Integration of transcriptomics and metabolomics analysis for unveiling the toxicological profile in the liver of mice exposed to uranium in drinking water.

Uranium is a contaminate in the underground water in many regions of the world, which poses health risks to the local populations through drinking water. Although the health hazards of natural uranium have been concerned for decades, the controversies about its detrimental effects continue at present since it is still unclear how uranium interacts with molecular regulatory networks to generate toxicity. Here, we integrate transcriptomic and metabolomic methods to unveil the molecular mechanism of lipid metabolism disorder induced by uranium. Following exposure to uranium in drinking water for twenty-eight days, aberrant lipid metabolism and lipogenesis were found in the liver, accompanied with aggravated lipid peroxidation and an increase in dead cells. Multi-omics analysis reveals that uranium can promote the biosynthesis of unsaturated fatty acids through dysregulating the metabolism of arachidonic acid (AA), linoleic acid, and glycerophospholipid. Most notably, the disordered metabolism of polyunsaturated fatty acids (PUFAs) like AA may contribute to lipid peroxidation induced by uranium, which in turn triggers ferroptosis in hepatocytes. Our findings highlight disorder of lipid metabolism as an essential toxicological mechanism of uranium in the liver, offering insight into the health risks of uranium in drinking water.

Roles of glutathione peroxidase 4 on the mercury-triggered ferroptosis in renal cells: implications for the antagonism between selenium and mercury.

Understanding of how mercury species cause cellular impairments at the molecular level is critical for explaining the detrimental effects of mercury exposure on the human body. Previous studies have reported that inorganic and organic mercury compounds can induce apoptosis and necrosis in a variety of cell types, but more recent advances reveal that mercuric mercury (Hg2+) and methylmercury (CH3Hg+) may result in ferroptosis, a distinct form of programmed cell death. However, it is still unclear which protein targets are responsible for ferroptosis induced by Hg2+ and CH3Hg+. In this study, human embryonic kidney 293T cells were used to investigate how Hg2+ and CH3Hg+ trigger ferroptosis, given their nephrotoxicity. Our results demonstrate that glutathione peroxidase 4 (GPx4) plays a key role in lipid peroxidation and ferroptosis in renal cells induced by Hg2+ and CH3Hg+. The expression of GPx4, the only lipid repair enzyme in mammal cells, was downregulated in response to Hg2+ and CH3Hg+ stress. More importantly, the activity of GPx4 could be markedly inhibited by CH3Hg+, owing to the direct binding of the selenol group (-SeH) in GPx4 to CH3Hg+. Selenite supplementation was demonstrated to enhance the expression and activity of GPx4 in renal cells, and consequently relieve the cytotoxicity of CH3Hg+, suggesting that GPx4 is a crucial modulator implicated in the Hg-Se antagonism. These findings highlight the importance of GPx4 in mercury-induced ferroptosis, and provide an alternative explanation for how Hg2+ and CH3Hg+ induce cell death.

High-Throughput Absolute Quantification Sequencing Reveals that a Combination of Leguminous Shrubs Is Effective in Driving Soil Bacterial Diversity During the Process of Desertification Reversal.

Desertification leads to the extreme fragility of ecosystems and seriously threatens ecosystem functioning in desert areas. The planting of xerophytes, especially leguminous shrubs, is an effective and common means to reverse desertification. Soil microorganisms play a crucial role in nutrient cycling and energy flow in ecosystems. However, the effects of introducing leguminous shrubs on soil microbial diversity and the relevant mechanisms are not clear. Here, we employed the high-throughput absolute quantification 16S rRNA sequencing method to analyze the diversity of soil bacteria in sand-fixing areas of mixed shrublands with three combinations of shrubs, i.e., C. korshinskii × Corethrodendron scoparium (CaKCoS), C. korshinskii × Calligonum mongolicum (CaKCaM), and C. scoparium × C. mongolicum (CoSCaM), in the south of the Mu Us Sandy Land, China. This area suffered from moving dunes 20 years ago, but after introducing these shrubs to fix the dunes, the ecosystem was restored. Additionally, the effects of soil physicochemical properties on soil bacterial composition and diversity were analyzed with redundancy analysis (RDA) and structural equation modeling (SEM). It was found that the Shannon index of soil bacteria in CaKCoS was significantly higher than that in CaKCaM and CoSCaM, and the abundance of the dominant phyla, including Actinobacteria, Proteobacteria, Acidobacteria, Chloroflexi, Planctomycetes, Thaumarchaeota, Armatimonadetes, candidate_division_WPS-1, and Nitrospirae, increased significantly in CaKCoS and CaKCaM compared to that in CoSCaM. RDA showed that the majority of soil properties, such as total nitrogen (TN), available potassium (AK), N:P ratio, soil moisture (SM), and available phosphorus (AP), were important soil environmental factors affecting the abundance of the dominant phyla, and RDA1 and RDA2 accounted for 56.66% and 2.35% of the total variation, respectively. SEM showed that the soil bacterial α-diversity was positively affected by the soil organic carbon (SOC), N:P ratio, and total phosphorus (TP). Moreover, CaKCoS had higher SM, total carbon (TC), total potassium (TK), and AP than CaKCaM and CoSCaM. Collectively, these results highlight a conceptual framework in which the combination of leguminous shrubs can effectively drive soil bacterial diversity by improving soil physicochemical properties and maintaining ecosystem functioning during desertification reversal.

