TRIP13 is identified as a prognosis biomarker for renal clear cell carcinoma and promotes renal cell carcinoma cell proliferation, migration and invasion

This work aimed to discover new therapeutic targets in renal clear cell carcinoma by bioinformatics and detect the effect of candidate gene TRIP13 in renal cell carcinoma(RCC)cell proliferation,migration,and invasion.Differentially expressed mRNAs were screened based on The Cancer Genome Atlas(TCGA)-Kidney Renal Clear Cell Carcinoma(KIRC)databases,and functional enrichments,survival analysis,receiver operating characteristic curve(ROC),and Protein–Protein Interaction(PPI)protein interaction analysis were performed by R software to screen the candidate gene TRIP13.Then,the expression of candidate gene TRIP13 in 92 pairs of cancer and adjacent normal tissues of renal clear cell carcinoma patients were detected by qRT-PCR,western blotting,and immunochemical analysis.The TRIP13 level and clinicopathological characteristics of patients with renal clear cell carcinoma were analyzed.Using 186-O and ACHN RCC cell lines with TRIP13 overexpressing or downregulating,the effect of TRIP13 on cell viability and proliferation were detected by CCK8 and EdU staining,respectively.The migration and invasion were detected by Transwell assays.A total of 19858 differentially expressed genes,5823 differentially expressed genes,3657 up-regulated genes,and 2166 down-regulated genes were identified.TRIP13 was closed associated with cell cycle regulation,and survival and prognosis of renal clear cell carcinoma were selected as a candidate gene.The mRNA and protein levels of TRIP13 in cancer tissues were higher than that in adjacent normal tissues.TRIP13 level was significantly associated with tumor size,tumor stage,Fuhrman grade,and lymph node metastasis.TRIP13 overexpression significantly increased cell viability,proliferation,migration,and invasion,while downregulating of TRIP13 had opposite effects in both 186-O and ACHN cells.Therefore,TRIP13 promotes RCC proliferation and metastasis,which should be a novel biomarker for early diagnosis,treatment,and prognosis of RCC.

Tet methylcytosine dioxygenase 2 suppresses renal cell cancer proliferation and metastasis by regulating the miR-200c-SCD axis

Tet methylcytosine dioxygenase 2(TET2)acts as an antioncogene that is investigated in different cancers.But the effects of TET2 in renal cell cancer(RCC)is still known little.Here,quantitative real-time PCR(qRT-PCR),Western blot,and immunofluorescence were performed to exam gene and protein expression.Cell proliferation was measured using Cell Counting Kit-8(CCK-8).Transwell assay was performed to detect cell metastasis viability.Flow cytometry was performed to analyze the cell cycle and cell apoptosis.The effects of TET2 on RCC growth in vivo was analyzed using a mouse xenograft model.We found that TET2 and miR-200c were decreased in RCC tissues,and hypermethylation of miR-200c promoter was found.Overexpression of TET2 promoted miR-200c expression by reducing miR-200c promoter methylation.Additionally,overexpression of TET2 or miR-200c suppressed cell growth and metastasis.Also,knockdown of miR-200c could moderate TET2 mediated cell growth inhibition.Furthermore,we found miR-200c directly regulates Stearoyl-CoA desaturase(SCD)gene expression.Moreover,in vivo experiment results confirmed that TET2 inhibited tumor growth.In conclusion,TET2 acts as an antioncogene in RCC by regulating the miR-200c-SCD axis and providing a potential target for RCC diagnosis and treatment.

Influence of Temperature on Stacking Fault Energy and Creep Mechanism of a Single Crystal Nickel-based Superalloy

The influence of temperatures on the stacking fault energies and deformation mechanism of a Re- containing single crystal nickel-based superalloy during creep at elevated temperatures was investigated by means of calculating the stacking fault energy of alloy, measuring creep properties and performing contrast analysis of dislocation configuration. The results show that the alloy at 760 ℃ possesses lower stacking fault energy, and the stacking fault of alloy increases with increasing temperature. The defor- mation mechanism of alloy during creep at 760 ℃ is 7＇ phase sheared by 〈110〉 super-dislocations, which may be decomposed to form the configuration of Shockley partials plus super-lattice intrinsic stacking fault, while the deformation mechanism of alloy during creep at 1070 ℃ is the screw or edge super- dislocations shearing into the rafted 7＇ phase. But during creep at 7（50 and 980 ℃, some super- dislocations shearing into 7＇ phase may cross-slip from the {111} to {100} planes to form the K-W locks with non-plane core structure, which may restrain the dislocations slipping to enhance the creep resis- tance of alloy at high temperature. The interaction between the Re and other elements may decrease the diffusion rate of atoms to improve the microstructure stability, which is thought to be the main reason why the K-W locks are to be kept in the Re-containing superalloy during creep at 980 ℃.