Your search keyword '"developmental neurotoxicity"' showing total 142 results

1. Effects of cylindrospermopsin, chlorpyrifos and their combination in a SH-SY5Y cell model concerning developmental neurotoxicity

Author

Hinojosa, Maria G., Johansson, Ylva, Jos, A., Camean, A. M., Forsby, Anna, Hinojosa, Maria G., Johansson, Ylva, Jos, A., Camean, A. M., and Forsby, Anna

Abstract

The cyanotoxin cylindrospermopsin (CYN) has been postulated to cause neurotoxicity, although the studies in this concern are very few. In addition, some studies in vitro indicate its possible effects on development. Furthermore, pesticides can be present in the same environmental samples as cyanotoxins. Therefore, chlor-pyrifos (CPF) has been one of the most common pesticides used worldwide. The aim of this report was to study the effects of CYN, isolated and in combination with CPF, in a developmental neurotoxicity in vitro model. The human neuroblastoma SH-SY5Y cell line was exposed during 6 days of differentiation to both toxics to study their effects on cell viability and neurite outgrowth. To further evaluate effects of both toxicants on cholinergic signaling, their agonistic and antagonistic activities on the alpha 7 homomeric nicotinic acetylcholine receptor (nAChR) were studied upon acute exposure. Moreover, a transcriptomic analysis by qPCR was performed after 6 days of CYN-exposure during differentiation. The results showed a concentration-dependent decrease on both cell viability and neurite outgrowth for both toxics isolated, leading to effective concentration 20 (EC20) values of 0.35 mu M and 0.097 mu M for CYN on cell viability and neurite outgrowth, respectively, and 100 mu M and 58 mu M for CPF, while the combination demonstrated no significant variations. In addition, 95 mu M and 285 mu M CPF demonstrated to act as an antagonist to nicotine on the nAChR, although CYN up to 2.4 mu M had no effect on the efficacy of these receptors. Additionally, the EC20 for CYN (0.097 mu M) on neurite outgrowth downregulated expression of the 5 genes NTNG2 (netrin G2), KCNJ11 (potassium channel), SLC18A3 (vesicular acetylcholine transporter), APOE (apolipoprotein E), and SEMA6B (semaphorin 6B), that are all important for neuronal development. Thus, this study points out the importance of studying the effects of CYN in terms of neurotoxicity and developmental neuroto

Published

2024

2. Developmental exposure to the Fox River PCB mixture modulates behavior in juvenile mice

Author

Wilson, Rebecca J, Wilson, Rebecca J, Suh, Youjun P, Dursun, Ilknur, Li, Xueshu, da Costa Souza, Felipe, Grodzki, Ana Cristina, Cui, Julia Y, Lehmler, Hans-Joachim, Lein, Pamela J, Wilson, Rebecca J, Wilson, Rebecca J, Suh, Youjun P, Dursun, Ilknur, Li, Xueshu, da Costa Souza, Felipe, Grodzki, Ana Cristina, Cui, Julia Y, Lehmler, Hans-Joachim, and Lein, Pamela J

Abstract

Developmental exposures to PCBs are implicated in the etiology of neurodevelopmental disorders (NDDs). This observation is concerning given the continued presence of PCBs in the human environment and the increasing incidence of NDDs. Previous studies reported that developmental exposure to legacy commercial PCB mixtures (Aroclors) or single PCB congeners found in Aroclors caused NDD-relevant behavioral phenotypes in animal models. However, the PCB congener profile in contemporary human samples is dissimilar to that of the legacy Aroclors, raising the question of whether human-relevant PCB mixtures similarly interfere with normal brain development. To address this question, we assessed the developmental neurotoxicity of the Fox River Mixture (FRM), which was designed to mimic the congener profile identified in fish from the PCB-contaminated Fox River that constitute a primary protein source in the diet of surrounding communities. Adult female C57BL/6 J mouse dams (8-10 weeks old) were exposed to vehicle (peanut oil) or FRM at 0.1, 1.0, or 6.0 mg/kg/d in their diet throughout gestation and lactation, and neurodevelopmental outcomes were assessed in their pups. Ultrasonic vocalizations (USVs) and measures of general development were quantified at postnatal day (P) 7, while performance in the spontaneous alternation task and the 3-chambered social approach/social novelty task was assessed on P35. Triiodothyronine (T3) and thyroxine (T4) were quantified in serum collected from the dams when pups were weaned and from pups on P28 and P35. Developmental exposure to FRM did not alter pup weight or body temperature on P7, but USVs were significantly decreased in litters exposed to FRM at 0.1 or 6.0 mg/kg/d in the maternal diet. FRM also impaired male and female pups' performance in the social novelty task. Compared to sex-matched vehicles, significantly decreased social novelty was observed in male and female pups in the 0.1 and 6.0 mg/kg/d dose groups. FRM did not alter perf

Published

2024

3. Triggering Receptor Expressed on Myeloid Cells 2 Alleviated Sevoflurane-Induced Developmental Neurotoxicity via Microglial Pruning of Dendritic Spines in the CA1 Region of the Hippocampus

Author

Deng, Li, Deng, Li, Song, Shao-Yong, Zhao, Wei-Ming, Meng, Xiao-Wen, Liu, Hong, Zheng, Qing, Peng, Ke, Ji, Fu-Hai, Deng, Li, Deng, Li, Song, Shao-Yong, Zhao, Wei-Ming, Meng, Xiao-Wen, Liu, Hong, Zheng, Qing, Peng, Ke, and Ji, Fu-Hai

Abstract

Sevoflurane induces developmental neurotoxicity in mice; however, the underlying mechanisms remain unclear. Triggering receptor expressed on myeloid cells 2 (TREM2) is essential for microglia-mediated synaptic refinement during the early stages of brain development. We explored the effects of TREM2 on dendritic spine pruning during sevoflurane-induced developmental neurotoxicity in mice. Mice were anaesthetized with sevoflurane on postnatal days 6, 8, and 10. Behavioral performance was assessed using the open field test and Morris water maze test. Genetic knockdown of TREM2 and overexpression of TREM2 by stereotaxic injection were used for mechanistic experiments. Western blotting, immunofluorescence, electron microscopy, three-dimensional reconstruction, Golgi staining, and whole-cell patch-clamp recordings were performed. Sevoflurane exposures upregulated the protein expression of TREM2, increased microglia-mediated pruning of dendritic spines, and reduced synaptic multiplicity and excitability of CA1 neurons. TREM2 genetic knockdown significantly decreased dendritic spine pruning, and partially aggravated neuronal morphological abnormalities and cognitive impairments in sevoflurane-treated mice. In contrast, TREM2 overexpression enhanced microglia-mediated pruning of dendritic spines and rescued neuronal morphological abnormalities and cognitive dysfunction. TREM2 exerts a protective role against neurocognitive impairments in mice after neonatal exposures to sevoflurane by enhancing microglia-mediated pruning of dendritic spines in CA1 neurons. This provides a potential therapeutic target in the prevention of sevoflurane-induced developmental neurotoxicity.

Published

2024

4. In vitro and in silico approach methods for developmental neurotoxicity assessment : Examining acrylamide

Author

Johansson, Ylva and Johansson, Ylva

Abstract

Developmental neurotoxicity (DNT) is a branch of toxicology that examines the effects of chemicals on the developing nervous system. Traditional methods for assessing DNT mainly rely on animal testing, which raises ethical concerns, is time-consuming, and expensive. Consequently, there is a shift towards alternative methods, such as in vitro and in silico approaches, which offer faster and more efficient testing. The overall aim of this thesis was to contribute to the development and integration of alternative methods for DNT assessment, employing both in vitro and in silico techniques. In this work, the human neuroblastoma SH-SY5Y cell line was utilized as a robust, cost-effective, and easy-to-use model for DNT evaluation. Through RNA sequencing and morphological observation, it was determined that the SH-SY5Y cell line can differentiate into a more neuron-like phenotype (Paper I). Additionally, neurite outgrowth and the mRNA expression of genes important for neuronal development were studied by exposing the cells to chemicals known to induce DNT (Paper II). The thesis has also focused on acrylamide, a neurotoxic compound that may also cause DNT. In Paper I, it was found that acrylamide inhibited neuronal differentiation by suppressing neurite outgrowth at non-cytotoxic concentrations. Moreover, acrylamide altered the expression of several genes involved in the retinoic acid and CREB signaling pathways. The hypothesis that acrylamide impairs neuronal differentiation by depleting glutathione, leading to oxidative stress, was tested but not supported in the SH-SY5Y cells (Paper III). In Paper IV, we performed an in vitro to in vivo extrapolation by using a novel physiologically based toxicokinetic (PBTK) model for pregnant women, to assess the biological relevance of the acrylamide concentrations that affected neuronal differentiation of SH-SY5Y cells. The results revealed that doses that humans may be exposed to through food intake, resulted in fetal plasma acrylami

Published

2024

5. In vitro and in silico approach methods for developmental neurotoxicity assessment : Examining acrylamide

Author

Johansson, Ylva and Johansson, Ylva

Abstract

Developmental neurotoxicity (DNT) is a branch of toxicology that examines the effects of chemicals on the developing nervous system. Traditional methods for assessing DNT mainly rely on animal testing, which raises ethical concerns, is time-consuming, and expensive. Consequently, there is a shift towards alternative methods, such as in vitro and in silico approaches, which offer faster and more efficient testing. The overall aim of this thesis was to contribute to the development and integration of alternative methods for DNT assessment, employing both in vitro and in silico techniques. In this work, the human neuroblastoma SH-SY5Y cell line was utilized as a robust, cost-effective, and easy-to-use model for DNT evaluation. Through RNA sequencing and morphological observation, it was determined that the SH-SY5Y cell line can differentiate into a more neuron-like phenotype (Paper I). Additionally, neurite outgrowth and the mRNA expression of genes important for neuronal development were studied by exposing the cells to chemicals known to induce DNT (Paper II). The thesis has also focused on acrylamide, a neurotoxic compound that may also cause DNT. In Paper I, it was found that acrylamide inhibited neuronal differentiation by suppressing neurite outgrowth at non-cytotoxic concentrations. Moreover, acrylamide altered the expression of several genes involved in the retinoic acid and CREB signaling pathways. The hypothesis that acrylamide impairs neuronal differentiation by depleting glutathione, leading to oxidative stress, was tested but not supported in the SH-SY5Y cells (Paper III). In Paper IV, we performed an in vitro to in vivo extrapolation by using a novel physiologically based toxicokinetic (PBTK) model for pregnant women, to assess the biological relevance of the acrylamide concentrations that affected neuronal differentiation of SH-SY5Y cells. The results revealed that doses that humans may be exposed to through food intake, resulted in fetal plasma acrylami

Published

2024

6. Novel Endpoints To Unravel Developmental Neurotoxicity : From DNA methylation responses to methylmercury to the in vitro identification of endocrine disruptors

Author

Cediel-Ulloa, Andrea and Cediel-Ulloa, Andrea

Abstract

The developing brain is especially sensitive to environmental stressors due to its dependence on the precise spatiotemporal regulation of multiple signals, and the long time period required for its formation. Some chemicals can interfere with molecular and cellular processes driving brain development, including epigenetic processes such as DNA methylation. Hence, identification of DNA methylation changes induced by chemical exposure may serve as early molecular markers for developmental neurotoxicity (DNT). Chemicals known as endocrine disruptors (EDCs) can produce adverse effects due to their capability to alter the endocrine system. Since brain development is highly dependent on endocrine signals, the potential adverse effects of EDCs on brain development needs to be addressed. Detection of DNT in the regulatory context has been based on in vivo testing, however, the financial costs and time intensive characteristics of these methods have resulted in a limited assessment of the DNT hazard of chemicals. In addition, in order to regulate EDCs, it is paramount to demonstrate that their adverse effects are a product of disruption of endocrine signals. Yet, at the moment, there are no approved methods which address both an endocrine mode of action and adverse neurodevelopmental outcomes. This doctoral thesis had two main aims: Firstly, to identify epigenetic changes, at the level of DNA methylation, underlying DNT induced by exposure to methylmercury (MeHg); and secondly, to develop new approach methods (NAMs) for the detection of DNT induced by endocrine disruption. Epigenetic effects were studied both in epidemiological data and experimentally in vitro. Associations between prenatal MeHg exposure and DNA methylation of GRIN2B and NR3C1 were found in children. In vitro validation of DNA methylation changes found in epigenome-wide association studies of populations exposed to MeHg, uncovered the potential involvement of the Mediator Complex Subunit 31 (MED31) in MeHg D

