The role of thecal androgen production in the regulation of estradiol biosynthesis by dominant bovine follicles during the first follicular wave1,2

The first wave of follicular development following ovulation in cattle is characterized by selection and growth of a large, estrogenic dominant follicle. After the follicle becomes morphologically dominant, concentrations of estradiol in its follicular fluid decrease abruptly. The purpose of this study was to determine whether this decrease in estrogen production is caused by an insufficient supply of androgen from theca interna or decreased aromatization of androgen precursor by granulosa cells. Dominant follicles were collected from Holstein heifers on d 4, 6, or 8 of the first follicular wave (n = 5/d). Amounts of 17alpha-hydroxylase mRNA in theca interna were sevenfold higher (P < 0.01) on d 4 than on d 8. After 3 h in culture, secretion of androstenedione by theca interna collected on d 4 (236 +/- 44 pg/microg of protein) tended to be lower (P = 0.055) compared with d 6 (517 +/- 162 pg/microg protein) and was lower (P < 0.05) compared with d 8 (387 +/- 51 pg/microg of protein). In granulosa cells, amounts of aromatase mRNA decreased (P < 0.05) on d 8 compared with d 6 but not d 4. In vitro secretion of estradiol was higher in granulosa cells collected on d 4 (3.5 +/- 0.8 ng/[10(5) cells x 3 h]) compared with d 6 (1.8 +/- 0.6 ng/[10(5) cells x 3 h]; P < 0.05) and tended to be higher on d 4 than on d 8 (2.2 +/- 0.2 ng/[10(5) cells x 3 h]; P = 0.058). We conclude that the decrease in estradiol production observed during atresia of the dominant follicle is not due to lack of androgen substrate for aromatization or downregulated expression of the aromatase gene, but may be the direct result of decreased activity of the aromatase enzyme within granulosa cells.

Regulation of genes encoding steroidogenic factor-1 (SF-1) and gonadotropin subunits in the ovine pituitary gland

Steroidogenic factor-1 (SF-1) is a transcription factor originally characterized as a mediator of gene expression in steroidogenic tissues. Studies in SF-1 knockout mice revealed that SF-1 has additional roles at multiple levels of the hypothalamic-pituitary-gonadal axis, including regulation of gene expression in pituitary gonadotropes. Specific binding sites for SF-1 have been demonstrated in several pituitary genes with essential roles in gonadotropin synthesis, including alpha subunit, LHbeta subunit, and GnRH receptor. In studies aimed at identifying physiological factors controlling pituitary expression of SF-1, GnRH has been implicated as a co-regulator of SF-1 and gonadotropin subunit genes. In both rats and ewes, elevated endogenous secretion of GnRH following ovariectomy was associated with increased amounts of SF-1 mRNA in the anterior pituitary gland. Conversely, removal of GnRH input to the pituitary gland by hypothalamic-pituitary disconnection (HPD) in ovariectomized (OVX) ewes reduced SF-1 expression. Despite these changes, however, treatment of OVX ewes with GnRH following HPD only partially restored levels of SF-1 mRNA in the pituitary gland. Therefore, it is possible that regulation of SF-1 gene expression by GnRH during the estrous cycle may involve ovarian hormones or other hypothalamic factors. Additional studies are required to further define the physiological roles of SF-1 in regulation of the hypothalamic-pituitary-gonadal axis in domestic ruminants.

Pituitary effects of steroid hormones on secretion of follicle-stimulating hormone and luteinizing hormone

Steroid hormones have a profound influence on the secretion of the gonadotropins, follicle-stimulating hormone (FSH) and luteinizing hormone (LH). These effects can occur as a result of steroid hormones modifying the secretion of gonadotropin-releasing hormone (GnRH) from the hypothalamus, or a direct effect of steroid hormones on gonadotropin secreting cells in the anterior pituitary gland. With respect to the latter, we have shown that estradiol increases pituitary sensitivity to GnRH by stimulating an increase in expression of the gene encoding the GnRH receptor. Since an estrogen response element (ERE) has not been identified in the GnRH receptor gene, this effect appears to be mediated by estradiol stimulating production of a yet to be identified factor that in turn enhances expression of the GnRH receptor gene. However, the importance of estradiol for enhancing pituitary sensitivity to GnRH during the periovulatory period is questioned because an increase in mRNA for the GnRH receptor precedes the pre-ovulatory rise in circulating concentrations of estradiol. In fact, it appears that the enhanced pituitary sensitivity during the periovulatory period may occur as a result of a decrease in concentrations of progesterone rather than due to an increase in concentrations of estradiol. Estradiol also is capable of altering secretion of FSH and LH in the absence of GnRH. In a recent study utilizing cultured pituitary cells from anestrous ewes, we demonstrated that estradiol induced a dose-dependent increase in secretion of LH, but resulted in a dose-dependent decrease in the secretion of FSH. We hypothesized that the discordant effects on secretion of LH and FSH might arise from estradiol altering the production of some of the intrapituitary factors involved in synthesis and secretion of FSH. To examine this hypothesis, we measured amounts of mRNA for activin B (a factor known to stimulate synthesis of FSH) and follistatin (an activin-binding protein). We found no change in the mRNA for follistatin after treatment of pituitary cells with estradiol, but noted a decrease in the amount of mRNA for activin B. Thus, the inhibitory effect of estradiol on secretion of FSH appears to be mediated by its ability to suppress the expression of the gene encoding activin.

