Metabolic changes induced by heavy metal copper exposure in human ovarian granulosa cells

Nrf2 mediates mitochondrial and NADPH oxidase-derived ROS during mild heat stress at 40 °C

Hyperthermia is an adjuvant to chemotherapy and radiotherapy and sensitizes tumors to these treatments. However, repeated heat treatments result in acquisition of heat resistance (thermotolerance) in tumors. Thermotolerance is an adaptive survival response that appears to be mediated by upregulated cellular defenses. However, the mechanisms of activation remain unclear. When HeLa cells were exposed to mild heat shock at 40 °C for 3 h, levels of superoxide and peroxides increased. Cells were treated with mitochondrial antioxidant MitoQ and NADPH oxidase (NOX) inhibitor apocynin to characterize the contribution of these two sources to the total reactive oxygen species (ROS) pool. We found that both mitochondria and NOX are sources of ROS during mild heat shock at 40 °C. Heat-derived ROS are thought to activate the adaptive survival response at 40 °C. Nrf2, the master regulator of the cellular antioxidant response, is thought to play a pivotal role in establishing the adaptive survival response. Nrf2 was overexpressed or knocked down to assess its role. Moreover, Nrf2 levels correlate with the cellular redox state, and do so via scavenging of mitochondria- and NOX-derived ROS. Knockdown of Nrf2 markedly increased levels of ROS that were scavenged by either apocynin or MitoQ. Finally, critical defense proteins such as DJ-1 and PGAM5 seemed to require a two-key activation system mediated by Nrf2 and mitochondrial ROS. Our study characterized mitochondrial and NOX-derived ROS as being essential in activating cellular defenses alongside Nrf2 and underlines potential therapeutic targets that may contribute to the acquisition of thermotolerance.

Reproductive toxicity of perfluorobutane sulfonate in zebrafish (Danio rerio): Impacts on oxidative stress, hormone disruption and HPGL axis dysregulation

Per and polyfluoroalkyl substances (PFAS) are anthropogenic chemicals extensively used in consumer products. Perfluorobutane sulfonate (PFBS), a short-chain PFAS, has been introduced as an alternative to long-chain PFAS, but limited studies have investigated its reproductive toxicity in fish. In this study, adult zebrafish were exposed to PFBS at concentrations of 0.14, 1.4, and 14 μM for 28 days. PFBS accumulation in male and female gonads was confirmed by specific mass spectrum peaks detected in exposed samples. PFBS exposure at 14 μM significantly reduced egg production and hatching rates. The gonadosomatic index (GSI) was decreased by 73 % in males and 50 % in females compared to the control. PFBS impaired antioxidant enzyme activity, with superoxide dismutase (SOD) 4.73 U/mg protein in testes and 3.46 U/mg protein in ovaries, leading to elevated lipid peroxidation and nitric oxide levels in males (0.053 μmol/mg/ml and 5.65 μM) and females (0.047 μmol/mg/ml and 4.01 μM), respectively. PFBS exposure induced endocrine disruption through the hypothalamic-pituitary-gonadal-liver (HPGL) axis, showing increased estrogen (50 pg/g) in males and testosterone (181.6 pg/g) in females. Gene expression analysis revealed significant alteration in the HPGL axis, including cyp19b, er2b, fshb, lhb, 17βhsd, lhr, cyp19a, and vtg, indicating PFBS influence on sex hormone synthesis. Histopathological analysis of PFBS exposure groups revealed a reduction of spermatozoa in the testes and late vitellogenic oocytes in the ovaries. Overall, the result of the present study indicates that PFBS exposure induces oxidative stress, disrupts hormone synthesis, dysregulates HPGL axis gene expression, and causes reproductive toxicity in both male and female zebrafish.