Published

2024

7. In vitro and in silico approach methods for developmental neurotoxicity assessment : Examining acrylamide

Author

Johansson, Ylva and Johansson, Ylva

Abstract

Developmental neurotoxicity (DNT) is a branch of toxicology that examines the effects of chemicals on the developing nervous system. Traditional methods for assessing DNT mainly rely on animal testing, which raises ethical concerns, is time-consuming, and expensive. Consequently, there is a shift towards alternative methods, such as in vitro and in silico approaches, which offer faster and more efficient testing. The overall aim of this thesis was to contribute to the development and integration of alternative methods for DNT assessment, employing both in vitro and in silico techniques. In this work, the human neuroblastoma SH-SY5Y cell line was utilized as a robust, cost-effective, and easy-to-use model for DNT evaluation. Through RNA sequencing and morphological observation, it was determined that the SH-SY5Y cell line can differentiate into a more neuron-like phenotype (Paper I). Additionally, neurite outgrowth and the mRNA expression of genes important for neuronal development were studied by exposing the cells to chemicals known to induce DNT (Paper II). The thesis has also focused on acrylamide, a neurotoxic compound that may also cause DNT. In Paper I, it was found that acrylamide inhibited neuronal differentiation by suppressing neurite outgrowth at non-cytotoxic concentrations. Moreover, acrylamide altered the expression of several genes involved in the retinoic acid and CREB signaling pathways. The hypothesis that acrylamide impairs neuronal differentiation by depleting glutathione, leading to oxidative stress, was tested but not supported in the SH-SY5Y cells (Paper III). In Paper IV, we performed an in vitro to in vivo extrapolation by using a novel physiologically based toxicokinetic (PBTK) model for pregnant women, to assess the biological relevance of the acrylamide concentrations that affected neuronal differentiation of SH-SY5Y cells. The results revealed that doses that humans may be exposed to through food intake, resulted in fetal plasma acrylami

Published

2024

8. Novel Endpoints To Unravel Developmental Neurotoxicity : From DNA methylation responses to methylmercury to the in vitro identification of endocrine disruptors

Author

Cediel-Ulloa, Andrea and Cediel-Ulloa, Andrea

Abstract

The developing brain is especially sensitive to environmental stressors due to its dependence on the precise spatiotemporal regulation of multiple signals, and the long time period required for its formation. Some chemicals can interfere with molecular and cellular processes driving brain development, including epigenetic processes such as DNA methylation. Hence, identification of DNA methylation changes induced by chemical exposure may serve as early molecular markers for developmental neurotoxicity (DNT). Chemicals known as endocrine disruptors (EDCs) can produce adverse effects due to their capability to alter the endocrine system. Since brain development is highly dependent on endocrine signals, the potential adverse effects of EDCs on brain development needs to be addressed. Detection of DNT in the regulatory context has been based on in vivo testing, however, the financial costs and time intensive characteristics of these methods have resulted in a limited assessment of the DNT hazard of chemicals. In addition, in order to regulate EDCs, it is paramount to demonstrate that their adverse effects are a product of disruption of endocrine signals. Yet, at the moment, there are no approved methods which address both an endocrine mode of action and adverse neurodevelopmental outcomes. This doctoral thesis had two main aims: Firstly, to identify epigenetic changes, at the level of DNA methylation, underlying DNT induced by exposure to methylmercury (MeHg); and secondly, to develop new approach methods (NAMs) for the detection of DNT induced by endocrine disruption. Epigenetic effects were studied both in epidemiological data and experimentally in vitro. Associations between prenatal MeHg exposure and DNA methylation of GRIN2B and NR3C1 were found in children. In vitro validation of DNA methylation changes found in epigenome-wide association studies of populations exposed to MeHg, uncovered the potential involvement of the Mediator Complex Subunit 31 (MED31) in MeHg D

Published

2024

9. Novel Endpoints To Unravel Developmental Neurotoxicity : From DNA methylation responses to methylmercury to the in vitro identification of endocrine disruptors

Author

Cediel-Ulloa, Andrea and Cediel-Ulloa, Andrea

Abstract

The developing brain is especially sensitive to environmental stressors due to its dependence on the precise spatiotemporal regulation of multiple signals, and the long time period required for its formation. Some chemicals can interfere with molecular and cellular processes driving brain development, including epigenetic processes such as DNA methylation. Hence, identification of DNA methylation changes induced by chemical exposure may serve as early molecular markers for developmental neurotoxicity (DNT). Chemicals known as endocrine disruptors (EDCs) can produce adverse effects due to their capability to alter the endocrine system. Since brain development is highly dependent on endocrine signals, the potential adverse effects of EDCs on brain development needs to be addressed. Detection of DNT in the regulatory context has been based on in vivo testing, however, the financial costs and time intensive characteristics of these methods have resulted in a limited assessment of the DNT hazard of chemicals. In addition, in order to regulate EDCs, it is paramount to demonstrate that their adverse effects are a product of disruption of endocrine signals. Yet, at the moment, there are no approved methods which address both an endocrine mode of action and adverse neurodevelopmental outcomes. This doctoral thesis had two main aims: Firstly, to identify epigenetic changes, at the level of DNA methylation, underlying DNT induced by exposure to methylmercury (MeHg); and secondly, to develop new approach methods (NAMs) for the detection of DNT induced by endocrine disruption. Epigenetic effects were studied both in epidemiological data and experimentally in vitro. Associations between prenatal MeHg exposure and DNA methylation of GRIN2B and NR3C1 were found in children. In vitro validation of DNA methylation changes found in epigenome-wide association studies of populations exposed to MeHg, uncovered the potential involvement of the Mediator Complex Subunit 31 (MED31) in MeHg D

Published

2024

10. Novel Endpoints To Unravel Developmental Neurotoxicity : From DNA methylation responses to methylmercury to the in vitro identification of endocrine disruptors

Author

Cediel-Ulloa, Andrea and Cediel-Ulloa, Andrea

Abstract

The developing brain is especially sensitive to environmental stressors due to its dependence on the precise spatiotemporal regulation of multiple signals, and the long time period required for its formation. Some chemicals can interfere with molecular and cellular processes driving brain development, including epigenetic processes such as DNA methylation. Hence, identification of DNA methylation changes induced by chemical exposure may serve as early molecular markers for developmental neurotoxicity (DNT). Chemicals known as endocrine disruptors (EDCs) can produce adverse effects due to their capability to alter the endocrine system. Since brain development is highly dependent on endocrine signals, the potential adverse effects of EDCs on brain development needs to be addressed. Detection of DNT in the regulatory context has been based on in vivo testing, however, the financial costs and time intensive characteristics of these methods have resulted in a limited assessment of the DNT hazard of chemicals. In addition, in order to regulate EDCs, it is paramount to demonstrate that their adverse effects are a product of disruption of endocrine signals. Yet, at the moment, there are no approved methods which address both an endocrine mode of action and adverse neurodevelopmental outcomes. This doctoral thesis had two main aims: Firstly, to identify epigenetic changes, at the level of DNA methylation, underlying DNT induced by exposure to methylmercury (MeHg); and secondly, to develop new approach methods (NAMs) for the detection of DNT induced by endocrine disruption. Epigenetic effects were studied both in epidemiological data and experimentally in vitro. Associations between prenatal MeHg exposure and DNA methylation of GRIN2B and NR3C1 were found in children. In vitro validation of DNA methylation changes found in epigenome-wide association studies of populations exposed to MeHg, uncovered the potential involvement of the Mediator Complex Subunit 31 (MED31) in MeHg D

Published

2024

11. Two thyroperoxidase-inhibiting chemicals induce shared transcriptional changes in hippocampus of developing rats

Author

Ramhøj, Louise, Svingen, Terje, Evrard, Bertrand, Chalmel, Frédéric, Axelstad, Marta, Ramhøj, Louise, Svingen, Terje, Evrard, Bertrand, Chalmel, Frédéric, and Axelstad, Marta

Abstract

Thyroid hormone (TH) system disrupting compounds can impair brain development by perturbing TH action during critical life stages. Human exposure to TH system disrupting chemicals is therefore of great concern. To better protect humans against such chemicals, sensitive test methods that can detect effects on the developing brain are critical. Worryingly, however, current test methods are not sensitive and specific towards TH-mediated effects. To address this shortcoming, we performed RNA-sequencing of rat brains developmentally exposed to two different thyroperoxidase (TPO) inhibiting compounds, the medical drug methimazole (MMI) or the pesticide amitrole. Pregnant and lactating rats were exposed to 8 and 16 mg/kg/day(d) MMI or 25 and 50 mg/kg/d amitrole from gestational day 7 until postnatal day 16. Bulk-RNA-seq was performed on hippocampus from the 16-days old male pups. MMI and amitrole caused pronounced changes to the transcriptomes; 816 genes were differentially expressed, and 425 gene transcripts were similarly affected by both chemicals. Functional terms indicate effects from key cellular functions to changes in cell development, migration and differentiation of several cell populations. Of the total DEGs, 106 DEGs appeared to form a consistent transcriptional fingerprint of developmental hypothyroidism as they were similarly and dose-dependently expressed across all treatment groups. Using a filtering system, we identified 20 genes that appeared to represent the most sensitive, robust and dose-dependent markers of altered TH-mediated brain development. These markers provide inputs to the adverse outcome pathway (AOP) framework where they, in the context of linking TPO inhibiting compounds to adverse cognitive function, can be used to assess altered gene expression in the hippocampus in rat toxicity studies.

Published

2024

12. Perfluorinated chemicals (PFOA) can, by interacting with highly brominated diphenyl ethers (PBDE 209) during a defined period of neonatal brain development, exacerbate neurobehavioural defects

Author

Eriksson, Per, Johansson, Niclas, Viberg, Henrik, Buratovic, Sonja, Fredriksson, Anders, Eriksson, Per, Johansson, Niclas, Viberg, Henrik, Buratovic, Sonja, and Fredriksson, Anders

Abstract

Perfluorinated compounds (PFCs) and polybrominated diphenyl ethers (PBDEs) are ubiquitous persistent environmental compounds, present in humans and at higher levels in infants/children than in adults. This study shows that co-exposure to pentadecafluorooctanoic acid (PFOA) and 2,2 ',3,3 ',4,4 ',5,5 ',6,6'-decaBDE (PBDE 209) can significantly exacerbate developmental neurobehavioural defects. Neonatal male NMRI mice, 3 and 10 days old, were exposed perorally to PBDE 209 (1.4 or 8.0 mu mol/kg bw), PFOA (1.4 or 14 mu mol/kg bw), co-exposed to PBDE 209 and PFOA (at the given doses), or a vehicle (20% fat emulsion) and observed for spontaneous behaviour in a novel home environment when 2 and 4 months old. The behavioural defects observed included hyperactivity and reduced habituation indicating cognitive defects. This interaction appears most likely dependent on the presence of PBDE 209 and/or its metabolites together with PFOA, during a defined critical period of neonatal brain development, corresponding to the perinatal and newborn period in humans.