Differentiation of dominant versus subordinate follicles in cattle

Selection of a dominant follicle, capable of ovulating, from among a cohort of similarly sized follicles is a critical transition in follicular development. The mechanisms that regulate the selection of a species-specific number of dominant follicles for ovulation are not well understood. Cattle provide a very useful animal model for studies on follicular selection and dominance. During the bovine estrous cycle, two or three sequential waves of follicular development occur, each producing a dominant follicle capable of ovulating if luteal regression occurs. Follicles are large enough to allow analysis of multiple endpoints within a single follicle, and follicular development and regression can be followed via ultrasonographic imaging. Characteristics of recruited and selected follicles, obtained at various times during the first follicular wave, have been determined in some studies, whereas dominant and subordinate follicles have been compared around the time of selection in others. As follicular recruitment proceeds, mRNA for P450 aromatase increases. By the time of morphological selection, the dominant follicle has much higher concentrations of estradiol in follicular fluid, and its granulosa cells produce more estradiol in vitro than cells from subordinate follicles. Shortly after selection, dominant follicles have higher levels of mRNAs for gonadotropin receptors and steroidogenic enzymes. It has been hypothesized that granulosa cells of the selected follicle acquire LH receptors (LHr) to allow them to increase aromatization in response to LH, as well as FSH. However, LH does not appear to stimulate estradiol production by bovine granulosa cells, and the role of LHr acquisition remains to be determined. Recent evidence suggests a key role for changes in the intrafollicular insulin-like growth factor (IGF) system in selection of the dominant follicle. When follicular fluid was sampled in vivo before morphological selection, the lowest concentration of IGF binding protein-4 (IGFBP-4) was more predictive of future dominance than size or estradiol concentration. Consistent with this finding, dominant follicles acquire an FSH-induced IGFBP-4 protease activity. Thus, a decrease in IGFBP-4, which would make more IGF available to interact with its receptors and synergize with FSH to promote follicular growth and aromatization, appears to be a critical determinant of follicular selection for dominance.

Activin modulates differential effects of estradiol on synthesis and secretion of follicle-stimulating hormone in ovine pituitary cells

In several physiological paradigms, secretion of FSH and LH are not coordinately regulated. Because these hormones appear to be produced by a single cell type in the anterior pituitary gland, their discordant regulation must be related to differential intracellular responses to various stimuli. Estradiol-17beta (estradiol) has been shown to influence secretion of both FSH and LH and some of its effects are mediated directly on the gonadotrope. Changes in expression of intrapituitary factors such as activin and follistatin may mediate effects of estradiol and account for discordant patterns of FSH and LH. The aims of this study were 1) to determine if estradiol alters expression of genes encoding activin, follistatin, or both in ovine pituitary cells; and 2) to observe the effects of immunoneutralizing activin B in vitro on gonadotropin secretion. Pituitary cells from five ewes in the anestrous season were cultured for 24 h with estradiol (0.01 or 1.0 nM). Estradiol reduced basal secretion of FSH in a dose-dependent manner (P: < 0.001) and simultaneously increased basal secretion of LH (P: < 0.001). Decreased secretion of FSH in estradiol-treated cultures was accompanied by suppressed levels of FSHbeta subunit mRNA (P: < 0.001). Amounts of mRNA for activin beta(B) were reduced in a dose-dependent manner by estradiol (27% +/- 4.9% at 0.01 nM, P: < 0.02; and 46% +/- 3.9% at 1.0 nM, P: < 0.002). In contrast, mRNA for follistatin was not affected by treatment with estradiol. Treatment of pituitary cells with an antibody to activin B reduced secretion of FSH by 50% (P: < 0.01) without influencing secretion of LH. These data lead us to conclude that discordant secretion of gonadotropins can be induced by estradiol acting directly at the pituitary level. The inhibitory effect of estradiol on FSH secretion may be mediated indirectly through decreased pituitary expression of the activin gene.

