Application of dual pre-embedding stains for gonadotropins to pituitary cell monolayers with avidin-biotin (ABC) and peroxidase-antiperoxidase (PAP) complexes: light microscopic studies

Double stains for gonadotropins and gonadotropin-releasing hormone were developed for fixed whole pituitary cells from cycling female rats. Monolayer cells were stimulated with [D-Lys6]GnRH, fixed in 2.5% glutaraldehyde, and then stained for luteinizing hormone (LH) (1:50,000-12 h) or follicle stimulating hormone (FSH) (1:60,000-12 h) and the avidin-biotin-peroxidase complex technique (ABC) with a jet-black substrate (nickel intensified diaminobenzidine-DAB). This was followed by a stain for the other gonadotropin with either ABC or peroxidase-antiperoxidase complex (PAP) techniques and amber (DAB) or red (3-amino-9-ethyl-carbazole) substrates. Additional monolayers were stimulated with biotinylated [D-Lys6]GnRH and stained with the ABC technique and the black (nickel-DAB) substrate. These monolayers were then stained immunocytochemically for LH or FSH with either ABC or PAP methods and orange or red substrates. The controls showed that the omission of the second primary antiserum abolished the stain indicating that the second staining solutions did not react with components in the first group. The addition of the second peroxidase substrate in sequence after the first stain indicated that no residual peroxidase activity remained from the first stain. Our tests also showed that saponin was not needed to aid reagent or antibody penetration. The dual stains demonstrated that 50-60% of the gonadotropes stored LH and FSH together, often in separate regions of the same cell. Some cells contained only one hormone (20-22%). The dual stains for GnRH and gonadotropins demonstrated that 80-90% of the GnRH bound cells are gonadotropes. These techniques allow a study of storage sites for multiple hormones in or on whole cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Application of Dual Pre-Embedding Stains for Gonadotropins to Pituitary Cell Monolayers with Avidin-Biotin (ABC) and Peroxidase-Antiperoxidase (PAP) Complexes: Light Microscopic Studies

Double stains for gonadotropins and gonadotropin-releasing hormone were developed for fixed whole pituitary cells from cycling female rats. Monolayer cells were stimulated with [d-Lys⁶]GnRH, fixed in 2.5% glutaraldehyde, and then stained for luteinizing hormone (LH) (1:50,000-12 h) or follicle stimulating hormone (FSH) (1:60,000-12 h) and the avidin-biotin-peroxidase complex technique (ABC) with a jet-black substrate (nickel intensified diaminobenzidine—DAB). This was followed by a stain for the other gonadotropin with either ABC or peroxidase-antiperoxidase complex (PAP) techniques and amber (DAB) or red (3-amino-9-ethyl-carbazole) substrates. Additional monolayers were stimulated with biotinylated [d-Lys⁶]GnRH and stained with the ABC technique and the black (nickel-DAB) substrate. These monolayers were then stained immunocytochemically for LH or FSH with either ABC or PAP methods and orange or red substrates. The controls showed that the omission of the second primary antiserum abolished the stain indicating that the second staining solutions did not react with components in the first group. The addition of the second peroxidase substrate in sequence after the first stain indicated that no residual peroxidase activity remained from the first stain. Our tests also showed that saponin was not needed to aid reagent or antibody penetration. The dual stains demonstrated that 30-60% of the gonadotropes stored LH and FSH together, often in separate regions of the same cell. Some cells contained only one hormone (20-22%). The dual stains for GnRH and gonadotropins demonstrated that 80-90% of the GnRH bound cells are gonadotropes. These techniques allow a study of storage sites for multiple hormones in or on whole cells. The studies agree with and augment the results from the use of serial sections.     

Detection of luteinizing hormone beta messenger ribonucleic acid (RNA) in individual gonadotropes after castration: use of a new in situ hybridization method with a photobiotinylated complementary RNA probe