Published

2023

13. Perfluorinated chemicals (PFOA) can, by interacting with highly brominated diphenyl ethers (PBDE 209) during a defined period of neonatal brain development, exacerbate neurobehavioural defects

Author

Eriksson, Per, Johansson, Niclas, Viberg, Henrik, Buratovic, Sonja, Fredriksson, Anders, Eriksson, Per, Johansson, Niclas, Viberg, Henrik, Buratovic, Sonja, and Fredriksson, Anders

Abstract

Perfluorinated compounds (PFCs) and polybrominated diphenyl ethers (PBDEs) are ubiquitous persistent environmental compounds, present in humans and at higher levels in infants/children than in adults. This study shows that co-exposure to pentadecafluorooctanoic acid (PFOA) and 2,2 ',3,3 ',4,4 ',5,5 ',6,6'-decaBDE (PBDE 209) can significantly exacerbate developmental neurobehavioural defects. Neonatal male NMRI mice, 3 and 10 days old, were exposed perorally to PBDE 209 (1.4 or 8.0 mu mol/kg bw), PFOA (1.4 or 14 mu mol/kg bw), co-exposed to PBDE 209 and PFOA (at the given doses), or a vehicle (20% fat emulsion) and observed for spontaneous behaviour in a novel home environment when 2 and 4 months old. The behavioural defects observed included hyperactivity and reduced habituation indicating cognitive defects. This interaction appears most likely dependent on the presence of PBDE 209 and/or its metabolites together with PFOA, during a defined critical period of neonatal brain development, corresponding to the perinatal and newborn period in humans.

Published

2023

14. Perfluorinated chemicals (PFOA) can, by interacting with highly brominated diphenyl ethers (PBDE 209) during a defined period of neonatal brain development, exacerbate neurobehavioural defects

Author

Eriksson, Per, Johansson, Niclas, Viberg, Henrik, Buratovic, Sonja, Fredriksson, Anders, Eriksson, Per, Johansson, Niclas, Viberg, Henrik, Buratovic, Sonja, and Fredriksson, Anders

Abstract

Perfluorinated compounds (PFCs) and polybrominated diphenyl ethers (PBDEs) are ubiquitous persistent environmental compounds, present in humans and at higher levels in infants/children than in adults. This study shows that co-exposure to pentadecafluorooctanoic acid (PFOA) and 2,2 ',3,3 ',4,4 ',5,5 ',6,6'-decaBDE (PBDE 209) can significantly exacerbate developmental neurobehavioural defects. Neonatal male NMRI mice, 3 and 10 days old, were exposed perorally to PBDE 209 (1.4 or 8.0 mu mol/kg bw), PFOA (1.4 or 14 mu mol/kg bw), co-exposed to PBDE 209 and PFOA (at the given doses), or a vehicle (20% fat emulsion) and observed for spontaneous behaviour in a novel home environment when 2 and 4 months old. The behavioural defects observed included hyperactivity and reduced habituation indicating cognitive defects. This interaction appears most likely dependent on the presence of PBDE 209 and/or its metabolites together with PFOA, during a defined critical period of neonatal brain development, corresponding to the perinatal and newborn period in humans.

Published

2023

15. Perfluorinated chemicals (PFOA) can, by interacting with highly brominated diphenyl ethers (PBDE 209) during a defined period of neonatal brain development, exacerbate neurobehavioural defects

Author

Eriksson, Per, Johansson, Niclas, Viberg, Henrik, Buratovic, Sonja, Fredriksson, Anders, Eriksson, Per, Johansson, Niclas, Viberg, Henrik, Buratovic, Sonja, and Fredriksson, Anders

Abstract

Perfluorinated compounds (PFCs) and polybrominated diphenyl ethers (PBDEs) are ubiquitous persistent environmental compounds, present in humans and at higher levels in infants/children than in adults. This study shows that co-exposure to pentadecafluorooctanoic acid (PFOA) and 2,2 ',3,3 ',4,4 ',5,5 ',6,6'-decaBDE (PBDE 209) can significantly exacerbate developmental neurobehavioural defects. Neonatal male NMRI mice, 3 and 10 days old, were exposed perorally to PBDE 209 (1.4 or 8.0 mu mol/kg bw), PFOA (1.4 or 14 mu mol/kg bw), co-exposed to PBDE 209 and PFOA (at the given doses), or a vehicle (20% fat emulsion) and observed for spontaneous behaviour in a novel home environment when 2 and 4 months old. The behavioural defects observed included hyperactivity and reduced habituation indicating cognitive defects. This interaction appears most likely dependent on the presence of PBDE 209 and/or its metabolites together with PFOA, during a defined critical period of neonatal brain development, corresponding to the perinatal and newborn period in humans.

Published

2023

16. Non-disclosure of developmental neurotoxicity studies obstructs the safety assessment of pesticides in the European Union

Author

Mie, Axel, Rudén, Christina, Mie, Axel, and Rudén, Christina

Abstract

Background In the European Union (EU), the safety assessment of plant protection products relies to a large extent on toxicity studies commissioned by the companies producing them. By law, all performed studies must be included in the dossier submitted to authorities when applying for approval or renewal of the active substance. Methods For one type of toxicity, i.e. developmental neurotoxicity (DNT), we evaluated if studies submitted to the U.S. Environmental Protection Agency (EPA) had also been disclosed to EU authorities. Results We identified 35 DNT studies submitted to the U.S. EPA and with the corresponding EU dossiers available. Of these, 9 DNT studies (26%) were not disclosed by the pesticide company to EU authorities. For 7 of these studies, we have identified an actual or potential regulatory impact. Conclusions We conclude that (1) non-disclosure of DNT studies to EU authorities, in spite of clear legal requirements, seems to be a recurring phenomenon, (2) the non-disclosure may introduce a bias in the regulatory risk assessment, and (3) without full access to all performed toxicity studies, there can be no reliable safety evaluation of pesticides by EU authorities. We suggest that EU authorities should cross-check their data sets with their counterparts in other jurisdictions. In addition, applications for pesticide approval should be cross-checked against lists of studies performed at test facilities operating under Good Laboratory Practice (GLP), to ensure that all studies have been submitted to authorities. Furthermore, rules should be amended so that future studies should be commissioned by authorities rather than companies. This ensures the authorities’ knowledge of existing studies and prevents the economic interest of the company from influencing the design, performance, reporting and dissemination of studies. The rules or practices should also be revised to ensure that non-disclosure of toxicity studies carries a significant legal risk for pesti

Published

2023

17. Evaluation of mRNA markers in differentiating human SH-SY5Y cells for estimation of developmental neurotoxicity

Author

Hinojosa, M. G., Johansson, Y., Cediel Ulloa, Andrea, Ivanova, E., Gabring, N., Gliga, A., Forsby, A., Hinojosa, M. G., Johansson, Y., Cediel Ulloa, Andrea, Ivanova, E., Gabring, N., Gliga, A., and Forsby, A.

Abstract

Current guidelines for developmental neurotoxicity (DNT) evaluation are based on animal models. These have limitations so more relevant, efficient and robust approaches for DNT assessment are needed. We have used the human SH-SY5Y neuroblastoma cell model to evaluate a panel of 93 mRNA markers that are frequent in Neuronal diseases and functional annotations and also differentially expressed during retinoic acid-induced differentiation in the cell model. Rotenone, valproic acid (VPA), acrylamide (ACR) and methylmercury chlo-ride (MeHg) were used as DNT positive compounds. Tolbutamide, D-mannitol and clofibrate were used as DNT negative compounds. To determine concentrations for exposure for gene expression analysis, we developed a pipeline for neurite outgrowth assessment by live-cell imaging. In addition, cell viability was measured by the resazurin assay. Gene expression was analyzed by RT-qPCR after 6 days of exposure during differentiation to concentrations of the DNT positive compounds that affected neurite outgrowth, but with no or minimal effect on cell viability. Methylmercury affected cell viability at lower concentrations than neurite outgrowth, hence the cells were exposed with the highest non-cytotoxic concentration. Rotenone (7.3 nM) induced 32 differentially expressed genes (DEGs), ACR (70 mu M) 8 DEGs, and VPA (75 mu M) 16 DEGs. No individual genes were significantly dysregulated by all 3 DNT positive compounds (p < 0.05), but 9 genes were differentially expressed by 2 of them. Methylmercury (0.8 nM) was used to validate the 9 DEGs. The expression of SEMA5A (encoding semaphorin 5A) and CHRNA7 (encoding nicotinic acetylcholine receptor subunit alpha 7) was downregulated by all 4 DNT positive compounds. None of the DNT negative compounds dysregulated any of the 9 DEGs in common for the DNT positive compounds. We suggest that SEMA5A or CHRNA7 should be further evaluated as biomarkers for DNT studies in vitro since they also are involved in neurodevelo

Published

2023

18. Evaluation of mRNA markers in differentiating human SH-SY5Y cells for estimation of developmental neurotoxicity

Author

Hinojosa, M. G., Johansson, Y., Cediel Ulloa, Andrea, Ivanova, E., Gabring, N., Gliga, A., Forsby, A., Hinojosa, M. G., Johansson, Y., Cediel Ulloa, Andrea, Ivanova, E., Gabring, N., Gliga, A., and Forsby, A.

Abstract

Current guidelines for developmental neurotoxicity (DNT) evaluation are based on animal models. These have limitations so more relevant, efficient and robust approaches for DNT assessment are needed. We have used the human SH-SY5Y neuroblastoma cell model to evaluate a panel of 93 mRNA markers that are frequent in Neuronal diseases and functional annotations and also differentially expressed during retinoic acid-induced differentiation in the cell model. Rotenone, valproic acid (VPA), acrylamide (ACR) and methylmercury chlo-ride (MeHg) were used as DNT positive compounds. Tolbutamide, D-mannitol and clofibrate were used as DNT negative compounds. To determine concentrations for exposure for gene expression analysis, we developed a pipeline for neurite outgrowth assessment by live-cell imaging. In addition, cell viability was measured by the resazurin assay. Gene expression was analyzed by RT-qPCR after 6 days of exposure during differentiation to concentrations of the DNT positive compounds that affected neurite outgrowth, but with no or minimal effect on cell viability. Methylmercury affected cell viability at lower concentrations than neurite outgrowth, hence the cells were exposed with the highest non-cytotoxic concentration. Rotenone (7.3 nM) induced 32 differentially expressed genes (DEGs), ACR (70 mu M) 8 DEGs, and VPA (75 mu M) 16 DEGs. No individual genes were significantly dysregulated by all 3 DNT positive compounds (p < 0.05), but 9 genes were differentially expressed by 2 of them. Methylmercury (0.8 nM) was used to validate the 9 DEGs. The expression of SEMA5A (encoding semaphorin 5A) and CHRNA7 (encoding nicotinic acetylcholine receptor subunit alpha 7) was downregulated by all 4 DNT positive compounds. None of the DNT negative compounds dysregulated any of the 9 DEGs in common for the DNT positive compounds. We suggest that SEMA5A or CHRNA7 should be further evaluated as biomarkers for DNT studies in vitro since they also are involved in neurodevelo

Published

2023

19. Evaluation of mRNA markers in differentiating human SH-SY5Y cells for estimation of developmental neurotoxicity

Author

Hinojosa, M. G., Johansson, Y., Cediel Ulloa, Andrea, Ivanova, E., Gabring, N., Gliga, A., Forsby, A., Hinojosa, M. G., Johansson, Y., Cediel Ulloa, Andrea, Ivanova, E., Gabring, N., Gliga, A., and Forsby, A.

