Gut microbiota related response of Oryzias melastigma to combined exposure of polystyrene microplastics and tetracycline

Global distribution characteristics and ecological risk assessment of microplastics in aquatic organisms based on meta-analysis

As microplastic pollution in the natural environment intensifies, the risk of microplastic contamination faced by aquatic organisms has garnered increasing widespread attention. Most studies have primarily focused on the impacts of microplastics within specific regions and on particular species. However, with the global migration of microplastics, it is necessary to conduct comprehensive research on the distribution characteristics, ingestion mechanisms, and ecological impacts of microplastics across various aquatic organisms. To address this research gap, the present study systematically evaluates the distribution status of microplastics in global aquatic organisms and assesses their potential ecological risks. Firstly, a review of the sources and impacts of microplastics within aquatic organisms is provided. Secondly, a bibliometric analysis is employed to examine the current research landscape and trends, coupled with a quantitative analysis of how the biological characteristics of aquatic organisms influence microplastic ingestion and the distribution patterns of microplastics within these organisms. Thirdly, the study investigates the mechanisms by which microplastics affect aquatic food chains by examining their impact on organisms at different trophic levels. Finally, strategies to reduce microplastic input into water bodies and future research directions are proposed. The findings offer scientific foundations and decision-making support for global microplastic pollution control, aiming to protect the health and sustainable development of aquatic ecosystems.

Co-exposure to polystyrene nanoplastics and mercury synergistically exacerbates toxicity in rare minnow (Gobiocypris rarus) compared to individual exposures

Nanoplastics (NPs) and mercury (Hg) are ubiquitous pollutants that co-occur in aquatic ecosystems. However, the interaction between NPs and Hg, particularly whether NPs affect the accumulation and in vivo biotransformation of Hg in aquatic organisms, remains unclear. The toxicity of NPs and mercuric chloride (HgCl2), both individually and in combination at environmentally relevant concentrations, on rare minnow (Gobiocypris rarus) were investigated in this study. The results demonstrated that NPs increased total Hg accumulation by 33.33 % but had limited effects on methylmercury (MeHg) content and its proportional distribution in muscle tissue compared to single Hg exposure. Both NPs and Hg induced significant growth inhibition, intestinal damage, oxidative stress, and inflammatory responses in rare minnow, with endpoint-specific effect patterns. Moreover, NPs and Hg dramatically altered gut microbiota composition and co-occurrence networks, with NPs inducing more metabolic pathway changes than Hg. Notably, combined exposure exacerbated almost all toxic effects in rare minnow compared to individual exposures, indicating synergistic interactions between NPs and Hg. These findings highlight the need to consider co-existing contaminants when evaluating NP toxicity.

Phase-dependent hepatotoxicity of Aluminum oxide nanoparticles mediated through the intestinal microbiota

Aluminum oxide (Al2O3) nanoparticles (NPs) are extensively utilized in the food industry for applications such as food packaging, antimicrobial coatings, food processing equipment, and additives. Despite their widespread use, the mechanisms underlying Al2O3 NP-induced hepatotoxicity and the relationship between their physicochemical properties and toxicity remain inadequately understood. In this study, we explored the hepatotoxic effects of α-Al2O3 and γ-Al2O3 NPs in rats subjected to oral exposure for 28 days. Employing an integrated metabolomics and microbiome approach, we aimed to elucidate the potential mechanisms involved. Our findings revealed distinct hepatotoxic profiles for α-Al2O3 and γ-Al2O3 NPs, potentially mediated by differential interactions with the intestinal microbiome. α-Al2O3 NPs exhibited reduced hepatotoxicity, as evidenced by minimal liver oxidative stress, which may be associated with the upregulation of digestion-related intestinal flora such as Peptococcaceae and Romboutsia, potentially influencing Al2O3 accumulation in the liver. Conversely, γ-Al2O3 NPs demonstrated pronounced hepatotoxicity, characterized by liver histopathological changes and elevated levels of alanine aminotransferase, malondialdehyde, and glutathione. This increased toxicity was correlated with alterations in intestinal flora, including Ruminococcaceae and Exiguobacterium, which affected metabolites like L-phenylalanine and arachidonic acid, potentially contributing to hepatotoxicity. The results underscore the importance of the intestinal microbiome in mediating NP-induced toxicity and determining differences in toxicities of different NP phases. This study provides valuable insights into the differential toxicological impacts of Al2O3 NP phases, paving the way for safer nanomaterial design and application in the food industry.

