It may also be speculated that the MCP disruption of the Gal-3 lattice by competitive binding to the carbohydrate recognition domain in the extracellular tumor microenvironment may enhance the effect of the radiation exposure to the cells

It may also be speculated that the MCP disruption of the Gal-3 lattice by competitive binding to the carbohydrate recognition domain in the extracellular tumor microenvironment may enhance the effect of the radiation exposure to the cells. Since side effects of radiation can include induced inflammation and tissue damage, Gal-3 also plays a pivotal role in tissue remodeling and fibrosis. of reactive oxygen species production Ixazomib citrate to treatment effects on cell viability was tested. Results: Radiotherapy combined with MCP reduced viability and enhanced radiosensitivity associated with a decrease in Gal-3, cleavage of the precursor of caspase-3, increased expression of the pro-apoptotic protein Bax, and downregulation of DNA repair pathways, poly-ADP-ribose polymerase, and proliferating cell nuclear antigen. MCP significantly HSPA1A reduced the invasive and migratory potential of PCa cells. Combining sodium pyruvate with MCP and IR mitigated the effect on cell viability. Conclusion: Our findings demonstrated that MCP sensitized PCa cells to IR by downregulating anti-apoptotic Gal-3, modulating DNA repair pathways, and increasing ROS production. For the first time the correlation between MCP, radiotherapy, and Gal-3 for prostatic cancer treatment was found. In addition, MCP reduced the metastatic properties of PCa cells. These findings provide MCP as a radiosensitizing agent to enhance IR cytotoxicity, overcome radioresistance, and reduce clinical IR dose. test with unequal variance and was considered as statistically significant if .05. Results MCP and IR Reduced PCa Cells Viability As found by XTT assay, the treatment of all 3 tested cultured prostate carcinoma cells (PC-3, Cl-1, and Du-145) with MCP for 72 hours induced a dose-dependent decrease in cell viability (Figure 1B). DU-145 cells were more sensitive to this treatment. Open in a separate window Figure 1. Effect of MCP (B) and IR (A) alone on PCa cells viability. Cell viability was evaluated by XTT assay. The graphs represent mean SE survival values of irradiated/treated cells from 3 experiments each performed in triplicate (* .05; ** .01; *** .001). The irradiation of PCa cells with a single dose of IR (2-4 Gy) resulted in significant survival decrease (Figure 1A): PC-3 demonstrated the highest radiosensitivity, while DU-145 cells were the most radioresistant. The combined effect of MCP and IR on cell Ixazomib citrate survival was more significant than the effect of each treatment alone (Figure 2). CalcuSyn software used to analyze the mode of interaction between these treatments revealed that on DU-145 cells the combination of MCP and IR resulted in a synergistic effect at high and low doses, whereas the effect was additive at median doses (Figure 2). On PC-3 and Cl-1 cells, the combined treatment resulted in mostly additive effect (Figure 2). Open in a separate window Figure 2. Combined effect of MCP and IR on cell viability. (A, B, and C) Survival of cells evaluated by XTT assay. (D, E, and F) Normalized isobolograms indicating mode of treatments interaction. DU-145 cells, in which the maximal synergistic effect was observed, were chosen for further studies. In addition, the effect of treatments on DU-145 cell survival was also evaluated by a more sensitive clonogenic assay. The inhibitory effect of each treatment alone and in combination was more significant than the effect found by XTT assay (Figure 3). The highest inhibition was found at 4 mg/mL MCP. The inhibitory effect of 2 and 4 Gy was very significant. MCP and IR in combination resulted in enhanced inhibition, thus corroborating synergistic effect observed by the XTT assay. Open in a separate window Figure 3. Effect of MCP and IR on DU-145 cell survival evaluated by clonogenic assay. Cell survival after MCP (A) and IR (B) treatments alone and after combined treatment (C). MCP Induced Apoptosis and Moderated G2/M Cell Cycle Arrest The effect of MCP on PCa cell cycle was evaluated by flow cytometry of PI-stained Du-145 cells as more sensitive to MCP treatment and characterized by high radioresistance. After 12 hours of MCP treatment, the cell distribution in the cell cycle revealed accumulation of cells in the G0/G1 phase (58.9% for 1 mg and 68.2% for 2 mg). Moderate G2/M phase arrest appeared after 24 hours of exposure (9.62% for 1 mg and 14.2% for 2 mg). More obvious changes in G2/M phase were observed after 72 hours of treatment (19.1% for 1 mg and 17.9% for 2 mg, compared with 12.4% in control; Figure 4A). Open in a separate window Figure 4. Induction of apoptosis in DU-145 cells treated by MCP. (A) Ixazomib citrate PI staining and (B) double Annexin-V-FITC/7-AAD staining. Double-negative cells are intact cells, Annexin-V-FITC positive cells indicated early apoptosis, double-positive cells indicated late apoptosis, and 7-AAD positive cells indicated necrotic cells. To explore whether MCP can cause cell damage through the induction of apoptosis, the treated cells were tested by FACS analysis using Annexin V-FITC/7-AAD double staining (Figure 4A and ?andB).B). According to the manufacturers instructions, cells stained with Annexin V-FITC alone demonstrated early apoptosis, cells double stained with Annexin V-FITC/7-AAD represented a late apoptotic population, while cells stained with 7-AAD alone indicated necrotic cells. Comparing with the negative control, MCP treatment of DU-145 cells Ixazomib citrate for 72 hours resulted in early (4.49%) and late apoptosis (13.94%; Figure 4B), and.