Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UNIPROT:P01178 (oxytocin)
15,767 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The objective of this research was to determine if ergotamine, an ergopeptine alkaloid isolated from Neotyphodium-infected grasses and associated with toxicoses in livestock, altered plasma concentrations of reproductive hormones in follicular phase heifers and in cows given a progestin implant. In Experiment 1, blood was sampled for 8h from four cycling heifers 2 days after synchronized luteolysis. Heifers were treated with ergotamine tartrate (19microg/kg) i.v. or saline vehicle in a simple cross-over design after 1h of pre-treatment blood sampling. Heifers received oxytocin (100USP units) i.v. 4h after ergotamine or saline treatment. Ergotamine reduced (P<0.01) prolactin concentrations from 1 to 4h post-treatment and increased (P<0.01) 13,14-dihydro-15-keto prostaglandin F2alpha (PGFM) concentrations from 2 to 5h post-treatment. A PGFM response to oxytocin was not detected. In Experiment 2, blood was sampled for 8h from six cycling cows 10 days after receiving a s.c. norgestomet implant. Cows were treated i.v. with ergotamine (20microg/kg) or saline in a simple cross-over design after 1h of pre-treatment blood sampling. Cows received gonadorelin (GnRH, 100microg) i.v. 1h after ergotamine or saline. Cows received oxytocin (100USP units) i.v. 4h after ergotamine or saline treatment. Ergotamine reduced (P<0.01) serum prolactin concentrations by 120min after treatment, with prolactin returning to pre-treatment concentrations by 200min after treatment. Saline-treated cows had lower (P<0.01) prolactin by 280min after treatment. Ergotamine-treated cows had higher (P<0.01) PGFM concentrations compared to saline-treated cows 120-240min after treatments, but the groups exhibited similar increases in PGFM after oxytocin. Plasma LH and FSH concentrations increased to peaks 100-120min after GnRH for both groups. However, the LH response to GnRH was greater (P<0.01) for ergotamine-treated cows. In summary, ergotamine lowered prolactin and elevated PGFM concentrations in follicular phase heifers and cows on norgestomet therapy. Ergotamine increased the LH response to exogenous GnRH in cows with norgestomet implants. These data highlight the potential of ergopeptine alkaloids to affect reproduction through altered endocrine function.
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PMID:Effect of an acute ergotamine challenge on reproductive hormones in follicular phase heifers and progestin-treated cows. 1134 77

Four separate components combine to produce the progesterone and biologically active 5 alpha-reduced pregnanes needed to maintain pregnancy in the mare. The primary corpus luteum (CL) is prolonged beyond its cyclical lifespan by the down-regulation of endometrial oxytocin receptors to prevent activation of the luteolytic pathway and its waning progesterone production is supplemented from day 40 of gestation by the formation of a series of accessory CL which develop in the maternal ovaries as a result of the gonadotrophic actions of pituitary FSH and the equine chorionic gonadotrophin (eCG). From around day 100 the allantochorion secretes progesterone and progestagens directly to the endometrium and underlying myometrium and, in the last month of gestation, the enlarging foetal adrenal gland secretes appreciable quantities of pregnenelone which is also utilized by the placenta to synthesize progestagens. Between 10 and 15% of mares undergo foetal death and abortion at some time in gestation and the majority of these losses occur during the first 40 days of gestation when the primary CL is the sole source of progesterone. Yet, all the available evidence suggests that untoward luteolysis is not common in this period and the losses that do occur have other underlying causes. Beyond day 40 the secondary CL receive powerful luteotrophic support from eCG and from day 80-100 until term the supply organ (placenta) and target tissues (endometrium and myometrium) are in direct contact with each other over their entire surface. In the face of this interlocking and failsafe system for progestagen production throughout pregnancy, and despite a paucity of evidence that a deficiency of progesterone production is a cause of pregnancy loss in the mare, it is surprising, and worrying, that annually many thousands of pregnant mares throughout the world are given exogenous progestagen therapy during part or all of their gestation as a form of preventative insurance against the possibility of pregnancy failure. Basic investigative research is required urgently to validate or debunk the practice.
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PMID:Luteal deficiency and embryo mortality in the mare. 1155 57

