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Inorganic arsenic (iAs) is a common carcinogen that exists in the environment. Liver, as the main target organ of arsenic metabolism, long-term exposure to iAs can ultimately lead to carcinogenesis through two stages: liver fibrosis and cirrhosis. Ferroptosis is a type of programmed cell death caused by the accumulation of iron dependent lipid peroxides that affects the normal function of mitochondria. It has been found that ferroptosis occurs during liver fibrosis. Liver fibrosis caused by iAs has been a global health problem for a long time, but so far there is no effective treatment. The discovery of ferroptosis provides a new way to solve this problem. Therefore, this article will review the research progress of the mechanism of liver injury caused by iAs and ferroptosis.
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Objective:To analyze DNA methylation sites related to fibrosis and autophagy in human hepatic stellate cells (LX-2 cells) induced by sodium arsenite (NaAsO 2), and to screen specific methylation genes related to fibrosis and autophagy. Methods:Genome-wide DNA detection was performed using Illumina Infinium Methylation EPIC BeadChips (850K methylation chip) to derive differential methylation sites in LX-2 cells (control group) and the fibrosis and autophagy models of LX-2 cells induced by NaAsO 2(low, medium and high dose groups: the final concentrations were 5, 10, 15 μmol/L NaAsO 2, respectively, after 48 h intervention). Gene ontology (GO) function enrichment analysis and Kyoto encyclopedia of genes and genomes (KEGG) signaling pathway enrichment analysis were used to explore gene function. Results:The model of cell fibrosis and autophagy was established successfully in high dose group. The results of 850K methylation chip detection showed that there were 25 817 significant different methylation sites between the high dose group and the control group, including 12 083 hypermethylation sites and 13 734 hypomethylation sites. GO function enrichment analysis showed that the molecular functions of differentially methylated genes mainly included protein binding, ion binding, catalytic activity, enzyme binding. KEGG signaling pathway enrichment analysis showed that the pathways involved in differentially methylated genes mainly included metabolic pathway, cancer pathway, phosphatidylinositol-3-kinase-protein kinase B (PI3K-Akt) signaling pathway, endocytosis, and mitogen activated protein kinase (MAPK) signaling pathway. In the promoter region, 11 and 29 differentially methylated genes related to fibrosis and autophagy were screened, respectively.Conclusions:A large number of differential methylation sites exist in the process of NaAsO 2 induced fibrosis and autophagy of LX-2 cells. Specific methylation genes related to fibrosis and autophagy are screened out.
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Objective:To learn about the arsenic status of drinking water in Urumqi City and evaluate its health risk, so as to provide scientific basis for the construction of water improvement projects in Urumqi City.Methods:From 2018 to 2020, 687 water samples were collected at monitoring sites in 7 districts and 1 county of Urumqi City for three consecutive years, and arsenic in drinking water was detected according to "Standard Examination Methods for Drinking Water - Nonmetal Parameters" (GB/T 5750.5-2006), and the arsenic in drinking water was evaluated according to "Standards for Drinking Water" (GB/T 5749-2006). The health risk of arsenic in drinking water in Urumqi City was evaluated by using the health risk assessment model recommended by United States Environmental Protection Agency (USEPA).Results:All of 687 water samples were centralized water supply, the arsenic compliance rates in dry season ( n = 342) and wet season ( n = 345), surface water ( n = 414) and underground water ( n = 273) were 100.0%. In dry season, the carcinogenic risk of arsenic via drinking water was 8.24 × 10 -6/a. In wet season, the carcinogenic risk of arsenic via drinking water was 3.30 × 10 -6/a. Conclusions:Remarkable achievements have been made in the construction of water improvement projects in Urumqi City, and the drinking water arsenic condition is good, the health risk of arsenic via drinking water is small. In the future, we should continue to strengthen the monitoring of drinking water quality, promote the construction of water improvement projects, further improve the drinking water sanitation, and put forward targeted prevention and control measures to ensure drinking water safety.
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Objective@#To examine the effect of chronic exposure to sodium arsenite on liver damages in rats. @*Methods@#Fifty-six healthy adult SD rats (28 males and 28 females) were randomly divided into 4 groups. Rats in the low-, medium- and high-dose groups were given sodium arsenite solutions at doses of 2, 10 and 50 mg/L for successive 24 weeks, while animals in the control group were given deionized water. The rat body and liver weights were measured and the liver coefficient was estimated. The urine arsenic level was detected using atomic fluorescence spectrometry, and hepatic tissue sections were stained with uranium acetate and lead citrate for morphological observations under an electron microscope. @*Results@#The body weights of both male and female rats appeared a tendency towards a rise with the duration of exposure to sodium arsenite (male rat: Wald χ2=3 610.621, P<0.001; female rat: Wald χ2=2 186.217, P<0.001, and there were no significant differences in the rat body weight 24 weeks post-exposure to sodium arsenite in each group, while there was an interaction between time and group (male rat: Wald χ2=15.874, P=0.001; Wald χ2=9.460, P=0.024). There were significant differences in the rat liver weight and liver coefficient in each group (male rat: F=18.964 and 29.968, both P<0.001; female rat: F=11.919 and 15.070, both P<0.001), with the lowest liver weight (10.17±1.15) g and liver coefficient (1.99±0.21)% measured in male rats in the high-dose group, and the highest liver weight (12.91±1.29) g and liver coefficient (4.10±0.56)% in female rats in the high-dose group. The median urine arsenic levels (interquartile range) were 25.60 (30.27), 146.56 (101.06), 1 034.68 (600.06) and 3 796.98 (19 966.89) μg/L in rats in the control, low-dose, medium-dose and high-dose groups, respectively (χ2=50.211, P<0.001), and the urine arsenic level was significantly higher in the medium- and high-dose groups than in the control group (both P<0.001). Hepatic edema was seen in rats in the low- and medium-dose groups, and hepatic edema, focal hepatic cell necrosis, hyperplasia of bile capillaries and peri-bile capillary endolysis were observed in rats in the high-dose group.@*Conclusions@#Chronic exposure to arsenic may cause morphological alterations of rat hepatic tissues, and the rat hepatic damage aggravates with the dose of exposure to arsenic.