Cellular Oxidative Damage of HEK293T Cells Induced by Combination of CdCl_2 and Nano-TiO_2

This study investigated the conjoined cellular oxidative damage of human embryo kidney 293T（HEK293T） cells induced by cadmium chloride（CdCl2） and nanometer titanium dioxide（nano-TiO2）.RT-PCR technique was used to detect the expressions of Heme oxygenase-1（HO-1） and 8-oxoguanine DNA glycosylase（OGG1）.The activities of superoxide dismutase（SOD） and catalase enzyme（CAT） and concentrations of reactive oxygen species（ROS） and maldondialdehyde（MDA） were measured by different approaches.The results showed that CdCl2 and nano-TiO2 at a low concen-tration of 0.75 total toxic unit（TU） exerted an additive effects on HO-1 gene expression,CAT activities and MDA concentrations.When the total TU was increased to 1 or 1.25 TU,the interaction was syner-getic.Moreover,the mixture with high proportion of CdCl2 produced an additive effect on the OGG1 gene expression,and the interaction was changed to be synergetic when the concentration of CdCl2 was lower than or equal to that of nano-TiO2.Synergetic effects of CdCl2 and nano-TiO2 on cellular oxida-tive damage of HEK293T cells were found as indicated by the changes in the SOD activities and ROS concentrations.It was concluded that CdCl2 and nano-TiO2 exerts synergistic effects on the cellular oxidative damage of HEK293T cells,and the sensitivity of these indicators of oxidative damage varies with the proportion of CdCl2 and nano-TiO2 in the mixture.

Protective Effect of Reduced Glutathione C_(60) Derivative against Hydrogen Peroxide-induced Apoptosis in HEK 293T Cells

Hydrogen peroxide（H_2O_2） and free radicals cause oxidative stress, which induces cellular injuries, metabolic dysfunction, and even cell death in various clinical abnormalities. Fullerene（C_（60）） is critical for scavenging oxygen free radicals originated from cell metabolism, and reduced glutathione（GSH） is another important endogenous antioxidant. In this study, a novel water-soluble reduced glutathione fullerene derivative（C_（60）-GSH） was successfully synthesized, and its beneficial roles in protecting against H_2O_2-induced oxidative stress and apoptosis in cultured HEK 293 T cells were investigated. Fourier Transform infrared spectroscopy and 1H nuclear magnetic resonance were used to confirm the chemical structure of C_（60）-GSH. Our results demonstrated that C_（60）-GSH prevented the reactive oxygen species（ROS）-mediated cell damage. Additionally, C_（60）-GSH pretreatment significantly attenuated H_2O_2-induced superoxide dismutase（SOD） consumption and malondialdehyde（MDA） elevation. Furthermore, C_（60）-GSH inhibited intracellular calcium mobilization, and subsequent cell apoptosis via bcl-2/bax-caspase-3 signaling pathway induced by H_2O_2 stimulation in HEK 293 T cells. Importantly, these protective effects of C_（60）-GSH were superior to those of GSH. In conclusion, these results suggested that C_（60）-GSH has potential to protect against H_2O_2-induced cell apoptosis by scavenging free radicals and maintaining intracellular calcium homeostasis without evident toxicity.

Downregulation of Serum PTEN Expression in Mercury-Exposed Population and PI3K/AKT Pathway-Induced Inflammation

Objective This study investigated the impact of occupational mercury(Hg) exposure on human gene transcription and expression, and its potential biological mechanisms.Methods Differentially expressed genes related to Hg exposure were identified and validated using gene expression microarray analysis and extended validation. Hg-exposed cell models and PTEN lowexpression models were established in vitro using 293T cells. PTEN gene expression was assessed using qRT-PCR, and Western blotting was used to measure PTEN, AKT, and PI3K protein levels. IL-6 expression was determined by ELISA.Results Combined findings from gene expression microarray analysis, bioinformatics, and population expansion validation indicated significant downregulation of the PTEN gene in the high-concentration Hg exposure group. In the Hg-exposed cell model(25 and 10 μmol/L), a significant decrease in PTEN expression was observed, accompanied by a significant increase in PI3K, AKT, and IL-6 expression.Similarly, a low-expression cell model demonstrated that PTEN gene knockdown led to a significant decrease in PTEN protein expression and a substantial increase in PI3K, AKT, and IL-6 levels.Conclusion This is the first study to report that Hg exposure downregulates the PTEN gene, activates the PI3K/AKT regulatory pathway, and increases the expression of inflammatory factors, ultimately resulting in kidney inflammation.