Regulation of GnRH receptor gene expression in sheep and cattle

The GnRH receptor plays a pivotal role in reproduction. This review summarizes current knowledge of the regulation of GnRH receptor gene expression by endocrine factors in sheep and cattle. Expression of the GnRH receptor gene, measured by steady-state amounts of GnRH receptor messenger RNA (mRNA), is maximal during the preovulatory period. The molecular events leading to maximal GnRH receptor gene expression are probably triggered by decreased circulating concentrations of progesterone at luteolysis. Because GnRH is a positive homologous regulator of its own receptor, increased pulsatile GnRH after removal of negative feedback effects of progesterone stimulates expression of the GnRH receptor gene early in the preovulatory period. Oestradiol is also a positive regulator of GnRH receptor gene expression, and increased serum concentrations of oestradiol from developing follicles probably maintain high abundance of GnRH receptor mRNA later in the preovulatory period. Since increased amount of GnRH receptor mRNA precedes maximal numbers of GnRH receptors before the LH surge, increased expression of the GnRH receptor gene is an important mechanism by which maximal sensitivity of gonadotrophs to GnRH is achieved. Future efforts should be directed towards elucidating the molecular mechanisms underlying transcriptional regulation of the GnRH receptor gene in ruminants by endocrine factors.

Regulation of gonadotropin-releasing hormone (GnRH) receptor gene expression in sheep: interaction of GnRH and estradiol

GnRH and estradiol are important regulators of GnRH receptors. When delivered to the anterior pituitary gland continuously, GnRH decreases numbers of GnRH receptors on gonadotropes. Treatment with estradiol consistently increases numbers of GnRH receptors. Because estradiol acts via intracellular receptors while GnRH exerts its effects through a membrane receptor, it is likely that these hormones influence GnRH receptor expression via different mechanisms. In this experiment, we tested two hypotheses: 1) continuous infusion of GnRH will decrease expression of the GnRH receptor gene; and 2) estradiol will override the negative effects of continuous infusion of GnRH on GnRH receptor expression. Ovariectomized ewes were administered either GnRH (10 microg/h, n = 10) or saline (n = 10) continuously for 136 h. At 124 h, 5 ewes in each group were administered estradiol (25 microg i.m.) and anterior pituitary glands were collected 12 h later. Treatment with GnRH caused an abrupt increase in circulating concentrations of LH, and the maximal mean concentration was observed 4 h after the start of GnRH infusion. Following this increase, concentrations of LH in GnRH-treated ewes declined and were similar to those in saline-treated ewes from 8 h to 124 h. After injection of estradiol at 124 h, circulating concentrations of LH increased in both GnRH- and saline-treated ewes. However, this response occurred within 6 h in ewes treated with GnRH compared with 9 h in ewes treated with saline (P < 0.05). Compared with saline-treated controls, treatment with GnRH decreased mean steady-state amount of GnRH receptor messenger RNA (mRNA) (P < 0.01) and concentration of GnRH receptors (P < 0.05). Treatment with estradiol caused an increase in concentrations of GnRH receptor mRNA (P < 0.05) and GnRH receptors (P < 0.01). Amounts of GnRH receptor mRNA and numbers of GnRH receptors in ewes treated with both GnRH and estradiol were not different from those in the control group but were higher (P < 0.002) relative to ewes treated with GnRH alone. Treatment with GnRH and estradiol also influenced the expression of genes encoding the LHbeta and FSHbeta subunits. Compared with saline-treated controls, treatment with GnRH reduced steady-state amounts of mRNA encoding LHbeta subunit (P < 0.005) and FSHbeta subunit (P < 0.05). Treatment with estradiol caused a decrease in concentrations of FSHbeta subunit mRNA (P < 0.01) but did not affect amounts of LHbeta subunit mRNA. The combined treatment of GnRH and estradiol reduced concentrations of mRNA encoding LHbeta subunit (P < 0.01) and FSHbeta subunit (P < 0.005). From these data we conclude that 1) reduced numbers of GnRH receptors during continuous infusion of GnRH are mediated in part by decreased expression of the GnRH receptor gene; and 2) estradiol is able to override the negative effect of GnRH by stimulating an increase in GnRH receptor gene expression and GnRH receptor concentrations. Therefore, although the gonadotrope becomes refractory to GnRH during homologous desensitization, this desensitization does not affect the cell's ability to respond to estradiol.