Oxytocin secretion by bovine granulosa cells increases dramatically after the LH/FSH surge. We have shown that oxytocin stimulates progesterone secretion and inhibits FSH-stimulated estradiol secretion in vitro by granulosa cells from bovine preovulatory follicles obtained before the LH/FSH surge. To determine if oxytocin regulates LH-stimulated steroid production by bovine theca interna cells, theca cells were isolated from preovulatory follicles obtained before the LH surge and were cultured for 4 days in the presence or absence of LH (2 or 4 ng/ml), without or with graded doses of oxytocin (125-1000 ng/ml). LH increased accumulation of androstenedione and progesterone. Oxytocin inhibited LH-stimulated androstenedione production, but had no effect on LH-stimulated progesterone production by cultured theca interna. The next objective was to determine if oxytocin regulates LH-stimulated steroidogenesis by modulating the levels of mRNA for steroidogenic enzymes and/or Steroidogenic Acute Regulatory protein (StAR). Low doses of LH alone increased the levels of mRNA for P450 17 alpha-hydroxylase (17 alpha-OH), 3beta-hydroxysteroid dehydrogenase (3beta-HSD) and cytochrome P450 side-chain cleavage, but not for StAR. In contrast, the effects of oxytocin on LH-stimulated androstenedione production were not associated with changes in the levels of mRNA for steroidogenic enzymes or StAR. These results suggest that oxytocin may play a paracrine role in regulating the follicular/luteal phase shift in steroidogenesis by decreasing androstenedione secretion by theca cells of the ovulatory follicle and that this effect is not mediated by changes in the levels of mRNA for steroidogenic enzymes and StAR.
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PMID:Oxytocin inhibits LH-stimulated production of androstenedione by bovine theca cells. 1191 54

The presented overview gives clear evidence for steroids as local regulators of follicular and luteal activity. In the follicle, estrogen receptor-alpha (ERalpha) and ERbeta expression are demonstrated in cow, ewe and pig. Besides species specific effects in general, there is evidence that estradiol-17beta (E(2)) exerts a dose-dependent inhibition on the secretion of progesterone (P(4)) by both theca interna cells (TI) and granulosa cells (GC). GC enhance the ability of the TI to produce androstendione by supplying them with progestin precursor. Androgen produced by TI enhances the ability of the GC to make E(2), and high concentrations of E(2) in the preovulatory follicle inhibit 3beta-HSD in both TI and GC and thus, may promote the use of the pathway Delta(5) for TI androgen production. The authors suggest that E(2) acts within the follicle to exert positive feedback on androgen and E(2) production, and exerts mitotic and anti-atretic or anti-apoptotic effects on follicular cells. Parts of the E(2)-mediated local action are regulated by stimulating effects on hormone receptors (LH, FSH, oxytocin). Gap junctions permit transfer of nutrients and cytokines to and from the avascular GC and oocyte, and formation is stimulated by estrogens. In bovine corpus luteum (CL) there is evidence that P(4) may directly regulate the production of P(4), oxytocin and prostaglandins (PGs) in a cycle dependent fashion. In most of domestic animal species, there is clear evidence for CL production of E(2) with clear stimulatory and luteotropic effects on P(4), and an intraluteal circuit that involves paracrine effects of E(2), oxytocin and PGF(2alpha) (especially in pigs). In contrast, there are species (ruminants, mares) in which the evidence for important local effects of E(2) is less clear, although expression of ERalpha, ERbeta and progesterone receptor (PR) is documented. Progesterone is very important for the regulation of CL lifetime by effects on the endometrium and release of the luteolytic signal PGF(2alpha). In conclusion, steroids as local regulators of ovarian activity are now documented and may stimulate further research in this field.
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PMID:Steroids as local regulators of ovarian activity in domestic animals. 1214 26