Abstract

Current guidelines for developmental neurotoxicity (DNT) evaluation are based on animal models. These have limitations so more relevant, efficient and robust approaches for DNT assessment are needed. We have used the human SH-SY5Y neuroblastoma cell model to evaluate a panel of 93 mRNA markers that are frequent in Neuronal diseases and functional annotations and also differentially expressed during retinoic acid-induced differentiation in the cell model. Rotenone, valproic acid (VPA), acrylamide (ACR) and methylmercury chlo-ride (MeHg) were used as DNT positive compounds. Tolbutamide, D-mannitol and clofibrate were used as DNT negative compounds. To determine concentrations for exposure for gene expression analysis, we developed a pipeline for neurite outgrowth assessment by live-cell imaging. In addition, cell viability was measured by the resazurin assay. Gene expression was analyzed by RT-qPCR after 6 days of exposure during differentiation to concentrations of the DNT positive compounds that affected neurite outgrowth, but with no or minimal effect on cell viability. Methylmercury affected cell viability at lower concentrations than neurite outgrowth, hence the cells were exposed with the highest non-cytotoxic concentration. Rotenone (7.3 nM) induced 32 differentially expressed genes (DEGs), ACR (70 mu M) 8 DEGs, and VPA (75 mu M) 16 DEGs. No individual genes were significantly dysregulated by all 3 DNT positive compounds (p < 0.05), but 9 genes were differentially expressed by 2 of them. Methylmercury (0.8 nM) was used to validate the 9 DEGs. The expression of SEMA5A (encoding semaphorin 5A) and CHRNA7 (encoding nicotinic acetylcholine receptor subunit alpha 7) was downregulated by all 4 DNT positive compounds. None of the DNT negative compounds dysregulated any of the 9 DEGs in common for the DNT positive compounds. We suggest that SEMA5A or CHRNA7 should be further evaluated as biomarkers for DNT studies in vitro since they also are involved in neurodevelo

Published

2023

20. Evaluation of mRNA markers in differentiating human SH-SY5Y cells for estimation of developmental neurotoxicity

Author

Hinojosa, M. G., Johansson, Y., Cediel Ulloa, Andrea, Ivanova, E., Gabring, N., Gliga, A., Forsby, A., Hinojosa, M. G., Johansson, Y., Cediel Ulloa, Andrea, Ivanova, E., Gabring, N., Gliga, A., and Forsby, A.

Abstract

Current guidelines for developmental neurotoxicity (DNT) evaluation are based on animal models. These have limitations so more relevant, efficient and robust approaches for DNT assessment are needed. We have used the human SH-SY5Y neuroblastoma cell model to evaluate a panel of 93 mRNA markers that are frequent in Neuronal diseases and functional annotations and also differentially expressed during retinoic acid-induced differentiation in the cell model. Rotenone, valproic acid (VPA), acrylamide (ACR) and methylmercury chlo-ride (MeHg) were used as DNT positive compounds. Tolbutamide, D-mannitol and clofibrate were used as DNT negative compounds. To determine concentrations for exposure for gene expression analysis, we developed a pipeline for neurite outgrowth assessment by live-cell imaging. In addition, cell viability was measured by the resazurin assay. Gene expression was analyzed by RT-qPCR after 6 days of exposure during differentiation to concentrations of the DNT positive compounds that affected neurite outgrowth, but with no or minimal effect on cell viability. Methylmercury affected cell viability at lower concentrations than neurite outgrowth, hence the cells were exposed with the highest non-cytotoxic concentration. Rotenone (7.3 nM) induced 32 differentially expressed genes (DEGs), ACR (70 mu M) 8 DEGs, and VPA (75 mu M) 16 DEGs. No individual genes were significantly dysregulated by all 3 DNT positive compounds (p < 0.05), but 9 genes were differentially expressed by 2 of them. Methylmercury (0.8 nM) was used to validate the 9 DEGs. The expression of SEMA5A (encoding semaphorin 5A) and CHRNA7 (encoding nicotinic acetylcholine receptor subunit alpha 7) was downregulated by all 4 DNT positive compounds. None of the DNT negative compounds dysregulated any of the 9 DEGs in common for the DNT positive compounds. We suggest that SEMA5A or CHRNA7 should be further evaluated as biomarkers for DNT studies in vitro since they also are involved in neurodevelo

Published

2023

21. A case study of neurodevelopmental risks from combined exposures to lead, methyl-mercury, inorganic arsenic, polychlorinated biphenyls, polybrominated diphenyl ethers and fluoride

Author

Sprong, Corinne, te Biesebeek, Jan Dirk, Chatterjee, Mousumi, Wolterink, Gerrit, van den Brand, Annick, Blaznik, Urska, Christodoulou, Despo, Crépet, Amélie, Jensen, Bodil Hamborg, Sokolićg, Darja, Rauscher-Gabernig, Elke, Ruprich, Jiri, Kortenkamp, Andreas, van Klaveren, Jacob, Sprong, Corinne, te Biesebeek, Jan Dirk, Chatterjee, Mousumi, Wolterink, Gerrit, van den Brand, Annick, Blaznik, Urska, Christodoulou, Despo, Crépet, Amélie, Jensen, Bodil Hamborg, Sokolićg, Darja, Rauscher-Gabernig, Elke, Ruprich, Jiri, Kortenkamp, Andreas, and van Klaveren, Jacob

Abstract

We performed a mixture risk assessment (MRA) case study of dietary exposure to the food contaminants lead, methylmercury, inorganic arsenic (iAs), fluoride, non-dioxin-like polychlorinated biphenyls (NDL-PCBs) and polybrominated diphenyl ethers (PBDEs), all substances associated with declines in cognitive abilities measured as IQ loss. Most of these chemicals are frequently measured in human biomonitoring studies. A component-based, personalised modified reference point index (mRPI) approach, in which we expressed the exposures and potencies of our chosen substances as lead equivalent values, was applied to perform a MRA for dietary exposures. We conducted the assessment for four different age groups (toddlers, children, adolescents, and women aged 18–45 years) in nine European countries. Populations in all countries considered exceeded combined tolerable levels at median exposure levels. NDL-PCBs in fish, other seafood and dairy, lead in grains and fruits, methylmercury in fish and other seafoods, and fluoride in water contributed most to the combined exposure. We identified uncertainties for the likelihood of co-exposure, assessment group membership, endpoint-specific reference values (ESRVs) based on epidemiological (lead, methylmercury, iAs, fluoride and NDL-PCBs) and animal data (PBDE), and exposure data. Those uncertainties lead to a complex pattern of under- and overestimations, which would require probabilistic modelling based on expert knowledge elicitation for integration of the identified uncertainties into an overall uncertainty estimate. In addition, the identified uncertainties could be used to refine future MRA for cognitive decline.

Published

2023

22. Is periventricular heterotopia a useful endpoint for developmental thyroid hormone system disruption in mouse toxicity studies?

Author

Ramhøj, Louise, Guyot, Romain, Svingen, Terje, Kortenkamp, Andreas, Flamant, Frédéric, Axelstad, Marta, Ramhøj, Louise, Guyot, Romain, Svingen, Terje, Kortenkamp, Andreas, Flamant, Frédéric, and Axelstad, Marta

Abstract

In rats, hypothyroidism during fetal and neonatal development can disrupt neuronal migration and induce the formation of periventricular heterotopia in the brain. However, it remains uncertain if heterotopia also manifest in mice after developmental hypothyroidism and whether they could be used as a toxicological endpoint to detect TH-mediated effects caused by TH system disrupting chemicals. Here, we performed a mouse study where we induced severe hypothyroidism by exposing pregnant mice (n = 3) to a very high dose of propylthiouracil (PTU) (1500 ppm) in the diet. This, to obtain best chances of detecting heterotopia. We found what appears to be very small heterotopia in 4 out of the 8 PTU-exposed pups. Although the incidence rate could suggest some utility for this endpoint, the small size of the ectopic neuronal clusters at maximum hypothyroidism excludes the utility of heterotopia in mouse toxicity studies aimed to detect TH system disrupting chemicals. On the other hand, parvalbumin expression was manifestly lower in the cortex of hypothyroid mouse offspring demonstrating that offspring TH-deficiency caused an effect on the developing brain. Based on overall results, we conclude that heterotopia formation in mice is not a useful toxicological endpoint for examining TH-mediated developmental neurotoxicity.

Published

2023

23. Evaluation of mRNA markers in differentiating human SH-SY5Y cells for estimation of developmental neurotoxicity

Author

Hinojosa, M. G., Johansson, Y., Cediel Ulloa, Andrea, Ivanova, E., Gabring, N., Gliga, A., Forsby, A., Hinojosa, M. G., Johansson, Y., Cediel Ulloa, Andrea, Ivanova, E., Gabring, N., Gliga, A., and Forsby, A.

Abstract

Current guidelines for developmental neurotoxicity (DNT) evaluation are based on animal models. These have limitations so more relevant, efficient and robust approaches for DNT assessment are needed. We have used the human SH-SY5Y neuroblastoma cell model to evaluate a panel of 93 mRNA markers that are frequent in Neuronal diseases and functional annotations and also differentially expressed during retinoic acid-induced differentiation in the cell model. Rotenone, valproic acid (VPA), acrylamide (ACR) and methylmercury chlo-ride (MeHg) were used as DNT positive compounds. Tolbutamide, D-mannitol and clofibrate were used as DNT negative compounds. To determine concentrations for exposure for gene expression analysis, we developed a pipeline for neurite outgrowth assessment by live-cell imaging. In addition, cell viability was measured by the resazurin assay. Gene expression was analyzed by RT-qPCR after 6 days of exposure during differentiation to concentrations of the DNT positive compounds that affected neurite outgrowth, but with no or minimal effect on cell viability. Methylmercury affected cell viability at lower concentrations than neurite outgrowth, hence the cells were exposed with the highest non-cytotoxic concentration. Rotenone (7.3 nM) induced 32 differentially expressed genes (DEGs), ACR (70 mu M) 8 DEGs, and VPA (75 mu M) 16 DEGs. No individual genes were significantly dysregulated by all 3 DNT positive compounds (p < 0.05), but 9 genes were differentially expressed by 2 of them. Methylmercury (0.8 nM) was used to validate the 9 DEGs. The expression of SEMA5A (encoding semaphorin 5A) and CHRNA7 (encoding nicotinic acetylcholine receptor subunit alpha 7) was downregulated by all 4 DNT positive compounds. None of the DNT negative compounds dysregulated any of the 9 DEGs in common for the DNT positive compounds. We suggest that SEMA5A or CHRNA7 should be further evaluated as biomarkers for DNT studies in vitro since they also are involved in neurodevelo

Published

2023

24. Perfluorinated chemicals (PFOA) can, by interacting with highly brominated diphenyl ethers (PBDE 209) during a defined period of neonatal brain development, exacerbate neurobehavioural defects

Author

Eriksson, Per, Johansson, Niclas, Viberg, Henrik, Buratovic, Sonja, Fredriksson, Anders, Eriksson, Per, Johansson, Niclas, Viberg, Henrik, Buratovic, Sonja, and Fredriksson, Anders

Abstract

Perfluorinated compounds (PFCs) and polybrominated diphenyl ethers (PBDEs) are ubiquitous persistent environmental compounds, present in humans and at higher levels in infants/children than in adults. This study shows that co-exposure to pentadecafluorooctanoic acid (PFOA) and 2,2 ',3,3 ',4,4 ',5,5 ',6,6'-decaBDE (PBDE 209) can significantly exacerbate developmental neurobehavioural defects. Neonatal male NMRI mice, 3 and 10 days old, were exposed perorally to PBDE 209 (1.4 or 8.0 mu mol/kg bw), PFOA (1.4 or 14 mu mol/kg bw), co-exposed to PBDE 209 and PFOA (at the given doses), or a vehicle (20% fat emulsion) and observed for spontaneous behaviour in a novel home environment when 2 and 4 months old. The behavioural defects observed included hyperactivity and reduced habituation indicating cognitive defects. This interaction appears most likely dependent on the presence of PBDE 209 and/or its metabolites together with PFOA, during a defined critical period of neonatal brain development, corresponding to the perinatal and newborn period in humans.