Regulation of ovine GnRH receptor gene expression by progesterone and oestradiol

The objective of this study was to determine whether progesterone prevents the stimulatory effects of oestradiol on GnRH receptor gene expression. In Expt 1, ewes were treated during the luteal phase (days 10-12 of the oestrous cycle) with either one or five subcutaneous implants containing oestradiol (n = 6 per group). Control ewes received no treatment (n = 6). Anterior pituitary glands were collected 16 h after treatment with oestradiol. Steady-state amounts of GnRH receptor mRNA were similar among all three treatment groups despite increased circulating concentrations of oestradiol in implanted ewes at the time of pituitary collection (4.3 +/- 0.6 and 24.7 +/- 2.6 pg ml-1 in ewes treated with one or five implants, respectively, compared with 0.5 pg ml-1 in controls). Experiment 2 was designed to determine whether progesterone was the ovarian factor preventing the stimulatory effects of oestradiol on expression of the GnRH receptor gene in Expt 1. Twenty-five ewes were ovariectomized on day 6 or day 7 of the oestrous cycle and assigned to one of five treatment groups (n = 5 per group). Control ewes received no further treatment. Endogenous luteal phase concentrations of progesterone were replaced in three groups of ewes at the time of ovariectomy via intravaginal implants. Three days after ovariectomy, one group of progesterone-treated ewes received one oestradiol implant, while another group of progesterone-treated ewes received five oestradiol implants. An additional group was treated with five oestradiol implants only, and anterior pituitary glands were collected from all ewes 16 h later. Compared with untreated ovariectomized ewes, treatment with progesterone alone did not affect amounts of GnRH receptor mRNA. In ewes treated with progesterone and either one or five oestradiol implants, steady-state amounts of GnRH receptor mRNA were increased twofold (P < 0.01). Treatment with oestradiol in the absence of progesterone increased amounts of GnRH receptor mRNA threefold (P < 0.001). These results provide evidence that the stimulatory effects of oestradiol on the expression of the GnRH receptor gene are prevented during the natural luteal phase in ewes. However, progesterone does not appear to act independently to mediate this effect.

Steady-state concentrations of mRNA encoding two inhibitors of protein kinase C in ovine luteal tissue

Prostaglandin F2 alpha (PGF2 alpha) decreases secretion of progesterone from the corpus luteum in domestic ruminants. However, it is less effective during the early part of the oestrous cycle (Louis et al., 1973) and at the time of maternal recognition of pregnancy (Silvia and Niswender, 1984; Lacroix and Kann, 1986). Decreased luteal responsiveness may be due to failure of PGF2 alpha to activate fully its normal second messenger system, protein kinase C (PKC). Alternatively, increased resistance of the corpus luteum to PGF2 alpha might be attributable to greater concentrations of recently identified biological inhibitors of PKC. These possibilities were addressed by measuring steady-state concentrations of mRNA encoding PGF2 alpha receptor and two inhibitors of PKC, protein kinase C inhibitor-1 (PKCI-1) and kinase C inhibitor protein-1 (KCIP-1, brain 14-3-3 protein), in corpora lutea collected from ewes on days 4, 10 and 15 of the oestrous cycle (n = 5 per day) and day 15 of pregnancy (n = 7). There were no differences in mean concentrations of mRNA encoding PGF2 alpha receptor among the groups. However, concentrations of mRNA encoding both inhibitors of PKC were higher (P < 0.01) on day 4 of the oestrous cycle compared with the other groups. Treatment of ewes with a luteolytic dose of PGF2 alpha, which activates PKC, did not change concentrations of mRNA encoding either PKCI-1 or KCIP-I up to 24 h later. Luteal expression of mRNA encoding the PKC inhibitors and PGF2 alpha receptor was also examined in ewes treated with oestradiol in vivo for 16 h in the midluteal phase. High concentrations of oestradiol in serum (20 and 70 pg ml-1) did not influence quantities of any of the mRNAs examined. Therefore, an increase in PKC inhibitors may be involved in resistance of the corpus luteum to PGF2 alpha during the early part of the oestrous cycle but does not appear to mediate the increased resistance of the corpus luteum to PGF2 alpha during maternal recognition of pregnancy. Neither PGF2 alpha nor oestradiol affected steady-state concentrations of mRNAs encoding PKCI-1 or KCIP-I.

Effects of bovine follicular fluid and passive immunization against gonadotropin-releasing hormone (GnRH) on messenger ribonucleic acid for GnRH receptor and gonadotropin subunits in ovariectomized ewes

In cultured ovine pituitary cells, inhibin increases concentrations of mRNA encoding GnRH receptor and numbers of GnRH receptors. The objective of this study was to test the hypothesis that inhibin increases concentrations of ovine GnRH receptor mRNA in vivo. Ovariectomized ewes were used to eliminate effects of endogenous ovarian hormones, and passive immunization against GnRH was employed to avoid possible confounding influences of GnRH on GnRH receptor gene expression. Two groups of ewes (n = 5/group) were treated with 50 ml GnRH antiserum on Days 0 and 3 of the experiment. One group of immunized ewes received 10 ml charcoal-extracted bovine follicular fluid (bFF) as a source of inhibin every 8 h for 48 h on Days 4-6 of the experiment. A third group of ewes was not passively immunized and was treated only with bFF, and control ewes received no treatments. Anterior pituitary glands were collected from all ewes on Day 6. Passive immunization against GnRH, alone or in combination with treatment with bFF, decreased mean concentrations of LH (p < 0.01) and LH pulse amplitude (p < 0.001). In ewes treated only with GnRH antiserum, number of LH pulses was also reduced (p < 0.03). Circulating concentrations of FSH tended to be lower (p = 0.06) in passively immunized ewes compared to controls. Treatment with bFF, alone or in combination with GnRH antiserum, reduced circulating concentrations of FSH (p < 0.02) and amounts of FSHbeta subunit mRNA (p < 0.001) to less than 30% and 10% of control values, respectively. Despite effects of bFF on concentrations of FSHbeta mRNA and secretion of FSH, concentrations of GnRH receptor mRNA were similar among controls, ewes treated with bFF alone, and passively immunized ewes treated with bFF. Passive immunization against GnRH did not affect concentrations of GnRH receptor mRNA but resulted in a reduction (p < 0.05) in amount of LHbeta mRNA. Treatment with bFF did not affect amounts of either alpha subunit or LHbeta subunit mRNA except when combined with treatment with antiserum, when amounts of both alpha and LHbeta subunit mRNA were reduced (p < 0.05). These results do not support the hypothesis that inhibin increases concentrations of GnRH receptor mRNA in the ewe, and they provide evidence that inhibin is not an acute regulator of ovine GnRH receptor gene expression in vivo.

