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Objective:To explore the effect of miR-1249-5p on the proliferation, metastasis and cell cycle of PC-3 cell in prostate cancer.Methods:The relationship between the expression level of miR-1249-5p and the overall survival of prostate cancer patients was analyzed using OncoMir Cancer Database (OMCD). The human prostate cancer cell line PC-3 was divided into two groups: miR-1249-5p group and negative control group. Mediated by Lipofectamine 2000, miR-1249-5p mimics liposome complex or negative miRNA liposome complex were transfected into PC-3 cell at logarithmic growth stage. Real-time quantitative polymerase chain reaction (RT-qPCR) was used to detect the expression of miR-1249-5p in PC-3 cell of two groups. Colony formation assay was used to detect the changes of the proliferation ability of PC-3 cell in the two groups. Transwell experiment was used to detect the changes of PC-3 cell invasion in the two groups, and the cell cycle changes of the two groups of PC-3 were detected by flow cytometry. The miRNA prediction software miRGator was used to predict the target gene of miR-1249-5p. RT-qPCR and Western blotting were used to detect the target gene expression of miR-1249-5p. Measurement data were expressed as mean±standard deviation ( ± s), and t-test was used for comparison between two groups. Results:Compared with prostate cancer patients with low miR-1249-5p expression, prostate cancer patients with higher miR-1249-5p expression had longer overall survival, and the difference was statistically significant ( P<0.01). The expression level of miR-1249-5p in the miR-1249-5p group (10.74±1.19) was significantly higher than that of the negative control group (1.56±0.27), the difference was statistically significant ( P<0.01). The number of colonies formed in the miR-1249-5p group (35.86±6.94) was significantly less than that in the negative control group (88.94±11.66), and the difference was statistically significant ( P<0.01). The number of transmembrane cells [(25.01±6.83)/high power field of view] in the miR-1249-5p group was significantly less than that of the negative control group [(82.76±8.35)/high power field of view], and the difference was statistically significant ( P<0.01). The proportion of cells in the G 0-G 1 phase in the miR-1249-5p group [(50.79±6.61)%] was significantly higher than that in the negative control group [(27.09±2.30)%], the difference was statistically significant ( P<0.01), and PC-3 cell were inhibited in the G 0-G 1 phase. Neural precursor cell expressed developmentally down-regulated 9 ( NEDD9) may be the target gene of miR-1249-5p. Compared with the negative control group, the NEDD9 gene expression in the miR-1249-5p group was significantly lower than that of the negative control group, the difference was statistically significant ( P<0.01). Conclusion:miR-1249-5p can inhibit the proliferation, metastasis and cell cycle of PC-3 cell in prostate cancer, which may be achieved by negatively regulating the expression of proto-oncogene NEDD9.
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Objective:To investigate the effects of astragalin on the cell proliferation and cell cycle of prostate cancer cell line C4-2B through up-regulating the expression of miRNA-513 (miR-513).Methods:Prostate cancer cell line C4-2B cells were taken and treated with 125 μg/L of astragalin for 48 h (astragalin group), and untreated C4-2B cells were set as the control group. The methyl thiazolyl tetrazolium (MTT) method was used to detect the proliferation ability of C4-2B cells in the two groups, and cell cycle was detected by using flow cytometry. The miRNAMap prediction software was used to predict that the targeted gene of miR-513 was the forkhead box protein R2 (FOXR2), and the dual luciferase gene reporter assay was used to verify it. Real-time fluorescent quantitative polymerase chain reaction (qRT-PCR) was used to detect the relative expression levels of miR-513 and FOXR2 mRNA in the two groups of cells. Western blotting was used to detect the expressions of FOXR2, cyclin-dependent kinase 7 (CDK7), β-actin and cyclin H in the two groups of C4-2B cells.Results:Compared with the control group, the proliferation activity of C4-2B cells in the astragalin group was decreased from day 2 to day 5 (all P < 0.05). The proportions of S-phase cells in the control group and the astragalin group were (48.1±3.2)% and (36.0±2.1)%, respectively. The proportion of S-phase cells in the astragalin group was decreased ( t = 3.12, P = 0.021); the proportions of G 2-phase cells were (24.9±3.3)% and (11.8±2.4)%, respectively. The proportion of G 2-phase cells in the astragalin group was decreased ( t = 3.18, P = 0.019). The relative expression levels of miR-513 in C4-2B cells of the control group and the astragalin group were 1.01±0.22 and 6.55±0.61, respectively. The relative expression levels of miR-513 in C4-2B cells in the astragalin group was increased ( t = 7.70, P < 0.01). The dual luciferase reporter gene assay verified that FOXR2 was the targeted gene of miR-513. The relative expression level of FOXR2 mRNA in C4-2B cells of the control group and the astragalin group was 1.04±0.14 and 0.19±0.06, respectively, and the difference was statistically significant ( t = 5.53, P = 0.002), suggesting that after astragalin promoted the expression of miR-513, the FOXR2 mRNA expression was decreased. The relative expression levels of FOXR2, CDK7 and cyclin H protein in C4-2B cells in the astragalin group were all decreased compared with those in the control group. Conclusions:Astragalin inhibits the proliferation of prostate cancer C4-2B cells and induces cell cycle arrest by up-regulating the expression of miR-513.