Tumor biomarkers contribute to the diagnosis and clinical management of the O-RADS MRI risk stratification system for epithelial ovarian tumors

BACKGROUND

To assess the effectiveness of tumor biomarkers in distinguishing epithelial ovarian tumors (EOTs) and guiding clinical decisions across each Ovarian-Adnexal Reporting and Data System (O-RADS) MRI risk category, the aim is to prevent unnecessary surgeries for benign lesions, avoid delays in treating malignancies, and benefit individuals requiring fertility preservation or those intolerant to over-extensive surgery.

METHODS

A total of 54 benign, 104 borderline, and 203 malignant EOTs (BeEOTs, BEOTs and MEOTs) were enrolled and retrospectively assigned risk scores. The role of tumor biomarkers in diagnosing and managing EOTs within each risk category was evaluated by combining receiver operating characteristic (ROC) curves with clinicopathological characteristics.

RESULTS

A score of 3 was assigned to 66.67% of BeEOTs, 50.96% of BEOTs, and 13.80% of MEOTs, whereas cancer antigen 125 (CA125) ≥ 60.39 U/ml helped identify MEOTs with a low-risk time-intensity curve (TIC) for prompt surgical assessment. Only 3.7% of the BeEOTs were classified as O-RADS MRI 4/5, whereas 48.08% and 86.2% of the BEOTs and MEOTs were classified, respectively. Overall, EOTs with a score of 4/5 are candidates for semi-elective surgery owing to the low probability of benign lesions. For EOTs with a ROMA index less than 20.14% (premenopausal) or 29.9% (postmenopausal), minimally invasive surgery is recommended for diagnostic and therapeutic purposes. Comprehensive staging or cytoreductive surgery is recommended for the remaining patients, especially when fertility preservation is not a priority.

CONCLUSIONS

The O-RADS MRI primarily differentiates BeEOTs with risk scores of 2/4/5 from BEOTs/MEOTs, while tumor biomarkers further enhance the diagnosis and clinical management of EOTs with scores of 3/4/5. Future studies should focus on multi-center, prospective studies with larger sample sizes to validate and refine the integration of O-RADS MRI with tumor biomarkers.

AI-Driven Microscopy: Cutting-Edge Approach for Breast Tissue Prognosis Using Microscopic Images

Microscopic imaging aids disease diagnosis by describing quantitative cell morphology and tissue size. However, the high spatial resolution of these images poses significant challenges for manual quantitative evaluation. This project proposes using computer-aided analysis methods to address these challenges, enabling rapid and precise clinical diagnosis, course analysis, and prognostic prediction. This research introduces advanced deep learning frameworks such as squeeze-and-excitation and dilated dense convolution blocks to tackle the complexities of quantifying small and intricate breast cancer tissues and meeting the real-time requirements of pathological image analysis. Our proposed framework integrates a dense convolutional network (DenseNet) with an attention mechanism, enhancing the capability for rapid and accurate clinical assessments. These multi-classification models facilitate the precise prediction and segmentation of breast lesions in microscopic images by leveraging lightweight multi-scale feature extraction, dynamic region attention, sub-region classification, and regional regularization loss functions. This research will employ transfer learning paradigms and data enhancement methods to enhance the models' learning further and prevent overfitting. We propose the fine-tuning employing pre-trained architectures such as VGGNet-19, ResNet152V2, EfficientNetV2-B1, and DenseNet-121, modifying the final pooling layer in each model's last block with an SPP layer and associated BN layer. The study uses labeled and unlabeled data for tissue microscopic image analysis, enhancing models' robust features and classification abilities. This method reduces the costs and time associated with traditional methods, alleviating the burden of data labeling in computational pathology. The goal is to provide a sophisticated, efficient quantitative pathological image analysis solution, improving clinical outcomes and advancing the computational field. The model, trained, validated, and tested on a microscope breast image dataset, achieved recognition accuracy of 99.6% for benign and malignant secondary classification and 99.4% for eight breast subtypes classification. Our proposed approach demonstrates substantial improvement compared to existing methods, which generally report lower accuracies for breast subtype classification ranging between 85% and 94%. This high level of accuracy underscores the potential of our approach to provide reliable diagnostic support, enhancing precision in clinical decision-making.

