Mechanistic exploration on neurodevelopmental toxicity induced by upregulation of alkbh5 targeted by triclosan exposure to larval zebrafish

Combined exposure of polystyrene nanoplastics and silver nanoparticles exacerbating hepatotoxicity in zebrafish mediated by ferroptosis pathway through increased silver accumulation

Silver nanoparticles (AgNPs) are extensively utilized for their antibacterial properties, leading to their release into the environment and subsequent bioaccumulation and biomagnification within the food chain. Polystyrene nanoplastics (PSNPs), as emerging pollutants, act as carriers for contaminants and alter their transformation processes. However, the toxicological effects and underlying mechanisms associated with the coexistence of these pollutants remain largely unexplored. Herein, the hepatotoxic effects and underlying mechanisms of acute combined exposure to PSNPs and AgNPs were explored using zebrafish as a model organism. After exposed to PSNPs and AgNPs, the larvae (120 hours post-fertilization) exhibited lipid metabolism disorders, increased oxidative stress, hepatomegaly, and liver dysfunction, with these effects being more pronounced than those observed with AgNPs exposure alone. This increase in hepatic toxicity may be due to the enhanced accumulation of AgNPs under combined exposure. Mechanistic investigations revealed that co-exposure led to a significant elevation in malondialdehyde and Fe2 + levels, a loss of mitochondrial cristae and a decrease in membrane potential, along with the abnormal expression of ferroptosis-related genes, which are hallmark indicators of ferroptosis. Furthermore, the introduction of the ferroptosis inhibitor deferoxamine alleviated all observed hepatotoxic phenotypes, thereby confirming that PS+AgNPs co-exposure induced liver injury through the ferroptosis pathway.

Transgenerational thyroid hormone disruption in zebrafish induced by environmentally relevant concentrations of triclosan

The use of triclosan (TCS)-containing disinfectants has become increasingly prevalent in response to the COVID-19 pandemic, leading to a heightened presence of TCS in aquatic ecosystems. Thyroid hormones (THs), which are essential for numerous developmental and metabolic processes, are structurally similar to TCS, rendering it prone to exert endocrine-disrupting effects. In this study, we demonstrate that TCS can induce thyroid hormone disruption in zebrafish, with transgenerational consequences. Zebrafish embryos were exposed to environmentally relevant concentrations of TCS (0, 1, 3, and 10 μg/L) for 30, 60, and 180 days. TCS accumulated in zebrafish over an extended period, causing significant, dose-dependent alterations in TH levels. Furthermore, TCS significantly thereby interfered with the expression of thyroid axis-related genes in the P0-F1 generations. Molecular docking further confirmed that TCS induces transgenerational thyroid effects through potentially strong interactions with thyroglobulin (TG), interfering with the normal physiological function of THs. These findings suggest that TCS at environmentally relevant concentrations can exert ecologically harmful effects by disrupting THs. A rigorous ecological assessment of TCS is recommended before promoting or substituting antimicrobial agents in future disinfection products.

Mechanism of N6-Methyladenosine Modification in the Pathogenesis of Depression

N6-methyladenosine (m6A) is one of the most common post-transcriptional RNA modifications, which plays a critical role in various bioprocesses such as immunological processes, stress response, cell self-renewal, and proliferation. The abnormal expression of m6A-related proteins may occur in the central nervous system, affecting neurogenesis, synapse formation, brain development, learning and memory, etc. Accumulating evidence is emerging that dysregulation of m6A contributes to the initiation and progression of psychiatric disorders including depression. Until now, the specific pathogenesis of depression has not been comprehensively clarified, and further investigations are warranted. Stress, inflammation, neurogenesis, and synaptic plasticity have been implicated as possible pathophysiological mechanisms underlying depression, in which m6A is extensively involved. Considering the extensive connections between depression and neurofunction and the critical role of m6A in regulating neurological function, it has been increasingly proposed that m6A may have an important role in the pathogenesis of depression; however, the results and the specific molecular mechanisms of how m6A methylation is involved in major depressive disorder (MDD) were varied and not fully understood. In this review, we describe the underlying molecular mechanisms between m6A and depression from several aspects including inflammation, stress, neuroplasticity including neurogenesis, and brain structure, which contain the interactions of m6A with cytokines, the HPA axis, BDNF, and other biological molecules or mechanisms in detail. Finally, we summarized the perspectives for the improved understanding of the pathogenesis of depression and the development of more effective treatment approaches for this disorder.