Published

2023

25. What you don’t know can still hurt you - underreporting in EU pesticide regulation

Author

Mie, Axel, Rudén, Christina, Mie, Axel, and Rudén, Christina

Abstract

The safety evaluation of pesticides in the European Union (EU) relies to a large extent on toxicity studies commissioned and funded by the industry. The herbicide glyphosate and four of its salts are currently under evaluation for renewed market approval in the EU. The safety documentation submitted by the applicant companies does not include any animal study regarding developmental neurotoxicity (DNT) that is compliant with test guidelines. For a fifth salt, not included in the present application for re-approval, such a DNT study was sponsored by one of the applicant companies in 2001. That study shows an effect of that form of glyphosate on a neurobehavioural function, motor activity, in rat offspring at a dose previously not known to cause adverse effects. Counter to regulatory requirements, these effects were apparently not communicated to authorities in EU countries where that form of glyphosate was authorised at that time. That DNT study may also be relevant for the ongoing assessment of glyphosate but was not included in the present or previous applications for re-approval. In this commentary, we highlight that it is the responsibility of the industry to evaluate and ensure the safety of their products, taking all available scientific knowledge into account. We argue that the legal obligation for industry to submit all potentially relevant data to EU authorities is clear and far-reaching, but that these obligations were not fulfilled in this case. We claim that authorities cannot reliably pursue a high level of protection of human health, if potentially relevant evidence is withheld from them. We suggest that a retrospective cross-check of lists of studies performed by test laboratories against studies submitted to regulatory authorities should be performed, in order to investigate the completeness of data submitted to authorities. We further suggest that future toxicity studies should be commissioned by authorities rather than by companies, to improve the a

Published

2022

26. Impact of endocrine disrupting chemicals on neurodevelopment : the need for better testing strategies for endocrine disruption-induced developmental neurotoxicity

Author

Cediel-Ulloa, Andrea, Lupu, Diana Loana, Johansson, Ylva, Hinojosa, Maria, Özel, Fatih, Rüegg, Joëlle, Cediel-Ulloa, Andrea, Lupu, Diana Loana, Johansson, Ylva, Hinojosa, Maria, Özel, Fatih, and Rüegg, Joëlle

Abstract

Introduction: Brain development is highly dependent on hormonal regulation. Exposure to chemicals disrupting endocrine signaling has been associated with neurodevelopmental impairment. This raises concern about exposure to the suspected thousands of endocrine disruptors, and has resulted in efforts to improve regulation of these chemicals. Yet, the causal links between endocrine disruption and developmental neurotoxicity, which would be required for regulatory action, are still largely missing. Areas covered: In this review, we illustrate the importance of two endocrine systems, thyroid hormone and retinoic acid pathways, for neurodevelopment. We place special emphasis on TH and RA synthesis, metabolism, and how endocrine disrupting chemicals known or suspected to affect these systems are associated with developmental neurotoxicity. Expert opinion: While it is clear that neurodevelopment is dependent on proper hormonal functioning, and evidence is increasing for developmental neurotoxicity induced by endocrine disrupting chemicals, this is not grasped by current chemical testing. Thus, there is an urgent need to develop test methods detecting endocrine disruption in the context of neurodevelopment. Key to this development is further mechanistic insights on the involvement of endocrine signaling in neurodevelopment as well as increased support to develop and validate new test methods for the regulatory context.

Published

2022

27. Impact of endocrine disrupting chemicals on neurodevelopment : the need for better testing strategies for endocrine disruption-induced developmental neurotoxicity

Author

Cediel Ulloa, Andrea, Lupu, Diana, Johansson, Ylva, Hinojosa, Maria, Ozel, Fatih, Rüegg, Joëlle, Cediel Ulloa, Andrea, Lupu, Diana, Johansson, Ylva, Hinojosa, Maria, Ozel, Fatih, and Rüegg, Joëlle

Abstract

Introduction: Brain development is highly dependent on hormonal regulation. Exposure to chemicals disrupting endocrine signaling has been associated with neurodevelopmental impairment. This raises concern about exposure to the suspected thousands of endocrine disruptors, and has resulted in efforts to improve regulation of these chemicals. Yet, the causal links between endocrine disruption and developmental neurotoxicity, which would be required for regulatory action, are still largely missing. Areas covered: In this review, we illustrate the importance of two endocrine systems, thyroid hormone and retinoic acid pathways, for neurodevelopment. We place special emphasis on TH and RA synthesis, metabolism, and how endocrine disrupting chemicals known or suspected to affect these systems are associated with developmental neurotoxicity. Expert opinion: While it is clear that neurodevelopment is dependent on proper hormonal functioning, and evidence is increasing for developmental neurotoxicity induced by endocrine disrupting chemicals, this is not grasped by current chemical testing. Thus, there is an urgent need to develop test methods detecting endocrine disruption in the context of neurodevelopment. Key to this development is further mechanistic insights on the involvement of endocrine signaling in neurodevelopment as well as increased support to develop and validate new test methods for the regulatory context.

Published

2022

28. Impact of endocrine disrupting chemicals on neurodevelopment : the need for better testing strategies for endocrine disruption-induced developmental neurotoxicity

Author

Cediel Ulloa, Andrea, Lupu, Diana, Johansson, Ylva, Hinojosa, Maria, Ozel, Fatih, Rüegg, Joëlle, Cediel Ulloa, Andrea, Lupu, Diana, Johansson, Ylva, Hinojosa, Maria, Ozel, Fatih, and Rüegg, Joëlle

Abstract

Introduction: Brain development is highly dependent on hormonal regulation. Exposure to chemicals disrupting endocrine signaling has been associated with neurodevelopmental impairment. This raises concern about exposure to the suspected thousands of endocrine disruptors, and has resulted in efforts to improve regulation of these chemicals. Yet, the causal links between endocrine disruption and developmental neurotoxicity, which would be required for regulatory action, are still largely missing. Areas covered: In this review, we illustrate the importance of two endocrine systems, thyroid hormone and retinoic acid pathways, for neurodevelopment. We place special emphasis on TH and RA synthesis, metabolism, and how endocrine disrupting chemicals known or suspected to affect these systems are associated with developmental neurotoxicity. Expert opinion: While it is clear that neurodevelopment is dependent on proper hormonal functioning, and evidence is increasing for developmental neurotoxicity induced by endocrine disrupting chemicals, this is not grasped by current chemical testing. Thus, there is an urgent need to develop test methods detecting endocrine disruption in the context of neurodevelopment. Key to this development is further mechanistic insights on the involvement of endocrine signaling in neurodevelopment as well as increased support to develop and validate new test methods for the regulatory context.

Published

2022

29. Impact of endocrine disrupting chemicals on neurodevelopment : the need for better testing strategies for endocrine disruption-induced developmental neurotoxicity

Author

Cediel-Ulloa, Andrea, Lupu, Diana Loana, Johansson, Ylva, Hinojosa, Maria, Özel, Faith, Rüegg, Joëlle, Cediel-Ulloa, Andrea, Lupu, Diana Loana, Johansson, Ylva, Hinojosa, Maria, Özel, Faith, and Rüegg, Joëlle

Abstract

Introduction: Brain development is highly dependent on hormonal regulation. Exposure to chemicals disrupting endocrine signaling has been associated with neurodevelopmental impairment. This raises concern about exposure to the suspected thousands of endocrine disruptors, and has resulted in efforts to improve regulation of these chemicals. Yet, the causal links between endocrine disruption and developmental neurotoxicity, which would be required for regulatory action, are still largely missing. Areas covered: In this review, we illustrate the importance of two endocrine systems, thyroid hormone and retinoic acid pathways, for neurodevelopment. We place special emphasis on TH and RA synthesis, metabolism, and how endocrine disrupting chemicals known or suspected to affect these systems are associated with developmental neurotoxicity. Expert opinion: While it is clear that neurodevelopment is dependent on proper hormonal functioning, and evidence is increasing for developmental neurotoxicity induced by endocrine disrupting chemicals, this is not grasped by current chemical testing. Thus, there is an urgent need to develop test methods detecting endocrine disruption in the context of neurodevelopment. Key to this development is further mechanistic insights on the involvement of endocrine signaling in neurodevelopment as well as increased support to develop and validate new test methods for the regulatory context.

Published

2022

30. Impact of endocrine disrupting chemicals on neurodevelopment : the need for better testing strategies for endocrine disruption-induced developmental neurotoxicity

Author

Cediel-Ulloa, Andrea, Lupu, Diana Loana, Johansson, Ylva, Hinojosa, Maria, Özel, Faith, Rüegg, Joëlle, Cediel-Ulloa, Andrea, Lupu, Diana Loana, Johansson, Ylva, Hinojosa, Maria, Özel, Faith, and Rüegg, Joëlle

Abstract

Introduction: Brain development is highly dependent on hormonal regulation. Exposure to chemicals disrupting endocrine signaling has been associated with neurodevelopmental impairment. This raises concern about exposure to the suspected thousands of endocrine disruptors, and has resulted in efforts to improve regulation of these chemicals. Yet, the causal links between endocrine disruption and developmental neurotoxicity, which would be required for regulatory action, are still largely missing. Areas covered: In this review, we illustrate the importance of two endocrine systems, thyroid hormone and retinoic acid pathways, for neurodevelopment. We place special emphasis on TH and RA synthesis, metabolism, and how endocrine disrupting chemicals known or suspected to affect these systems are associated with developmental neurotoxicity. Expert opinion: While it is clear that neurodevelopment is dependent on proper hormonal functioning, and evidence is increasing for developmental neurotoxicity induced by endocrine disrupting chemicals, this is not grasped by current chemical testing. Thus, there is an urgent need to develop test methods detecting endocrine disruption in the context of neurodevelopment. Key to this development is further mechanistic insights on the involvement of endocrine signaling in neurodevelopment as well as increased support to develop and validate new test methods for the regulatory context.

Published

2022

31. Impact of endocrine disrupting chemicals on neurodevelopment : the need for better testing strategies for endocrine disruption-induced developmental neurotoxicity

Author

Cediel Ulloa, Andrea, Lupu, Diana, Johansson, Ylva, Hinojosa, Maria, Ozel, Fatih, Rüegg, Joëlle, Cediel Ulloa, Andrea, Lupu, Diana, Johansson, Ylva, Hinojosa, Maria, Ozel, Fatih, and Rüegg, Joëlle

Abstract

Introduction: Brain development is highly dependent on hormonal regulation. Exposure to chemicals disrupting endocrine signaling has been associated with neurodevelopmental impairment. This raises concern about exposure to the suspected thousands of endocrine disruptors, and has resulted in efforts to improve regulation of these chemicals. Yet, the causal links between endocrine disruption and developmental neurotoxicity, which would be required for regulatory action, are still largely missing. Areas covered: In this review, we illustrate the importance of two endocrine systems, thyroid hormone and retinoic acid pathways, for neurodevelopment. We place special emphasis on TH and RA synthesis, metabolism, and how endocrine disrupting chemicals known or suspected to affect these systems are associated with developmental neurotoxicity. Expert opinion: While it is clear that neurodevelopment is dependent on proper hormonal functioning, and evidence is increasing for developmental neurotoxicity induced by endocrine disrupting chemicals, this is not grasped by current chemical testing. Thus, there is an urgent need to develop test methods detecting endocrine disruption in the context of neurodevelopment. Key to this development is further mechanistic insights on the involvement of endocrine signaling in neurodevelopment as well as increased support to develop and validate new test methods for the regulatory context.