This review of the physiology of ovarian contractility cites the functions of FSH and LH and the contribution of chorionic gonadotropin (HCG) to follicular swelling and rupture. Endogenous estrogen priming seems to be needed for this response. Luteninizing hormone releasing hormone (LHRH) administered during the ovulatory phase also causes changes to occur in ovaries treated with smooth muscle stimulants. A contractile response may be induced by alpha-adrenergic receptors, which confirms the finding of smooth muscle fibers in the ovaries. Spontaneous contractions have also been observed in ovaries removed from animals at estrus. Estrogen activate, progesterone inhibits ovarian contractility. In rabbits and guinea pigs spontaneous activity of the ovary is increased during early pregnancy. Treatment with nor- epinephrine inhibits this. Quiescent ovaries show marked activation with nor-adrenergic compounds such as nor-epinephrine and phenilephrine. Pretreatment with alpha-adrenergic blocking agents such as progranolol reverses this effect. Prostaglandin F-2-alpha is a more powerful stimulant on ovarian motility than vasopressin or oxytocin. The role of ovarian contractions in the reproductive function is still unknown. Further studies may provide ways of interfering with reproduction at the ovarian level.
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PMID:Ovarian contractility and ovulation. 1225 6

In mice deficient in progesterone receptor (PR), follicles of ovulatory size develop but fail to ovulate, providing evidence for an essential role for progesterone and PR in ovulation in mice. However, little is known about the expression and regulation of PR mRNA in preovulatory follicles of ruminant species. One objective of this study was to determine whether and when PR mRNA is expressed in bovine follicular cells during the periovulatory period. Luteolysis and the LH/FSH surge were induced with prostaglandin F(2alpha) and a GnRH analogue, respectively, and the preovulatory follicle was obtained at 0, 3.5, 6, 12, 18, or 24 h after GnRH treatment. RNase protection assays revealed a transient increase in levels of PR mRNA, which peaked at 6 h after GnRH and declined to the time 0 value by 12 h and a second increase at 24 h. The second objective was to investigate the mechanisms that regulate PR mRNA expression through in vitro studies on follicular cells of preovulatory follicles obtained before the LH/FSH surge. Theca and granulosa cells were isolated and cultured with or without a luteinizing dose of LH or FSH, progesterone, LH + progesterone, or LH + antiprogestin (RU486). Levels of PR mRNA increased in a time-dependent manner in granulosa cells cultured with LH or FSH and in theca cells cultured with LH, peaking at 10 h of culture. In contrast, progesterone (200 ng/ml) did not upregulate mRNA for its own receptor, and neither progesterone nor RU486 affected LH-stimulated PR mRNA accumulation. Furthermore, RU486 completely blocked LH-stimulated expression of oxytocin mRNA, indicating that PR induced by LH in vitro is functional. These results show that the gonadotropin surge induces a rapid and transient increase in expression of PR mRNA in both theca and granulosa cells of bovine periovulatory follicles followed by a second rise close to the time of ovulation and that the first increase in PR mRNA can be mimicked in vitro by gonadotropins but not by progesterone. These results suggest multiple and time-dependent roles for progesterone and PR in the regulation of periovulatory events in cattle.
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PMID:Gonadotropin surge induces two separate increases in messenger RNA for progesterone receptor in bovine preovulatory follicles. 1244 77

In cattle, production of oxytocin by granulosa cells of preovulatory follicles is induced by the LH/FSH surge and intrafollicular oxytocin increases dramatically toward the end of the interval between the surge and ovulation. We reported previously that oxytocin modulates steroid production by both theca and granulosa cells obtained from bovine preovulatory follicles, implying actions of oxytocin on both cell types of preovulatory follicles. The objective of the present study was to examine the temporal expression of oxytocin receptor mRNA and protein in both theca and granulosa cells of bovine periovulatory follicles. To induce luteal regression and initiate a follicular phase, heifers were injected with prostaglandin F(2alpha) on Day 6 or 7 of the estrous cycle and 36 h later, a GnRH analogue was administered to induce the LH/FSH surge. The periovulatory follicle was isolated at 0, 3.5, 12, or 24 h after GnRH injection. A significant increase in the levels of mRNA for oxytocin was detected in granulosa, but not theca, cells of periovulatory follicles at 12 and 24 h after GnRH injection, relative to time 0. In contrast, the levels of oxytocin receptor mRNA and specific binding sites for oxytocin in granulosa cells had decreased significantly at 12 and 24 h post-GnRH. In theca cells, the levels of oxytocin receptor mRNA were significantly lower at 12 and 24 h compared with values at 3.5 h, but specific binding of oxytocin to thecal cell membranes was not different at any time point. Immunopositive staining for oxytocin receptor was localized to both the theca and granulosa cell layer of periovulatory follicles at all four times of follicle isolation. These results suggest the direct action of oxytocin on both theca and granulosa cells of bovine periovulatory follicles through binding to its receptor, supporting the hypothesis that follicular oxytocin plays an important role(s) in the regulation of the final stage of follicular development. Down-regulation of oxytocin receptor mRNA and oxytocin binding may serve to temporally limit the actions of oxytocin on the preovulatory follicle.
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PMID:Changes in oxytocin receptor in bovine preovulatory follicles between the gonadotropin surge and ovulation. 1264 97

