Project description:Zinc Oxide nanoparticles (ZnO NPs) are being rapidly developed for use in consumer products, wastewater treatment and chemotherapy providing several possible routes for ZnO NP exposure to humans and aquatic organisms. Recent studies have shown that ZnO NPs undergo rapid dissolution to Zn+2, but the relative contribution of Zn+2 to ZnO NP bioavailability and toxicity is not clear. Gene expression profiling of D. magna exposed to ZnO NPs or ZnSO4 at equitoxic concentrations demonstrated that the particles cause toxicity through a distinct mechanism compared with Zn+2. D. magna were also exposed to a SiO NPs as a particle control at equimolar concentrations. The SiO NPs resulted in few differentially expressed genes and there was very little overlap between the genes affected by the ZnO NPs and the SiO NPs, suggesting that ZnO NPs cause a distinct pattern of differentially expressed genes. In the ZnO NP exposures, effects were observed to genes involved in cytoskeletal transport, cellular respiration and reproduction. Three biomarker genes including a multi-cystatin, ferritin and a C1q containing gene were confirmed as differentially expressed in a specific pattern by ZnO NP and provide a suite of biomarkers for identifying environmental exposure to ZnO NP and differentiating between NP and ionic exposure. We exposed Daphnia magna to the 1/10 LC50 and LC25 of ZnO nanoparticles and Zn++ as ZnSO4 for 24-h. For each exposure condition, we performed 3 exposures and 2 technical replicates (as dye swap) for each exposure (6 microarrays total). All exposures were compared to a unexposed laboratory control

Project description:We have employed whole genome microarray expression to distinguish the effect of environmental aging on the toxicity of several cerium oxide nanoparticles (NPs) in human intestinal cells compared . Cells were exposed in vitro, and datasets of differentially expressed genes were identified for each type of NPs versus control samples. NPs induced gene expression in Caco-2 cells was measured at 24 hours after exposure . Six independent experiments were performed using different NPs and controls for each experiment.

Project description:Due to its antimicrobial activity, silver nanoparticles (Ag-NPs) are among the most used NPs worldwide, yet little information is available regarding their effects, particularly in soil dwelling organisms. Enchytraeids (Oligochaeta) are important members of the soil fauna which actively contribute to the acceleration of organic matter decomposition and nutrient recycling processes. Hence, for hazard and risk assessment it is important to provide toxicity data for these organisms and to understand more in regard to the mode of action of Ag-NPs within organism. To study this we conducted toxicity experiments using the OECD standard guideline, testing Ag-NPs and AgNO3, having assessed survival, reproduction and differential gene expression. Population toxicity responses were assessed showing higher toxicity for the AgNO3. In an attempt to understand the mode of action we performed transcription profiling using the microarray. Gene expression profile of Enchytraeus albidus was analysed after 2 days of exposure to 100 and 200 mg/kg of two silver forms (nanoparticles and salt_silver nitrate) in OECD soil. Three biological replicates per test treatment and control (clean OECD soil) were used.

Project description:This study investigated the pulmonary toxicity of Copper oxide nanoparticles (CuO NPs) surface modified with polyethylenimine (PEI) or ascorbate (ASC), was investigated. Rats were exposed nose-only to a fixed exposure concentration of ASC or PEI coated CuO NPs for 5 consecutive days. On day 6 and day 27 post-exposure, pulmonary toxicity markers in bronchoalveolar lavage fluid (BALF) were analyzed and histopathological evaluation of the lungs was performed, along with microarray analyses on whole lung tissue samples.

Project description:Zinc Oxide nanoparticles (ZnO NPs) are being rapidly developed for use in consumer products, wastewater treatment and chemotherapy providing several possible routes for ZnO NP exposure to humans and aquatic organisms. Recent studies have shown that ZnO NPs undergo rapid dissolution to Zn+2, but the relative contribution of Zn+2 to ZnO NP bioavailability and toxicity is not clear. Gene expression profiling of D. magna exposed to ZnO NPs or ZnSO4 at equitoxic concentrations demonstrated that the particles cause toxicity through a distinct mechanism compared with Zn+2. D. magna were also exposed to a SiO NPs as a particle control at equimolar concentrations. The SiO NPs resulted in few differentially expressed genes and there was very little overlap between the genes affected by the ZnO NPs and the SiO NPs, suggesting that ZnO NPs cause a distinct pattern of differentially expressed genes. In the ZnO NP exposures, effects were observed to genes involved in cytoskeletal transport, cellular respiration and reproduction. Three biomarker genes including a multi-cystatin, ferritin and a C1q containing gene were confirmed as differentially expressed in a specific pattern by ZnO NP and provide a suite of biomarkers for identifying environmental exposure to ZnO NP and differentiating between NP and ionic exposure.

Project description:In this study, we first characterized commercially available cobalt boride (Co2B) nanoparticles (NPs) using X-ray crystallography (XRD), transmission electron microscope (TEM), scanning electron microscope (SEM) and energy-dispersive X-ray spectroscopy (EDX) techniques. Next, we selected 3-(4,5-dimethyl-thiazol-2-yl) 2,5-diphenyltetrazolium bromide (MTT), neutral red (NR) and lactate dehydrogenase (LDH) release assays for cell viability against Co2B NPs exposure and found that cell viability tests unveiled LC20 value for Co2B NPs was 310.353 mg/L. Moreover, we performed cytotoxicity tests using human pulmonary alveolar epithelial cells (HPAEpiC) since the interaction with the nanoparticles generally starts with inhaling from the air. We performed whole-genome microarray analysis to reveal the global gene expressions differentiations of HPAEpiC cells after Co2B NPs application and found that our analysis displayed 719 genes expression differentiations (FC≥2) after 40.000 genes analysis. Visualization and integrated discovery (DAVID) analysis showed that there are interactions between various gene pathways and NPs administration. Based on gene ontology biological processes analysis, we found that P53 signaling pathway, cell cycle, cancer affecting genes and growth factors were mostly affected by the Co2B NPs. In conclusion, we observed that Co2B NPs would be a safe nano-molecule for industrial, environmental and medical applications.