Understanding the effects of perfluorobutane sulfonate in zebrafish larvae model (Danio rerio): Insights into potential ecotoxicological risks and human health

Perfluorobutane sulfonate (PFBS) is a synthetic organic molecule that belongs to the per and polyfluoroalkyl substances family. Due to its unique physicochemical characteristics, PFBS has been extensively used in consumer products and industries. However, its increasing usage and chemical stability cause environmental pollution and bioaccumulation. The toxicological effects of PFBS were not well studied. In this study, the impact of PFBS on zebrafish embryos was evaluated. PFBS (1000-1500 μM) exposure exhibited increased mortality and malformation in a concentration-dependent manner. After 96 hour post-fertilization of PFBS exposure, the LC50 was estimated to be 1378 μM. Furthermore, PFBS (1.4, 14, 140, 1400 μM) exposure significantly increases oxidative stress by suppressing antioxidant levels. Locomotor behavior analysis revealed that PFBS exposure caused locomotor changes in zebrafish larvae. Acetylcholine esterase activity was also reduced in the PFBS-exposed groups. Gene expression study showed that PFBS exposure downregulated the antioxidant gene expression in zebrafish larvae. Overall, the current study reveals that PFBS can trigger oxidative stress-induced apoptosis by reducing antioxidant activity in zebrafish larvae.

Effects of mixed exposure to PFAS on adolescent non-alcoholic fatty liver disease: Integrating evidence from human cohorts, toxicogenomics, and animal models to uncover mechanisms and potential target sites

Extensive evidence suggests a correlation between environmental pollutants, specifically perfluoroalkyl and polyfluoroalkyl substances (PFAS) and non-alcoholic fatty liver disease (NAFLD). This study aims to investigate the association and underlying mechanisms of PFAS-induced NAFLD in adolescents by employing a comprehensive approach of population-based studies, toxicogenomics, and animal models. A total of 2014 freshmen from Dali University were recruited for this study, with 1694 participants undergoing serum testing for PFAS exposure. Additionally, Comparative Toxicogenomics Database analysis and PFAS exposure experiments were conducted by orally administering PFAS to 8-week-old adult C57/6 J mice for 28 days. Epidemiological analysis of the adolescent cohort revealed that perfluorohexanesulfonic acid and perfluorooctanoic acid are significant risk factors for NAFLD in adolescents. Toxicogenomic analysis revealed that the negative regulation of gap junction assembly and glutathione derivative biosynthesis contributes to NAFLD development. Animal model studies further demonstrated that combined PFAS exposure led to pathological changes in hepatocytes, including inflammation and steatosis, elevated liver enzymes, cholestasis, and bile canalicular blockage. This study reveals that PFAS exposure serves as a significant risk factor for hepatic steatosis/NAFLD in adolescents. The activation of cytochrome P4502E1 and glutathione S-transferase A1 signaling highlights new molecular targets for PFAS-induced disruptions in hepatic lipid metabolism.

Marine mussel metabolism under stress: Dual effects of nanoplastics and coastal hypoxia

Emerging challenges in marine environments include nanoplastics (NPs) pollution and coastal hypoxia. Although NPs toxicity in marine organisms is being increasingly documented, the complex interactions between coastal hypoxia and NPs remain largely unexplored. This study investigated the dual effects of polystyrene nanoplastics and different oxygen levels on redox homeostasis and bioenergetics in the marine model organism Mytilus galloprovincialis. Both NPs and hypoxia significantly disrupted redox homeostasis in mussels. Exposure to NPs alone increased electron transport chain activity, whereas exposure to hypoxia alone and co-exposure significantly reduced this activity. Metabolomic analysis showed that NPs primarily affected the pentose phosphate pathway (PPP), tricarboxylic acid (TCA) cycle, and amino acid metabolism; hypoxia exposure alone disrupted the TCA cycle, pyruvate metabolism, and glycolysis/gluconeogenesis, whereas combined exposure notably altered the TCA cycle, PPP, and sugar interconversion. This suggests that regulating these pathways would help mussels cope with the combined environmental stress. Furthermore, co-exposure severely disrupted redox homeostasis and energy metabolism in mussels, suggesting that hypoxia exacerbates NPs toxicity. We believe that these new findings would enhance our understanding of the compounded ecological risks posed by NPs in the context of climate change.

