New nonsteroidal molecules as blockers of the steroidogenic pathway

Background: Testosterone circulating levels decrease in aging. This fact affects the emotional response to captivating pictures. Therefore, naturally increasing androgens within neurons could be a way to improve the mood of agedpeople. Objective: This study aimed to determine the biological activity of new nonsteroidal derivatives of 2-aminonaphthalene-1,4-dione (2-amino-3-iodonaphthalene-1,4-dione and 2-(iodoamino)-3-methylnaphthalene-1,4-dione) as inhibitors of the aldo-keto reductase 1 enzymes (AKR1C1, AKR1C2). Method: The 2-amino-3-iodonaphthalene-1,4-dione and 2-(iodoamino)-3-methylnaphthalene-1,4-dione were synthesized, and their effect in vivo and in vitro was determined. The human prostate cell membrane was used as a source of steroidogenic enzymes. The 2-amino-3-iodonaphthalene-1,4-dione and 2-(iodoamino)-3-methylnaphthalene-1,4-dione bindings to the androgen receptors were also assayed using cytosol from the rat prostate. In vivo experiments, we determined the effects of 2-amino-3-iodonaphthalene-1,4-dione, 2-(iodoamino)-3-methylnaphthalene-1,4-dione on the weight of androgen-dependent glands of castrated hamsters treated with testosterone and finasteride or 2-amino-3-iodonaphthalene-1,4-dione or 2-(iodoamino)-3-methylnaphthalene-1,4-dione was determined. Results: 2-amino-3-iodonaphthalene-1,4-dione and 2-(iodoamino)-3-methylnaphthalene-1,4-dione inhibited AKR1C1 enzyme activity with an IC50 value of 420 nM (2-amino-3-iodonaphthalene-1,4-dione) and 1.95 µM (2-(iodoamino)-3-methylnaphthalene-1,4-dione), respectively. They also blocked AKR1C2 with an IC50 value of 300 nM (2-amino-3-iodonaphthalene-1,4-dione) and 1.52 µM (2-(iodoamino)-3-methylnaphthalene-1,4-dione). Thus 2-amino-3-iodonaphthalene-1,4-dione and 2-(iodoamino)-3-methylnaphthalene-1,4-dione prevent the formation of 3α and 3β-androstanediols. Moreover, these compounds did not bind to AR and did not reduce prostate and seminal vesicle weight. The latter is because of the accumulation of dihydrotestosterone, which is an anabolic androgen. Conclusion: 2-amino-3-iodonaphthalene-1,4-dione and 2-(iodoamino)-3-methylnaphthalene-1,4-dione inhibited AKR1C1 and AKR1C2 enzyme activity; consequently, dihydrotestosterone was accumulated in androgen-dependent glands. These derivatives could potentially use therapeutics via direct nasal administration in aged patients, increasing DHT in neurons.

Reconstitution of rat fetal testis during the masculinisation programming window induces focal dysgenesis consistent with testicular dysgenesis syndrome

Focal dysgenesis is a consistent feature of testicular dysgenesis syndrome (TDS) in humans. Rodent studies show that perturbation of androgens (e.g. following phthalate exposure) during a fetal masculinisation programming window (MPW) predisposes to a TDS phenotype. This study aimed to determine whether dissociation and reconstitution of rat fetal testis tissue during the MPW can be used to model and manipulate seminiferous cord development, including induction of focal dysgenesis, as described in TDS. Dissociated fetal rat testes were xenotransplanted subcutaneously into recipient mice for 4 weeks. Transplanted mice were treated with vehicle or di-n-butyl-phthalate (DBP, a plasticising chemical known to induce testicular dysgenesis in vivo in rats). Testosterone production by the transplants was measured in recipient mice and immunofluorescence was performed on the retrieved transplants to identify features consistent with focal testicular dysgenesis. Re-aggregation of rat fetal testis tissue xenotransplants during the MPW results in reconstitution of seminiferous cords. Features of focal testicular dysgenesis were present in re-aggregated testis, including ectopic Sertoli cells and intratubular Leydig cells (ITLCs). DBP exposure of recipient mice reduced androgen-dependent seminal vesicle weight (8.3 vs 26.7 mg; p < 0.05), but did not enhance features of focal dysgenesis including number of ITLCs (0.07 vs 0.10 cells/mm2; p > 0.05). We conclude that seminiferous cord reformation during the MPW results in development of focal dysgenesis. The system may be used to separate specific effects (e.g. androgen suppression) of individual chemical exposures from other mechanisms that may be conserved in TDS.

