Parallel Biotransformation of Tetrabromobisphenol A in Xenopus laevis and Mammals: Xenopus as a Model for Endocrine Perturbation Studies

The flame retardant tetrabromobisphenol A (TBBPA) is a high production flame retardant that interferes with thyroid hormone (TH) signaling. Despite its rapid metabolism in mammals, TBBPA is found in significant amounts in different tissues. Such findings highlight first a need to better understand t...

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Published in	Toxicological Sciences Vol. 125; no. 2; pp. 359 - 367
Main Authors	Fini, Jean-Baptiste, Riu, Anne, Debrauwer, Laurent, Hillenweck, Anne, Le Mével, Sébastien, Chevolleau, Sylvie, Boulahtouf, Abdelaye, Palmier, Karima, Balaguer, Patrick, Cravedi, Jean-Pierre, Demeneix, Barbara A., Zalko, Daniel
Format	Journal Article
Language	English
Published	United States Oxford University Press 01.02.2012 Oxford University Press (OUP)
Subjects	Animals Antithyroid Agents - metabolism Antithyroid Agents - toxicity Binding, Competitive Biotransformation Chromatography, Liquid Dose-Response Relationship, Drug Endocrine Disruptors - metabolism Endocrine Disruptors - toxicity Flame Retardants - metabolism Flame Retardants - toxicity Genes, Reporter Glucuronides - metabolism Humans Kinetics Larva - drug effects Larva - metabolism Life Sciences Polybrominated Biphenyls - metabolism Polybrominated Biphenyls - toxicity Spectrometry, Mass, Electrospray Ionization Sulfates - metabolism Thyroid Hormone Receptors alpha - drug effects Thyroid Hormone Receptors alpha - genetics Thyroid Hormone Receptors alpha - metabolism Toxicity Tests - methods Transcriptional Activation - drug effects Transfection Triiodothyronine - metabolism Xenopus laevis - embryology Xenopus laevis - genetics Xenopus laevis - metabolism Zebrafish Proteins - drug effects Zebrafish Proteins - genetics biotransformation thyroid hormone vertebrate model metabolism TBBPA endocrine disruption phase II metabolism
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ISSN	1096-6080 1096-0929 1096-0929 1096-6099
DOI	10.1093/toxsci/kfr312

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Abstract	The flame retardant tetrabromobisphenol A (TBBPA) is a high production flame retardant that interferes with thyroid hormone (TH) signaling. Despite its rapid metabolism in mammals, TBBPA is found in significant amounts in different tissues. Such findings highlight first a need to better understand the effects of TBBPA and its metabolites and second the need to develop models to address these questions experimentally. We used Xenopus laevis tadpoles to follow radiolabeled 14C-TBBPA uptake and metabolism. Extensive and rapid uptake of radioactivity was observed, tadpoles metabolizing > 94% of 14C-TBBPA within 8 h. Four metabolites were identified in water and tadpole extracts: TBBPA-glucuronide, TBBPA-glucuronide-sulfate, TBBPA-sulfate, and TBBPA-disulfate. These metabolites are identical to the TBBPA conjugates characterized in mammals, including humans. Most radioactivity (> 75%) was associated with sulfated conjugates. The antithyroid effects of TBBPA and the metabolites were compared using two in vivo measures: tadpole morphology and an in vivo tadpole TH reporter gene assay. Only TBBPA, and not the sulfated metabolites, disrupted thyroid signaling. Moreover, TBBPA treatment did not affect expression of phase II enzymes involved in TH metabolism, suggesting that the antithyroid effects of TBBPA are not due to indirect effects on TH metabolism. Finally, we show that only the parent TBBPA inhibits T3-induced transactivation in cells expressing human, zebrafish, or X. laevis TH receptor, TRα. We conclude, first, that perturbation of thyroid signaling by TBBPA is likely due to rapid direct action of the parent compound, and second, that Xenopus is an excellent vertebrate model for biotransformation studies, displaying homologous pathways to mammals.