Published

2022

32. Impact of endocrine disrupting chemicals on neurodevelopment : the need for better testing strategies for endocrine disruption-induced developmental neurotoxicity

Author

Cediel Ulloa, Andrea, Lupu, Diana, Johansson, Ylva, Hinojosa, Maria, Ozel, Fatih, Rüegg, Joëlle, Cediel Ulloa, Andrea, Lupu, Diana, Johansson, Ylva, Hinojosa, Maria, Ozel, Fatih, and Rüegg, Joëlle

Abstract

Introduction: Brain development is highly dependent on hormonal regulation. Exposure to chemicals disrupting endocrine signaling has been associated with neurodevelopmental impairment. This raises concern about exposure to the suspected thousands of endocrine disruptors, and has resulted in efforts to improve regulation of these chemicals. Yet, the causal links between endocrine disruption and developmental neurotoxicity, which would be required for regulatory action, are still largely missing. Areas covered: In this review, we illustrate the importance of two endocrine systems, thyroid hormone and retinoic acid pathways, for neurodevelopment. We place special emphasis on TH and RA synthesis, metabolism, and how endocrine disrupting chemicals known or suspected to affect these systems are associated with developmental neurotoxicity. Expert opinion: While it is clear that neurodevelopment is dependent on proper hormonal functioning, and evidence is increasing for developmental neurotoxicity induced by endocrine disrupting chemicals, this is not grasped by current chemical testing. Thus, there is an urgent need to develop test methods detecting endocrine disruption in the context of neurodevelopment. Key to this development is further mechanistic insights on the involvement of endocrine signaling in neurodevelopment as well as increased support to develop and validate new test methods for the regulatory context.

Published

2022

33. Mixture risk assessment of complex real-life mixtures—The PANORAMIX project

Author

Escher, Beate, Lamoree, M., Antignac, J.-P., Scholze, M., Herzler, M., Hamers, T., Jensen, T.K., Audebert, M., Busquet, F., Maier, D., Oelgeschläger, M., Valente, M.J., Boye, H., Schmeisser, S., Dervilly, G., Piumatti, M., Motteau, S., König, Maria, Renko, K., Margalef, M., Cariou, R., Ma, Y., Treschow, A.F., Kortenkamp, A., Vinggaard, A.M., Escher, Beate, Lamoree, M., Antignac, J.-P., Scholze, M., Herzler, M., Hamers, T., Jensen, T.K., Audebert, M., Busquet, F., Maier, D., Oelgeschläger, M., Valente, M.J., Boye, H., Schmeisser, S., Dervilly, G., Piumatti, M., Motteau, S., König, Maria, Renko, K., Margalef, M., Cariou, R., Ma, Y., Treschow, A.F., Kortenkamp, A., and Vinggaard, A.M.

Abstract

Humans are involuntarily exposed to hundreds of chemicals that either contaminate our environment and food or are added intentionally to our daily products. These complex mixtures of chemicals may pose a risk to human health. One of the goals of the European Union’s Green Deal and zero-pollution ambition for a toxic-free environment is to tackle the existent gaps in chemical mixture risk assessment by providing scientific grounds that support the implementation of adequate regulatory measures within the EU. We suggest dealing with this challenge by: (1) characterising ‘real-life’ chemical mixtures and determining to what extent they are transferred from the environment to humans via food and water, and from the mother to the foetus; (2) establishing a high-throughput whole-mixture-based in vitro strategy for screening of real-life complex mixtures of organic chemicals extracted from humans using integrated chemical profiling (suspect screening) together with effect-directed analysis; (3) evaluating which human blood levels of chemical mixtures might be of concern for children’s development; and (4) developing a web-based, ready-to-use interface that integrates hazard and exposure data to enable component-based mixture risk estimation. These concepts form the basis of the Green Deal project PANORAMIX, whose ultimate goal is to progress mixture risk assessment of chemicals.

Published

2022

34. Inhibition of neurite outgrowth and enhanced effects compared to baseline toxicity in SH-SY5Y cells

Author

Lee, Jungeun, Escher, Beate, Scholz, Stefan, Schlichting, Rita, Lee, Jungeun, Escher, Beate, Scholz, Stefan, and Schlichting, Rita

Abstract

Early life exposure to environmental chemicals can cause developmental neurotoxicity (DNT). The impairment of key neurodevelopmental processes such as neurite outgrowth inhibition can be used as endpoints for screening of DNT effects. We quantified neurite-specific effects using the ratio of effect concentrations for cytotoxicity and neurite outgrowth inhibition (SRcytotoxicity). Baseline cytotoxicity, the minimal toxicity of any chemical, was used to quantify enhanced cytotoxicity (toxic ratio, TR) and neuronal-specific toxicity (SRbaseline) by comparing baseline cytotoxicity with the effects on cell viability and neurite outgrowth, respectively. The effects on cell viability and neurite length were measured based on image analysis in human neuroblastoma SH-SY5Y cells. Baseline cytotoxicity was predicted from hydrophobicity descriptors using a previously published model for SH-SY5Y cells. Enhanced cytotoxicity and neuronal-specific toxicity were more often observed for hydrophilic chemicals, which indicates that they are more likely to act through specific modes of action (MOA) on cell viability and neurite outgrowth. Hydrophobic chemicals showed a tendency to act through baseline toxicity without showing specific or enhanced toxicity, but were highly potent considering their low effect concentrations for both cytotoxicity and neurite outgrowth inhibition. The endpoint-specific controls (narciclasine, colchicine, cycloheximide, and rotenone), two carbamates (3-hydroxycarbofuran and carbaryl), and two redox cyclers (diquat and paraquat) showed distinct neurite-specific effects (SRcytotoxicity > 4). By comparing neurite-specific effects with enhanced cytotoxicity, one can explain whether the observed effects involve specific inhibition of neurite outgrowth, other specific MOAs, or merely baseline toxicity arising from hydrophobicity.

Published

2022

35. Mixture Risk Assessment of Complex Real-Life Mixtures—The PANORAMIX Project

Author

Escher, Beate I., Lamoree, Marja, Antignac, Jean-Philippe, Scholze, Martin, Herzler, Matthias, Hamers, Timo, Jensen, Tina Kold, Audebert, Marc, Busquet, Francois, Maier, Dieter, Oelgeschläger, Michael, Valente, Maria João, Boye, Henriette, Schmeisser, Sebastian, Dervilly, Gaud, Piumatti, Matteo, Motteau, Soléne, König, Maria, Renko, Kostja, Margalef, Maria, Cariou, Ronan, Ma, Yanying, Treschow, Andreas Frederik, Kortenkamp, Andreas, Vinggaard, Anne Marie, Escher, Beate I., Lamoree, Marja, Antignac, Jean-Philippe, Scholze, Martin, Herzler, Matthias, Hamers, Timo, Jensen, Tina Kold, Audebert, Marc, Busquet, Francois, Maier, Dieter, Oelgeschläger, Michael, Valente, Maria João, Boye, Henriette, Schmeisser, Sebastian, Dervilly, Gaud, Piumatti, Matteo, Motteau, Soléne, König, Maria, Renko, Kostja, Margalef, Maria, Cariou, Ronan, Ma, Yanying, Treschow, Andreas Frederik, Kortenkamp, Andreas, and Vinggaard, Anne Marie

Abstract

Humans are involuntarily exposed to hundreds of chemicals that either contaminate our environment and food or are added intentionally to our daily products. These complex mixtures of chemicals may pose a risk to human health. One of the goals of the European Union’s Green Deal and zero-pollution ambition for a toxic-free environment is to tackle the existent gaps in chemical mixture risk assessment by providing scientific grounds that support the implementation of adequate regulatory measures within the EU. We suggest dealing with this challenge by: (1) characterising ‘real-life’ chemical mixtures and determining to what extent they are transferred from the environment to humans via food and water, and from the mother to the foetus; (2) establishing a high-throughput whole-mixture-based in vitro strategy for screening of real-life complex mixtures of organic chemicals extracted from humans using integrated chemical profiling (suspect screening) together with effect-directed analysis; (3) evaluating which human blood levels of chemical mixtures might be of concern for children’s development; and (4) developing a web-based, ready-to-use interface that integrates hazard and exposure data to enable component-based mixture risk estimation. These concepts form the basis of the Green Deal project PANORAMIX, whose ultimate goal is to progress mixture risk assessment of chemicals.

Published

2022

36. Impact of endocrine disrupting chemicals on neurodevelopment : the need for better testing strategies for endocrine disruption-induced developmental neurotoxicity

Author

Cediel-Ulloa, Andrea, Lupu, Diana Loana, Johansson, Ylva, Hinojosa, Maria, Özel, Faith, Rüegg, Joëlle, Cediel-Ulloa, Andrea, Lupu, Diana Loana, Johansson, Ylva, Hinojosa, Maria, Özel, Faith, and Rüegg, Joëlle

Abstract

Introduction: Brain development is highly dependent on hormonal regulation. Exposure to chemicals disrupting endocrine signaling has been associated with neurodevelopmental impairment. This raises concern about exposure to the suspected thousands of endocrine disruptors, and has resulted in efforts to improve regulation of these chemicals. Yet, the causal links between endocrine disruption and developmental neurotoxicity, which would be required for regulatory action, are still largely missing. Areas covered: In this review, we illustrate the importance of two endocrine systems, thyroid hormone and retinoic acid pathways, for neurodevelopment. We place special emphasis on TH and RA synthesis, metabolism, and how endocrine disrupting chemicals known or suspected to affect these systems are associated with developmental neurotoxicity. Expert opinion: While it is clear that neurodevelopment is dependent on proper hormonal functioning, and evidence is increasing for developmental neurotoxicity induced by endocrine disrupting chemicals, this is not grasped by current chemical testing. Thus, there is an urgent need to develop test methods detecting endocrine disruption in the context of neurodevelopment. Key to this development is further mechanistic insights on the involvement of endocrine signaling in neurodevelopment as well as increased support to develop and validate new test methods for the regulatory context.

Published

2022

37. Impact of endocrine disrupting chemicals on neurodevelopment : the need for better testing strategies for endocrine disruption-induced developmental neurotoxicity

Author

Cediel Ulloa, Andrea, Lupu, Diana, Johansson, Ylva, Hinojosa, Maria, Ozel, Fatih, Rüegg, Joëlle, Cediel Ulloa, Andrea, Lupu, Diana, Johansson, Ylva, Hinojosa, Maria, Ozel, Fatih, and Rüegg, Joëlle

Abstract

Introduction: Brain development is highly dependent on hormonal regulation. Exposure to chemicals disrupting endocrine signaling has been associated with neurodevelopmental impairment. This raises concern about exposure to the suspected thousands of endocrine disruptors, and has resulted in efforts to improve regulation of these chemicals. Yet, the causal links between endocrine disruption and developmental neurotoxicity, which would be required for regulatory action, are still largely missing. Areas covered: In this review, we illustrate the importance of two endocrine systems, thyroid hormone and retinoic acid pathways, for neurodevelopment. We place special emphasis on TH and RA synthesis, metabolism, and how endocrine disrupting chemicals known or suspected to affect these systems are associated with developmental neurotoxicity. Expert opinion: While it is clear that neurodevelopment is dependent on proper hormonal functioning, and evidence is increasing for developmental neurotoxicity induced by endocrine disrupting chemicals, this is not grasped by current chemical testing. Thus, there is an urgent need to develop test methods detecting endocrine disruption in the context of neurodevelopment. Key to this development is further mechanistic insights on the involvement of endocrine signaling in neurodevelopment as well as increased support to develop and validate new test methods for the regulatory context.

Published

2022

38. Impact of endocrine disrupting chemicals on neurodevelopment : the need for better testing strategies for endocrine disruption-induced developmental neurotoxicity

Author

Cediel-Ulloa, Andrea, Lupu, Diana Loana, Johansson, Ylva, Hinojosa, Maria, Özel, Faith, Rüegg, Joëlle, Cediel-Ulloa, Andrea, Lupu, Diana Loana, Johansson, Ylva, Hinojosa, Maria, Özel, Faith, and Rüegg, Joëlle

Abstract

Introduction: Brain development is highly dependent on hormonal regulation. Exposure to chemicals disrupting endocrine signaling has been associated with neurodevelopmental impairment. This raises concern about exposure to the suspected thousands of endocrine disruptors, and has resulted in efforts to improve regulation of these chemicals. Yet, the causal links between endocrine disruption and developmental neurotoxicity, which would be required for regulatory action, are still largely missing. Areas covered: In this review, we illustrate the importance of two endocrine systems, thyroid hormone and retinoic acid pathways, for neurodevelopment. We place special emphasis on TH and RA synthesis, metabolism, and how endocrine disrupting chemicals known or suspected to affect these systems are associated with developmental neurotoxicity. Expert opinion: While it is clear that neurodevelopment is dependent on proper hormonal functioning, and evidence is increasing for developmental neurotoxicity induced by endocrine disrupting chemicals, this is not grasped by current chemical testing. Thus, there is an urgent need to develop test methods detecting endocrine disruption in the context of neurodevelopment. Key to this development is further mechanistic insights on the involvement of endocrine signaling in neurodevelopment as well as increased support to develop and validate new test methods for the regulatory context.