Curcumin ameliorates atrophy of seminal vesicle via reduction of oxidative stress in castrated mice

Background The growth and function of seminal vesicle are dependent on androgen. This study was conducted to investigate the role of oxidative stress in castration-induced seminal vesicle atrophy and to explore the effects of curcumin, an antioxidant extracted from rhizome of turmeric, on seminal vesicle of castrated mice. Methods C57BL/6J mice were randomly divided into three groups: control, castration, and castration with curcumin (n = 10 for each group). After surgical castration, mice in the curcumin treatment group received intragastric administration of curcumin at 100 mg/kg body weight for 4 weeks, whereas mice in the other two groups were treated with olive oil. After that, the body weight, seminal vesicle weight and serum testosterone of mice were measured. Apoptosis and oxidative stress levels in seminal vesicle were also determined. Results After castration, both the weight and size of seminal vesicle decreased dramatically. The expression of three NADPH oxidase (NOX) subtypes: NOX1, NOX2 and NOX4, increased in seminal vesicle of castrated mice, resulting in high level oxidative stress. The ratio of Bax to Bcl-2 was also elevated after castration, accompanied by enhanced caspase3 activity. Additionally, castration increased the number of apoptotic cells in seminal vesicle. Curcumin treatment could inhibit the expression of NOX1, NOX2 and NOX4, decreasing oxidative stress and apoptosis. The atrophy of seminal vesicle caused by castration was ameliorated by curcumin. Conclusion Castration could cause atrophy of seminal vesicle probably via inducing oxidative stress. Curcumin treatment could reduce the oxidative stress in seminal vesicle by decreasing the expression of NOX1, NOX2 and NOX4, thereby ameliorating apoptosis and atrophy of seminal vesicle. Oxidative stress might play a role in castration-induced seminal vesicle atrophy.

The Coadministration of N-Acetylcysteine Ameliorates the Effects of Arsenic Trioxide on the Male Mouse Genital System

Arsenic trioxide (As2O3) has shown effectiveness in treatment of leukemia but is also associated with reproductive toxicity. Since remediation with N-acetylcysteine (NAC) may mitigate the adverse effects caused by exposure, we assessed the effects of As2O3and its potential reversibility after exposure cessation or coadministration of NAC. Animals received 0.3 or 3.0 mg/Kg/day of As2O3subcutaneously and 40 mM of NAC in tap water. As2O3treatment impaired spermatogenesis and sperm motility and decreased seminal vesicle weight and testosterone serum levels; after suspension of treatment, these parameters remained altered. When NAC was administered, animals showed improvement in sperm parameters and seminal vesicle weight.In vitroepididymal contractility was increased in As2O3-treated animals. We concluded that As2O3is toxic to the male mouse genital system by compromising sperm quality and quantity; these effects persisted even after suspension of the treatment. However, the coadministration of NAC ameliorates the harmful effects of the drug on the male genital system.

