Identification of Prognostic Related Hub Genes in Clear-Cell Renal Cell Carcinoma via Bioinformatical Analysis

Objective To identify new genes that correlate with prognosis of clear-cell renal cell carcinoma(ccRCC)via bioinformatics analysis.Methods The gene expression profiles of 62 ccRCC and 54 normal kidney tissues were available from the Gene Expression Omnibus database:GSE12606,GSE36895 and GSE66272.The differentially expressed genes were screened with GEO2R and J Venn online tools.Functional annotation including Gene Ontology(GO)and Kyoto Encyclopedia of Genes and Genomes(KEGG)was applied to identify the possible function of the hub genes involved in prognosis of ccRCC.In protein protein interaction network(PPI network),the STRING online tool was used to visualize the network of the differentially expressed genes,and the core gene was selected by MCODE App in Cytoscape software.Finally,GEPIA Survival Plot was performed to assess genes associated with worse survival.Results We totally found 648 diflerentially expressed genes,including 222 up-regulated genes and 426 down-regulated genes.PPI network showed that in 28 up-regulated genes 7(CCNE2,CDK1,CDC6,CCNB2,BUB1,TTK and PTTG1)enriched in cell cycle and 4 genes(CCNE2,CDK1,CCNB2 and RRM2)enriched in p53 signaling pathway.GEPIA Survival Plot assay revealed that ccRCC patients carrying CDK1,CCNB2,RRM2t BUB1,and PTTG1 had a worse survival.GEPIA Box Plot showed that BUB1,CCNB2,PTTG1,and RRM2 were over expressed in the ccRCC tissues in contrast to the normal tissues(P<O.OS).Conclusion ccRCC patients with the four up-regulated differentially expressed genes including BUB1,CCNB2,PTTG1,and RRM2 might manifest a poor prognosis.

Te-doped Fe_(3)O_(4) flower enabling low overpotential cycling of Li-CO_(2) batteries at high current density

Li-CO_(2)batteries(LCBs)suffer from high overpotentials caused by sluggish CO_(2)reaction kinetics.This work designs a Te-doped Fe_(3)O_(4)(Te-Fe_(3)O_(4))flower-like microsphere catalyst to lower the overpotential and improve the reversibility of LCBs.Experimental results reveal that Te doping modifies the electronic structure of Fe_(3)O_(4)and reduces the overpotential.The stable Te-O bond between Te and C_(2)O^(2-)_(4)could effectively inhibit the dispro-portionation reaction of the latter,enabling the Te-Fe_(3)O_(4)cathodes to exhibit a remarkable capacity(9485 mAh g^(-1))and a long cycling life(155 cycles)with an overpotential of 1.21 V and an energy efficiency of about 80%at a high current density(2000 mA g^(-1)).Through the interaction between Te and Li_(2)C_(2)O_(4)to inhibit the dispro-portionation reaction,this work successfully achieves long-term cycling of LCBs with low overpotential at high current density.

Synergized oxygen vacancies with Mn_(2)O_(3)@CeO_(2)heterojunction as high current density catalysts for Li-O_(2)batteries

The application of Li-O_(2)batteries(LOBs)with ultra-high theoretical energy density is limited due to the slow redox kinetics and serious side reactions,especially in high-rate cycles.Herein,CeO_(2)is constructed on the surface of Mn_(2)O_(3)through an interface engineering strategy,and Mn_(2)O_(3)@CeO_(2)heterojunction with good activity and stability at high current density is prepared.The interfacial properties of catalyst and formation mechanism of Li_(2)O_(2)are deeply studied by density functional theory(DFT)and experiments,revealing the charge-discharge reaction mechanism of LOBs.The results show that the strong electron coupling between Mn_(2)O_(3)and CeO_(2)can promote the formation of oxygen vacancies.Heterojunction combined with oxygen vacancy can improve the affinity for O_(2)and LiO_(2)reaction intermediates,inducing the formation of thin-film Li_(2)O_(2)with low potential and easy decomposition,thus improving the cycle stability at high current density.Consequently,it achieved a high specific capacity of 12545 at 1000 mA g^(-1)and good cyclability of 120 cycles at 4000 mA g^(-1).This work thus sheds light on designing efficient and stable catalysts for LOBs under high current density.