Published

2022

39. Impact of endocrine disrupting chemicals on neurodevelopment : the need for better testing strategies for endocrine disruption-induced developmental neurotoxicity

Author

Cediel-Ulloa, Andrea, Lupu, Diana Loana, Johansson, Ylva, Hinojosa, Maria, Özel, Faith, Rüegg, Joëlle, Cediel-Ulloa, Andrea, Lupu, Diana Loana, Johansson, Ylva, Hinojosa, Maria, Özel, Faith, and Rüegg, Joëlle

Abstract

Introduction: Brain development is highly dependent on hormonal regulation. Exposure to chemicals disrupting endocrine signaling has been associated with neurodevelopmental impairment. This raises concern about exposure to the suspected thousands of endocrine disruptors, and has resulted in efforts to improve regulation of these chemicals. Yet, the causal links between endocrine disruption and developmental neurotoxicity, which would be required for regulatory action, are still largely missing. Areas covered: In this review, we illustrate the importance of two endocrine systems, thyroid hormone and retinoic acid pathways, for neurodevelopment. We place special emphasis on TH and RA synthesis, metabolism, and how endocrine disrupting chemicals known or suspected to affect these systems are associated with developmental neurotoxicity. Expert opinion: While it is clear that neurodevelopment is dependent on proper hormonal functioning, and evidence is increasing for developmental neurotoxicity induced by endocrine disrupting chemicals, this is not grasped by current chemical testing. Thus, there is an urgent need to develop test methods detecting endocrine disruption in the context of neurodevelopment. Key to this development is further mechanistic insights on the involvement of endocrine signaling in neurodevelopment as well as increased support to develop and validate new test methods for the regulatory context.

Published

2022

40. Perinatal exposure to the thyroperoxidase inhibitors methimazole and amitrole perturbs thyroid hormone system signaling and alters motor activity in rat offspring

Author

Ramhøj, Louise, Svingen, Terje, Frädrich, Caroline, Rijntjes, Eddy, Wirth, Eva K., Pedersen, Katrine, Köhrle, Josef, Axelstad, Marta, Ramhøj, Louise, Svingen, Terje, Frädrich, Caroline, Rijntjes, Eddy, Wirth, Eva K., Pedersen, Katrine, Köhrle, Josef, and Axelstad, Marta

Abstract

Disruption of the thyroid hormone system during development can impair brain development and cause irreversible damage. Some thyroid hormone system disruptors act by inhibiting the thyroperoxidase (TPO) enzyme, which is key to thyroid hormone synthesis. For the potent TPO-inhibiting drug propylthiouracil (PTU) this has been shown to result in thyroid hormone system disruption and altered brain development in animal studies. However, an outstanding question is which chemicals beside PTU can cause similar effects on brain development and to what degree thyroid hormone insufficiency must be induced to be able to measure adverse effects in rats and their offspring. To start answering these questions, we performed a perinatal exposure study in pregnant rats with two TPO-inhibitors: the drug methimazole (MMI) and the triazole herbicide amitrole. The study involved maternal exposure from gestational day 7 through to postnatal day 22, to MMI (8 and 16 mg/kg body weight/day) or amitrole (25 and 50 mg/kg body weight/day). Both MMI and amitrole reduced serum T4 concentrations in a dose-dependent manner in dams and offspring, with a strong activation of the hypothalamic-pituitary-thyroid axis. This reduction in serum T4 leads to decreased thyroid hormone-mediated gene expression in the offspring's brains and caused adverse effects on brain function, seen as hyperactivity and decreased habituation in preweaning pups. These dose-dependent effects induced by MMI and amitrole are largely the same as those observed with PTU. This demonstrates that potent TPO-inhibitors can induce effects on brain development in rats and that these effects are driven by T4 deficiency. This knowledge will aid the identification of TPO-inhibiting thyroid hormone system disruptors in a regulatory context and can serve as a starting point in search of more sensitive markers of developmental thyroid hormone system disruption.

Published

2022

41. Chlorpyrifos, permethrin and cyfluthrin effect on cell survival, permeability, and tight junction in an in-vitro model of the human blood-brain barrier (BBB)

Author

Universitat Rovira i Virgili, Deepika D; Kumar S; Bravo N; Esplugas R; Capodiferro M; Sharma RP; Schuhmacher M; Grimalt JO; Blanco J; Kumar V, Universitat Rovira i Virgili, and Deepika D; Kumar S; Bravo N; Esplugas R; Capodiferro M; Sharma RP; Schuhmacher M; Grimalt JO; Blanco J; Kumar V

Abstract

The blood-brain barrier (BBB) is a structural and functional interface between the plasma and the human brain. Predictive BBB in-vitro models like immortalized human capillary microvascular endothelial cells (HCMEC/D3) can be used to explore the BBB disruption potential of daily exposed chemicals. The present study was focused on investigating the human BBB permeation potential of one organophosphate pesticide, chlorpyrifos (CPF), and two pyrethroids, permethrin (PMT) and cyfluthrin (CFT). HCMEC/D3 cells were exposed to the chemical and the time-dependent pass across BBB along with permeation coefficient (Papp) was calculated. Transendothelial electrical resistance (TEER) was measured for the cells to check the monolayer formation and later to check the reduction in integrity after chemical exposure. Real time PCR was conducted to investigate the effect of chemicals on the expression BBB´s tight and adherens junction proteins. Calculated Papp value for three chemicals was in the following order: CPF>CFT>PMT, where CPF showed the highest permeation coefficient. TEER calculation showed that the integrity decreased after CPF exposure which was in concordance with Papp value whereas for other chemicals, no change in TEER after exposure was observed. In addition, the transwell study showed a higher efflux ratio (ER) (>2) of CFT indicating that CFT could be a substrate for active transport. For CPF and PMT, ER was less than 2, so no active transport seems to be involved. The evaluation of the mRNA expression analysis revealed a statistically significant decrease in Occludin (OCLN) gene expression for CPF, VE-Cadherin (CDH5) for PMT and Zonula Occludens (ZO1) expression for CFT. Our study showed that CPF has the highest potential for inducing cell death, higher permeation, and

Published

2022

42. Prenatal, but not postnatal exposure to chlorpyrifos affects social behavior of mice and the excitatory-inhibitory balance in a sex-dependent manner

Author

Psicologia, Ciències Mèdiques Bàsiques, Bioquímica i Biotecnologia, Universitat Rovira i Virgili, Biosca-Brull J; Guardia-Escote L; Blanco J; Basaure P; Cabré M; Sánchez-Santed F; Domingo JL; Colomina MT, Psicologia, Ciències Mèdiques Bàsiques, Bioquímica i Biotecnologia, Universitat Rovira i Virgili, and Biosca-Brull J; Guardia-Escote L; Blanco J; Basaure P; Cabré M; Sánchez-Santed F; Domingo JL; Colomina MT

Abstract

The balance between excitatory and inhibitory neurotransmitters is essential for proper brain development. An imbalance between these two systems has been associated with neurodevelopmental disorders. On the other hand, literature also associates the massive use of pesticides with the increase of these disorders, with a particular focus on chlorpyrifos (CPF) a world-wide used organophosphate pesticide. This study was aimed at assessing social autistic-like behaviors on mice pre or postnatally exposed to CPF (0 or 1 mg/kg/day), in both sexes. In prenatal exposure, C57BL/6J pregnant mice were exposed to CPF through the diet, between gestational days (GD) 12 and 18, while a positive control group for some autistic behaviors was exposed to valproic acid (VPA) on GD 12 and 13. To assess postnatal exposure, C57BL/6J mice were orally exposed to the vehicle (corn oil) or CPF, from postnatal days (PND) 10–15. Social behavior and gene expression analysis were assessed on PND 45. Results showed social alterations only in males prenatally treated. GABA system was upregulated in CPF-treated females, whereas an increase in both systems was observed in both treated males. These findings suggest that males are more sensitive to prenatal CPF exposure, favoring the sex bias observed in ASD.

Published

2022

43. Evaluation of neurotoxic effects in zebrafish embryos by automatic measurement of early motor behaviors

Author

Llorens, J., Barenys, M., Teixidó, Elisabet, Klüver, Nils, Ogungbemi, Afolarin Olaposi, Küster, Eberhard, Scholz, Stefan, Llorens, J., Barenys, M., Teixidó, Elisabet, Klüver, Nils, Ogungbemi, Afolarin Olaposi, Küster, Eberhard, and Scholz, Stefan

Abstract

Zebrafish (Danio rerio) has rapidly become a popular model species for behavioral studies that may be relevant to drug screening and safety toxicology. Zebrafish embryos show a complex behavioral repertoire already a few hours after fertilization. Particularly, early stage zebrafish show characteristic behavioral features such as spontaneous tail coiling (STC) or induced movements when exposed to a short and bright light flash (called photomotor response—PMR). In this chapter, we provide the methods for assessing STC and PMR in zebrafish embryos and to detect changes provoked by chemicals. One of the protocols uses video analysis suitable for automated high-throughput screening. Moreover, both protocols describe the use of automated video analysis by using an open-source integration platform (KNIME® analytics platform), providing a flexible workflow system that can be adapted to a diversity of video recordings. We also provide a toxicological validation of this assay and show that these protocols can be used to provide an automated, high data-content readout for zebrafish behavioral responses.

Published

2021

44. The insecticide permethrin induces transgenerational behavioral changes linked to transcriptomic and epigenetic alterations in zebrafish (Danio rerio)

Author

Blanc, Mélanie, Antczak, Philipp, Cousin, Xavier, Grunau, Christoph, Scherbak, Nikolai, Rüegg, Joëlle, Keiter, Steffen H., Blanc, Mélanie, Antczak, Philipp, Cousin, Xavier, Grunau, Christoph, Scherbak, Nikolai, Rüegg, Joëlle, and Keiter, Steffen H.

Abstract

The pyrethroid insecticide permethrin is widely used for agricultural and domestic purposes. Previous data indicated that it acts as a developmental neurotoxicant and can induce transgenerational effects in non-target organisms. However, associated underlying mechanisms remain unclear. The aim of this study was to investigate permethrin-related transgenerational effects in the zebrafish model, and to identify possible molecular mechanisms underlying inheritance. Zebrafish (F0) were exposed to permethrin during early-life (2 h post-fertilization up to 28 days). The F1 and F2 offspring generations were obtained by pairing exposed F0 males and females, and were bred unexposed. Locomotor and anxiety behavior were investigated, together with transcriptomic and epigenomic (DNA methylation) changes in brains. Permethrin exposed F0 fish were hypoactive at adulthood, while males from the F1 and F2 generations showed a specific decrease in anxiety-like behavior. In F0, transcriptomic data showed enrichment in pathways related to glutamatergic synapse activity, which may partly underlie the behavioral effects. In F1 and F2 males, dysregulation of similar pathways was observed, including a subset of differentially methylated regions that were inherited from the F0 to the F2 generation and indicated stable dysregulation of glutamatergic signaling. Altogether, the present results provide novel evidence on the transgenerational neurotoxic effects of permethrin, as well as mechanistic insight: a transient exposure induces persistent transcriptional and DNA methylation changes that may translate into transgenerational alteration of glutamatergic signaling and, thus, into behavioral alterations.