Anogenital Distance Plasticity in Adulthood: Implications for Its Use as a Biomarker of Fetal Androgen Action

Androgen action during the fetal masculinization programming window (MPW) determines the maximum potential for growth of androgen-dependent organs (eg, seminal vesicles, prostate, penis, and perineum) and is reflected in anogenital distance (AGD). As such, determining AGD in postnatal life has potential as a lifelong easily accessible biomarker of overall androgen action during the MPW. However, whether the perineum remains androgen responsive in adulthood and thus responds plastically to perturbed androgen drive remains unexplored. To determine this, we treated adult male rats with either the antiandrogen flutamide or the estrogen diethylstilbestrol (DES) for 5 weeks, followed by a 4-week washout period of no treatment. We determined AGD and its correlate anogenital index (AGI) (AGD relative to body weight) at weekly intervals across this period and compared these with normal adult rats (male and female), castrated male rats, and appropriate vehicle controls. These data showed that, in addition to reducing circulating testosterone and seminal vesicle weight, castration significantly reduced AGD (by ∼17%), demonstrating that there is a degree of plasticity in AGD in adulthood. Flutamide treatment increased circulating testosterone yet also reduced seminal vesicle weight due to local antagonism of androgen receptor. Despite this suppression, surprisingly, flutamide treatment had no effect on AGD at any time point. In contrast, although DES treatment suppressed circulating testosterone and reduced seminal vesicle weight, it also induced a significant reduction in AGD (by ∼11%), which returned to normal 1 week after cessation of DES treatment. We conclude that AGD in adult rats exhibits a degree of plasticity, which may be mediated by modulation of local androgen/estrogen action. The implications of these findings regarding the use of AGD as a lifelong clinical biomarker of fetal androgen action are discussed.

Insulin Action on GABA Neurons Is a Critical Regulator of Energy Balance But Not Fertility in Mice

Insulin signaling in the brain plays an important role in the central regulation of energy homeostasis and fertility, such that mice exhibiting brain-specific deletion of insulin receptors (InsRs) display a diet-sensitive obesogenic phenotype and hypothalamic hypogonadism. However, the specific neurons mediating insulin's central effects on fertility remain largely unidentified. The neurotransmitters γ-aminobutyric acid (GABA) and glutamate are important modulators of fertility and energy homeostasis and are widely distributed in the hypothalamus. We therefore investigated whether insulin signaling via GABAergic or glutamatergic neurons plays an important role in the metabolic regulation of fertility. We used the Cre-loxP system to generate mice with a selective inactivation of the Insr gene from GABAergic (Vgat+) or glutamatergic (Vglut2+) cells by crossing Insr-flox mice with Vgat-Cre or Vglut2-Cre mice, respectively. Multiple reproductive and metabolic parameters were then compared between male and female Insr-flox/Vgat-Cre+ (VgatIRKO), Insr-flox/Vglut2-Cre+ (VglutIRKO), and Insr-flox/Cre-negative control (CON) mice. Female VgatIRKO mice exhibited a significant increase in adult body weight, abdominal fat mass, and fasting plasma insulin and leptin concentrations, but normal fasting glucose concentration and glucose tolerance compared with CON mice. Surprisingly, VgatIRKO and VglutIRKO mice exhibited normal reproductive maturation and function compared with CONs. No differences in the age of puberty onset, estrous cyclicity, or fertility were observed between VgatIRKO, VglutIRKO, and CON mice. However, male VgatIRKO mice exhibited significantly augmented LH concentration and a trend toward reduced seminal vesicle weight compared with CON mice, which may be indicative of primary hypogonadism. Our results therefore demonstrate that insulin signaling via GABAergic and glutamatergic cells is not required for fertility in mice, but show that GABAergic neurons encompass circuitry through which insulin acts to modulate energy homeostasis.

