The Journal of Toxicological Sciences Volume 48, Issue 2

Development of a non-invasive method for testicular toxicity evaluation using a novel compact magnetic resonance imaging system

In non-clinical animal studies for drug discovery, histopathological evaluation is the most powerful tool to assess testicular toxicity. However, histological analysis is extremely invasive; many experimental animals are needed to evaluate changes in the pathology and anatomy of the testes over time. As an alternative, small animal magnetic resonance imaging (MRI) offers a non-invasive methodology to examine testicular toxicity without radiation. The present study demonstrated the suitability of a new, ready-to-use compact MRI platform using a high-field permanent magnet to assist with the evaluation of testicular toxicity. To validate the utility of the MRI platform, male mice were treated with busulfan (40 mg/kg, intraperitoneal injection). Twenty-eight days after treatment, both testes in busulfan-treated and control mice (n = 6/group) were non-invasively scanned in situ by MRI at 1 tesla. On a T1-weighted 3D gradient-echo MRI sequences (voxel size: 0.23 × 0.23 × 0.50 mm), the total testicular volume in busulfan-treated mice was significantly smaller than in controls. On T1-weighted images, the signal intensity of the testes was significantly higher in busulfan-treated mice than in controls. The mice were sacrificed, and the testes were isolated for histopathological analysis. The weight of the testes in busulfan-treated mice significantly decreased, similar to the results of the non-invasive analysis. Additionally, periodic acid-Schiff stain–positive effusions were observed in the interstitium of the busulfan-treated mouse testes, potentially explaining T1 shortening due to a high concentration of glycoproteinaceous content. The present data demonstrated a rapid evaluation of testicular toxicity in vivo by compact MRI.

Lipopolysaccharide administration increases the susceptibility of mitochondrial permeability transition pore opening via altering adenine nucleotide translocase conformation in the mouse liver

Lipopolysaccharide (LPS), a component of the outer membrane of gram-negative bacteria, induces various biological reactions in vivo. Our previous study suggested that LPS administration disrupts respiratory chain complex activities, enhances reactive oxygen species production, especially in the liver mitochondria, and sensitizes mitochondrial permeability transition (MPT) pore opening in rats. However, it is unknown whether LPS-induced MPT pore opening in rats is similarly observed in mice and whether the mechanism is the same. LPS administration to mice increased not only cyclosporin A-sensitive swelling (MPT pore opening) susceptibility, but also induced cyclosporin A-insensitive basal swelling, unlike in rats. In addition, respiratory activity observed after adding ADP was significantly decreased. Based on these results, we further investigated the role of adenine nucleotide translocase (ANT). Carboxyatractyloside (CATR; an ANT inhibitor) treatment decreased respiratory activity after ADP was added in vehicle-treated mitochondria similarly to LPS administration. Additionally, CATR treatment increased MPT pore opening susceptibility in LPS-treated mitochondria compared to that of vehicle-treated mitochondria. Our study shows that ANT maintained a c-state conformation upon LPS administration, which increased MPT pore opening susceptibility in mice. These results suggest that LPS enhances MPT pore opening susceptibility across species, but the mechanism may differ between rat and mouse.

Plasma membrane damage triggered by benzalkonium chloride and cetylpyridinium chloride induces G₀/G₁ cell cycle arrest via Cdc6 reduction in human lung epithelial cells

Quaternary ammonium compounds, including benzalkonium chloride (BAC) and cetylpyridinium chloride (CPC), are widely used as disinfectants. Increased use of inhalable products containing BAC or CPC has raised concerns for lung toxicity. This study sought to elucidate the microstructure of plasma membrane damage caused by BAC and CPC and the subsequent mechanism by which the damage is mediated, as assessed using two human pulmonary epithelial cell lines (A549 and BEAS-2B). Scanning electron microscopic observation showed that exposure to BAC or CPC for 3 hr reduced the length and density of microvilli on the plasma membrane in A549 cells. Analysis of cell cycle distribution following plasma membrane damage revealed that BAC and CPC promote G₀/G₁ cell cycle arrest in both cell lines. The protein levels of Cdc6, an essential regulator of DNA replication during G₁/S transition, are decreased significantly and dose dependently by BAC or CPC exposure. CPC and BAC decreased the Cdc6 levels that had been increased by a PI3K agonist in A549 cells, and levels of phosphorylated AKT were reduced in response to BAC or CPC. Conversely, exposure to equivalent concentrations of pyridinium chloride (lacking a hydrocarbon tail) induce no changes. These results suggest that plasma membrane damage triggered by BAC or CPC causes Cdc6-dependent G₀/G₁ cell cycle arrest in pulmonary cells. These effects are attributable to the long alkyl chains of BAC and CPC. The reduction of Cdc6 following plasma membrane damage may be caused, at least in part, by diminished signaling via the PI3K/AKT pathway.

