Sexual Activity Influences the Secretion of Reproductive Hormones in the Stallion (original) (raw)
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Endocrine and paracrine control of sperm production in stallions
Animal Reproduction Science, 2001
The specific nature and relative contribution of the major hormones involved in regulation of reproductive function of the stallion are not well defined nor have paracrine or autocrine factors been identified. Over the last 12 years, our laboratory has been engaged in characterizing the hypothalamic-pituitary-testicular axis (HPT) in stallions. A number of endocrine factors and mechanisms important for normal reproductive function have been investigated. Studies investigating poor fertility in stallions suggest that a closer look at the testicular level is warranted. For a complete understanding of intratesticular control mechanisms including cell-to-cell interactions in the stallion, studies on the actions of paracrine/autocrine factors such as growth factors, inhibin, activin, and oxytocin are needed. In other species, paracrine/autocrine systems appear to be important in modulating endocrine control of testicular function and spermatogenesis.
Animal Reproduction Science, 2008
It is well established in many mammalian species, including the horse that normal testicular function is dependent upon a functional hypothalamic-pituitary-testicular (HPT) axis, which involves classic feedback mechanisms. The major HPT hormones involved in the stallion are gonadotropin-releasing hormone (GnRH), luteinizing hormone (LH), follicle stimulating hormone (FSH), testosterone (T), estrogens (Es) and inhibin (INH). Although prolactin (PRL) fluctuates with season in the stallion and both PRL and thyroid hormone (TH) affect reproduction in other male species, their effects on stallion reproduction have not been elucidated. Growth hormone (GH) in the stallion may be involved in sperm motility, production and secretion of insulinlike growth factor-1 (IGF-1) and LH-induced testosterone release. The action of these hormones and the products involved for normal spermatogenesis require cell to cell communication within the testis. The somatic cell types, Leydig, Sertoli and peritubular myoid cells, all support germ cell development, maturation and release into the seminiferous tubule lumen. The cell to cell crosstalk involves an intricate network of paracrine-autocrine systems that support the endocrine input to modulate cell function. In other male species, researchers have demonstrated the reproductive effects of such paracrine-autocrine factors as IGF-1, transferrin, androgens, estrogens, inhibin, insulin like peptide 3 (INSL3), beta-endorphin and oxytocin. The specific nature and relative contribution of these various factors on testicular function in fertile and subfertile stallions are under investigation. This review summarizes current information regarding the nature of the multiple endocrine-paracrine-autocrine systems that may be necessary for normal testicular function in the stallion.
Journal of Animal Science, 1980
Sixteen stallions were castrated and 30 days later assigned to one of four treatments: (1) testosterone propionate (175 ~tg/kg body weight), (2) 173-estradiol-3-benzoate (44 /ag/kg body weight), (3) a combination of both steroids or, (4) vehicle only. These dosages were administered every other day for 18 days. The dosages were then doubled and continued for 20 days. Concentrations of testosterone and estradiol in serum decreased rapidly after castration and stabilized within about 6 hours. Mean concentrations of testosterone and estradiol maintained by the steroids were 1.4 and 90 pg/ml, respectively, during treatment at the lower dosage, and 2.6 and 186 pg/ml during treatment at the higher dosage. Libido and the ability to ejaculate were gradually lost after castration. Testosterone restored both aspects of sexual behavior within 2 weeks. Estradiol effectively restored libido at the higher dosage, but was less effective in restoring the ability to ejaculate. The pH of gel-free semen increased after castration and was subsequently decreased by treatment with testosterone or the combination of both steroids. Estradiol had no effect on seminal pH. Weights of the seminal vesicles, ampullae and prostate were greater in geldings treated with testosterone or with both steroids than in estradiol-treated or control geldings. Since estradiol alone was able to restore libido in geldings, it is possible that the maintenance of libido in intact stallions involves either estradiol secreted directly by the testes or estradiol arising from aromatization t Anim. Reprod. Lab. From a thesis submitted to the Graduate Faculty of Colorado State Univ. by the senior author in partial fulfillment of requirements for the degree of Doctor of Philosophy.
Endocrine Regulation of Reproductive Function in Fertile, Subfertile and Infertile Stallions
Reproduction in Domestic Animals, 1995
The specific nature and relative contribution of the various factors involved in the endocrine/paracrine/autocrine control of reproductive function in normal stallions are not well defined nor have they been elucidated in the idiopathic subfertilelinfertile stallion. Over the last 9 years, our laboratory has been engaged in characterizing the hypothalamic-pituitary-testicular axis (HIT) in fertile, subfertile (idiopathic oligospermia) and infertile (idiopathic azw spermia) stallions. Our studes have not only identlfied endocrine factors and mechanisms important for normal reproductive function, but they have demonstrated specific hormonal alterations in pituitary and testicular function between fertile, subfertile and infertile stallions. Recent evidence suggests that the primary defect is at the level of the testes. The nature of the dysfunction does not appear to involve changes in LH receptor binding kinetics but may be related to post-receptor mechanisms.
Hormones and Behavior, 2007
Mounting interactions in mares isolated from stallions and the relationship to stage of the estrous cycle and level of circulating hormones were studied for 3 years in a herd averaging 105 mares. Mares were assigned to mounting, standing, and control groups. A control mare was selected by being within 1 day of the number of days after ovulation in a mounting mare. A total of 15 mounting interactions were detected by chance observation during the 3 years. A blood sample was collected immediately after the mounting interaction from each mare in the three groups, and a transrectal ultrasonographic examination of the reproductive tract was done. Two mounting interactions occurred during the early luteal phase and 13 during the follicular phase. The interactions that occurred during the follicular phase were used for comparisons among groups. The interval between mounting and the next ovulation, diameter of the two largest follicles, and the number of follicles larger and smaller than 20 mm were not different significantly among the mounting, standing, and control groups. Testosterone concentrations were higher (P<0.01) in the mounting group (17.7+/-2.3 pg/ml) than in standing group (10.9+/-0.5 pg/ml), and the difference between the mounting group and the control group (12.8+/-0.6 pg/ml) approached significance (P<0.08). Concentrations of androstenedione, estradiol, estrone, and progesterone did not differ significantly among groups. Results indicated that mounting behavior between mares is rare, usually occurs during the follicular phase, and is related to high circulating concentrations of testosterone.
Free and Conjugated Estrogens and Androgens in Stallion Semen
General and Comparative Endocrinology, 2002
The steroid content of semen from a total of 11 mature fertile stallions was studied during two breeding seasons and one winter. The levels of free and conjugated substrates (testosterone and androstenedione), and products (estradiol and estrone), of aromatase were measured by radioimmunoassay with a validated method. The results were seasonally and monthly highly variable with characteristic peaks. The concentrations of free and conjugated estrogens were always higher in the gel-free ejaculate than in the gel except in one subfertile stallion used as comparison. Furthermore, the steroid production and the maximal resulting aromatase activity, estimated by the estrogens/androgens ratio, peaked in April-May and June. The breeding season (spring and summer) presents a clear estrogenic profile with estrogens/androgens ratios higher in contrast to the nonbreeding period (autumn and winter). The involvement of estrogens in the regulation of reproduction and equine spermatogenesis is discussed, and estrogens production and thus equine aromatase is proposed as a strong marker of testicular endocrine function. © 2002 Elsevier Science (USA)