Derivation of sperm from xenografted testis cells and tissues of the peccary (Tayassu tajacu)

Because the collared peccary (Tayassu tajacu) has a peculiar Leydig cell cytoarchitecture, this species represents a unique mammalian model for investigating testis function. Taking advantage of the well-established and very useful testis xenograft technique, in the present study, testis tissue and testis cell suspensions from immature collared peccaries (n=4; 3 months old) were xenografted in SCID mice (n=48) and evaluated at 2, 4, 6, and 8 months after grafting. Complete spermatogenesis was observed at 6 and 8 months after testis tissue xenografting. However, probably due to de novo testis morphogenesis and low androgen secretion, functionally evaluated by the seminal vesicle weight, a delay in spermatogenesis progression was observed in the testis cell suspension xenografts, with the production of fertile sperm only at 8 months after grafting. Importantly, demonstrating that the peculiar testicular cytoarchitecture of the collared peccary is intrinsically programmed, the unique Leydig cell arrangement observed in this species was re-established after de novo testis morphogenesis. The sperm collected from the xenografts resulted in diploid embryos that expressed the paternally imprinted gene NNAT after ICSI. The present study is the first to demonstrate complete spermatogenesis with the production of fertile sperm from testis cell suspension xenografts in a wild mammalian species. Therefore, due to its unique testicular cytoarchitecture, xenograft techniques, particularly testis cell suspensions, may represent a new and very promising approach to evaluate testis morphogenesis and to investigate spermatogonial stem cell physiology and niche in the collared peccary.

Effect of donor age on success of spermatogenesis in feline testis xenografts

Ectopic xenografting of ‘donor’ feline testicular tissue into a ‘recipient’ immunodeficient mouse is a promising tool to preserve the male genome from genetically valuable felids. To define parameters under which the technique can succeed, we compared the effect of donor age on xenograft spermatogenesis among four age groups of domestic cats (Felis catus; age range 8 weeks to 15 months). In all cases, fresh tissue was grafted into castrated mice and collected 10, 30 and 50 weeks later. The percentage of xenografts recovered decreased as donor age increased. Mature testicular spermatozoa were observed in xenografts from the 8 and 9–16 week age groups; only a single 7-month-old donor produced elongating spermatids and xenografts from donors ≥ 8 months of age degenerated. Seminal vesicle weight, an indicator of bioactive testosterone, was not significantly different between donors aged 8 weeks to 7 months and controls, suggesting that xenograft Leydig cells were ultimately functional even in the 5–7 month age group. Regardless of donor age, production of mature spermatozoa from xenografts was markedly delayed compared with controls. Comparison of xenografts that produced sperm with normal controls revealed a decrease in tubule cross-sections having post-meiotic germ cells. Together, these results indicate that the maximum practical donor age was just before the onset of puberty and that even successful xenografts had abnormalities in spermatogenesis.

280.Reproductive consequences of circadian dysfunction: fertility in the Bmal1 null mouse

Circadian rhythms are generated by a suite of genes called clock genes that are expressed in the brain and also in many peripheral tissues. In the peripheral tissues, these genes assist in regulating the expression of many genes involved in cell growth, angiogenesis and development. Bmal1 is a critical gene involved in circadian rhythm generation. Here we report on the fertility and fecundity of Bmal1 knockout mice (Bmal1–/–). Male Bmal1–/– mice have impaired fertility compared to controls [(litters produced/number of animals) wild type (5/5), CBA controls (5/5), Bmal1–/– (1/15)]. Fifty percent of male Bmal1–/– mice had defective caudal sperm, showing sperm that was both non-motile and malformed. Seminal vesicle weight was significantly reduced in the Bmal1–/– mice (50% reduction) in males at both 4 and 5.5 months old. Female Bmal1–/– mice had irregular oestrus cycles and failed to maintain a pregnancy to term following natural mating [(litters produced/number of animals) wild type (5/5) CBA controls (5/5) Bmal1–/– (0/5)]. When embryos were flushed from the uterus 4 days after natural mating, there was a reduced number of released oocytes and a reduced development to blastocysts in the Bmal1–/– female mice. Following a standard PMSG/HCG super ovulation protocol, Bmal1–/– mice showed both a reduction in ovulation rate as well as a slowed progression of embryos to blastocyst stage (Table 1, see PDF file). These results suggest that disruption of a key clock gene has detrimental consequences on fertility in the mouse. Further, this reduction in fertility appears to be acting at multiple levels. Continued investigation into the importance of rhythm genes in reproductive function is required.