Emerging Role of Gut Microbiota in Breast Cancer Development and Its Implications in Treatment

Background: The human digestive system contains approximately 100 trillion bacteria. The gut microbiota is an emerging field of research that is associated with specific biological processes in many diseases, including cardiovascular disease, obesity, diabetes, brain disease, rheumatoid arthritis, and cancer. Emerging evidence indicates that the gut microbiota affects the response to anticancer therapies by modulating the host immune system. Recent studies have explained a high correlation between the gut microbiota and breast cancer: dysbiosis in breast cancer may regulate the systemic inflammatory response, hormone metabolism, immune response, and the tumor microenvironment. Some of the gut bacteria are related to estrogen metabolism, which may increase or decrease the risk of breast cancer by changing the number of hormones. Further, the gut microbiota has been seen to modulate the immune system in respect of its ability to protect against and treat cancers, with a specific focus on hormone receptor-positive breast cancer. Probiotics and other therapies claiming to control the gut microbiome by bacterial means might be useful in the prevention, or even in the treatment, of breast cancer. Conclusions: The present review underlines the various aspects of gut microbiota in breast cancer risk and its clinical application, warranting research on individualized microbiome-modulated therapeutic approaches to breast cancer treatment.

The complex role of regulatory cells in breast cancer: implication for immunopathogenesis and immunotherapy

Breast cancers (BCs) are frequently linked to an immunosuppressive microenvironment that facilitates tumor evasion of anti-cancer immunity. The cells that suppress the immune system such as regulatory B cells (Bregs), regulatory T cells (Tregs), tumor-associated macrophages (TAMs), tumor-associated neutrophils (TANs), myeloid-derived suppressor cells (MDSCs), play a crucial role in immune resistance. Also, tumor progression and immune evasion of cancers are facilitated by cytokines and factors released by tumor cells or immunosuppressive cells. Targeting these regulatory cells therapeutically, whether through elimination, inactivation, or reprogramming, has resulted in hopeful anti-tumor reactions. Yet, the substantial diversity and adaptability of these cells, both in terms of appearance and function, as well as their variation over time and depending on where they are in the body, have posed significant challenges for using them as reliable biomarkers and creating focused therapies that could target their creation, growth, and various tumor-promoting roles. The immunotherapy approaches in BC and their effectiveness in treating certain subtypes are still in their initial phases. In this review, we thoroughly outlined the characteristics, roles, and possible treatment options for these immune-suppressing cells in the tumor environment.

Mechanisms of calcium-induced protection against lead toxicity in Ulmus umbraculifera L.: a physiological and biochemical perspective

Lead (Pb) is a toxic stressor in the soil, which affects plant morphological and physiological events differently. A pot study was initiated to characterize the effect of calcium (Ca) application (20 and 40 mM) on Ulmus umbraculifera L. under Pb treatment (200 and 400 µM). The results revealed that higher levels of Pb significantly reduced plant height (48.3%), total dry weight (44.7%), leaf area index (45%), chlorophyll a (53.7%), chlorophyll b (51.4%), carotenoids (37.8%), and Fv/Fm ratio (20.4%) compared to untreated plants. However, the Ca application improved the aforementioned physiological features. Additionally, Pb toxicity disrupted oxidative status in the plants by increasing malondialdehyde (MDA), methylglyoxal, superoxide anion, and H₂O₂, which also induced the activities of SOD, GR, APX, and CAT. In contrast, Ca decreased MDA, methylglyoxal, superoxide anion, and H₂O₂ by enhancing SOD, CAT, GR, and APX activities compared to the control. Notably, ascorbate (AsA), dehydroascorbic acid (DHA), glutathione (GSH), oxidized glutathione (GSSG) levels, and AsA-DHA and GSH-GSSG ratios changed significantly with Pb and Pb + Ca treatments. According to our findings, monodehydroascorbate reductase (MDHAR), dehydroascorbate reductase (DHAR), glyoxalase (Gly) I, and Gly II activities increased with Pb treatment; however, Ca application further promoted their activities. Furthermore, Pb treatment significantly suppressed the uptake of mineral nutrients and increased Pb accumulation, whereas Ca application improved the uptake of these elements and lowered Pb content. These observations confirmed that the positive effects of Ca application on photosynthetic efficiency, nutrient absorption, and enzymatic and non-enzymatic antioxidants enhanced plant tolerance under Pb toxicity.

