Objective To identify candidate compounds that activate thermogenesis during cold exposure by integrating the Library of Integrated Network-Based Cellular Signatures(LINCS)with RNA expression profiles specific to cold-induced thermogenesis.Methods Gene expression profiles of interscapular brown adipose tissue(BAT)and inguinal white adipose tissue(iWAT)were generated from 8-week-old C57BL/6J mice which were housed at 5 ℃ or room temperature(23 ℃)for 7 days.The gene expression signatures of the cold-induced BAT and iWAT were compared to the LINCS dataset to predict potential candidates for testing in a cold challenge model that was intended to assess thermogenesis activation.The pharmacological potential of the identified compounds was evaluated in a cold-exposed mouse model.The core body temperature and infrared thermal imaging were collected to monitor physiological responses during cold exposure.Additionally,hematoxylin and eosin(HE)staining was used to assess morphological changes of fat cells of BAT,iWAT,and epididymal white adipose tissue(eWAT).Results The transcriptomic signatures related to cold-induced thermogenesis were obtained and the top 20 candidate compounds were identified by comparison with the LINCS dataset.Mice treated with withaferin A(WA)during the cold challenge exhibited elevated rectal temperatures and smaller adipocyte sizes compared to controls.Conclusion Our drug repurposing strategy,which connects transcriptional profiles with LINCS data,identifies potential compounds.WA enhances thermogenesis and metabolic activity in adipose tissue,which helps maintain body temperature,and improves cold tolerance during exposure to low temperatures.

Objective To investigate the effects of insulin-like growth factor binding protein 7(IGFBP7)on the sensitivity of glioma cells to temozolomide(TMZ)and the related mechanism.Methods IGFBP7 mRNA expression levels in TMZ-sensitive(U87 TMZ-S,U251 TMZ-S)and TMZ-resistant(U87 TMZ-R,U251 TMZ-R)glioma cells were analyzed using RNA sequencing data from the gene expression omnibus(GEO)dataset GSE151680.TMZ-resistant U87 and U251 cell lines were established via stepwise dose escalation.IGFBP7 expressions in TMZ-R cells were detected by quantitative real-time PCR(qPCR)and Western blotting.IGFBP7 was stably knock-downed in TMZ-R cells while IGFBP7 was stably overexpressed in TMZ-S cells using lentiviral infection.Cell viability,migration,invasion and TMZ sensitivity were assessed using CCK-8 assay,apoptosis assay,wound healing assay,Transwell invasion assay and colony formation assay respectively.Cellular senescence was detected by β-galactosidase(SA-β-Gal)staining.The expression levels of senescence molecular markers cyclin-dependent kinase inhibitor 1(p21)and tumor protein p53(p53),as well as DNA damage marker γ-H2A histone family member X(γ-H2AX)were determined by Western blotting.The differences in mRNA expressions of IGFBP7 between glioma tissues and normal tissues as well as the correlations with the overall survival of glioma patients were analyzed using the cancer genome atlas(TCGA),Chinese Glioma Genome Atlas(CGGA),genotype-tissue expression(GTEx)database.Results Compared to normal glioma cells,IGFBP7 expressions were significantly elevated in TMZ-R glioma cells.Overexpression of IGFBP7 in TMZ-S glioma cells enhanced cell viability but suppressed apoptosis following TMZ treatment.The expressions of senescence-associated marker(p21,p53)and DNA damage marker(γ-H2AX)were upregulated in these cells.Notably,IGFBP7 expressions were significantly higher in glioma tissues than in normal tissues,and high IGFBP7 expressions were associated with poor prognosis in glioma patients.Conclusion Knockdown of IGFBP7 promotes TMZ-induced cell senescence and DNA damage,thereby enhancing the sensitivity of gliomas cells to TMZ.

Objective: To explore the function and molecular mechanism of Timeless in promoting hepatocellular carcinoma (HCC) growth. Methods: The expression of Timeless in HCC and paracancer tissues were analyzed by using the public data of HCC. Timeless was overexpressed in MHCC97L cells and silenced in MHCC97H cells, respectively, and the expression of Timeless and its downstream molecules were detected by real-time PCR and western blot. The effects of Timeless on cell glycolysis, oxidative phosphorylation and proliferation were detected by the glucose uptake experiment, lactic acid detection experiment, the extracellular fluid pH detection experiment, cell oxygen consumption test and cell viability assay, respectively. Results: The level of Timeless in HCC tissue was significantly higher than that of paracancer tissue (P<0.05). The relative cellular glucose uptake levels in the groups of Timeless knockdown, including siTimeless-1 and siTimeless-2 group were 0.510±0.119 and 0.508±0.099, respectively, significantly different from that of control group (P<0.05); The relative cellular uptake level of Timeless overexpressed group was 1.953±0.324, significantly different from that of vector transfected group (P<0.05). The relative levels of lactic acid production in the siTimeless-1 and siTimeless-2 group were 0.579±0.096 and 0.550±0.120, respectively, significantly different from that of control group (P<0.05); The relative production level of lactic acid in the Timeless overexpressed group was 1.463±0.179, significantly different that of vector transfected group (P<0.05). The extracellular pH values of siTimeless-1 and siTimeless-2 group were 7.390±0.035 and 7.370±0.060, respectively, significantly different from that of control group (P<0.05); the extracellular pH value of Timeless overexpressed group was 7.130±0.031, significantly different than vector transfected group (P<0.05). Oxygen consumption rate of siTimeless-1 and siTimeless-2 group were 3.686±0.389 and 3.955±0.431, respectively, significantly higher than 1.690±0.297 of control group (P<0.05); Oxygen consumption rate of Timeless overexpressed group was 1.302±0.336, significantly lower than 3.185±0.262 of vector transfected group (P<0.05) Timeless inhibited the expression of p53. The cell glucose uptake, lactic acid production, the pH of extracellular culture medium and cell oxygen consumption of control group were not significantly different from that of Timeless and p53 co-silenced group [(si-Timeless+sip53) group] (P>0.05); the glucose uptake, the production of lactic acid, the pH of the extracellular culture medium and the oxygen consumption of Timeless co-transfected with p53 (Timeless+p53) group were not significantly different from those of vector transfected group (P>0.05). Timeless promoted the proliferation of HCC cells through inhibiting the expression of p53. Conclusion Timeless promotes reprogramming of glucose metabolism and proliferation of HCC cells by inhibiting the p53-dependent signaling pathway.