Project description:Following introduction into a biological environment, nanoparticles (NPs) interact with biomolecules forming a biocorona (BC) on their surface altering cell interactions and toxicity. Metabolic syndrome (MetS) is a prevalent condition and enhances susceptibility to inhaled exposures. We hypothesize distinct NP-biomolecule interactions occur in the lungs due to MetS resulting in the formation of unique NP-BCs contributing to enhanced toxicity. Bronchoalveolar lavage fluid (BALF) was collected from healthy and MetS mouse models and used to evaluate variations in the BC formation on 20 nm iron oxide NPs. NPs without or with BCs were characterized for hydrodynamic size and zeta potential. Protein and lipid components of the BCs were evaluated via proteomic and lipidomic assessments. Unique biomolecules were determined to associate with iron oxide NPs while shared biomolecules demonstrated differential abundance based on disease state. A mouse macrophage cell line was utilized to examine alterations in cell interactions and toxicity due to BCs. Exposures for 1h or 24h with NPs did not demonstrate overt cytotoxicity. Darkfield microscopy and X-ray fluorescence (XRF) analysis determined enhanced iron oxide NP internalization due to the MetS BC compared to the healthy BC. Macrophages exposed to NPs with a MetS-BC for 1h or 24h demonstrated enhanced gene expression of inflammatory markers CCL2, IL-6, and TNF-alpha compared to ion oxide NPs with a healthy BC. Inflammatory pathways were examined by western blots to determine activation of specific proteins within the MAP kinase, Jak-Stat, and NF- kB signaling pathways. Activation of STAT3, NF-kB, and ERK pathways were determined to be upregulated due to the MetS-BC. Specifically, the Jak-Stat pathway was determined to be the most upregulated inflammatory pathway following exposure to NPs with a MetS BC.

Project description:The widespread commercial use of TiO2-NPs, such as in medical stents, has led to extensive investigations on their toxicity and biological impact but lacks a detailed study on their effects. Proteomics and transcriptomics are key methodologies to unravel cellular dynamics, macromolecular interactions and biological response to NP exposure through the protein or gene identification and quantification. We focus on integration of several Omics strategies that could offer a more complex understanding of the impact. In this study, our goal was to gain insight into the cellular response after the exposure to sublethal concentration of TiO2-ultra small nanoparticles (USNPs) and NPs by analyzing the modification on the genomic and proteomic expression in human microdermal endothelial cells (HMEC-1). We investigated the correlation between the NP size and the cellular response to the exposure. We evaluated if multiOmics approaches could thus reveal more extensive information on the potential cellular responses to NPs exposure.

Project description:The in vitro and in vivo toxicity of copper oxide nanoparticles (CuO NPs) is attributed to both particle and dissolved copper ion species. However, a clear understanding of 1) the specific cellular responses that are modulated by the two species and 2) the temporal dynamics in toxicity, as the proportional amount of particulate and ionic forms change over time, is lacking. In the current study, in vitro responses to microparticulate CuO (CuO MPs), CuO NPs, and dissolved Cu2+ were characterized in order to elucidate particle and ion induced kinetic effects. Particle dissolution experiments were carried out in relevant cell culture medium, using CuO NPs and MPs. Mouse lung epithelial cells were exposed for 2 - 48 h with 1 - 25 µg/mL CuO MPs, CuO NPs, or 7 & 54 µg/mL CuCl2. Cellular viability and genome-wide transcriptional responses were assessed. Dose and time dependent cytotoxicity was observed in CuO NP exposed cells, which was delayed and subtle in CuCl2 and not observed in CuO MPs treated cells. Analyses of differentially expressed genes and associated pathway perturbations showed that dissolved ions released by CuO NPs in extracellular medium are insufficient to account for the observed potency and cytotoxicity. Further organization of gene expression results in an Adverse Outcome Pathway (AOP) framework revealed a series of key events potentially involved in CuO NPs toxicity. The AOP is applicable to soluble metal oxide nanoparticle induced toxicity in general, and thus, can facilitate the development of in vitro alternative strategies to screen their toxicity.

Project description:The widespread use of silver nanoparticles (Ag NPs) has raised substantial health risks to environmental and human beings. Although various negative effects had been reported, little is known about the epigenetic toxicity induced by Ag+ and Ag NPs. This study characterized physiological and lncRNA profiles to explore the toxic effects and epigenetic mechanisms in Tetrahymena thermophila on exposure to Ag+ and three types of Ag NPs. We found that both of Ag+ and Ag NPs exhibited strong growth-inhibiting effects on T. thermophila. The toxicity was mainly caused by high levels of reactive oxygen species (ROS), which subsequently led to lipid peroxidation and mitochondrial dysfunction. As a defense mechanism against oxidative stress, the protist elicited an antioxidant response. Importantly, 1250 lncRNAs were differentially expressed under Ag+ or Ag NPs exposure relative to the non-exposure control, which were clustered into 15 expression modules in weighted gene co-expression network analysis. These gene modules exhibited toxicant-specific expression patterns, indicating that they play various regulatory roles, including cell growth inhibition, cell membrane cation channel activation, and oxidoreductase activity promotion. Taken together, this research illuminates how post-transcriptional mechanisms of a ciliated protozoa regulate responses to Ag+ and Ag NPs toxicities.