Patterns of gonadotropin storage in individual gonadotropes change with alterations in the physiological state. After castration in the male rat, there is a 2.5-fold increase in the percentage of gonadotropes and an increase in the proportion of gonadotropes storing both LH and FSH. In addition, there are 6- to 8-fold increases in the pituitary concentrations of LH beta subunit mRNAs. In order to determine whether these changes are due to increases in the number of gonadotropes containing subunit mRNA, or the amount of mRNA per cell or both, an in situ hybridization technique using a photobiotinylated rat LH beta cRNA probe (bio-LH beta-cRNA) was applied to detect LH beta mRNA in fixed whole rat pituitary cells from intact or castrated rats. After hybridization, the bio-LH beta-cRNA was localized with either avidin-biotin peroxidase complex or the fluorescent streptavidin phycoprobe methods. The cells containing LH beta mRNA were then counted and the amount of mRNA per cell was measured by video microdensitometry. Ten percent of the anterior pituitary cells from intact animals contained LH beta mRNA. After castration (2-4 weeks) this percentage rose to 19-24.5%. Image and microdensitometric analyses showed that castration produced a 1.9-fold increase in the amount of LH beta mRNA per cell, and a 2.2-fold increase in the area of cells containing LH beta mRNA. Hence, castration resulted in an increase in the level of LH beta mRNA per cell as well as the number of LH beta mRNA-containing cells. When in situ hybridization was followed by immunocytochemistry in cells from intact rats, 83% of gonadotropes that stained for LH beta and 80% of gonadotropes that stained for FSH beta contained LH beta mRNA whereas after castration 99% of LH-storing and 93% of FSH-storing cells contained LH beta mRNA. This new in situ hybridization protocol is rapid and allows quantification of mRNA within individual gonadotropes. In addition, since the hybridization protocol does not apparently alter the gonadotropin antigens, the hormone content of the same gonadotrope may be defined by immunocytochemistry.     

Cytochemical characterization of pituitary target cells for biotinylated gonadotropin releasing hormone

These studies describe the application of new cytochemical stains that co-localize a biotin-labeled gonadotropin releasing hormone (GnRH) analog and FSH or LH in the same field or cell. Pituitary monolayer cells were stimulated with the [D-Lys6] GnRH analog or the same analog labeled with biotin. Biotinylated [D-Lys6] GnRH exhibited a higher affinity and was 7-10 X more potent than unlabeled [D-Lys6] GnRH. The avidin-biotin peroxidase complex technique (ABC) was applied to localize the biotinylated GnRH on the cells with the use of a dense black peroxidase substrate. Specificity tests showed that the stain could be eliminated by competition with unlabeled [D-Lys6] GnRH. The GnRH stain was followed by immunocytochemical stains for LH beta, FSH beta or 25-39ACTH with a different peroxidase substrate (amber or orange-red). Stain for GnRH was found on the surfaces of 16% of the cells and 60-90% of the GnRH stained cells also stained for one of the gonadotropins. Most (90-100%) of the gonadotropes showed stain for GnRH. Our studies demonstrate that a potent biotinylated GnRH analog binds cells that can be identified specifically as gonadotropes.     

Purification of gonadotropes and intracellular free calcium oscillation. Effects of gonadotropin-releasing hormone and interleukin 6

The intracellular free calcium concentration ([Ca2+]i) in single gonadotropes was measured with a calcium-sensitive fluorescent dye indo-1 or fura-2 and a digital imaging fluorescence microscopic system to determine how interleukin-6 (IL-6) increases release of gonadotropins. IL-6 induced an increase in the basal [Ca2+]i or the amplitude of spontaneous oscillation of [Ca2+]i in gonadotropes in a mixed population. Gonadotropin-releasing hormone (Gn-RH) induced a biphasic increase in [Ca2+]i, a transient increase, and then a prolonged increase. These effects were inhibited by the absence of extracellular calcium or pretreatment with calcium channel blockers, cobalt or nifedipine. Next, purified gonadotropes were prepared by fluorescence-activated cell sorting and argon laser treatment of the cells. Gonadotropes labeled with anti-luteinizing hormone antibody were sorted by fluorescence-activated cell sorting and then cultured as monolayers for 24-48 h. In this way, gonadotropes were concentrated from 5-10% to 70-85% from whole pituitary cells. After relabeling with anti-luteinizing hormone antibody, 100% purified gonadotropes were obtained by killing other types of cells with an argon laser. Gonadotropin-releasing hormone induced almost the same responses of [Ca2+]i in the purified cell population as in the mixed cell population, but IL-6 did not affect [Ca2+]i in the purified gonadotropes. These results suggest that IL-6 affects calcium mobilization in gonadotropes indirectly via paracrine pathways.     