Effects of ovariectomy and hypothalamic-pituitary disconnection on amounts of steroidogenic factor-1 mRNA in the ovine anterior pituitary gland

Steroidogenic factor-1 (SF-1) is a transcription factor involved in regulation of steroidogenic enzymes. Recent evidence indicates that SF-1 is also important in the anterior pituitary gland, where it may influence gene expression in gonadotropes. We isolated a cDNA encoding ovine SF-1 and demonstrated that the SF-1 gene is expressed in the anterior pituitary gland of sheep. SF-1 transcripts and luteinizing hormone (LH) were colocalized in gonadotropes by in situ hybridization and immunohistochemistry, respectively. To test the hypothesis that GnRH stimulates pituitary expression of ovine SF-1 mRNA, ewes were ovariectomized to increase endogenous secretion of GnRH. Compared to ovary-intact ewes, ovariectomy resulted in three- and fourfold increases in steady-state amounts of mRNA encoding SF-1 and LH beta subunit, respectively. In ovariectomized ewes in which delivery of GnRH to the anterior pituitary gland was prevented by hypothalamic-pituitary disconnection (HPD), steady-state amounts of mRNA encoding SF-1 and LH beta-subunit were decreased. These results provide evidence that pituitary SF-1 gene expression in sheep is regulated by GnRH. Coordinate regulation of mRNAs encoding SF-1 and LH beta-subunit raises the possibility that SF-1 may be an important transcriptional regulator of LH beta-subunit gene expression in ovine gonadotropes.

Effect of gonadotropin-releasing hormone (GnRH) pulse frequency on serum and pituitary concentrations of luteinizing hormone and follicle-stimulating hormone, GnRH receptors, and messenger ribonucleic acid for gonadotropin subunits in cows

Thirty-two nutritionally anestrous cows were used to determine the effect of the frequency of exogenous GnRH pulses on ovarian follicular growth, serum concentrations of LH and FSH, and concentrations of LH, FSH, GnRH receptors (GnRH-R), messenger RNA (mRNA) for GnRH-R, and mRNA for gonadotropin subunits in the pituitary. Cows were randomly assigned to one of four treatments: 2 micrograms GnRH infused (i.v.) continuously during 1 h, 2 micrograms GnRH infused during 5 min once every hour, 2 micrograms GnRH infused during 5 min once every fourth hour, or saline (control) for 13 days. Infusion of GnRH every hour increased LH concentrations in serum (P < 0.05), but FSH concentrations were not affected by GnRH infusion. Luteal activity (LA) was assessed by the presence of corpora lutea and/or serum progesterone greater than 1 ng/ml. Six of eight cows infused with GnRH every hour had LA by day 13, whereas only 25% of cows infused either continuously or with a pulse every fourth hour had LA by day 13. None of the control cows had LA during the experiment (P < 0.01). Concentrations of LH and FSH in the pituitary were significantly reduced when GnRH was infused hourly or continuously. Concentrations of common alpha and FSH beta mRNA were not influenced by treatment. However, continuous infusion of GnRH decreased (P < 0.05) LH beta mRNA subunit. Concentrations of GnRH-R (P < 0.1) and GnRH-R mRNA (P < 0.05) were reduced when GnRH was infused continuously. We concluded that pulsatile secretion of LH is necessary for follicular growth and LA in beef cattle, and GnRH treatment differentially regulates LH and FSH gene transcription and serum concentrations of LH and FSH in cattle.