Expression of fluorescent tagged recombinant erythroferrone protein

Objective: To produce fluorescent tagged recombinant erythroferrone protein(ERFE_eGFP) for laboratory investigations. Methods: Erythroferrone(ERFE) gene was fused to green fluorescent protein(eGFP) gene and cloned in a pSecTag2Hygro plasmid. The constructed plasmid was amplified in Escherichia coli DH5α and the eGFP-fused ERFE(ERFE_eGFP) protein was expressed in human embryonic kidney(HEK293T) cell line. Results: The plasmid constructed from colony C6 contained ERFE_eGFP with the correct restriction sizes of 4.2 kb and expressed secretory ERFE_eGFP fusion protein(approximately size of 75 kDa) in HEK293T cell line. Conclusions: ERFE_eGFP recombinant protein is successfully expressed as a secretory functional protein and could be sensitively detected using fluorometry. This fusion protein might benefit future applications for localization of cellular ERFE receptors and competitive immunoassay of ERFE concentration.

Heterologous expression and cell membrane localization of dinoflagellate opsins (rhodopsin proteins) in mammalian cells

Rhodopsins are now found in all domains of life,and are classified into two large groups:type II,found in animals and type I found in microbes including Bacteria,Archaea,and Eukarya.While type II rhodopsin functions in many photodependent signaling processes including vision,type 1 among others contains rhodopsins that function as a light-driven proton pump to convert light into ATP as in proteobacteria(named proteorhodopsin).Proteorhodopsin homologs have been documented in dinoflagellates,but their subcellular localizations and functions are still poorly understood.Even though sequence analyses suggest that it is a membrane protein,experimental evidence that dinoflagellate rhodopsins are localized on the plasma membrane or endomembranes is still lacking.As no robust dinoflagellate gene transformation tool was available,we used HEK 293T cells to construct a mammalian expression system for two dinoflagellate rhodopsin genes.The success of expressing these genes in the system shows that this mammalian cell type is suitable for expressing dinoflagellate genes.Immunofluorescence of the expressed protein locates these dinoflagellate rhodopsins on the cell membrane.This result indicates that the protein codons and membrane targeting signal of the dinoflagellate genes are compatible with the mammalian cells,and the proteins'subcellular localization is consistent with proton pump rhodopsins.

The class A macrophage scavenger receptor type I (SR-AI) recognizes complement iC3b and mediates NF-κB activation

The macrophage scavenger receptor SR-AI binds to host tissue debris to perform clearance and it binds to bacteria for phagocytosis.In addition,SR-AI modulates macrophage activation through cell signaling.However,investigation of SR-AI signaling on macrophages is complicated due to its promiscuous ligand specificity that overlaps with other macrophage receptors.Therefore,we expressed SR-AI on HEK 293T cells to investigate its ligand binding and signaling.On 293T cells,SR-AI could respond to E.coli DH5α,leading to NF-κB activation and IL-8 production.However,this requires E.coli DH5αto be sensitized by fresh serum that is treated with heat-inactivation or complement C3 depletion.Anti-C3 antibody inhibits the binding of SR-AI to serum-sensitized DH5αand blocks DH5αstimulation of SR-AI signaling.Further analysis showed that SR-AI can directly bind to purified iC3b but not C3 or C3b.By mutagenesis,The SRCR domain of SR-AI was found to be essential in SR-AI binding to serum-sensitized DH5α.These results revealed a novel property of SR-AI as a complement receptor for iC3b-opsonized bacteria that can elicit cell signaling.