We have demonstrated that sexual activity produces transient sympathoadrenal activation and a pronounced, long-lasting increase in prolactin in men and women. However, by analyzing endocrine alterations at 10-min intervals, a precise assignment of these changes to the pre-, peri- and postorgasmic periods was not possible. Thus, the current study aimed to accurately differentiate the endocrine response to sexual arousal and orgasm in men using an automatic blood collection technique with 2-min sampling intervals. Blood was drawn continuously before, during and after orgasm over a total period of 40 min in 10 healthy subjects and were compared with samples obtained under a control condition. Sexual activity induced transient increases of plasma epinephrine and norepinephrine levels during orgasm with a rapid decline thereafter. In contrast, prolactin levels increased immediately after orgasm and remained elevated throughout the experiment. Although oxytocin was acutely increased after orgasm, these changes were not consistent and did not reach statistical significance. Vasopressin, LH, FSH and testosterone plasma concentrations remained unaltered during sexual arousal and orgasm. These data confirm that prolactin is secreted after orgasm and, compared with oxytocin, seems to represent a more reliable and sustained marker for orgasm in man. The results further reinforce a role for prolactin either as a neuroendocrine reproductive reflex or as a feedback mechanism modulating dopaminergic systems in the central nervous system that are responsible for appetitive behavior.
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PMID:Specificity of the neuroendocrine response to orgasm during sexual arousal in men. 1269 37

The pituitary gland is an important component of the endocrine system, and together with the hypothalamus, exerts considerable influence over the functions of other endocrine glands. The hypothalamus either positively or negatively regulates hormonal productions in the pituitary through its release of various trophic hormones which act on specific cell types in the pituitary to secrete a variety of pituitary hormones that are important for growth and development, metabolism, reproductive and nervous system functions. The pituitary is divided into three sections-the anterior lobe which constitute the majority of the pituitary mass and is composed primarily of five hormone-producing cell types (thyrotropes, lactotropes, corticotropes, somatotropes and gonadotropes) each secreting thyrotropin, prolactin, ACTH, growth hormone and gonadotropins (FSH and LH) respectively. There is also a sixth cell type in the anterior lobe-the non-endocrine, agranular, folliculostellate cells. The intermediate lobe produces melanocyte-stimulating hormone and endorphins, whereas the posterior lobe secretes anti-diuretic hormone (vasopressin) and oxytocin. Representative cell lines of all the six cell types of the anterior pituitary have been established and have provided valuable information on genealogy of the various cell lineages, endocrine feedback control of hormone synthesis and secretions, intrapituitary interactions between the various cell types, as well as the role of specific transcription factors that determine each differentiated cell phenotype. In this review, we will discuss the morphology and function of the cell types that make up the anterior pituitary, and the characteristics of the various functional anterior pituitary cell systems that have been established to be representative of each anterior pituitary cell lineage.
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PMID:Pituitary cell lines and their endocrine applications. 1554 69

The adipose tissue signals to the brain via its secretory products. However, it is unknown whether the brain itself can directly contact the fat tissue. In order to test this hypothesis, the adipocytic expression of receptors for pituitary hormones and hypothalamic peptides was investigated. Besides FSH- and LH-receptors, adipocytes do express the specific receptors for ACTH, TSH, GH, prolactin, oxytocin and the three receptor subtypes for vasopressin. Thus, the adipose tissue might no longer be regarded as an inert and steady tissue but as a fast acting player downstream of and under the control of the brain. Based on this, the potential existence and clinical impact of a hypothalamic-pituitary-adipose axis should further be investigated.
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PMID:Hypothesis paper Brain talks with fat--evidence for a hypothalamic-pituitary-adipose axis? 1604 Jan 19


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