Emerging health risks and underlying toxicological mechanisms of uranium contamination: Lessons from the past two decades.

Uranium contamination is a global health concern. Regarding natural or anthropogenic uranium contamination, the major sources of concern are groundwater, mining, phosphate fertilizers, nuclear facilities, and military activities. Many epidemiological and laboratory studies have demonstrated that environmental and occupational uranium exposure can induce multifarious health problems. Uranium exposure may cause health risks because of its chemotoxicity and radiotoxicity in natural or anthropogenic scenarios: the former is generally thought to play a more significant role with regard to the natural uranium exposure, and the latter is more relevant to enriched uranium exposure. The understanding of the health risks and underlying toxicological mechanisms of uranium remains at a preliminary stage, and many controversial findings require further research. In order to present state-of-the-art status in this field, this review will primarily focus on the chemotoxicity of uranium, rather than its radiotoxicity, as well as the involved toxicological mechanisms. First, the natural or anthropogenic uranium contamination scenarios will be briefly summarized. Second, the health risks upon natural uranium exposure, for example, nephrotoxicity, bone toxicity, reproductive toxicity, hepatotoxicity, neurotoxicity, and pulmonary toxicity, will be discussed based on the reported epidemiological cases and laboratory studies. Third, the recent advances regarding the toxicological mechanisms of uranium-induced chemotoxicity will be highlighted, including oxidative stress, genetic damage, protein impairment, inflammation, and metabolic disorder. Finally, the gaps and challenges in the knowledge of uranium-induced chemotoxicity and underlying mechanisms will be discussed.

Aerobic biodegradation process of petroleum and pathway of main compounds in water flooding well of Dagang oil field.

Aerobic biodegradation of crude oil and its pathways were investigated via in vitro culture and GC-MS analysis in water flooding wells of Dagang oil field. The in vitro aerobic culture lasted 90 days when 99.0% of n-alkanes and 43.03-99.9% of PAHs were degraded and the biomarkers and their ratios were changed. The spectra of components in the residual oil showed the similar biodegradation between aerobic process of 90 days and degradation in reservoir which may last for some millions years, and the potential of serious aerobic biodegradation of petroleum in reservoir. 24 Metabolites compounds were separated and identified from aerobic culture, including fatty acid, naphthenic acid, aromatic carboxylic acid, unsaturated acid, alcohols, ketones and aldehydes. The pathways of alkanes and aromatics were proposed, which suggests that oxidation of hydrocarbon to organic acid is an important process in the aerobic biodegradation of petroleum.

[Investigation on the dietary iron intake of infants from four month-old to one year-old in Shunyi District of Beijing].

OBJECTIVE: To understand the present status of dietary iron intake of infants from 4 to 12 month-old in urban and rural areas of Shunyi District of Beijing, and to provide scientific basis for their supplementary foods. METHODS: Two hundred and sixty-six infants were selected and investigated with a 3-day (72h) dietary record questionary. RESULTS: The average dietary iron intake of 4 - 5 month-old infants has achieved to the Dietary Reference Intakes, and no significant difference was observed between the intakes in urban and rural areas (P > 0.05). The proportion of infants whose dietary iron intake was higher than the Adequate Intakes (AI) of iron was just 19.8% among the studied infants in rural and 36. 9% in urban areas (P < 0.01). There was no significant difference on breastfeeding rates in rural and urban groups (P > 0.05). The main dietary iron sources were from cereals, fruits, eggs, vegetables and meat. CONCLUSION: The dietary iron intake of 6 - 12 month-old infants in Shunyi was significantly insufficient. Encouraging mothers to go on fully breastfeeding for at least 6 months, as well as giving supplementary foods rich in iron at the right time according to the state of infants.

[Primary culture and morphologic observation of eutopic and ectopic endometrial cells from patients with endometriosis].

OBJECTIVE: To explore the method of primary culture for endometriotic cells and to find out the differences in morphological manifestations among endometriotic cells and eutopic endometrial cells sampled from patients with endometriosis and endometriosis-free women. METHODS: Endometriotic and eutopic endometrial cells were cultured by modified method of primary culture. The endometriotic cell types were observed and differentiated under optical and electron microscopes. RESULTS: The success rates for culture of eutopic endometrial cells from endometriosis-free women and patients with endometriosis were 91.67% and 93.75% respectively. The success rate for culture of endometriotic cells was 75.00%. The size of endometriotic glandular cells was similar to those of eutopic endometrial glandular cells from endometriosis-free women and patients with endometriosis. The chromatin was manifold and the nucleus was augmented in the endometriotic glandular cells. The endometriotic stromal cells were smaller than the eutopic endometrial stromal cells from endometriosis-free women and patients with endometriosis. Many tiny villi and protuberances on plasma membrane could be seen in the endometriotic stromal cells. CONCLUSION: The success rate for culture of endometriotic cells can be elevated through improving the method of primary culture. The ultrastructures of endometriotic glandular and stromal cells are obviously different from those of eutopic endometrial glandular and stromal cells from endometriosis-free women and patients with endometriosis.