AbstractList	The flame retardant tetrabromobisphenol A (TBBPA) is a high production flame retardant that interferes with thyroid hormone (TH) signaling. Despite its rapid metabolism in mammals, TBBPA is found in significant amounts in different tissues. Such findings highlight first a need to better understand the effects of TBBPA and its metabolites and second the need to develop models to address these questions experimentally. We used Xenopus laevis tadpoles to follow radiolabeled (14)C-TBBPA uptake and metabolism. Extensive and rapid uptake of radioactivity was observed, tadpoles metabolizing > 94% of (14)C-TBBPA within 8 h. Four metabolites were identified in water and tadpole extracts: TBBPA-glucuronide, TBBPA-glucuronide-sulfate, TBBPA-sulfate, and TBBPA-disulfate. These metabolites are identical to the TBBPA conjugates characterized in mammals, including humans. Most radioactivity (> 75%) was associated with sulfated conjugates. The antithyroid effects of TBBPA and the metabolites were compared using two in vivo measures: tadpole morphology and an in vivo tadpole TH reporter gene assay. Only TBBPA, and not the sulfated metabolites, disrupted thyroid signaling. Moreover, TBBPA treatment did not affect expression of phase II enzymes involved in TH metabolism, suggesting that the antithyroid effects of TBBPA are not due to indirect effects on TH metabolism. Finally, we show that only the parent TBBPA inhibits T3-induced transactivation in cells expressing human, zebrafish, or X. laevis TH receptor, TRα. We conclude, first, that perturbation of thyroid signaling by TBBPA is likely due to rapid direct action of the parent compound, and second, that Xenopus is an excellent vertebrate model for biotransformation studies, displaying homologous pathways to mammals. The flame retardant tetrabromobisphenol A (TBBPA) is a high production flame retardant that interferes with thyroid hormone (TH) signaling. Despite its rapid metabolism in mammals, TBBPA is found in significant amounts in different tissues. Such findings highlight first a need to better understand the effects of TBBPA and its metabolites and second the need to develop models to address these questions experimentally. We used Xenopus laevis tadpoles to follow radiolabeled (14)C-TBBPA uptake and metabolism. Extensive and rapid uptake of radioactivity was observed, tadpoles metabolizing > 94% of (14)C-TBBPA within 8 h. Four metabolites were identified in water and tadpole extracts: TBBPA-glucuronide, TBBPA-glucuronide-sulfate, TBBPA-sulfate, and TBBPA-disulfate. These metabolites are identical to the TBBPA conjugates characterized in mammals, including humans. Most radioactivity (> 75%) was associated with sulfated conjugates. The antithyroid effects of TBBPA and the metabolites were compared using two in vivo measures: tadpole morphology and an in vivo tadpole TH reporter gene assay. Only TBBPA, and not the sulfated metabolites, disrupted thyroid signaling. Moreover, TBBPA treatment did not affect expression of phase II enzymes involved in TH metabolism, suggesting that the antithyroid effects of TBBPA are not due to indirect effects on TH metabolism. Finally, we show that only the parent TBBPA inhibits T3-induced transactivation in cells expressing human, zebrafish, or X. laevis TH receptor, TRα. We conclude, first, that perturbation of thyroid signaling by TBBPA is likely due to rapid direct action of the parent compound, and second, that Xenopus is an excellent vertebrate model for biotransformation studies, displaying homologous pathways to mammals.The flame retardant tetrabromobisphenol A (TBBPA) is a high production flame retardant that interferes with thyroid hormone (TH) signaling. Despite its rapid metabolism in mammals, TBBPA is found in significant amounts in different tissues. Such findings highlight first a need to better understand the effects of TBBPA and its metabolites and second the need to develop models to address these questions experimentally. We used Xenopus laevis tadpoles to follow radiolabeled (14)C-TBBPA uptake and metabolism. Extensive and rapid uptake of radioactivity was observed, tadpoles metabolizing > 94% of (14)C-TBBPA within 8 h. Four metabolites were identified in water and tadpole extracts: TBBPA-glucuronide, TBBPA-glucuronide-sulfate, TBBPA-sulfate, and TBBPA-disulfate. These metabolites are identical to the TBBPA conjugates characterized in mammals, including humans. Most radioactivity (> 75%) was associated with sulfated conjugates. The antithyroid effects of TBBPA and the metabolites were compared using two in vivo measures: tadpole morphology and an in vivo tadpole TH reporter gene assay. Only TBBPA, and not