Combined effects of co-exposure to microcystin-LR and polystyrene microplastics on growth, brain pathology and thyroid hormone homeostasis in adult zebrafish

The concurrent presence of algal blooms and microplastics pollution in natural water bodies poses a novel threat. However, the joint effects of microcystin-LR (MCLR) in combination with polystyrene microplastics (PSMPs) on the thyroid endocrine system of adult fish remains unclear. In our study, male zebrafish (Danio rerio) were exposed to environmentally relevant concentrations of MCLR alone (0, 0.8, 4, 20 μg/L) and a mix of MCLR and PSMPs (100 μg/L) for 60 days. Alterations in brain histology, thyroid hormone (TH) levels, and the transcription levels of hypothalamic-pituitary-thyroid (HPT)-axis genes were used to assess the thyroid function. In the MCLR-only treatment groups, we observed mild brain tissue damage characterized by glial scarring and hyperemia. The presence of PSMPs exacerbated the brain damage cause by MCLR, resulting in more pronounced ventriculomegaly and hyperemia. No significant changes in whole-body thyroxine (T4) and triiodothyronine (T3) levels were observed in the MCLR-only groups, while a significant decrease was noted in the groups co-exposed to MCLR and PSMPs. Additionally, significant alterations in crh, tshβ, ttr, trα, and trβ expression levels in the combined exposure groups provided further confirmation that MCLR and PSMPs jointly cause thyroid endocrine disruption. Our findings suggest that the fish can trigger a compensatory mechanism to maintain thyroid hormone homeostasis in response to environmentally relevant concentrations of MCLR. However, the presence of PSMPs disrupts this self-regulatory equilibrium, thereby exacerbates the thyroid endocrine disruption cause by MCLR in zebrafish.

Microbial diversity and metabolomics analysis of colon contents exposed to cadmium and polystyrene microplastics

Cadmium and microplastics, common pollutants, can accumulate in the body, impacting the intestinal barrier and harming livestock breeding. In order to explore the damage mechanism of cadmium and cadmium combined microplastic on the colon of mice, 60 mice were divided into three groups: The control group (0.2 mL of saline), cadmium group (Cd group, 0.2 mL of 4.8 mg/kg/d CdCl2) and mixed group (Mix group, 0.2 mL of mixed solution containing 4.8 mg/kg/d CdCl2 and 10.0 mg/d MPs) were fed for 42 d. The changes of colon histopathology were observed, and the changes of microbial diversity and metabolomics of colon contents were analyzed. Pathological sections of the colon showed abnormal mucosal hyperemia with mixed exposure compared to cadmium exposure. Microbial diversity analysis showed increased abundances of Enterococcus, Adlercreutzia, and Bifidobacterium in the Cd and Mix groups, with Dubosiella being the most significantly increased. Metabolomic analysis indicated significant differences in nucleotide and purine metabolism between the Cd and control groups, and in linoleic acid and bile acid metabolism between the Mix and control groups. The ABC transporter metabolites increased with Cd exposure, while the PPAR pathway metabolites were enriched with MPs exposure. Correlation analysis highlighted several key findings: Pasteurella exhibited a notably negative association with pantothenate. Conversely, Enterococcus demonstrated a significant positive link with palmitoylcarnitine. Additionally, both Adlercreutzia and norank_f_Eggerthellaceae showed a positive correlation with azelaic acid. These findings suggest that Cd and MPs disrupt intestinal microbiota and metabolic pathways, providing insights into potential treatments for such exposures.

Unlocking the combined impact of microplastics and emerging contaminants on fish: A review and meta-analysis

