Long non-coding RNA TUG1 contributes to tumorigenesis of human osteosarcoma by sponging miR-9-5p and regulating POU2F1 expression.

Recent studies have shown that long non-coding RNAs (lncRNAs) have critical roles in tumorigenesis, including osteosarcoma. The lncRNA taurine-upregulated gene 1 (TUG1) was reported to be involved in the progression of osteosarcoma. Here, we investigated the role of TUG1 in osteosarcoma cells and the underlying mechanism. TUG1 expression was measured in osteosarcoma cell lines and human normal osteoblast cells by quantitative real-time PCR (qRT-PCR). The effects of TUG1 on osteosarcoma cells were studied by RNA interference in vitro and in vivo. The mechanism of competing endogenous RNA (ceRNA) was determined using bioinformatic analysis and luciferase assays. Our data showed that TUG1 knockdown inhibited cell proliferation and colony formation, and induced G0/G1 cell cycle arrest and apoptosis in vitro, and suppressed tumor growth in vivo. Besides, we found that TUG1 acted as an endogenous sponge to directly bind to miR-9-5p and downregulated miR-9-5p expression. Moreover, TUG1 overturned the effect of miR-9-5p on the proliferation, colony formation, cell cycle arrest, and apoptosis in osteosarcoma cells, which involved the derepression of POU class 2 homeobox 1 (POU2F1) expression. In conclusion, our study elucidated a novel TUG1/miR-9-5p/POU2F1 pathway, in which TUG1 acted as a ceRNA by sponging miR-9-5p, leading to downregulation of POU2F1 and facilitating the tumorigenesis of osteosarcoma. These findings may contribute to the lncRNA-targeted therapy for human osteosarcoma.

Sensitive detection of cyanide using bovine serum albumin-stabilized cerium/gold nanoclusters.

A simple, sensitive, and selective fluorescence assay for the detection of CN(-) has been demonstrated using bovine serum albumin-stabilized cerium/gold nanoclusters (BSA-Ce/Au NCs). When excited at 325 nm, BSA-Ce/Au NCs have two fluorescence bands centered at 410 and 658 nm, which are assigned to BSA-Ce/Au complexes and Au NCs, respectively. Each BSA-Ce/Au NC contains 22 Au atoms and 8 Ce ions. Through etching of the Au core in BSA-Ce/Au NCs by CN(-), the fluorescence at 658 nm is quenched, while that at 410 nm enhances during the formation of complexes among BSA, Ce(4+), and [Au(CN)2](-). The circular dichroism spectra reveal that relative to BSA-Au NCs, BSA-Ce/Au NCs have looser structures of the BSA templates. As a result, it is easier for CN(-) to access the Au cores in BSA-Ce/Au NCs, allowing faster (within 15 min) etching of the Au cores by CN(-). At pH 12.0, this assay allows the detection of CN(-) down to 50 nM, with linearity over 0.1-15 µM. This assay has been applied to the determination of the concentrations of CN(-) in spiked drinking water and pond water samples.

Nitrogen Pretreatment of Growth Substrates for Vacancy-Saturated MoS2.

Two-dimensional transition-metal dichalcogenides (2D TMDCs) are considered promising materials for optoelectronics due to their unique optical and electric properties. However, their potential has been limited by the occurrence of atomic vacancies during synthesis. While post-treatment processes have demonstrated the passivation of such vacancies, they increase process complexity and affect the TMDC's quality. We here introduce the concept of pretreatment as a facile and powerful route to solve the problem of vacancies in MoS2. Low-temperature nitridation of the sapphire substrate prior to growth provides a nondestructive method to MoS2 modification without introducing new processing steps or increasing the thermal budget. Spectroscopic characterization and atomic-resolution microscopy reveal the incorporation of nitrogen from the sapphire surface layer into chalcogen vacancies. The resulting MoS2 with nitrogen-saturated defects shows a decrease in midgap states and more intrinsic doping as confirmed by ab initio calculations and optoelectronic measurements. The demonstrated pretreatment method opens up new routes toward future, high-performance 2D electronics, as evidenced by a 3-fold reduction in contact resistance and a 10-fold improved performance of 2D photodetectors.

Identification and characterization of infectious bursal disease virus subviral particles by capillary zone electrophoresis: potential application for vaccine production and quality control.

The infectious bursal disease (IBD) causes immunosuppression in chicken of all ages and high mortality in young chicken, posing serious threat to poultry industry worldwide. One promising strategy for preventing this highly contagious disease is using recombinant subunit vaccine, employing VP2 subviral particles (SVP) as epitomic antigen. Analytical techniques of viral-like particles such as SDS-PAGE, western blot, or high-performance size-exclusion chromatography have been widely applied, but mostly unsatisfactory. In the present study, a simple, fast and cost-effective capillary zone electrophoresis (CZE) method with UV-detection was developed to analyze purified IBDV-SVP (expressed by Escherichia coli system) using commercial monoclonal antibody (mAb) against VP2. To find satisfying CZE conditions, injection mode, separation voltage, and separation buffer were explored. Through the modified CZE, mAb and SVP could be well separated and shown distinct peaks in the electropherogram. Furthermore, to determine the stoichiometry, the area of the mAb peak versus SVP/mAb binding ratio was plotted and indicated that 2 or 3 receptor molecules were bound per SVP. The purity and integrity of SVP and the interactions between SVP and mAb could be analyzed by the developed simple CZE-UV method in less than half hour. This CZE-UV method proved to be a valuable and useful tool in detection, characterization, and quantification of IBDV-SVP and the mAb, offering potential applications of in-process quality control of vaccine production, surveillance of serum antibody produced against IBDV infection, or vaccine immunization.