Dose-dependent toxic effects of triclosan on Rana omeimontis larvae: Insights into potential implications for neurodegenerative diseases

The widespread use of antimicrobial agent triclosan (TCS) poses significant health risks to both aquatic organisms and humans. The research on its neurotoxicity and underlying mechanisms is, however, limited. Here we first conducted a 32-day exposure experiment with five TCS concentrations (10, 30, 60, 90 and 120 µg/L) to investigate its impact on overall gene expression in Rana omeimontis larvae. Transcriptomics analysis unveiled a strong dose-dependent pattern of gene expression alterations, with a distinct transcriptomic shift observed in the T030 (30 µg/L) group. In addition, neurodegenerative disease pathway and oxidative stress response GO (gene ontology) terms were found to be highly enriched across the regulated genes in all TCS-exposed groups, suggesting potential TCS-induced neurotoxicity. To further explore this, we performed a 40-day experiment with a low (30 µg/L) or high (90 µg/L) TCS concentration. Morphological assessments revealed that TCS-exposed larvae exhibited developmental and growth inhibition. Using RT-qPCR and immunohistochemical analysis, we confirmed that TCS exposure induced neurotoxicity and triggered neurodegenerative diseases as suggested by Tau protein aggregation in the midbrain. Consistent with these findings, TCS-exposed larvae displayed abnormal behaviors. Our study thus for the first time presents a comprehensive assessment of the adverse effects of TCS exposure on amphibian larvae, encompassing morphological, biochemical, and physiological aspects. Notably, we identified RNF112 and Tau as potential molecular targets that may mediate TCS-induced neurotoxicity. These findings advance the knowledge on how organisms respond to environmental changes and highlight the importance of further investigation into the potential neurotoxicity of TCS within aquatic ecosystems and its implications for human health.

Link between gut damage and neurotoxicity with gender differences in zebrafish: Dibutyl phthalate-driven microbiota dysbiosis as a possible major cause

Among plasticizers, dibutyl phthalate (DBP) is widely used in in industry, posing significant health risks to aquatic organisms. In this study, adult male and female zebrafish were exposed to 0 and 30 μg/L DBP for 15 days. Behavioral monitoring, immunofluorescence, protein immunoblotting, and high-throughput sequencing were used to investigate the critical role of the gut microbiome in DBP-induced dysfunction of the zebrafish gut-brain axis. The results showed pronounced, sex-specific toxic effects of acute DBP exposure in adult zebrafish, with males experiencing more severe neurological damage, while females exhibited greater intestinal damage. DBP exposure caused marked anxiety behaviors in males and significant weight loss in females. Males showed reduced neuronal expression, while females exhibited increased intestinal permeability and lower levels of the tight junction protein (ZO-1). The Firmicutes/Bacteroidota (F/B) ratio decreased, indicating severe gut microbiota dysbiosis. Changes in the gut and fecal microbiota composition, along with PICRUSt2 functional predictions, suggest that female zebrafish experienced more severe metabolic disturbances than males. Analysis of key gene expression in the brain-derived neurotrophic factor (bdnf) pathway revealed that changes in the abundance of tryptophan-metabolizing bacteria in the gut may explain the sex-specific effects of DBP on neurotransmitter serotonin levels in the brain, which influence the gut-brain axis in zebrafish. This study contributes to the understanding of toxic effects of DBP on aquatic organisms and provides strong evidence for assessing its environmental risks.

Integrated multi-omics analysis reveals the underlying molecular mechanism for the neurotoxicity of triclosan in zebrafish

Triclosan (TCS) is a primary broad-spectrum antibacterial agent commonly present in the environment. As a new type of environmental endocrine disruptor, it causes range of toxicities, including hepatotoxicity and reproductive toxicity. However, few research has examined the toxicity of long-term TCS-induced exposure in zebrafish at ambient concentrations, in contrast to the early life stage investigations. In the present study, we investigated the behavioral effects of TCS at environmental concentrations (300 μg/L) during constant exposure in zebrafish adults；An integrated transcriptomic and metabolomic analysis was performed to analyze the molecular mechanism underlying behavioral effects of TCS. Our results show that TCS exposure significantly induces behavioral disruptions such as anxiety-like behavior, memory problems, and altered social preferences. Histopathological investigations and neural ultrastructural observations demonstrated that TCS could induce variable levels of pyknosis and vacuolation in the cytoplasm of neurons as well as torn mitochondrial membranes, shrinkage and broken or absent cristae. Transcriptomics indicated that immune- and metabolism-related gene expression patterns were severely disturbed by TCS. Metabolomic analysis revealed 82 distinct metabolites in adult zebrafish exposed to TCS. Lipid metabolism, especially glycerophospholipid metabolism, and amino acid regulation pathways were co-enriched by multi-omics combinatorial analysis. Hence, this study highlights a number of biomarkers for the risk assessment of TCS against non-target organisms, offering a reference dataset for the behavioral toxicity of TCS to zebrafish, and strengthening the early warning, management, and control of TCS pollution.