Microplastics (MPs) possess unique adsorptive properties that render their surfaces prone to absorbing other contaminants. When interacting with these emerging contaminants, MPs may have unpredictable negative impacts on fish. Prior studies have primarily concentrated on the impact of single contaminants, while investigations into combined pollution have not received adequate attention. Therefore, research on combined pollution holds greater practical significance. The physiological indicators of fish affected by emerging contaminants and the mechanisms behind these effects are not yet fully clear. To address this issue, a meta-analysis was performed to evaluate the impact of combined pollution of MPs-containing emerging contaminants on various aspects of fish health, encompassing behavior, consumption, development, and reproduction, along with the assessment of oxidative stress and neurotoxicity of fish. The results of the meta-analysis indicated that combined pollution adversely impacted fish reproduction, development, oxidative stress, and neurotoxicity. Importantly, significant differences were observed between fish species regarding their susceptibility to function and oxidative stress. Further investigation into the mechanisms of the impact of combined pollution on fish revealed that the magnitude of this impact is closely associated with the characteristics of the MPs themselves. MPs with higher adsorption capacities tend to lead to more severe consequences, while the impact of MPs with lower adsorption capacities relies more on their toxicity. Nevertheless, a close correlation between the duration of exposure to combined pollution and the level of oxidative stress in fish was not identified. Through a systematic analysis of existing studies, this review not only explored the cumulative effects of combined pollution on fish but also highlighted the intricate nature of such pollution within aquatic ecosystems. It contributes to the growing body of knowledge on the subject and emphasizes the need for further research to unravel the complexities associated with the combined impact of MPs-containing emerging contaminants on aquatic life.

Polystyrene microplastic exposure modulates gut microbiota and gut-liver axis in gilthead seabream (Sparus aurata)

Microplastics (MPs) are a threat of growing concern for living organisms as they exist in all ecosystems. The bidirectional communication between the gut, its microbiota, and the liver, has been conceptualized as gut-liver axis and may be influenced by environmental factors. MPs can cause intestinal and hepatic injuries, but there is still limited research exploring their impact on gut-liver axis. The aim of this study was to assess the effects of MP ingestion on gut-liver axis balance in gilthead seabream (Sparus aurata) fed with a diet enriched with polystyrene (PS)-MPs (0, 25, or 250 mg/kg b.w./day) for 21 days. PS-MPs affected the composition of gut microbiota, enhancing the evenness of gut microbial species. We also observed the impoverishment of core microbiota, suggesting reduced stability and permanence of microbiota members. Furthermore, PS-MPs reduced predominant bacteria in the gut of gilthead seabreams, increasing low-abundance species, including potential harmful taxa. On the other hand, PS-MPs increased the gene expression of immune and inflammatory mediators (i.e., TLR2, TLR5, and COX-2) in the liver. PS-MP exposure also increased serum triglycerides and bile acids (BAs) without modifying cholesterol. Moreover, the hepatic BA metabolism was impacted by PS-MPs which increased the expression of genes involved in primary BA kinetic (i.e., CYP27A1 and LXRa), which in turn can modulate intestinal microbial community. Indeed, PICRUSt2 mapping of BA-related functions predicted the increase of factors involved in BA metabolism. Specifically, K01442 (choloylglycine hydrolase) and K00076 (7α-hydroxysteroid dehydrogenase) were augmented by PS-MPs, suggesting a possible adaptation or co-evolution of gut microbiota to the modified hepatic BA metabolism. Thus, the obtained results showed that ingested PS-MPs impact the gut microbiota architecture and functions, the hepatic innate immunity, and the BA metabolism, suggesting the involvement of the gut-liver axis in MP-induced toxicity.

Biological exposure to microplastics and nanoplastics and plastic additives: impairment of glycolipid metabolism and adverse effects on metabolic diseases

Microplastics and nanoplastics (M-NPs) are widespread pollutants in the environment, posing growing risks to human health and garnering increasing concern from researchers. Due to their small particle size, ease of adsorption, and resistance to degradation, M-NPs can retain and migrate in the environment for long-term periods. Upon entering organisms, M-NPs have been reported to cause inflammation and oxidative stress and result in abnormalities in glycolipid metabolism. Furthermore, research suggests that exposure to M-NPs may act as a causative agent for metabolic and cardiovascular diseases such as diabetes, obesity, and atherosclerosis. This paper aims to review the consequences of exposure to M-NPs on animal and cellular glycolipid metabolism and discusses the disruption of gut microbial homeostasis and the subsequent emergence of insulin resistance. PPAR signaling pathway activation after exposure to M-NPs was found to lead to increased hepatic fat accumulation and impaired lipid metabolism. Additionally, the paper highlights how M-NPs exacerbate the progression of obesity and diabetes in patients, induce damage to vascular endothelial cells, trigger oxidative stress, and contribute to the development of atherosclerosis. Despite the growing concern, the toxicity and molecular mechanism of M-NPs on glycolipid metabolism remain understudied, and effective methods for removing plastic pollutants deposited in the body are yet to be established. These findings provide valuable insights for future research in this field.