The gene encoding the ovine gonadotropin-releasing hormone (GnRH) receptor: cloning and initial characterization

We have isolated four lambda clones, which, in their aggregate, contain the entire coding sequence of the ovine gene encoding the gonadotropin-releasing hormone (GnRH) receptor (GnRHR). Like its human and murine counterparts, ovine GnRHR exists as a single-copy gene and is comprised of three exons and two introns. Furthermore, the locations of all exon-intron boundaries are perfectly conserved among the human, ovine and murine genes. The most striking difference among these genes is the location of the transcription start points (tsp) and, thus, the length of 5' untranslated region (UTR). This variation in size of the 5' UTR between the murine, human and ovine genes raises the possibility that different mechanisms have evolved for cell-specific expression of this gene. Isolation of the ovine GnRHR and its associated 5' flanking region is the essential first step in defining the molecular mechanisms underlying cell-specific and hormonal regulation of its expression in ruminants.

Hormonal regulation of messenger ribonucleic acid encoding steroidogenic acute regulatory protein in ovine corpora lutea

Steroidogenic acute regulatory protein (StAR), proposed to be involved in the transport of cholesterol to the inner mitochondrial membrane, has recently been cloned from MA-10 cells. Using reverse transcription-polymerase chain reaction, we generated a complementary DNA encoding 404 base pairs of StAR from ovine luteal tissue to perform studies regarding regulation of the messenger RNA (mRNA) encoding this protein. In Exp 1, ewes were hypophysectomized (HPX) on day 5 of the estrous cycle and administered saline or physiological regimens of LH and/or GH until collection of luteal tissue on day 12 of the estrous cycle (n = 4/group). Luteal concentrations [mean +/- SEM; femtomoles per microgram poly(A)+ RNA] of mRNA encoding StAR were lower (P < 0.05) in the HPX plus saline-treated ewes (26.4 +/- 7.3) than in day 12 pituitary-intact ewes (n = 4; 77.7 +/- 9.3). Replacement of LH (59.1 +/- 13.1), GH (59.1 +/- 12.8), or LH and GH (69.9 +/- 4.5) in HPX ewes increased (P < 0.05) concentrations of mRNA encoding StAR to values not different from those in day 12 controls. In Exp 2, ewes on day 11 or 12 of the estrous cycle were injected with prostaglandin F2 alpha (PGF2 alpha) to induce luteal regression. Corpora lutea were collected 4, 12, or 24 h after injection (n = 4-5/time point) and from untreated control ewes (n = 4) or 24 h after injection of saline (n = 4). Treatment with PGF2 alpha decreased (P < 0.05) concentrations of progesterone in serum 4, 12, and 24 h after injection. Concentrations of StAR mRNA were decreased (P < 0.01) to 47%, 19%, and 8% of control values 4, 12, and 24 h after PGF2 alpha injection, respectively. In Exp 3, ewes received ovarian arterial infusions of saline, PGF2 alpha, or phorbol 12-myristate 13-acetate (PMA), and luteal tissue was collected 0 (no infusion), 4, 12, or 24 h later (n = 3-4/group). Treatment with PGF2 alpha or PMA decreased (P < 0.05) concentrations of progesterone in serum 4, 12, and 24 h postinjection. Steady state concentrations of mRNA encoding StAR (P < 0.05) were 36% and 25% of the control value 12 and 24 h after PGF2 alpha injection. Injection of PMA decreased (P < 0.05) concentrations of StAR mRNA to 75% and 50% of control values at 4 and 12 h, but concentrations of mRNA encoding StAR were not different from control values at 24 h.(ABSTRACT TRUNCATED AT 400 WORDS)

Effects of estradiol on concentrations of gonadotropin-releasing hormone receptor messenger ribonucleic acid following removal of progesterone

To test the hypothesis that low levels of estradiol are sufficient to increase concentrations of GnRH receptor mRNA in the absence of progesterone, ewes were ovariectomized and immediately treated with estradiol implants for 12 h to achieve circulating concentrations of estradiol typical of the early (n=5) or late (n=4) follicular phase. Five additional ewes underwent lutectomy, and control ewes were untreated. Treatment of ewes with 1/2 or 1 estradiol implant increased concentrations of estradiol in serum to 3.0 ± 0.8 pg/ml or 6.3 ± 0.3 pg/ml, respectively, and concentrations of estradiol in lutectomized ewes (2.4 ± 0.5 pg/ml) were intermediate. Ovariectomy did not alter concentrations of GnRH receptor mRNA or numbers of GnRH receptors. Treatment of ewes with 1 estradiol implant increased concentrations of GnRH receptor mRNA and numbers of GnRH receptors. In ewes treated with 1/2 estradiol implant, concentrations of GnRH receptor mRNA were intermediate between controls and ewes treated with 1 estradiol implant, and numbers of GnRH receptors were greater than controls. Lutectomy increased concentrations of GnRH receptor mRNA but did not affect numbers of GnRH receptors. We conclude that estradiol stimulates expression of the GnRH receptor gene and numbers of GnRH receptors in the absence of progesterone. However, effects of estradiol on expression of the GnRH receptor gene were clearly evident only when concentrations of estradiol were elevated to levels typical of the late follicular phase.