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Objective:To investigate the mechanism of physcion affecting the cell cycle and proliferation of prostate cancer DU145 cell line by regulating the expression of miR-380-3p.Methods:Prostate cancer DU145 cells were treated with 50 μg/mL physcion as physcion group, and normal cultured DU145 cells without any treatment were used as control group. Flow cytometry was used to detect DU145 cell cycle changes. MTT proliferation test was used to detect the proliferation of DU145 cells. quantitative real-time polymerase chain reaction (qRT-PCR) was used to detect the expression of miR-380-3p in DU145 cells. The bioinformatics software RNAhybrid was used to predict the target genes of miR-380-3p. qRT-PCR and Western blotting methods were used to detect the expression of miR-380-3p target gene. Measurement data were expressed as mean ± standard deviation ( ± s), t-test was used for comparison between two groups. Results:Compared with the control group, DU145 cells in the physcion group were blocked in the G 0/G 1 phase ( P<0.01), and the proliferation ability of DU145 cells was significantly inhibited ( P<0.05). The expression of miR-380-3p in DU145 cells in the control group and physcion group was 8.36 ± 1.42 and 1.08 ± 0.39, respectively. Physcion could promote the expression of miR-380-3p ( t=4.96, P<0.01). The functional target gene of miR-380-3p may be UHRF1. The relative expression levels of UHRF1 mRNA in DU145 cells in the physcion group and control group were 0.23±0.06 and 1.04±0.15, respectively. Compared with the control group, the expression of UHRF1 gene in DU145 cells in the physcion group was decreased ( t=4.55, P<0.01). Conclusion:Physcion can inhibit the proliferation of prostate cancer DU145 cells and induce G 0/G 1 block in DU145 cells, which may be closely related to the regulation of miR-380-3p.
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Objective:To explore the expression of microRNA (miRNA)-6516-5p in renal cancer cell lines and the molecular mechanisms regulating the proliferation and migration of renal cancer cells.Methods:quantitative real-time polymerase chain reaction (qRT-PCR) was used to detect the expression of miR-6516-5p in renal cancer cell lines and normal proximal renal tubular epithelial cell lines. The liposome method was used to transiently transfect miR-6516-5p mimic and nonsense sequence (NC) into renal cancer cells with the lowest expression of miR-6516-5p, namely miR-6516-5p group and NC group. qRT-PCR was used to detect the expression of miR-6516-5p in transfected cells. CCK-8 and Transwell migration experiment were used to detect the proliferation and migration of transfected cells. Bioinformatics software and dual luciferase gene report experiment were used to predict and verify the regulation of miR-6516-5p on target gene, respectively. qRT-PCR and Western blotting were used to detect the expression of target gene in transfected cells. Measurement data were expressed as mean±standard deviation ( ± s), t-test was used for comparison between two groups, and one-way analysis of variance was used for comparison between multiple groups. Results:The expression of miR-6516-5p in renal cancer cell lines was significantly lower than that of normal proximal tubular epithelial cells ( P<0.01), and the expression of miR-6516-5p in 786-O cells was the lowest ( F=27.69, P<0.01). The expression of miR-6516-5p in 786-O cells in NC group and miR-6516-5p group was 1.01±0.08 and 9.91±1.16, respectively. Compared with the NC group, the expression of miR-6516-5p in 786-O cells in the miR-6516-5p group was significantly increased ( t=7.63, P<0.01). Up-regulation of miR-6516-5p can significantly inhibit the proliferation of 786-O cells ( P<0.05). The migration numbers of NC group and miR-6516-5p group were 85.65±8.77 and 28.05±6.20, respectively. Overexpression of miR-6516-5p could inhibit the migration of 786-O cells ( t=5.36, P< 0.01). The target gene of miR-6516-5p may be ornithine decarboxylase 1 ( ODC1), miR-6516-5p can significantly inhibit the luciferase activity of wild-type ODC1-3′UTR ( t=9.83, P<0.01). Up-regulation of miR-6516-5p can reduce the expression of ODC1 mRNA and protein in 786-O cells ( P<0.01). Conclusion:The expression of miR-6516-5p is reduced in renal cancer cell lines, miR-6516-5p inhibits the proliferation and migration of renal cancer 786-O cells by targeting ODC1, miR-6516-5p may become a potential molecular target of renal cancer.