Assessing the therapeutic potential of KK14 peptide derived from Cyprinus Carpio in reducing intercellular ROS levels in oxidative Stress-Induced In vivo zebrafish larvae model: An integrated bioinformatics, antioxidant, and neuroprotective analysis

H2O2 is a significant reactive oxygen species (ROS) that hinders redox-mediated processes and contributes to oxidative stress and neurodegenerative disorders. Oxidative stress causes impairment of cell macromolecules, which results in cell dysfunction and neurodegeneration. Alzheimer's disease and other neurodegenerative diseases are serious conditions linked to oxidative stress. Antioxidant treatment approaches are a novel and successful strategy for decreasing neurodegeneration and reducing oxidative stress. This study explored the antioxidant and neuroprotective characteristics of KK14 peptide synthesized from LEAP 2B (liver-expressed antimicrobial peptide-2B) derived from Cyprinus carpio L. Molecular docking studies were used to assess the antioxidant properties of KK14. The peptide at concentrations 5-45 μM was examined by using in vitro and in vivo assessment. Analysis was done on the developmental and neuroprotective potential of KK14 peptide treatment in H2O2-exposed zebrafish larvae which showed Nonlethal deformities. KK14 improves antioxidant enzyme activity like catalase and superoxide dismutase. Furthermore, it reduces neuronal damage by lowering lipid peroxidation and nitric oxide generation while increasing acetylcholinesterase activity. It improved the changes in swimming behavior and the cognitive damage produced by exposure to H2O2. To further substantiate the neuroprotective potential of KK14, intracellular ROS levels in zebrafish larvae were assessed. This led to a reduction in ROS levels and diminished lipid peroxidation. The KK14 has upregulated the antioxidant genes against oxidative stress. Overall, this study proved the strong antioxidant activity of KK14, suggesting its potential as a strong therapeutic option for neurological disorders caused by oxidative stress.

Neurobehavioral and bioaccumulative toxicity in adult in-vivo zebrafish model due to prolonged cadmium exposure in the presence of ketoprofen

Increasing industrial activity causes the release of chemical compounds into aquatic habitats, including toxic heavy metals like cadmium and medications like ketoprofen, posing considerable ecological concerns. Although previous studies have shown that cadmium and ketoprofen individually cause cognitive impairment, there is a lack of information on the combined neurological effects of the two substances. We investigated the neurological consequences of persistent cadmium exposure in the presence of ketoprofen on adult zebrafish, providing an essential model for understanding cumulative impacts on vertebrate organisms. Behavioral assessments, bioaccumulation rates, biochemical studies, and histopathological exams were conducted over 42 days in authentic environmental settings. The results of our study show that cadmium (10 µg/L) and ketoprofen (10 and 100 µg/L) at environmentally relevant concentrations had a significant impact on locomotor activity, social interactions, and cognitive responses, indicating cumulative neurotoxicity in co-exposure groups compared to single pollutant groups. Biochemical tests show disturbances in antioxidant defense systems, while histological examinations reveal structural changes in zebrafish brain regions. Ketoprofen influences cadmium accumulation in the brain, underscoring the importance of conducting complete evaluations to understand the intricate interactions between environmental pollutants. This study improves our understanding of the complex interactions between heavy metals and medications, stressing the need to consider combined exposure when assessing the neurological effects on vertebrate models.

