Project description:Organotin compounds are highly persistent organic pollutants that bioaccumulate in marine biota, behaving as potent endocrine disruptors. Tributyltin (TBT) has been described as an environmental obesogen, as it contributes in mammals to lipid accumulation in a mechanism mediated by PPARγ and RXR. With the aim of studying the molecular mechanisms that elicit TBT-induced pathogenesis in fish, thicklip grey mullets Chelon labrosus were exposed to low (10 ng/L) and high (500 ng/L) TBT concentrations for 1, 7 and 21 days, and gene transcription and metabolome profiles were studied. With this purpose, the multitissue transcriptome of mullet was sequenced by 454 pyrosequencing obtaining 126 Mb of sequence information. Assembly and annotation allowed spotting 8330 gene signatures on an oligonucleotide microarray that was used to identify hepatic gene transcription profiles specific to each TBT exposure set-up. Functional pathway analysis revealed that early profiles were characterized by genes related to response to organic substances and to oxidative stress and glucose metabolic processes. After 21 days of exposure, enriched GO terms in both concentrations were related to lipid homeostasis with a significant regulation of steroid metabolic and cholesterol biosynthetic processes. Also, the androgen receptor signalling pathway was regulated while PPAR signalling appeared as the most significantly regulated KEGG pathway. Neutral lipid accumulation measured by Oil-Red-O histochemistry did not show any treatment-related effect but hepatic and plasma NMR and GC-MS metabolomic analysis revealed distinctive metabolites. Aqueous profiles were characterised by lactate, glucose and alanine while GC-MS revealed a whole set of discriminating polyunsaturated fatty acids. Thus, TBT pathogenesis involves alterations of lipid metabolism through a mechanism that could involve PPARγ-regulated processes confirming the obesogen hypothesis for TBT in fish.

Project description:Thicklip grey mullet hepatic transcriptome comparission from PASAIA harbour, Basque Country Active biomonitoring using sentinel species caged in differentially polluted aquatic environments is being implemented worldwide. To determine the biological effects of pollutants in a heavily polluted Basque harbour (Pasaia, 431700N 015500W), two cages specially designed to deploy thicklip grey mullets (Chelon labrosus) were placed in the inner- and outer-harbour. Cages were deployed for 5 and 21 days to determine possible differences between sites, linked to specific chemical burdens. Hepatic gene expression profiles were studied using Q-PCR and a toxicology tailored low density mullet microarray (160 genes). Chemical analysis showed high concentrations of metals, PAHs, PCBs, phthalates, and organometallic compounds at both sites, most chemicals showing slightly higher concentrations in the inner-harbour. Q-PCR expression studies confirmed chemical data as metallothionein and CYP1A showed significant expression upregulation at day 21 at both sites, but showed no differences between sites. The microarray showed gene expression profiles that were able to distinguish mullets according to the site they were deployed in and the day they were captured. Regarding sites, 39 genes showed significant differences at p<0.05 on the last sampling day. Two families of genes are to be highlighted. Phase I and II biotransformation genes CYP2, CYP3 and UGT were upregulated in the inner-harbour together with AhR2 and AhRR. Similarly, TBT binding protein and genes involved in lipid metabolism such us PPARa and CYP7 were upregulated. The latter two genes have also been reported to be regulated by TBT. In summary, the low density microarray designed for mullets proved to be useful to unveil even slight differences in pollutant burdens in field conditions. 24 samples:6 hepatic samples from Inner harbour after 3 days of exposure, 6 hepatic samples from outer harbour after 3 days of exposure, 6 hepatic samples from Inner harbour after 15 days of exposure and 6 hepatic samples from outer harbour after 15 days of exposure