The role of gut microbiota in MP/NP-induced toxicity

Microplastics (MPs) and nanoplastics (NPs) are globally recognized as emerging environmental pollutants in various environmental media, posing potential threats to ecosystems and human health. MPs/NPs are unavoidably ingested by humans, mainly through contaminated food and drinks, impairing the gastrointestinal ecology and seriously impacting the human body. The specific role of gut microbiota in the gastrointestinal tract upon MP/NP exposure remains unknown. Given the importance of gut microbiota in metabolism, immunity, and homeostasis, this review aims to enhance our current understanding of the role of gut microbiota in MP/NP-induced toxicity. First, it discusses human exposure to MPs/NPs through the diet and MP/NP-induced adverse effects on the respiratory, digestive, neural, urinary, reproductive, and immune systems. Second, it elucidates the complex interactions between the gut microbiota and MPs/NPs. MPs/NPs can disrupt gut microbiota homeostasis, while the gut microbiota can degrade MPs/NPs. Third, it reveals the role of the gut microbiota in MP/NP-mediated systematic toxicity. MPs/NPs cause direct intestinal toxicity and indirect toxicity in other organs via regulating the gut-brain, gut-liver, and gut-lung axes. Finally, novel approaches such as dietary interventions, prebiotics, probiotics, polyphenols, engineered bacteria, microalgae, and micro/nanorobots are recommended to reduce MP/NP toxicity in humans. Overall, this review provides a theoretical basis for targeting the gut microbiota to study MP/NP toxicity and develop novel strategies for its mitigation.

Understanding the links between micro/nanoplastics-induced gut microbes dysbiosis and potential diseases in fish: A review

At present, the quantity of micro/nano plastics in the environment is steadily rising, and their pollution has emerged as a global environmental issue. The tendency of their bioaccumulation in aquatic organisms (especially fish) has intensified people's attention to their persistent ecotoxicology. This review critically studies the accumulation of fish in the intestines of fish through active or passive intake of micro/nano plastics, resulting in their accumulation in intestinal organs and subsequent disturbance of intestinal microflora. The key lies in the complex toxic effect on the host after the disturbance of fish intestinal microflora. In addition, this review pointed out the characteristics of micro/nano plastics and the effects of their combined toxicity with adsorbed pollutants on fish intestinal microorganisms, in order to fully understand the characteristics of micro/nano plastics and emphasize the complex interaction between MNPs and other pollutants. We have an in-depth understanding of MNPs-induced intestinal flora disorders and intestinal dysfunction, affecting the host's systemic system, including immune system, nervous system, and reproductive system. The review also underscores the imperative for future research to investigate the toxic effects of prolonged exposure to MNPs, which are crucial for evaluating the ecological risks posed by MNPs and devising strategies to safeguard aquatic organisms.

Effect of microplastics on oxytetracycline trophic transfer: Immune, gut microbiota and antibiotic resistance gene responses

Microplastics and antibiotics are prevalent and emerging pollutants in aquatic ecosystems, but their interactions in aquatic food chains remain largely unexplored. This study investigated the impact of polypropylene microplastics (PP-MPs) on oxytetracycline (OTC) trophic transfer from the shrimp (Neocaridina denticulate) to crucian carp (Carassius auratus) by metagenomic sequencing. The carrier effects of PP-MPs promoted OTC bioaccumulation and trophic transfer, which exacerbated enterocyte vacuolation and hepatocyte eosinophilic necrosis. PP-MPs enhanced the inhibitory effect of OTC on intestinal lysozyme activities and complement C3 levels in shrimp and fish, and hepatic immunoglobulin M levels in fish (p < 0.05). Co-exposure of MPs and OTC markedly increased the abundance of Actinobacteria in shrimp and Firmicutes in fish, which caused disturbances in carbohydrate, amino acid, and energy metabolism. Moreover, OTC exacerbated the enrichment of antibiotic resistance genes (ARGs) in aquatic animals, and PP-MPs significantly increased the diversity and abundance of ARGs and facilitated the trophic transfer of teta and tetm. Our findings disclosed the impacts of PP-MPs on the mechanism of antibiotic toxicity in aquatic food chains and emphasized the importance of gut microbiota for ARGs trophic transfer, which contributed to a deeper understanding of potential risks posed by complex pollutants on aquatic ecosystems.