representing 645 million bases. After assembly, 27,296 contigs and 87,686 singletons were obtained. from which 44% and 25% were annotated as protein-coding genes. We show that the high amount of orphan genes is not due to poor sequence or assemble quality: 84% of the contig sequences contains an open reading frame with a start codon and E. crypticus homologs were identified for 92% of the core eukaryotic genes. Moreover, 65 and 77% of the unknown singletons and contigs, respectively, showed transcriptional activity. An Agilent 180K microarray platform was designed and validated by hybridizing cDNA from 3 day zinc- exposed E. crypticus to the concentration corresponding to 50% reduction in reproduction (EC50). Overall, 70% of all probes exerted a hybridization signal above background level. More specifically, the probes derived from contigs showed a wider range of average intensities when compared to probes derived from singletons. In total, 522 significantly regulated transcripts were identifying upon zinc exposure. Several significantly regulated genes exerted predicted functions (e.g. zinc efflux, zinc transport) associated with zinc stress. Unexpectedly, the microarray data suggest that zinc exposure alters retrotransposon activity in the E. crypticus genome. In conclusion, characterization of the presented E. crypticus transcriptome and associated microarray platform is a valuable and high quality resource that permits further functional genomics experiments examining gene expression patterns underlying distinct environmental stress conditions. We show that unknown sequences are not the result of technical errors but mostly represent functional genes that are actively transcribed. The data presented in our manuscript is part of a larger experiment which was performed in single, large loop design. The analysis presented here can be replicated only by including all raw data from the larger experiment (all raw files are included in the archive linked to this submission). A single channel, interwoven loop design was used to test animals exposed to zinc EC50 on reproduction as compared to untreated controls for 4 days. 4 biological replicates per condition were used containing 25 grams of soil and 5 - 7, adult old animals per replicate. T4_con stands for untreated control soil while T4_50 are the samples exposed to EC50 of zinc on reproduction.
Project description:Transcriptome assembly and microarray construction for Enchytraeus crypticus, a model oligochaete to assess stress response mechanisms derived from soil conditions
Project description:Polycyclic Aromatic Hydrocarbons (PAHs) continue to cause environmental challenges due to their release in the environment by a great variety of anthropogenic activities and their accumulation in soil ecosystems. Here we studied the toxicological effect of the model PAH phenanthrene (Phe) on the soil invertebrate model Enchytraeus crypticus at the individual, tissue and molecular level. Organisms were exposed to Phe for 2 and 21 days to the (previously estimated) EC10 and EC50 (population reproduction over 3 weeks). Gene expression profiling did not reveal a typical Phe-induced biotransfor-mation signature, as it usually does in arthropods and vertebrates. Instead, we observed only general metabolic processes to be affected after 2 days of exposure, such as translation and ATP synthesis-coupled electron transport. Histological sections of tissues of 2-day exposed animals did not show any deviations from the control situation. In contrast, prolonged exposure up to 21 days showed histopathological effects: chloragogenous cells were highly vacuolated and hypertrophic. This was corroborated by differential expression of genes related to immune response and oxidative stress at the transcriptomic level. The data exemplify the complexity and species-specific features of PAH toxicity among soil invertebrate communities, which restricts read-across and extrapolation in the context of soil ecological risk assessment.