Published

2021

45. The insecticide permethrin induces transgenerational behavioral changes linked to transcriptomic and epigenetic alterations in zebrafish (Danio rerio)

Author

Blanc, Mélanie, Antczak, Philipp, Cousin, Xavier, Grunau, Christoph, Scherbak, Nikolai, Rüegg, Joëlle, Keiter, Steffen H., Blanc, Mélanie, Antczak, Philipp, Cousin, Xavier, Grunau, Christoph, Scherbak, Nikolai, Rüegg, Joëlle, and Keiter, Steffen H.

Abstract

The pyrethroid insecticide permethrin is widely used for agricultural and domestic purposes. Previous data indicated that it acts as a developmental neurotoxicant and can induce transgenerational effects in non-target organisms. However, associated underlying mechanisms remain unclear. The aim of this study was to investigate permethrin-related transgenerational effects in the zebrafish model, and to identify possible molecular mechanisms underlying inheritance. Zebrafish (F0) were exposed to permethrin during early-life (2 h post-fertilization up to 28 days). The F1 and F2 offspring generations were obtained by pairing exposed F0 males and females, and were bred unexposed. Locomotor and anxiety behavior were investigated, together with transcriptomic and epigenomic (DNA methylation) changes in brains. Permethrin exposed F0 fish were hypoactive at adulthood, while males from the F1 and F2 generations showed a specific decrease in anxiety-like behavior. In F0, transcriptomic data showed enrichment in pathways related to glutamatergic synapse activity, which may partly underlie the behavioral effects. In F1 and F2 males, dysregulation of similar pathways was observed, including a subset of differentially methylated regions that were inherited from the F0 to the F2 generation and indicated stable dysregulation of glutamatergic signaling. Altogether, the present results provide novel evidence on the transgenerational neurotoxic effects of permethrin, as well as mechanistic insight: a transient exposure induces persistent transcriptional and DNA methylation changes that may translate into transgenerational alteration of glutamatergic signaling and, thus, into behavioral alterations.

Published

2021

46. Acute effects of the imidacloprid metabolite desnitro-imidacloprid on human nACh receptors relevant for neuronal signaling

Author

Loser, Dominik, Grillberger, Karin, Hinojosa, Maria G., Blum, Jonathan, Haufe, Yves, Danker, Timm, Johansson, Ylva, Möller, Clemens, Nicke, Annette, Bennekou, Susanne H., Gardner, Iain, Bauch, Caroline, Walker, Paul, Forsby, Anna, Ecker, Gerhard F., Kraushaar, Udo, Leist, Marcel, Loser, Dominik, Grillberger, Karin, Hinojosa, Maria G., Blum, Jonathan, Haufe, Yves, Danker, Timm, Johansson, Ylva, Möller, Clemens, Nicke, Annette, Bennekou, Susanne H., Gardner, Iain, Bauch, Caroline, Walker, Paul, Forsby, Anna, Ecker, Gerhard F., Kraushaar, Udo, and Leist, Marcel

Abstract

Several neonicotinoids have recently been shown to activate the nicotinic acetylcholine receptor (nAChR) on human neurons. Moreover, imidacloprid (IMI) and other members of this pesticide family form a set of diverse metabolites within crops. Among these, desnitro-imidacloprid (DN-IMI) is of special toxicological interest, as there is evidence (i) for human dietary exposure to this metabolite, (ii) and that DN-IMI is a strong trigger of mammalian nicotinic responses. We set out here to quantify responses of human nAChRs to DN-IMI and an alternative metabolite, IMI-olefin. To evaluate toxicological hazards, these data were then compared to those of IMI and nicotine. Ca2+-imaging experiments on human neurons showed that DN-IMI exhibits an agonistic effect on nAChRs at sub-micromolar concentrations (equipotent with nicotine) while IMI-olefin activated the receptors less potently (in a similar range as IMI). Direct experimental data on the interaction with defined receptor subtypes were obtained by heterologous expression of various human nAChR subtypes in Xenopus laevis oocytes and measurement of the transmembrane currents evoked by exposure to putative ligands. DN-IMI acted on the physiologically important human nAChR subtypes alpha 7, alpha 3 beta 4, and alpha 4 beta 2 (high-sensitivity variant) with similar potency as nicotine. IMI and IMI-olefin were confirmed as nAChR agonists, although with 2-3 orders of magnitude lower potency. Molecular docking studies, using receptor models for the alpha 7 and alpha 4 beta 2 nAChR subtypes supported an activity of DN-IMI similar to that of nicotine. In summary, these data suggest that DN-IMI functionally affects human neurons similar to the well-established neurotoxicant nicotine by triggering alpha 7 and several non-alpha 7 nAChRs.

Published

2021

47. The insecticide permethrin induces transgenerational behavioral changes linked to transcriptomic and epigenetic alterations in zebrafish (Danio rerio)

Author

Blanc, Mélanie, Antczak, Philipp, Cousin, Xavier, Grunau, Christoph, Scherbak, Nikolai, Rüegg, Joëlle, Keiter, Steffen H., Blanc, Mélanie, Antczak, Philipp, Cousin, Xavier, Grunau, Christoph, Scherbak, Nikolai, Rüegg, Joëlle, and Keiter, Steffen H.

Abstract

The pyrethroid insecticide permethrin is widely used for agricultural and domestic purposes. Previous data indicated that it acts as a developmental neurotoxicant and can induce transgenerational effects in non-target organisms. However, associated underlying mechanisms remain unclear. The aim of this study was to investigate permethrin-related transgenerational effects in the zebrafish model, and to identify possible molecular mechanisms underlying inheritance. Zebrafish (F0) were exposed to permethrin during early-life (2 h post-fertilization up to 28 days). The F1 and F2 offspring generations were obtained by pairing exposed F0 males and females, and were bred unexposed. Locomotor and anxiety behavior were investigated, together with transcriptomic and epigenomic (DNA methylation) changes in brains. Permethrin exposed F0 fish were hypoactive at adulthood, while males from the F1 and F2 generations showed a specific decrease in anxiety-like behavior. In F0, transcriptomic data showed enrichment in pathways related to glutamatergic synapse activity, which may partly underlie the behavioral effects. In F1 and F2 males, dysregulation of similar pathways was observed, including a subset of differentially methylated regions that were inherited from the F0 to the F2 generation and indicated stable dysregulation of glutamatergic signaling. Altogether, the present results provide novel evidence on the transgenerational neurotoxic effects of permethrin, as well as mechanistic insight: a transient exposure induces persistent transcriptional and DNA methylation changes that may translate into transgenerational alteration of glutamatergic signaling and, thus, into behavioral alterations.

Published

2021

48. Evaluation of the dentate gyrus in adult mice exposed to acetaminophen (paracetamol) on postnatal day 10

Author

Philippot, Gaetan, Hellsten, Sofie V, Viberg, Henrik, Fredriksson, Robert, Philippot, Gaetan, Hellsten, Sofie V, Viberg, Henrik, and Fredriksson, Robert

Abstract

Acetaminophen (AAP; or paracetamol) is a widely used nonprescription drug with antipyretic and analgesic properties. Alarmingly, there is an increasing body of evidence showing that developmental exposure to AAP is associated with adverse behavioural outcomes later in life. We have previously shown that relevant doses of AAP in 10-day-old mice affected memory, learning and locomotor activity in the adult animals. Interestingly, the neurons of the dentate gyrus (DG) have a relatively late time of origin as they are generated during the first two weeks of postnatal life in rodents. Since the generation of these cells, which are important for memory processing, coincides with our AAP exposure, we aim to investigate if the cytoarchitecture of the DG is affected by postnatal day 10 AAP treatment. In addition, we investigate if markers for differentiation and migration in the hippocampus were affected by the same treatment. We did not observe any visual effects in adult DG cytoarchitecture, nor any changes of markers for differentiation/migration in the hippocampus in 24 hr after exposure. Even though a large effect size was estimated on adult DG thickness following AAP exposure, the estimated 95% CIs around the differences of the means reveal no significant effect. Hence, larger sample sizes are warranted to clarify if neonatal AAP exposure affects adult DG thickness in mice.

Published

2021

49. The insecticide permethrin induces transgenerational behavioral changes linked to transcriptomic and epigenetic alterations in zebrafish (Danio rerio)

Author

Blanc, Melanie, Antczak, Philipp, Cousin, Xavier, Grunau, Christoph, Scherbak, Nikolai, Rüegg, Joëlle, Keiter, Steffen H., Blanc, Melanie, Antczak, Philipp, Cousin, Xavier, Grunau, Christoph, Scherbak, Nikolai, Rüegg, Joëlle, and Keiter, Steffen H.

Abstract

The pyrethroid insecticide permethrin is widely used for agricultural and domestic purposes. Previous data indicated that it acts as a developmental neurotoxicant and can induce transgenerational effects in non target organisms. However, associated underlying mechanisms remain unclear. The aim of this study was to investigate permethrin-related transgenerational effects in the zebrafish model, and to identify possible molecular mechanisms underlying inheritance. Zebrafish (F 0) were exposed to permethrin during early life (2 h post-fertilization up to 28 days). The F1 and F2 offspring generations were obtained by pairing exposed F0 males and females, and were bred unexposed. Locomotor and anxiety behavior were investigated, together with transcriptomic and epigenomic (DNA methylation) changes in brains. Permethrin exposed F0 fish were hypoactive at adulthood, while males from the F1 and F2 generations showed a specific decrease in anxiety-like behavior. In F0, transcriptomic data showed enrichment in pathways related to glutamatergic synapse activity, which may partly underlie the behavioral effects. In F1 and F2 males, dysregulation of similar pathways was observed, including a subset of differentially methylated regions that were inherited from the F0 to the F2 generation and indicated stable dysregulation of glutamatergic signaling. Altogether, the present results provide novel evidence on the transgenerational neurotoxic effects of permethrin, as well as mechanistic insight: a transient exposure induces persistent transcriptional and DNA methylation changes that may translate into transgenerational alteration of glutamatergic signaling and, thus, into behavioral alterations. (c) 2021 The Author(s). Published by Elsevier B.V. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).

Published

2021

50. Does the food processing contaminant acrylamide cause developmental neurotoxicity? A review and identification of knowledge gaps

Author

Lindeman, Birgitte, Johansson, Ylva, Andreassen, Mathilda, Husøy, Trine, Dirven, Hubert, Hofer, Tim, Knutsen, Helle K., Caspersen, Ida H., Vejrup, Kristine, Paulsen, Ragnhild E., Alexander, Jan, Forsby, Anna, Myhre, Oddvar, Lindeman, Birgitte, Johansson, Ylva, Andreassen, Mathilda, Husøy, Trine, Dirven, Hubert, Hofer, Tim, Knutsen, Helle K., Caspersen, Ida H., Vejrup, Kristine, Paulsen, Ragnhild E., Alexander, Jan, Forsby, Anna, and Myhre, Oddvar

Abstract

There is a worldwide concern on adverse health effects of dietary exposure to acrylamide (AA) due to its presence in commonly consumed foods. AA is formed when carbohydrate rich foods containing asparagine and reducing sugars are prepared at high temperatures and low moisture conditions. Upon oral intake, AA is rapidly absorbed and distributed to all organs. AA is a known human neurotoxicant that can reach the developing foetus via placental transfer and breast milk. Although adverse neurodevelopmental effects have been observed after prenatal AA exposure in rodents, adverse effects of AA on the developing brain has so far not been studied in humans. However, epidemiological studies indicate that gestational exposure to AA impair foetal growth and AA exposure has been associated with reduced head circumference of the neonate. Thus, there is an urgent need for further research to elucidate whether pre- and perinatal AA exposure in humans might impair neurodevelopment and adversely affect neuronal function postnatally. Here, we review the literature with emphasis on the identification of critical knowledge gaps in relation to neurodevelopmental toxicity of AA and its mode of action and we suggest research strategies to close these gaps to better protect the unborn child.

Published

2021