Benzo(a)pyrene-induced mitochondrial respiration and glycolysis disturbance in human neuroblastoma cells

Mammalian cells generate ATP through mitochondrial respiration and glycolysis. Mitochondria not only play a key role in cell energy metabolism but also in cell cycle regulation. As a neurotoxic pollutant, benzo(a)pyrene (BaP) can trigger neuronal oxidative damage and apoptosis. However, the features of BaP-induced energy metabolism disturbance in SH-SY5Y cells has rarely been addressed. This study aimed to measure oxygen consumption rate (OCR) and extracellular acidification rate (ECAR) as indications of respiratory activities and glycolytic. SH-SY5Y cells were treated with BaP to establish a cytotoxicity model, and butylated hydroxy anisole (BHA) was used to alleviate the damages induced by BaP. Using the Seahorse Extracellular Flux analyzer (XFp), we found that BaP significantly reduced basal respiration, ATP-linked OCR in SH-SY5Y cells with dose- and time-dependent. BHA supplementation recovered the mitochondrial respiration, synchronously attenuated intracellular ROS generation and lipid peroxidation, and simultaneously reversed the abnormal changes in antioxidant biomarkers, then rescued BaP-induced cell apoptosis. But long-term exposure to BaP or exposure to a high dosage of BaP could decrease OCR associated with maximal respiratory, spare capacity, and glycolysis metabolism. At the same time, the damage to cells is also more severe with the rate of apoptosis and mitochondrial membrane potential (ΔΨm) loss rising sharply, which were not entirely reversed by BHA. This study provides energy metabolism-related, indicative biomarkers of cytotoxicity induced by BaP, which might provide information for early prevention and intervention.

Establishment of hyperoxic cell culture system for predicting drug-induced liver injury: reducing accumulated lipids in hepatocytes derived from chimeric mice with humanized liver

Drug-induced liver injury (DILI) is a major adverse reaction. Species-specific differences between humans and laboratory animals make it difficult to establish evaluation models that can accurately predict DILI in the preclinical phase. Chimeric mice with humanized liver are potential predictive models for understanding DILI. Chimeric mice generated by transplanting human hepatocytes into urokinase-type plasminogen activator/severe combined immunodeficient mice are known to develop fatty liver and show lipid accumulation in isolated hepatocytes. It is speculated that the lipids accumulated in hepatocytes may interfere with DILI assessment. It is known that normal 20% oxygen culture conditions do not meet oxygen demand because oxygen consumption rate is higher than the oxygen supply rate. Therefore, we predicted that hyperoxic cultures could induce hepatocyte function and reduce accumulated lipids. A culture of chimeric mouse hepatocytes in 40% oxygen showed reduced intracellular lipid and triglyceride levels compared to those cultured in 20% oxygen on days 7 and 10. In addition, fatty acid β-oxidation (FAO) activity increased from day 7 under 40% oxygen conditions. On the other hand, FAO activity increased on day 10 under 20% conditions. Microarray and Ingenuity Pathway Analysis showed that lipid metabolism-related pathways were downregulated under 40% oxygen conditions for 7 days, suggesting the involvement of several mechanisms in decreasing lipid levels and increasing FAO. Furthermore, some pathways related to cellular function and maintenance were upregulated under 40% oxygen conditions for 7 days. In conclusion, chimeric mouse hepatocytes cultured under hyperoxic conditions may be useful for predicting DILI.