Project description:The widely distributed thicklip grey mullet (Chelon labrosus) has been proposed as a suitable sentinel of pollution since it is able to survive heavily polluted marine/estuarine waters. Previous studies applying molecular to histological level biomarkers have indicated that mullets respond to exposure to chemical compounds. Microarrays are used to identify gene pathways responsive to specific chemical exposures. In this context, fragments of 129 genes relevant in peroxisome proliferation, detoxification, lipid metabolism, inflammatory/immune response, metal sequestration, oxidative and general stress, cell cycle regulation and proliferation, apoptosis, protein synthesis/degradation, and endocrine disruption were cloned through homological cloning using degenerate primers for microchip creation. Additional 31 sequences available in databases belonging to mugilid fishes were included in the final Agilent custom-microchip design. Female multitissue transcritome analysis was performed in mullets from Ondarrua. 108 genes showed differential expression when comparing female brain, gonad, gill and liver. Typical brain transcripts such as aromatase or dopamine receptor were expressed preferentially in the brain, whereas liver specific genes were detected in the liver; choriogenin-L, vitellogenins, fibrinogens or hepatocyte growth-factor. Genes related to peroxisome proliferation were systematically overrepresented in gonads. Female thicklip grey mullet tissue transcriptome comparission from Ondarrua, Basque Country GSM861357-GSM861379: 23 samples: 5 female samples from Gonad: female-Ondarru (F-L); 6 female samples from gonad: female-Ondarru (F-GO); 6 female samples from gill: female-Ondarru (F-GI); 6 female samples from brain: female-Ondarru (F-B); GSM886139-GSM886153: 15 samples: 2 intersex samples from Ondarru (I-L); 2 intersex gonad samples: intersex-Ondarru (I-GO); 6 female hepatic samples: female-Arriluze (F-A); 5 male hepatic samples: male-Arriluze (M-A) Immature Thicklip grey mullets were exposed to accetone, cadmium, benzo(a)pyrene and to nonylphenol and hepatic transcriptome was compared GSM886154-GSM886183: 30 samples: immature thicklip grey mullets hepatic samples 6 control seawater exposed samples, 6 acetone exposed samples; 6 cadmium exposed samples, 6 benzo(a)pyrene exposed samples (BAP) and 6 nonylphenol (NP) exposed samples.

Project description:Transcriptomic profiling of Daphnia magna samples exposed to tributyltin (TBT), pyriproxyfen (PP) and bisphenol A (BPA) at 8 and 24 hours. The analysis of lipid disruptive effects in invertebrates is limited by our poor knowledge of their lipidomes and of the associated metabolic pathways. Here we analyzed the subsequent transcriptome changes, using tributyltin (TBT), pyriproxyfen (PP) and bisphenol A (BPA). Changes in the whole transcriptome were assessed after 8 and 24 h of exposure, the period showing the greatest variation in storage lipid accumulation. The three compounds affected similarly to a total of 1388 genes (965 overexpressed and 423 underexpressed transcripts), but only after 24h of exposure. In addition,225 transcripts became up-regulated only in samples exposed to tributyltin for both 8h and 24 h. Using functional annotation from D. melanogaster, we determined that upregulated genes were enriched in members of KEGG modules implicated in fatty acid, phosphoinositol, glycerophospholipid, and glycerolipid metabolic pathways, as well as in genes related to membrane constituents , and to chitin and cuticle metabolic pathways. Conversely, down-regulated genes appeared mainly related with to visual perception, and to oocyte development signalling pathways. Many tributyltin specifically upregulated genes were related to neuro-active ligand receptor interaction signalling pathway. These changes are consistent with the previous observation that exposure of D. magna to the tested compounds increases lipid accumulation and reduces egg quality.

Project description:Obesogens such as tributyltin (TBT) are xenobiotic compounds that promote obesity, in part by distorting the normal balance of lipid metabolism. The obesogenic effects of TBT can be observed in directly exposed (F1 and F2 generations) and also subsequent generations (F3 and beyond) that were never exposed. To address the effects of TBT exposure on germ cells, we exposed pregnant transgenic OG2 mouse dams (F0), which specifically express EGFP in germline cells, to an environmentally relevant dose of TBT throughout gestation through drinking water. When fed with a high fat diet (HFD), F3 male offspring of TBT-exposed F0 dams (TBT-F3) accumulated much more body fat than did Control-F3 males. TBT-F3 males also lost more body fluid and lean compositions than did Control-F3 males. Expression of genes involved in transcriptional regulation or mesenchymal differ-entiation was upregulated in somatic cells of TBT-F1 (but not TBT-F3) E18.5 fetal testes, and promoter-associated CpG islands were hyper-methylated in TBT-F1 somatic cells. Global mRNA expression of protein-coding genes in F1 or F3 fetal testicular cells was unaffected by F0 exposure to TBT; however, expression of a subset of endogenous retroviruses was significantly affected in F1 and F3. We infer that TBT may directly target testicular somatic cells in F1 testes to irreversibly affect epigenetic suppression of endogenous retroviruses in both germline and somatic cells.

Project description:Imposex, the superimposition of male sexual characteristics in females, is caused by tributyltin (TBT) and provides one of the best ecological examples of anthropogenically-induced endocrine disruption in aquatic ecosystems. We used combinations of 454 Roche pyrosequencing and microarray technologies to understand the functional genomic basis of imposex in the prosobranch gastropod, Nucella lapillus, a recognised sentinel for TBT-induced imposex.

