Objective To study the in vitro killing effect of novel small molecule inhibitors, ribosomal S6 kinase1 (RSK1) inhibitor (BI-D1870) and polo-like kinase 1 (PLK1) inhibitor (BI2536), combined with recombinant attenuated vesicular stomatitis virus VSVΔM51 on various glioma cells. Methods (1) In vitro cultured GL261, CT2A and HS68 cells were divided into control group, rapamycin group, BI-D1870 group, BI-2536 group, VSVΔM51 group, rapamycin +VSVΔM51 group, BI-D1870+VSVΔM51 group, and BI2536+VSVΔM51 group; pretreatments with 100 nmol/L rapamycin, 10 μmol/L BI-D1870, and 100 nmol/L BI-2536 for 2 h were given to the cells from the above groups, respectively, and then, they were infected with VSVΔM51 virus at 0.1 mutiplicity of infection (MOI); at 72 h after treatments, the cell survival rate was determined by Alarma Blue method; VSV△M51 virus was infected at 10 MOI one h after pretreatment with the above drugs, apoptosis of GL261 cells was detected by cleaved caspase-3 staining 24 h after that; the expression of apoptotic protein polyadp-ribosomal polymerase (PARP) was detected by Western blotting; Annexin V-FITC/propidium iodide double staining was used to detect the cell apoptosis. (2) GL261 and CT2A cells were divided into VSVΔM51 group, rapamycin+VSVΔM51 group, BI-D1870+VSVΔM51 group, and BI2536+ VSVΔM51 group; VSV△M51 virus was infected at 0.1 MOI one h after pretreatment with the above drugs,; 48 h after treatments, fluorescence microscope was used to detect the expression of green fluorescent protein (GFP); IVIS200 in vivo imaging system was used to detect the changes of cell virus luciferase in the 4 groups. (3) Fifteen CT2A intracranial implanted glioma model mice were divided into VSVΔM51 group, BID-1870+VSVΔM51 group and BI2536+VSVΔM51 group according to random number table method (n=5); mice in the latter two groups were intraperitoneally injected with BI-1870 (100 mg/kg) or intravenously injected with BI-2536 (20 mg/kg); 24 h after that, mice in the three groups were intravenously injected with virus VSVΔM51; virus luciferase was detected by IVIS200 in vivo imaging system 24 and 72 h after treatments; the grouping and treatments of GL261 intracranial glioma model mice were the same as above, the expression of virus GFP was observed under fluorescence microscope 48 h after treatments, and virus titers of these mice were detected by virus plaque assay. Results (1) As compared with the control group, rapamycin group, BI-D1870 group, BI-2536 group, and VSVΔM51 group, the rapamycin+VSVΔM51 group, BI-D1870+VSVΔM51 group, and BI2536+VSVΔM51 group had significantly lower cell survival rate (P<0. 05); cleaved Caspase-3 staining showed no cell apoptosis in the control group, a small amount of apoptotic corpuscles in the rapamycin group, BI-D1870 group, BI-2536 group, and VSVΔM51 group, but obvious increased amount of apoptotic corpuscles in the rapamycin+VSVΔM51 group, BI-D1870+VSVΔM51 group, and BI2536+ VSVΔM51 group; Western blotting indicated that GL261 and CT2A cells from the control group, rapamycin group, BI-D1870 group, BI-2536 group, and VSVΔM51 group had lower cleaved PARP expression level than those from the rapamycin+VSVΔM51 group, BI-D1870+VSVΔM51 group, and BI2536+VSVΔM51 group. The results of Annexin V-FITC/propidium iodide double staining were consistent with those of cleaved Caspase-3 staining. (2) As compared with VSVΔM51 group and rapamycin+VSVΔM51 group, BI-D1870+VSVΔM51 group and BI2536+VSVΔM51 group had significantly increased GFP expression and statistically higher intensity of virus luciferase (P<0.05). (3) CT2A cells in the VSVΔM51 group, BID-1870+VSVΔM51 group and BI2536+VSVΔM51 group had increased intensity of virus luciferase successively, with significant differences (P<0.05); GL261 cells in the VSVΔM51 group, BID-1870+VSVΔM51 group and BI2536+VSVΔM51 group had increased virus titers successively, with significant differences (P<0.05). Conclusion Both small molecule inhibitors promote the replication of VSVΔM51 virus and enhance the killing effect on glioma cells, and its synergistic effect is obviously better than rapamycin.

Purpose: Clomiphene citrate (CC) is prescribed off-label in men to improve testosterone and sperm parameters, but the duration of treatment needed to reach maximal benefit remains unclear. Our objective was to examine temporal effects of CC on total testosterone (TT) and semen analysis (SA) using longitudinal follow-up data in treated men.   Materials and Methods: We analyzed an IRB-approved database of men treated with CC (25 mg q.d. or 50 mg q.o.d.) from January 2016 through May 2021. We identified patients with 3, 6, 9, and 12 month follow-up data for TT and 3, 6, and 9 month follow-up SA. Mean absolute changes in TT and sperm concentration compared to baseline were calculated, along with 95% confidence intervals. Men with prior genitourinary procedures or hormone therapy were excluded. Paired t-tests were used to compare TT and sperm concentration at each time point to baseline (alpha=0.05).  Results: One hundered thirty-four men received CC, mean age 37.7 years (SD 6.7, range 24–52). TT at all follow-ups (3, 6, 9, and 12 months) were available for 25 men, and SA at 3, 6, and 9 months for 26 men. Baseline TT was 358±145 ng/dL and sperm concentration was 13±17.2 M/mL. Significant improvement in TT was identified at 3 months (62.7 ng/dL, 95% CI: 0.49–125.0, p=0.048), additional benefit at 6 months (181.8 ng/dL, 95% CI: 114.1–249.5, p<0.01), and plateau at 9 and 12 months. Improvement in sperm concentration was first observed at 9 months (20.7 M/mL, 95% CI: 10.2–31.2, p<0.01). Semen volume and sperm motility did not change.   Conclusions Duration of treatment with clomiphene may impact testosterone and sperm concentration, and the historical 3 month milestone may be insufficient for clinical and research evaluation. Men taking CC may experience plateau in TT at 6 months and first benefit in sperm concentration at 9 months.