Investigating antioxidant effects of hamamelitannin-conjugated zinc oxide nanoparticles on oxidative stress-Induced neurotoxicity in zebrafish larvae model

BACKGROUND

An excessive amount of reactive oxygen species triggers oxidative stress, leading to an imbalance in cellular homeostasis. Antioxidant therapy is an effective tool for lowering the oxidative stress and associated ailments. Recently, green nano-based drug formulations have demonstrated promising antioxidant activity and neutralizing oxidative stress. In this study, a tannin molecule Hamamelitannin (HAM), was utilized to synthesize zinc oxide nanoparticles HAM-ZnO NPs, to mitigate oxidative stress and associated ailments .

METHODOLOGY

The HAM-ZnO NPs were synthesized and characterized by XRD, SEM, and FTIR. The antioxidant potentials of HAM-ZnO NPs were analyzed by in vitro antioxidant assays. Zebrafish embryos and larvae were used as in-vivo models to assess the toxicity and antioxidant protective mechanism. Hydrogen peroxide (1mM) was employed to induce oxidative stress and treated with HAM-ZnO NPs to study the cognitive impairment and antioxidant enzyme levels. Levels of reactive oxygen species and cell death due to oxidative stress induction were studied by 2',7'-dichlorodihydrofluorescein diacetate and Acridine orange staining methods. Additionally, expression of Antioxidant genes such as SOD, CAT, GPx, and GSR were studied. .

RESULTS

HAM-ZnO NPs exhibited a spherical morphology and size ranges between 48 and 53 nm. In vitro antioxidant studies revealed the antioxidant properties of HAM-ZnO NPs. Furthermore, in vivo studies indicated that HAM-ZnO NPs don't possess any cytotoxic effects in zebrafish larvae at concentrations between (5-25 µg/ml), The study also observed that HAM-ZnO NPs significantly reduced Hydrogen Peroxide-induced stress and increased antioxidant activity in zebrafish larvae. Also, the antioxidant gene expression was upregulated in the HAM-ZnO NPs zebrafish larvae.

CONCLUSION

Findings in this study showed that HAM-ZnO NPs might be a potential intervention for diseases linked to oxidative stress.

Assessing Heavy Metal Contamination in Commonly Used Fertilizers for Polyculture Fish Ponds and Its Implications for Human Health: A Comprehensive Investigation

Over-fertilizing fish ponds can cause pollution, introducing heavy metals into the food chain and posing health risks. The present study investigated the incidence of heavy metals (Pb, Cu, Cd, and Cr) in commonly applied fertilizers, including nitrogen, phosphorus and potassium (NPK), triple superphosphate (TSP), and di-ammonium phosphate (DAP), and their association with heavy metals in water, sediment, and cultured fish species (Catla catla, Labeo rohita, and Cyprinus carpio) in polyculture fish ponds. The study was conducted over 4 months, with four groups in triplicates: control (no fertilizer), group 1 (NPK), group 2 (TSP), and group 3 (DAP). Heavy metal analysis was carried out using atomic absorption spectrophotometry before and after fertilizer application. Significantly (p < 0.05) higher levels of heavy metals were observed in water and sediment after applying fertilizers, with the most pronounced results in group 3 (DAP) followed by group 2 (TSP). The concentration of heavy metals was significantly (p < 0.05) higher in group 3 (DAP) fertilizers compared to other groups. Compared to the control, the concentration and bioaccumulation of heavy metals were significantly (p < 0.05) higher in the fertilizer-applied groups, with notably higher levels in group 3 (DAP). Cluster analysis and the correlation matrix did not show any significant association between the heavy metals and the fertilizers, indicating a complex interplay between the biotic and abiotic factors of the system. The health index (HI) value was < 1 in fish muscles of all studied groups, indicating the fish are safe for consumption. The study recommends monitoring and regulating fertilizer use, especially DAP, to prevent heavy metal contamination, and exploring sustainable alternatives to minimize environmental and health risks.