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Objective:To investigate the expression of long non-coding RNA (lncRNA) BDNF-AS in kidney cancer tissues, and its effect on the proliferation and migration ability of kidney cancer cells and the molecular mechanism.Methods:Real-time reverse quantitative polymerase chain reaction (rRT-PCR) was used to detect the expression levels of BDNF-AS gene in renal cancer tissues, tumor-adjacent tissues of 67 renal cancer patients and normal renal tubular epithelial cells HK-2 and renal cancer cell lines A498, ACHN, OS-RC-2, Caki-1, 786-O in Huangshi Central Hospital of Edong Medical Group from May 2017 to July 2018. The kidney cancer cell line with the lowest expression of BDNF-AS was taken as the research object. Transient transfection with BDNF-AS overexpression plasmid was treated as the experiment group or a plasmid carrying meaningless sequences was treated as the control group. rRT-PCR was used to detect transfection efficiency. After the transfection with Caki-1 for 24 h, methythiazolyl tetrazolium (MTT) method was used to detect the proliferation of cells in both groups, Transwell migration assay was applied to detect the cell migration ability, rRT-PCR was used to detect the expression level of protein tyrosine phosphatase receptor type G (PTPRG) mRNA and Western blot was used to detect the expression level of PI3K-AKT pathway related-proteins.Results:The relative expression level of BDNF-AS in kidney cancer tissues was lower than that in tumor-adjacent tissues (0.96±0.24 vs. 4.62±0.84, t = 41.76, P < 0.01). The relative expression of BDNF-AS in kidney cancer cell lines was lower than that in normal renal tubular epithelial cells HK-2 (all P < 0.05), and the relative expression in Caki-1 cells was the lowest (0.10±0.01). The relative expression of BDNF-AS in the experimental group was higher than that in the control group ( P < 0.01). From the second day of transfection, the proliferation ability of Caki-1 cells in the experimental group was lower than that in the control group (all P < 0.05). The number of Caki-1 migrated cells in the experimental group was lower than that in the control group after migration for 15 h of Caki-1 cells transfected for 24 h [(51±8) vs. (192±25), t = 5.31, P < 0.01]. After 48 h transfection, the relative expression of PTPRG mRNA in Caki-1 cells ( P < 0.01) and protein expression of the experimental group were higher than those of the control group, the expression levels of PI3K-AKT signaling pathway related-proteins p-PI3K, p-AKT, p-Tpl2 in Caki-1 cells of the experimental group were lower than those of the control group. Conclusions:The expression of BDNF-AS is down-regulated in kidney cancer tissues and cell lines. Overexpression of BDNF-AS can inhibit the proliferation and migration ability of kidney cancer Caki-1 cells. The molecular mechanism may be related to the transduction that BDNF-AS promotes PTPRG gene expression and interferes with PI3K-AKT signaling pathway.