Pulsatile gonadotropin-releasing hormone (GnRH) increases concentrations of GnRH receptor messenger ribonucleic acid and numbers of GnRH receptors during luteolysis in the ewe

As circulating concentrations of progesterone decrease during the early preovulatory period, concentrations of mRNA encoding ovine GnRH receptor in the anterior pituitary gland increase. The purpose of this study was to determine whether removal of progesterone affects amounts of GnRH receptor mRNA directly or whether withdrawal of progesterone affects GnRH receptor gene expression indirectly by permitting secretion of GnRH to increase. Ovulation was induced in seasonally anestrous ewes, and luteolysis was initiated with prostaglandin F2 alpha (PGF2 alpha) 11 or 12 days later. Anterior pituitary glands were collected 0 h, 4 h, 12 h, or 24 h after treatment with PGF2 alpha, and 24 h after injection of saline (n = 3 or 4 animals/group). Two groups of ewes (n = 3) received infusions of GnRH (250 ng infused over 6 min) hourly for 12 h; luteolysis was induced in one of these groups at the time that treatment with GnRH was initiated, and anterior pituitary glands were collected at the end of the 12-h infusion period. Blood samples were collected at 15-min intervals for 12 h from all ewes treated with GnRH and from animals administered PGF2 alpha and killed 12 h later. No differences in concentrations of GnRH receptor mRNA, numbers of GnRH receptors, or circulating concentrations of progesterone or estradiol were detected between groups of animals at 0 h and 24 h after treatment with saline; therefore, data from these control groups were combined. Concentrations of progesterone in serum decreased in PGF2 alpha-treated ewes and were lower (p < 0.05) than those in controls 24 h after treatment with PGF2 alpha.(ABSTRACT TRUNCATED AT 250 WORDS)

Messenger ribonucleic acid for gonadotropin-releasing hormone receptor and numbers of gonadotropin-releasing hormone receptors in ovariectomized ewes after hypothalamic-pituitary disconnection and treatment with estradiol

To study the regulation of ovine GnRH receptors in the absence of GnRH, hypothalamic input was removed by hypothalamic-pituitary disconnection (HPD). Steady-state concentrations of GnRH receptor mRNA and numbers of GnRH receptors were measured after HPD and subsequent treatment with estradiol. Anterior pituitary glands were collected 24 (n = four), 36 (n = two), 48 (n = four), and 72 h (n = four) after HPD. An additional group of ewes received subcutaneous implants of estradiol 24 h after HPD, and pituitary glands were collected 0 (n = four), 12 (n = four), 24 (n = three), and 48 h (n = four) after exposure to estradiol. Pituitary glands were also obtained from four ovariectomized ewes that did not undergo HPD (OVX controls). At 24 h after HPD, mean number of GnRH receptors had decreased (P < .05) by 73%; however, mean concentration of GnRH receptor mRNA was not different from OVX controls. Relative to HPD ewes, treatment with estradiol increased mean concentrations of GnRH receptor mRNA and mean numbers of GnRH receptors (P < .01 and P < .001, respectively). From these data we conclude that 1) acute removal of GnRH decreases the numbers of GnRH receptors but does not affect steady-state concentrations of GnRH receptor mRNA and 2) estradiol increases the numbers of GnRH receptors and steady-state concentrations of GnRH receptor mRNA via direct effects at the level of the pituitary gland.

Regulation of gonadotropin-releasing hormone (GnRH) receptor messenger ribonucleic acid and GnRH receptors during the early preovulatory period in the ewe

