Effects of miR-214 on cervical cancer cell proliferation, apoptosis and invasion via modulating PI3K/AKT/mTOR signal pathway.

Since this article has been suspected of research misconduct and the corresponding authors did not respond to our request to prove originality of data and figures, "Effects of miR-214 on cervical cancer cell proliferation, apoptosis and invasion via modulating PI3K/AKT/mTOR signal pathway, by F. Wang, W.-H. Tan, W. Liu, Y.-X. Jin, D.-D. Dong, X.-J. Zhao, Q. Liu, published in Eur Rev Med Pharmacol Sci 2018; 22 (7): 1891-1898-DOI: 10.26355/eurrev_201804_14711-PMID: 29687840" has been withdrawn. The Publisher apologizes for any inconvenience this may cause. https://www.europeanreview.org/article/14711.

Effects of miR-214 on cervical cancer cell proliferation, apoptosis and invasion via modulating PI3K/AKT/mTOR signal pathway.

OBJECTIVE: PI3K/AKT/mTOR pathway plays important roles in tumor pathogenesis. mTOR is up-regulated and miR-214 is down-regulated in cervical can-*cers. This study investigated whether miR-214 regulated mTOR expression and affected cervical cancer cell proliferation, apoptosis or invasion. PATIENTS AND METHODS: Cervical cancer tissues were collected in parallel with normal epithelium for measuring the expression of miR-214 and mTOR. Dual luciferase expression assay was performed to evaluate the targeted relationship between miR-214 and mTOR. In vitro cultured SiHa cells were treated with miR-214 mimic or si-mTOR followed by measuring mTOR, p-mTOR and Bcl-2 expression. Cell apoptosis, proliferation and invasion were measured by flow cytometry and transwell assay. RESULTS: Bioinformatics analysis showed targeted binding sites between miR-214 and 3'-UTR of mTOR mRNA. Dual luciferase reporter assay confirmed this regulatory relationship between miR-214 and mTOR mRNA. Compared to normal cervical epithelium, cancer tissues had lower expression of miR-214 and higher mTOR, both of which were correlated with TNM stage and tissue pathology grade. Compared to Ect1/E6E7 cells, SiHa cells had lower level of miR-214 and higher mTOR/p-mTOR and Bcl-2 expression. Transfection of miR-214 mimic or si-mTOR significantly decreased mTOR/p-mTOR or Bcl-2 expression, inhibited cell proliferation or invasion, and enhanced cell apoptosis. CONCLUSIONS: miR-214 down-regulation plays a role in elevating mTOR expression and in facilitating cervical cancer pathogenesis. Over-expression of miR-214 inhibits cervical cancer cell proliferation or invasion, and facilitates apoptosis via targeted inhibition of mTOR expression.

Composition formulas of binary eutectics.

The present paper addresses the long-standing composition puzzle of eutectic points by introducing a new structural tool for the description of short-range-order structural unit, the cluster-plus-glue-atom model. In this model, any structure is dissociated into a 1(st)-neighbor cluster and a few glue atoms between the clusters, expressed by a cluster formula [cluster]gluex. This model is applied here to establish the structural model for eutectic liquids, assuming that a eutectic liquid consist of two subunits issued from the relevant eutectic phases, each being expressed by the cluster formula for ideal metallic glasses, i.e., [cluster](glue atom)(1 or 3). A structural unit is then composed of two clusters from the relevant eutectic phases plus 2, 4, or 6 glue atoms. Such a dual cluster formulism is well validated in all boron-containing (except those located by the extreme phase diagram ends) and in some commonly-encountered binary eutectics, within accuracies below 1 at.%. The dual cluster formulas vary extensively and are rarely identical even for eutectics of close compositions. They are generally formed with two distinctly different cluster types, with special cluster matching rules such as cuboctahedron plus capped trigonal prism and rhombidodecahedron plus octahedral antiprism.

Alleviation of streptozotocin-induced diabetes in nude mice by stem cells derived from human first trimester umbilical cord.

Cells isolated from human first trimester umbilical cord perivascular layer (hFTM-PV) tissues display the pluripotent characteristics of stem cells. In this study, we examined whether hFTM-PV cells can differentiate into islet-like clusters (ILCs) in vitro, and whether transplantation of the hFTM-PV cells with and without differentiation in vitro can alleviate diabetes in nude mice. The hFTM-PV cells were differentiated into ILCs in vitro through a simple stepwise culture protocol. To examine the in vivo effects of the cells, the hFTM-PV cells with and without differentiation in vitro were transplanted into the abdominal cavity of nude mice with streptozotocin (STZ)-induced diabetes. Blood glucose levels, body weight, and the survival probability of the diabetic nude mice were then statistically analyzed. The hFTM-PV cells were successfully induced into ILCs that could release insulin in response to elevated concentrations of glucose in vitro. In transplantation experiments, we observed that mice transplanted with the undifferentiated hFTM-PV cells, embryonic body-like cell aggregations, or ILCs all demonstrated normalized hyperglycemia and showed improved survival rate compared with those without cell transplantation. The hFTM-PV cells have the ability to differentiate into ILCs in vitro and transplantations of undifferentiated and differentiated cells can alleviate STZ-induced diabetes in nude mice. This may offer a potential cell source for stem cell-based therapy for treating diabetes in the future.