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Objective:To explore the molecular mechanism of microRNA (miRNA, miR)-1914-3p regulating the expression of ARL4C and affecting the invasion and proliferation of renal cancer cells.Methods:Real-time fluorescent quantitative polymerase chain reaction (qRT-PCR) was used to detect the expression level of miR-1914-3p in tumor tissues and adjacent tissues of 53 renal cancer patients, 4 types of renal cancer cell lines (ACHN, OS-RC-2, 786-O, A498) and normal proximal renal tubular epithelial cell line (HK-2). The nonsense sequence (NC) and miR-1914-3p mimic were transiently transfected into renal cancer cells with the lowest miR-1914-3p expression by liposome method, namely the NC group and miR-1914-3p group. qRT-PCR was used to detect the expression level of miR-1914-3p in transfected cells. Transwell invasion test and cell counting kit-8 (CCK-8) were used to detect the invasion and proliferation ability of each group of cells. Bioinformatics software and dual luciferase gene report experiment were used to predict and test the targeted regulation mechanism of miR-1914-3p on target genes. qRT-PCR and Western blot was conducted to analyze the target gene expression level in cells of each group.Results:The expression level of miR-1914-3p in renal cancer tissue was significantly lower than that in adjacent tissues ( P<0.01). The expression level of miR-1914-3p in renal cancer cell lines was significantly lower than that in HK-2 cell lines ( P<0.01), and the expression of miR-1914-3p in OS-RC-2 cells was the lowest ( P<0.01). The expression of miR-1914-3p in the NC group and the miR-1914-3p group were (1.04±0.17) and (11.40±0.91), respectively. The expression level of miR-1914-3p in the miR-1914-3p group was significantly increased ( P<0.01), indicating that the transfection was successful. Overexpression of miR-1914-3p can significantly inhibit the invasion ( P<0.01) and proliferation ( P<0.05) of renal cancer OS-RC-2 cells. Dual luciferase gene report experiment indicated that the target gene of miR-1914-3p may be ADP-ribosylation factor-like 4C (ARL4C); miR-1914-3p can significantly inhibit the luciferase activity of wild-type ARL4C-3′UTR ( P<0.01). Overexpression of miR-1914-3p decreased the expression of ARL4C mRNA and protein in OS-RC-2 cells ( P<0.01), and decreased the expression of cell invasion phenotype proteins (Snail, Slug) and cell proliferation phenotype proteins (Mcm2, Mcm7) ( P<0.01). Conclusions:miR-1914-3p is low-expressed in renal cell carcinoma. It inhibits the invasion and proliferation of renal cell carcinoma OS-RC-2 cells through targeted interference with the expression of the oncogene ARL4C, and participates in the occurrence and development of renal cell carcinoma.
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Objective:To explore the effect of long non-coding RNA (lncRNA) AC068768.1 on the cycle and proliferation of renal cancer cells and its molecular mechanism.Methods:Real-time quantitative polymerase chain reaction (qPCR) was used to detect the expression of AC068768.1 in renal cancer cell lines. The OS-RC-2 cells with the lowest expression of AC068768.1 were used as the transfection objects, OS-RC-2 transfected with the negative control plasmid was set as the control group, and the cells transfected with the AC068768.1 plasmid were set as the AC068768.1 group. qPCR was used to detect the expression of AC068768.1 in transfected OS-RC-2 cells. The effects of AC068768.1 on the cell cycle and proliferation of OS-RC-2 were detected by flow cytometry and tetramethylazazole blue colorimetric (MTT) proliferation experiments. Using bioinformatics methods to predict the microRNA (miRNA) that AC068768.1 may bind. qPCR was used to detect the expression of miRNA and downstream gene mRNA, and Western blot was used to detect the expression of downstream gene protein.The measurement data were expressed as mean±standard deviation ( Mean± SD), the comparison between the two groups adopts the t-test, and the comparison among multiple groups adopts the One-way analysis of variance. Results:Compared with normal renal tubular epithelial cells, the expression of AC068768.1 in renal cancer cell lines was significantly reduced, the difference was statistically significant ( P<0.01). The expression of AC068768.1 in OS-RC-2 cells in the AC068768.1 group was significantly higher than that in the control group, the difference was statistically significant ( P<0.01). Up-regulating the expression of AC068768.1 can inhibit the cycle ( P<0.05) and proliferating ability ( P<0.05) of renal cancer cells. miR-21-5p may be the functional target gene of AC068768.1. Up-regulation of AC068768.1 can significantly inhibit the expression of miR-21-5p ( P<0.01) and promote the expression of tissue inhibitor of metalloproteinase 3 (TIMP3) ( P<0.01). Conclusion:AC068768.1 promotes the expression of TIMP3 gene by regulating the expression of miR-21-5p, thereby inhibiting the cell cycle and proliferation of renal cancer OS-RC-2 cells.
