Stromal cell populations in the tumor microenvironment (TME) play a critical role in the oncogenesis and metastasis of renal cell carcinoma. In this study, we found that there are α-smooth muscle actin positive (α-SMA (+)) cells in the stroma of clear cell renal cell carcinoma (ccRCC) tissues, and their numbers are significantly associated with poor survival in ccRCC patients. Interleukin 6 (IL-6) is a critical diver that induces α-SMA (+) cells in ccRCC tissues via promotion of epithelial to mesenchymal transition (EMT) and stimulates migration and invasion in ccRCC. Peritumoral CD4+ T cells are the main source of IL-6 in ccRCC tissues. In addition to biochemical factors, mechanical compression within tumors affects tumor cell behavior. Tumors grown in a confined space exhibit intratumoral compressive stress and, with sufficient pressure, stress-stimulated migration of cancer cells. Moreover, a combination of IL-6 secreted by CD4+ T cells and growth-induced solid stress further contributes to the regulation of cancer cell morphogenesis, EMT and acquisition of a stemness phenotype. The effects in the combination group were driven by the Akt/GSK-3β/β-catenin signaling pathway, and deregulation of β-catenin expression was predictive of poor outcome in ccRCC patients. Notably, the expression of a cancer stem cell marker, CD44, was correlated with T stage, high Fuhrman grade and metastasis in ccRCC. These data provide evidence for new stress-reducing and IL-6 targeting strategies in cancer therapy.
It is known that aquaporin 9 (AQP9) in the prostate was strictly upregulated by androgen and may represent a novel therapeutic target for several cancers, but whether AQP9 plays a role in the regulation of androgen-independent prostate cancer still remains unclear. In the present study, AQP9 was determined in prostate cancer and adjacent cancer tissues; AQP9-siRNA was applied to silencing AQP9 in androgen-independent prostate cancer cell PC3 cell line. Western blot and flow cytometry analysis were employed to detect changes in related-function of control and AQP9-siRNA groups. The results showed that AQP9 is significantly induced in cancer tissues than that in adjacent cancer tissues. Moreover, knockdown of AQP9 in PC3 androgen-independent prostate cancer cell prostate cancer cells increased inhibition rates of proliferation. In addition, knockdown of AQP9 resulted in a significant decrease in the expression of the Bcl-2 and with a notable increase in the expression of Bax and cleaved caspase 3, indicated that AQP9 knockdown promoted apoptosis in prostate cancer cells. From wound healing assay and matrigel invasion, we suggested that AQP9 expression affects the motility and invasiveness of prostate cancer cells. Moreover, In order to explore the pathway may be involved in AQP9-mediated motility and invasion of prostate cancer cells, the phosphorylation of ERK1/2 was significant suppressed in AQP9 siRNA-transfected cells compared with that in control cells, suggesting that AQP9 is involved in the activation of the ERK pathway in androgen-independent prostate cancer cells.
A systematic search was conducted in PubMed, Cochrane Library. 6032 patients were included. There was no significant difference in survival between LND and NLND (non-lymph node dissection) among the patients. However, the patients in the LND group had more advanced tumour stages and grades (p < 0.001). In addition, among the muscle-invasive patients, LND demonstrated remarkable CSS improvement compared with NLND (HR: 2.19; 95% CI: 1.26-3.80; p = 0.005). Moreover, subgroup analyses found that patients with muscle-invasive UTUC had better CSS (HR: 1.22; 95% CI: 1.02-1.45; p < 0.001) than those patients with pN0 compared to pNx (NLND). In terms of RFS, the results showed no difference in the survival rates between pN0 and pNx patients in the subgroup of patients with muscle-invasive UTUC (HR: 1.40; 95% CI: 0.84-2.23; p = 0.19). Our meta-analysis supports that LND may prolong the CSS and RFS of UTUC, especially for patients with muscle-invasive UTUC.
We previously found that in normal epithelia of the prostate, localization of AQP3 is limited to the cell membranes; however, the expression of AQP3 protein in cancer epithelia is distributed to the plasma. Yet, the detailed mechanism remains unclear. In the present study, PC‑3 cell derivatives with stable knockdown of RAS like proto‑oncogene A (RalA) and overexpression of E‑cadherin were established. We found that overexpression of E‑cadherin and knockdown of RaLA resulted in an increase in AQP3 in prostate cancer cell plasma membranes. In order to investigate the functions caused by of the AQP3 redistribution in prostate cancer cells, the growth function of AQP3 redistribution was detected with clonogenic, MTT and MTS assays. In regards to the effect on apoptosis, flow cytometric analysis and DNA Ladder TUNEL assay were utilized. The results showed that AQP3 redistribution in PC‑3 cells significantly inhibited the proliferation of cells and enhanced cell apoptosis compared with these parameters in the control. Wound healing assay and Matrigel assays determined that knockout of RalA inhibited the motility and invasion capability of PC‑3 cells. To investigate the molecular mechanism involved in AQP3 redistribution in PC‑3 cells, the level of cAMP in PC‑3 cells was examined, and the results showed that AQP3 distribution was regulated through cAMP/PKA/RalA signal pathways. In conclusion, these studies suggest a novel function of AQP3, and provide a creative view for RalA-directed therapies.
Background. To assess the clinical characteristics, radiological predictors, and pathological features of perinephric fat adhesion degree (PFAD) graded based on fixed criteria and to determine the impact of adherent perinephric fat (APF) on retroperitoneal laparoscopic partial nephrectomy (RLPN) outcomes. Methods. 84 patients undergoing RLPN were included and graded into 4 groups based on PFAD. Univariate and multivariate analyses were performed for clinical characteristics and radiological predictors of PFAD. Perioperative data were compared between APF groups and non-APF groups. Masson staining determined collagen fibers. Immunohistochemistry detected CD45 immune cells and CD34 vessels. Results. 20, 28, 18, and 18 patients were graded as normal perinephric fat (NPF), mild adherent perinephric fat (MiPF), moderate adherent perinephric fat (MoPF), and severe adherent perinephric fat (SPF), respectively. Multivariate analysis revealed that gender ( p < 0.001), age ( p = 0.003), and hypertension ( p = 0.006) were significant clinical risk factors of PFAD, while radiological predictors included perinephric stranding ( p = 0.001), posterior perinephric fat thickness ( p = 0.009), and perinephric fat density ( p = 0.02). APF was associated with drain output ( p = 0.012) and accompanied by immune cells gathering in renal cortex near thickened renal capsule with many vessels. Conclusions. Clinical characteristics and radiological predictors can evaluate PFAD and may assist to guide preoperative surgical option. Pathological features of APF reflect decapsulation and bleeding during kidney mobilization at RLPN.
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