Which emerging micropollutants deserve more attention in wastewater in the post-COVID-19 pandemic period? Based on distribution, risk, and exposure analysis

Aggravated accumulation of emerging micropollutants (EMs) in aquatic environments, especially after COVID-19, raised significant attention throughout the world for safety concerns. This article reviews the sources and occurrence of 25 anti-COVID-19 related EMs in wastewater. It should be pointed out that the concentration of anti-COVID-19 related EMs, such as antivirals, plasticizers, antimicrobials, and psychotropic drugs in wastewater increased notably after the pandemic. Furthermore, the ecotoxicity, ecological, and health risks of typical EMs before and after COVID-19 were emphatically compared and analyzed. Based on the environmental health prioritization index method, the priority control sequence of typical EMs related to anti-COVID-19 was identified. Lopinavir (LPV), venlafaxine (VLX), di(2-ethylhexyl) phthalate (DEHP), benzalkonium chloride (BAC), triclocarban (TCC), di-n-butyl phthalate (DBP), citalopram (CIT), diisobutyl phthalate (DIBP), and triclosan (TCS) were identified as the top-priority control EMs in the post-pandemic period. Besides, some insights into the toxicity and risk assessment of EMs were also provided. This review provides direction for proper understanding and controlling the EMs pollution after COVID-19, and is of significance to evaluate objectively the environmental and health impacts induced by COVID-19.

Toxic effects of triclosan on hepatic and intestinal lipid accumulation in zebrafish via regulation of m6A-RNA methylation

Triclosan (TCS), recognized as an endocrine disruptor, has raised significant concerns due to its widespread use and potential health risks. To explore the impact of TCS on lipid metabolism, both larval and adult zebrafish were subjected to acute and chronic exposure to TCS. Through analyzes of biochemical and physiological markers, as well as Oil Red O (ORO) and hematoxylin and eosin (H&E) staining, our investigation revealed that TCS exposure induced hepatic and intestinal lipid accumulation in larval and adult zebrafish, leading to structural damage and inflammatory responses in these tissues. The strong affinity of TCS with PPARγ and subsequent pathway activation indicate that PPARγ pathway plays a crucial role in TCS-induced lipid buildup. Furthermore, we observed a decrease in m6A-RNA methylation levels in the TCS-treated group, which attributed to the increased activity of the demethylase FTO and concurrent suppression of the methyltransferase METTL3 gene expression by TCS. The alteration in methylation dynamics is identified as a potential underlying mechanism behind TCS-induced lipid accumulation. To address this concern, we explored the impact of folic acid-a methyl donor for m6A-RNA methylation-on lipid accumulation in zebrafish. Remarkably, folic acid administration partially alleviated lipid accumulation by restoring m6A-RNA methylation. This restoration, in turn, contributed to a reduction in inflammatory damage observed in both the liver and intestines. Additionally, folic acid partially mitigates the up-regulation of PPARγ and related genes induced by TCS. These findings carry substantial implications for understanding the adverse effects of environmental pollutants such as TCS. They also emphasize the promising potential of folic acid as a therapeutic intervention to alleviate disturbances in lipid metabolism induced by environmental pollutants.

Mechanistic illustration on lipid-metabolism disorders induced by triclosan exposure from the viewpoint of m6A-RNA epigenetic modification

As a typically anthropogenic contaminant, the toxicity effects of triclosan (TCS) were investigated in-depth from the viewpoint of m6A-pre-miRNAs modification. Based on miRNAs high-throughput sequencing, we unravelled the underlying molecular mechanisms regarding TCS-induced lipid-metabolism functional disorders. TCS exposure caused severe lipid accumulation in 120 hpf zebrafish liver and reduced their locomotor activity. Both bioinformatics analysis and experimental validation verified that TCS targeted miR-27b up-regulation to further trigger lipid-metabolism disorders and developmental malformations, including shortened body length, yolk cysts, curved spine and delayed yolk absorption. TCS exposure and miR-27b upregulation both caused the enhanced levels of triglyceride and total cholesterol. Knockdown and overexpression of miR-27b regulated the expression changes of several functional genes related to downstream lipid metabolism of miR-27b, and most downstream target genes of miR-27b were suppressed and enriched in the AMPK signaling pathway. The experiments of pathway inhibitors and agonists further evidenced that TCS caused lipid-metabolism disorders by suppressing the AMPK signaling pathway. In upstream of miR-27b, TCS decreased total m6A-RNA level by targeting upregulation of demethylase and downregulation of methylase reader ythdf1. Molecular docking and ythdf1 siRNA interference further confirmed that TCS targeted the expression change of ythdf1. Under ythdf1 knockdown in upstream of miR-27b, both abnormal lipid metabolism and miR-27b upregulation highlighted that TCS-induced lipid-metabolism disorders were attributable to the decreasing m6A-RNA methylation levels in vivo. These perspectives provide an innovative idea for prevention and treatment of the lipid metabolism-related diseases and these findings open a novel avene for TCS's risk assessment and early intervention of the contaminant.