This study examines the effect of melatonin on leptin-induced changes in transition of histone to protamine in adult rats during spermatogenesis. Twelve-week-old Sprague-Dawley rats were randomised into control, leptin-, leptin-melatonin-10-, leptin-melatonin-20- and melatonin-10-treated groups with six rats per group. Leptin was given via intraperitoneal injections (i.p.) daily for 42 days (60 μg/kg body weight). Rats in the leptin- and melatonin-treated groups were given either 10 or 20 mg day-1 kg-1 body weight of leptin in drinking water. Melatonin-10-treated group received only 10 mg of melatonin day-1 kg-1 body weight in drinking water for 42 days. Control rats received 0.1 ml of 0.9% saline. Upon completion of the treatment, sperm count, morphology and histone-to-protamine ratio were estimated. Gene expression of HAT, HDAC1, HDAC2, H2B, H2A, H1, PRM1, PRM2, TNP1 and TNP2 was determined. Data were analysed using ANOVA. Sperm count was significantly lower, whereas the fraction of spermatozoa with abnormal morphology, the ratio of histone-to-protamine transition and the expressions of HAT, HDAC1, HDAC2, H2B, H2A, H1, PRM1 were significantly higher in leptin-treated rats than those in controls or melatonin-treated rats. It appears that exogenous leptin administration adversely affects histone-to-protamine transition, which is prevented by concurrent administration of melatonin.
Altered epididymal sperm count and morphology following leptin treatment has been reported recently. This study examined the effects of 42 days of leptin treatment on sperm count and morphology and their reversibility during a subsequent 56-day recovery period. Twelve-week-old male Sprague-Dawley rats were randomised into four leptin and four saline-treated control groups (n = 6). Intraperitoneal injections of leptin were given daily (60 μg Kg(-1) body weight) for 42 days. Controls received 0.1 ml of 0.9% saline. Leptin-treated animals and their respective age-matched controls were euthanised on either day 1, 21, 42 or 56 of recovery for collection of epididymal spermatozoa. Sperm concentration was determined using a Makler counting chamber. Spermatozoa were analysed for 8-hydroxy-2-deoxyguanosine and DNA fragmentation (Comet assay). Data were analysed using anova. Sperm concentration was significantly lower but fraction of abnormal spermatozoa, and levels of 8-hydroxy-2-deoxyguanosine were significantly higher in leptin-treated rats on day 1 of recovery. Comet assays revealed significant DNA fragmentation in leptin-treated rats. These differences were reduced by day 56 of recovery. It appears that 42 days of leptin treatment to Sprague-Dawley rats has significant adverse effects on sperm count and morphology that reverse following discontinuation of leptin treatment.
Low sperm concentration, increased fraction of morphologically abnormal sperm, and raised levels of markers of oxidative stress are often reported in the seminal plasma of infertile obese males. The precise reason for changes remains unknown. This short review summarises evidence from human and animal studies linking leptin to the reproductive dysfunction reported in obese males and presents a possible mechanism for this based on the available data in the literature. Serum leptin concentrations correlate positively with body fat mass but its precise link to semen abnormalities reported in obese males has yet to be conclusively established. Decreased sperm concentration, increased fraction of morphologically abnormal sperm and increased markers of oxidative stress have been reported following six weeks of daily leptin treatment to normal weight rats. In addition, decreased expression of endogenous antioxidant enzymes and increased expression of respiratory chain enzymes noted in the testes of leptin treated rats increases the propensity to oxidative stress. Besides that, leptin's interference with histone to protamine transition in the DNA of sperm increases the susceptibility of sperm to free radical attack and may explain the often reported higher DNA fragmentation index in sperm of obese males. Concurrent supplementation of melatonin, a natural anti-oxidant, to these rats prevents the effects of leptin. The role of leptin in obesity-related reproductive dysfunction has to be considered seriously and these effects of leptin might involve increased oxidative stress.