the sulfated metabolites, disrupted thyroid signaling. Moreover, TBBPA treatment did not affect expression of phase II enzymes involved in TH metabolism, suggesting that the antithyroid effects of TBBPA are not due to indirect effects on TH metabolism. Finally, we show that only the parent TBBPA inhibits T3-induced transactivation in cells expressing human, zebrafish, or X. laevis TH receptor, TRα. We conclude, first, that perturbation of thyroid signaling by TBBPA is likely due to rapid direct action of the parent compound, and second, that Xenopus is an excellent vertebrate model for biotransformation studies, displaying homologous pathways to mammals. The flame retardant tetrabromobisphenol A (TBBPA) is a high production flame retardant that interferes with thyroid hormone (TH) signaling. Despite its rapid metabolism in mammals, TBBPA is found in significant amounts in different tissues. Such findings highlight first a need to better understand the effects of TBBPA and its metabolites and second the need to develop models to address these questions experimentally. We used Xenopus laevis tadpoles to follow radiolabeled 14C-TBBPA uptake and metabolism. Extensive and rapid uptake of radioactivity was observed, tadpoles metabolizing > 94% of 14C-TBBPA within 8 h. Four metabolites were identified in water and tadpole extracts: TBBPA-glucuronide, TBBPA-glucuronide-sulfate, TBBPA-sulfate, and TBBPA-disulfate. These metabolites are identical to the TBBPA conjugates characterized in mammals, including humans. Most radioactivity (> 75%) was associated with sulfated conjugates. The antithyroid effects of TBBPA and the metabolites were compared using two in vivo measures: tadpole morphology and an in vivo tadpole TH reporter gene assay. Only TBBPA, and not the sulfated metabolites, disrupted thyroid signaling. Moreover, TBBPA treatment did not affect expression of phase II enzymes involved in TH metabolism, suggesting that the antithyroid effects of TBBPA are not due to indirect effects on TH metabolism. Finally, we show that only the parent TBBPA inhibits T3-induced transactivation in cells expressing human, zebrafish, or X. laevis TH receptor, TRα. We conclude, first, that perturbation of thyroid signaling by TBBPA is likely due to rapid direct action of the parent compound, and second, that Xenopus is an excellent vertebrate model for biotransformation studies, displaying homologous pathways to mammals.
Author	Riu, Anne Chevolleau, Sylvie Palmier, Karima Zalko, Daniel Balaguer, Patrick Boulahtouf, Abdelaye Hillenweck, Anne Demeneix, Barbara A. Debrauwer, Laurent Le Mével, Sébastien Cravedi, Jean-Pierre Fini, Jean-Baptiste
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Copyright	The Author 2011. Published by Oxford University Press on behalf of the Society of Toxicology. All rights reserved. For permissions, please email: journals.permissions@oup.com 2012 Distributed under a Creative Commons Attribution 4.0 International License
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Keywords	biotransformation thyroid hormone vertebrate model metabolism TBBPA endocrine disruption phase II metabolism
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Snippet	The flame retardant tetrabromobisphenol A (TBBPA) is a high production flame retardant that interferes with thyroid hormone (TH) signaling. Despite its rapid...
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SubjectTerms	Animals Antithyroid Agents - metabolism Antithyroid Agents - toxicity Binding, Competitive Biotransformation Chromatography, Liquid Dose-Response Relationship, Drug Endocrine Disruptors - metabolism Endocrine Disruptors - toxicity Flame Retardants - metabolism Flame Retardants - toxicity Genes, Reporter Glucuronides - metabolism Humans Kinetics Larva - drug effects Larva - metabolism Life Sciences Polybrominated Biphenyls - metabolism Polybrominated Biphenyls - toxicity Spectrometry, Mass, Electrospray Ionization Sulfates - metabolism Thyroid Hormone Receptors alpha - drug effects Thyroid Hormone Receptors alpha - genetics Thyroid Hormone Receptors alpha - metabolism Toxicity Tests - methods Transcriptional Activation - drug effects Transfection Triiodothyronine - metabolism Xenopus laevis - embryology Xenopus laevis - genetics Xenopus laevis - metabolism Zebrafish Proteins - drug effects Zebrafish Proteins - genetics
Title	Parallel Biotransformation of Tetrabromobisphenol A in Xenopus laevis and Mammals: Xenopus as a Model for Endocrine Perturbation Studies
URI	https://www.ncbi.nlm.nih.gov/pubmed/22086976 https://www.proquest.com/docview/917573292 https://hal.inrae.fr/hal-02644396
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