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Objective:To investigate the expression of long non-coding RNA (lncRNA) COX10-AS1 in renal cell carcinoma tissues and cell lines and its effect on proliferation and migration of renal cancer cells.Methods:Fluorescence real-time quantitative PCR (qRT-PCR) was used to detect the expression of COX10-AS1 in surgical specimens that have been diagnosed as renal cancer tissues and adjacent tissues by pathology, renal cancer cell lines (786-O, CaKi-1, A498, ACHN) and normal renal tubular epithelium cell line (HK-2). The ACHN cells with the lowest expression were divided into a control group (transfected with a negative control plasmid carrying nonsense sequences) and an experimental group (transfected with a plasmid carrying COX10-AS1 sequences). The expression level of COX10-AS1 was detected by qRT-PCR in two groups of cells. The proliferation and migration ability of ACHN cells were detected by MTS assay and cell scratch assay. The expression of MFN2 mRNA was detected by qRT-PCR. The expressions of MFN2 and Ras-NF-κB signaling pathway proteins were detected by Western blotting. The measurement data were expressed as mean±standard deviation ( Mean± SD), the comparison between the two groups used the t-test, and the comparison among multiple groups adopts the one-way analysis of variance. Results:The expression of COX10-AS1 in renal cell carcinoma was significantly lower than that in adjacent tissues ( P<0.01), The expression of COX10-AS1 in renal cell carcinoma cells was significantly lower than that in renal tubular epithelial cells ( P<0.05), the expression of COX10-AS1 was the lowest in ACHN cells( P<0.01), the above differences were statistically significant compared with the control group, the expression of COX10-AS1 in ACHN cells of experimental group was significantly increased ( P<0.01), the above differences were statistically significant compared with the control cells, the proliferation of ACHN cells in the experimental group was significantly decreased ( P<0.05), and the cell migration ability was significantly decreased ( P<0.01). Compared with the control cells, the expression of MFN2 mRNA in ACHN cells of experimental group was significantly increased ( P<0.01). The expression levels of MFN2 were significantly up-regulated ( P<0.01), and Ras-NF-κB signaling pathway proteins were significantly down-regulated ( P<0.05), the above differences were statistically significant. Conclusions:The expression of COX10-AS1 is decreased in renal cell carcinoma tissues and cell lines. COX10-AS1 may inhibit the proliferation and migration of ACHN cells by promoting the expression of MFN2 gene.
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Objective To investigate the effect of miR-103b on the expression of P21 protein in renal cell carcinoma cell line 769-P and ACHN cells,and its effect on the growth of renal cell carcinoma.Methods Renal cancer cells were divided into two groups according to the transfected RNA,miR-103b (experimental group) and dsControl (control group),respectively.Real-time PCR and Western blotting were used to detect the expression of P21,cell cycle-dependent kinase 6,Cyclin D1 mRNA and protein expression.Flow cytometry was used to detect the cell cycle distribution.MTT assay was used to detect cell viability and colony formation assay was used to detect cell proliferation.Measurement data were represented as x ± s.Comparison between groups was analyed using t test.Results Real-time PCR results showed that the relative expression levels of P21,cell cycle-dependent kinase 6 and Cyclin D1 mRNA in 769-P and ACHN which belong to control group cells were 1.00 ±0.10 and 1.02 ±0.27,1.00 ±0.08 and 1.01 ±0.17,1.01 ±0.19 and 1.00 ±0.02.The experimental group was 2.36 ±0.51 and 2.03 ± 0.49,0.33 ± 0.20 and 0.58 ± 0.22,0.48 ± 0.11 and 0.60 ± 0.23,respectively,and the difference was statistically significant (P < 0.05).Western blotting results were consistent with Real-time PCR results.Flow cytometry results showed that compared with the control group,the proportion of cells located in G0/G1 phase in the experimental group increased (P < 0.05),suggesting that the cells were arrested in G0/G1 phase.MTT assay showed that the viability of 769-P and ACHN cells in the experimental group was significantly lower than that in the control group.Colony formation experiments showed that the number of colony formation in the experimental group was significantly less,suggesting that the cell proliferation capacity decreased.Conclusion miR-103b can inhibit the growth of renal cell carcinoma cells by activating the expression of P21 protein and blocking the progression of the renal cell cycle,which provides a theoretical basis for the molecular targeted therapy of renal cell carcinoma.