Ginsenoside Rg3 protects mouse leydig cells against triptolide by downregulation of miR-26a.

BACKGROUND: Ginsenoside Rg3 has been reported to exert protection function on germ cells. However, the mechanisms by which Rg3 regulates apoptosis in mouse Leydig cells remain unclear. In addition, triptolide (TP) has been reported to induce infertility in male rats. Thus, this study aimed to investigate the protective effect of Rg3 against TP-induced toxicity in MLTC-1 cells. METHODS: CCK-8, immunofluorescence assay, Western blotting and flow cytometry were used to detect cell proliferation and cell apoptosis, respectively. In addition, the dual luciferase reporter system assay was used to detect the interaction between miR-26a and GSK3ß in MLTC-1 cells. RESULTS: TP significantly inhibited the proliferation of MLTC-1 cells, while the inhibitory effect of TP was reversed by Rg3. In addition, TP markedly induced apoptosis in MLTC-1 cells via increasing the expressions of Bax, active caspase 3, Cyto c and active caspase 9, and decreasing the level of Bcl-2. However, Rg3 alleviated TP-induced apoptosis of MLTC-1 cells. Moreover, the level of miR-26a was obviously downregulated by Rg3 treatment. The protective effect of Rg3 against TP-induced toxicity in MLTC-1 cells was abolished by miR-26a upregulation. Meanwhile, dual-luciferase assay showed GSK3ß was the direct target of miR-26a in MLTC-1 cells. Overexpression of miR-26a markedly decreased the level of GSK3ß. As expected, upregulation of miR-26a could abrogate the protective effects of Rg3 against TP-induced cytotoxicity via inhibiting the expression of GSK3ß. CONCLUSION: These results indicated that Rg3 could protect MLTC-1 against TP by downregulation of miR-26a. Therefore, Rg3 might serve as a potential agent for the treatment of male hypogonadism.

Fibroblast growth factor 16 stimulates proliferation but blocks differentiation of rat stem Leydig cells during regeneration.

OBJECTIVES: We aim to investigate the effects of fibroblast growth factor 16 (FGF16) on Leydig cell regeneration in ethane dimethane sulphonate (EDS)-treated rat testis. METHODS: We intraperitoneally inject 75 mg/kg EDS to adult male Sprague Dawley rats and then intratesticularly inject FGF16 (0, 10 and 100 ng/testis/day) from post-EDS day 14 for 14 days. We investigate serum hormone levels, Leydig cell number, gene and protein expression in vivo. We also explore the effects of FGF16 treatment on stem Leydig cell proliferation in vitro. RESULTS: FGF16 lowers serum testosterone levels (21.6% of the control at a dose of 100 ng/testis) without affecting the levels of luteinizing hormone (LH) and follicle-stimulating hormone (FSH) on post-EDS day 28 in vivo. FGF16 increases Leydig cell number at doses of 10 and 100 ng/mg without affecting Sertoli cell number, increases the percentage of PCNA-positive Leydig cells, and down-regulates the expression of Leydig cell genes (Lhcgr, Scarb1, Star, Cyp11a1, Cyp17a1 and Hsd17b3) and Sertoli cell genes (Fshr, Dhh and Sox9) and their proteins in vivo. FGF16 increases phosphorylation of AKT1 and AKT2 as well as EKR1/2 in vivo, indicating that it possibly acts via AKT1/ATK2 and ERK1/2 pathways. FGF16 also lowers medium testosterone levels and down-regulates the expression of Leydig cell genes (Lhcgr, Scarb1, Star, Cyp11a1, Cyp17a1 and Hsd17b3) but increases EdU incorporation into stem Leydig cells in vitro. CONCLUSIONS: These data suggest that FGF16 stimulates stem and progenitor Leydig cell proliferation but blocks their differentiation, thus lowering testosterone biosynthesis.

Lupron depot prevention of antispermatogenic/antifertility activity of the indenopyridine, CDB-4022, in the rat.