Project description:Tributyltin (TBT) accumulates at higher levels in the liver than in any other organ, and it acts as a hepatotoxic agent. Most of the available studies on TBT have focused on observations at the cellular level, and studies at the level of genes and proteins have been limited; therefore, the information concerning possible mechanisms of TBT-induced adverse health effects remains scarce and inconclusive. In the present study, we applied a toxicogenomic approach to investigate the effects of TBT on gene expression in the human normal liver cell line HL7702.

Project description:Obesogenic compounds are chemicals that might have an influence on obesity development through in utero or chronic lifetime exposure. Tributyltin (TBT) is one of the most studied obesogenic compounds, inducing adipogenesis in vitro and increasing body fat after in utero exposure of mice. This study was designed to unravel the molecular mechanisms of TBT, using microarray analysis, and to evaluate the use of toxicogenomics for obesogen screening. The murine 3T3-L1 cell line was used to study TBT induced adipogenesis. Lipid staining as well as gene expression measurements of an adipocyte specific marker gene were performed to select relevant concentrations (10 nM, 50 nM) and time points (day1, day10) for microarray analysis. Additionally, solvent control and positive control (MDI) treated 3T3-L1 cells were included in the analysis. The microarray results were analysed using GO enrichment and Pathway analysis tools, which revealed enrichment of several GO terms involved in energy and fat metabolism after 10 days of TBT exposure. Pathway analysis unveiled PPAR signalling pathway as the sole pathway significantly enriched after 1 day and the most significantly enriched pathway after 10 days of exposure. By examination of effects on both cell physiological and gene expression level we provide a detailed overview of TBT induced obesogenic mechanisms. To our knowledge, this is the first study delivering an in depth mechanistic outline of the mode of action of TBT as an obesogen. Furthermore, our results show that combining omics with 3T3-L1 cells is promising for screening of potential obesogenic compounds. A separate v+2 A-optimal hybridization design was used for each time-point. Using this design each exposure condition is represented by three biological replicates, with each biological replicate analysed in technical duplicate while applying the dye swap principle to correct for dye bias. Two concentrations of TBT (10 nM, 50 nM), DMSO and MDI (positive control, adipogenic hormone cocktail) were the conditions tested, at two time-points (day 1 and day10).

Project description:Obesogenic compounds are chemicals that might have an influence on obesity development through in utero or chronic lifetime exposure. Tributyltin (TBT) is one of the most studied obesogenic compounds, inducing adipogenesis in vitro and increasing body fat after in utero exposure of mice. This study was designed to unravel the molecular mechanisms of TBT, using microarray analysis, and to evaluate the use of toxicogenomics for obesogen screening. The murine 3T3-L1 cell line was used to study TBT induced adipogenesis. Lipid staining as well as gene expression measurements of an adipocyte specific marker gene were performed to select relevant concentrations (10 nM, 50 nM) and time points (day1, day10) for microarray analysis. Additionally, solvent control and positive control (MDI) treated 3T3-L1 cells were included in the analysis. The microarray results were analysed using GO enrichment and Pathway analysis tools, which revealed enrichment of several GO terms involved in energy and fat metabolism after 10 days of TBT exposure. Pathway analysis unveiled PPAR signalling pathway as the sole pathway significantly enriched after 1 day and the most significantly enriched pathway after 10 days of exposure. By examination of effects on both cell physiological and gene expression level we provide a detailed overview of TBT induced obesogenic mechanisms. To our knowledge, this is the first study delivering an in depth mechanistic outline of the mode of action of TBT as an obesogen. Furthermore, our results show that combining omics with 3T3-L1 cells is promising for screening of potential obesogenic compounds.

Project description:Environmental obesogens are being studied for their potential role in the increasing prevalence of obesity globally. A major area of focus in this field of research has been on the mechanism by which these agents act. In this study we focused on the organotin tributyltin (TBT), a water pollutant exposed to humans through diet. The mechanism by which TBT is believed to act is by binding to the PPAR nuclear receptor which heterodimerizes with RXR to alter gene regulation. To test whether this was the dominant mechanism for TBT activity, we performed time-course studies of transcription and chromatin accessibility in mesenchymal stem cells differentiating to adipocytes. We found limited evidence for PPAR effects by TBT, but a strong response by Ras-related GTPases and evidence for the loss of TEAD transcription factor activity during differentiation. These observations combine to implicate a known property of organotins, to cause cytoskeletal depolymerization. We propose a model for TBT activity involving a primary effect of cytoskeletal damage, leading to the loss of YAP co-regulator activity and the consequent failure of TEAD repression of adipogenesis.