Estradiol increases the number of GnRH receptors in the ewe. Although results from studies conducted in vitro indicate that progesterone may have a negative influence on the number of ovine GnRH receptors, this effect of progesterone has not been documented in vivo. To explore the regulation of GnRH receptors at the level of gene expression, a partial complementary DNA (cDNA) encoding ovine GnRH receptor was isolated using reverse transcription and polymerase chain reaction methodology. This partial cDNA (701 basepairs) was used to isolate a full-length cDNA encoding GnRH receptor from an ovine pituitary cDNA library. Northern blot analysis of RNA from ovine pituitary glands using the partial cDNA as a molecular probe revealed four messenger RNA (mRNA) transcripts at 5.6, 3.8, 2.1, and 1.3 kilobases. In some samples, a fifth transcript at 0.8 kilobases was also evident. GnRH receptor mRNA was not detected in ovine brain, heart, kidney, adrenal, or liver tissues. To examine the regulation of GnRH receptor mRNA and GnRH receptors during the early preovulatory period, relationships among steady state concentrations of GnRH receptor mRNA, numbers of GnRH receptors, and circulating concentrations of progesterone and estradiol during luteolysis were characterized. We hypothesized that during luteolysis, decreased concentrations of progesterone would be associated with increased concentrations of GnRH receptor mRNA and increased numbers of GnRH receptors. On day 11 or 12 of the estrous cycle, luteolysis was induced in 14 ewes by treatment with prostaglandin F2 alpha (PGF2 alpha). Four ewes were treated with saline (saline controls). Anterior pituitary tissue was collected 4 h (n = 4), 12 h (n = 5), and 24 h (n = 5) after treatment with PGF2 alpha or 24 h after treatment with saline and from four untreated ewes on day 11 or 12 of the estrous cycle (untreated controls). Twelve hours after treatment with PGF2 alpha, circulating concentrations of progesterone had decreased (P < 0.05) to 46% of the control values; however, concentrations of estradiol were not different from those in control ewes. Concentrations of GnRH receptor mRNA increased 2-fold during luteolysis and were higher than control values 12 h after PGF2 alpha treatment (P < 0.05). This increase in GnRH receptor mRNA was not accompanied by an increase in the number of GnRH receptors. Twenty-four hours after treatment with PGF2 alpha, concentrations of progesterone in PGF2 alpha-treated ewes had decreased (P < 0.05) to 15% of control values, whereas concentrations of estradiol had increased (P < 0.05) to 321% of control values.(ABSTRACT TRUNCATED AT 400 WORDS)

Effects of suppressing plasma FSH on ovarian follicular dominance in cattle

The importance of FSH during development of the dominant follicle of the first wave of follicular growth in cattle was assessed by injecting heifers twice daily with 20 ml saline (n = 6) or 20 ml charcoal-extracted bovine follicular fluid (bFF; n = 10), containing inhibin, on days 6 and 7 of the oestrous cycle. All animals received a luteolytic dose of PGF2 alpha on day 8. The interval to oestrus after PGF2 alpha in controls was 2.6 +/- 0.2 days. Five of ten bFF-treated heifers exhibited oestrus at the same time as controls (2.7 +/- 0.1 days), whereas time to oestrus in the remaining five bFF-treated heifers was significantly longer (6.8 +/- 0.6 days; P < 0.05). Treatment with bFF suppressed plasma FSH during the 48 h injection period (P < 0.05). Concentrations of FSH were not different in bFF-treated animals that did not display delayed oestrus compared with those in animals that exhibited delayed oestrus. In controls, the dominant follicle of the first wave continued growing during treatment and ovulated after injection of PGF2 alpha. In all ten bFF-treated animals, growth of the dominant follicle of the first wave was arrested during the treatment period. In bFF-treated animals that did not exhibit delayed oestrus, the dominant follicle resumed growth after luteolysis and ovulated. In bFF-treated animals that displayed delayed oestrus, the dominant follicle regressed after luteolysis and the ovulatory follicle was selected from a newly recruited (second) wave of follicular growth.(ABSTRACT TRUNCATED AT 250 WORDS)

Suppression of the secondary FSH surge with bovine follicular fluid is associated with delayed ovarian follicular development in heifers

Holstein heifers were given 5 injections (twice/day) of 10 ml charcoal-extracted bovine follicular fluid (bFF; N = 6) or 10 ml saline (N = 5) beginning 12 h after the onset of oestrus. Blood samples were collected for determination of plasma concentrations of FSH, LH, progesterone and oestradiol-17 beta. Treatment with bFF suppressed the secondary FSH surge (P less than 0.01). Cessation of bFF injections was followed by a rebound period during which FSH was elevated compared with controls (P less than 0.01). Daily ultrasonographic examinations revealed that follicular growth occurred in waves, with 4 of 5 control heifers exhibiting 3 waves and the other 2 waves. In contrast, 5 of 6 bFF-treated animals exhibited 2 waves and the other 3 waves. Appearance of follicles in the first wave was delayed in bFF-treated heifers (Day 3.3 +/- 0.3 compared with Day 1.4 +/- 0.2; P less than 0.0001) and appearance of the dominant follicle of the first wave was delayed (Day 4.5 +/- 0.3 compared with Day 1.8 +/- 0.2; P less than 0.0001). Follicles in the second wave appeared later in animals treated with bFF (Day 12.7 +/- 0.4 compared with Day 10.4 +/- 0.6; P less than 0.01), and the dominant follicle of this wave also appeared later (Day 13.0 +/- 0.5 compared with Day 10.6 +/- 0.5; P less than 0.01). Oestradiol-17 beta increased during the early luteal phase, but this increase occurred later in heifers treated with bFF (peak concentrations on Day 6.3 +/- 0.6 compared with Day 4.2 +/- 0.2; P less than 0.05). LH, progesterone and cycle length were not affected by bFF. Delayed follicular growth associated with suppression of FSH suggests that the secondary FSH surge is important in the initiation of follicular development early in the bovine oestrous cycle, and thus may play a role in the regulation of ovarian follicular dynamics.