The goals of this study were to determine the CDB-4022 dose-response relationship for induction of acute decreases in testicular weight and germ cell depopulation in rats; establish the threshold dose of CDB-4022 required to induce infertility; and investigate whether CDB-4022-induced testicular damage could be prevented by a GnRH agonist (Lupron Depot). Reduction of testis weight and germ cell depopulation were observed 7 days after a single oral dose of 1 mg CDB-4022/kg, whereas 0.5 mg/kg had no observable effect. These effects were maximal at 12.5 or 25 mg CDB-4022/kg. After a single oral dose of either 2.5 or 5 mg/kg, CDB-4022 induced infertility in five of five treated rats by Week 5, whereas only one of five males was rendered infertile at a dose of 1 mg/kg. Proven fertile male rats (6/group) were treated with vehicle, CDB-4022 alone (2.5 mg/kg on Day 0), CDB-4022 plus Lupron Depot (on Weeks -1, 2, 5, and 8), or Lupron Depot alone. Control males demonstrated normal fertility throughout a 32-wk cohabitation period. Five of six rats were rendered transiently infertile with Lupron Depot alone, but all recovered fertility. CDB-4022 treatment resulted in infertility in all six rats, and only one of six regained fertility. Combined treatment also caused infertility in all six rats, but four of six recovered fertility (P = 0.08 compared to CDB-4022 alone). Testicular weight was decreased in the three treatment groups compared to vehicle controls; testicular weights were ranked from highest to lowest as follows: vehicle > Lupron Depot > Lupron Depot + CDB-4022 > CDB-4022. The tubule differentiation index of Lupron Depot-treated rats (96 +/- 4%) was not different from vehicle-treated rats (100%). CDB-4022 treatment decreased the number of differentiating tubules (15 +/- 8%). Lupron Depot plus CDB-4022 treatment resulted in a greater number of differentiating tubules (53 +/- 12%) than CDB-4022 alone, but this was still lower than vehicle- or Lupron Depot-treated rats. These data indicate that 2.5 mg/kg of CDB-4022 was the oral threshold dose that caused testicular damage rendering the majority of adult male rats permanently infertile within the study interval; 12.5 mg/kg of CDB-4022 induced maximal testicular damage. Suppression of gonadotropins and/or testosterone production by treatment with Lupron Depot before and after CDB-4022 prevented the CDB-4022-induced irreversible testicular damage.

Arginine acts as a protective and reversal agent against glycolytic inhibitors in spermatozoa.

It is known that the amino acid arginine stimulates sperm motility and glycolytic activity. We have earlier studied its efficacy as a stimulator of glycolysis in goat spermatozoa under anaerobic conditions. Here, we have assessed the influence of arginine in reversing the impairment caused by glycolytic inhibitors, iodoacetamide and iodoacetic acid. Glycolysis has been monitored by measuring the consumption of 13C labeled glucose and the amount of 13C labeled lactate produced under different experimental conditions, using 13C NMR. It is observed that both L- and D-arginine are able to prevent and reverse the inhibitory action of glycolytic inhibitors. The reversal effect of arginine gives rise to about eight times higher metabolic activity as compared to the inhibited cells while structurally related amino acids such as nitro-arginine, homo-arginine, lysine and ornithine are ineffective. The energetics of spermatozoa as measured by 31P NMR show a reduction in ATP level in cells incubated with iodoacetamide. Treatment of these cells with both L- and D-arginine restores the ATP level. The results may have significance in the treatment of male infertility.

Comparative protective actions of gonadotrophins and testosterone against the antispermatogenic action of ethane dimethanesulphonate.

After a single dose of ethane dimethanesulphonate (EDS) (75 mg/kg) to rats the prolonged antispermatogenic action is due to a temporary elimination of the functional Leydig cell population. Replacement therapy with testosterone propionate (3 mg/day) maintains the spermatogenic epithelium but the EDS effect develops when hormone treatment is discontinued. In contrast, a short treatment with hCG (10-100 i.u./day) or LH (714 micrograms/day), starting before the EDS dose, permanently protects the spermatogenic epithelium. FSH treatment was completely ineffective. Although histological protection of spermatogenesis appeared complete with testosterone or hCG, effects on fertility remained but over different periods of time. Antispermatogenic and antifertility effects were produced in mice using much higher doses of EDS (5 X 250 mg/kg) but there was no protection from androgen or hCG. It is suggested that EDS binds to Leydig cells irreversibly, interfering with the action of gonadotrophin. At the dose level used the evidence suggests that the degree of reaction renders most of the Leydig cell population non-viable. A direct cytotoxic effect of the compound upon the spermatogenic epithelium might account for the inability of testosterone or hCG alone or in combination to maintain fertility at normal levels.