Changes in thyrotroph and somatotroph cell populations induced by stimulation and inhibition of their secretory activity

Summary The populations of cells which produce immunoreactive growth hormone (GH) and thyroid stimulating hormone (TSH) in the rat pituitary gland do not occur in fixed percentages but vary greatly under different physiological and experimental conditions. These variations can be directly correlated to the levels of stimulation and/or inhibition of the specific secretory activity. In both types of cell, sustained stimulation with trophic hormones or blockage of the feedback mechanisms induces remarkable growth in the specific cell population. Conversely, the interruption or inhibition of the stimulus thwarted the hormonal secretion and caused a massive degeneration of redundant cells. The stimulation of both GH and TSH cells is accompanied by an enhanced secretory activity as judged by their higher concentrations in serum and hypertrophy of the cytoplasmic organelles involved in synthesis and intracellular processing of the hormones. By contrast, interruption of the stimulus is followed by a variable degree of disruption of the cytoplasmic organization, including a sizable degeneration of cells. In stimulated rats, the concentrations of both GH and TSH decreased significantly in pituitary tissue due to mobilization of the hormonal stores contained in secretory granules. On the other hand, the withdrawal of stimuli blocked the hormonal release; this is reflected by the accumulation of both hormones and secretory granules in pituitary tissue. The strict correlation between the size of the GH and TSH populations with stimulation and inhibition of hormonal secretory activity reported in this investigation further supports the critical role played by the cell renewal process in endocrine secretion.     

Steroidogenic factor 1 (SF1) is essential for pituitary gonadotrope function

Knockout mice lacking the orphan nuclear receptor steroidogenic factor 1 (SF1) exhibit a complex endocrine phenotype that includes adrenal and gonadal agenesis, impaired expression of pituitary gonadotropins, and absence of the ventromedial hypothalamic nucleus (VMH). These multiple defects complicate efforts to delineate primary versus secondary effects of SF1 deficiency in different tissues, such that its direct role in gonadotropes remains uncertain. To define this role, we have expressed Cre recombinase driven by the promoter region of the common alpha subunit of glycoprotein hormones (alpha GSU), thereby inactivating a loxP-modified SF1 locus in the anterior pituitary gland. Although pituitary-specific SF1 knockout mice were fully viable, they were sterile and failed to develop normal secondary sexual characteristics. Their adrenal glands and VMH appeared normal histologically, but their testes and ovaries were severely hypoplastic. alpha GSU-Cre, loxP mice had normal levels of most pituitary hormones, but had markedly decreased expression of LH and FSH. Treatment with exogenous gonadotropins stimulated gonadal steroidogenesis, inducing germ cell maturation in males and follicular and uterine maturation in females--establishing that the gonads can respond to gonadotropins. The pituitary-specific SF1 knockout mice are a novel genetic model of hypogonadotropic hypogonadism that establishes essential role(s) of SF1 in pituitary gonadotropes.     

Tissue specific compartmental analysis of gonadotropin stimulation of ovarian ornithine decarboxylase

Luteinizing hormone is known to stimulate the enzyme ornithine decarboxylase in the ovary. Highly purified human follicle stimulating hormone that is devoid of significant biologically active luteinizing hormone can also induce ornithine decarboxylase activity in intact immature rats with a time course of induction similar to that reported for luteinizing hormone. A maximum of 8–10-fold stimulation above controls was observed 4 h following intravenous administration of human follicle stimulating hormone. This stimulation followed a strict dose response relationship. Ovine luteinizing hormone and human chorionic gonadotropin always induced more ovarian ornithine decarboxylase activity than that achieved by maximally effective doses of follicle stimulating hormone. This could not be attributed solely to the ability of specific cell population to respond to the respective gonadotropins. Although granulosa cells contained little receptor for luteinizing hormone/human chorionic gonadotropin and the residual tissue contained little receptor for follicle stimulating hormone, each tissue responded to these gonadotropins in a manner suggestive of the mediation by one or more diffusable factors. A relationship between gonadotropin induced 3’5’-cyclic adenosine monophosphate (cyclic adenosine monophosphate) concentration and ornithine decarboxylase activity suggests that the mediation of gonadotropin stimulated ovarian ornithine decarboxylase is not solely through cyclic adenosine monophosphate, indicating the presence of other factors in the induction of gonadotropin increased ornithine decarboxylase activity.     

Parenchymal cells purified from Xenopus liver and maintained in primary culture synthesize vitellogenin in response to estradiol-17 beta and serum albumin in response to dexamethasone.

Xenopus liver was disaggregated by perfusion with collagenase. The released cells were separated according to their equilibrium densities on gradients of Metrizamide. Highly purified populations of parenchymal cells, sinusoidal cells, and melanocytes were obtained. All the parenchymal cells in an animal, before, during, and after hormone stimulation, are contained within a single density peak and subpopulations are not observed. Normal female parenchymal cells are less dense than normal male cells and estrogen stimulation causes a decrease in the peak density of the parenchymal cell population. Electron microscopic examination revealed the appearance and disappearance of lipid vacuoles in parenchymal cells following estrogen treatment. We hypothesize that the changing lipid content of these cells accounts for the shift in cell density. Immunofluorescent staining revealed that all liver parenchymal cells contain either vitellogenin or serum albumin, depending upon the prior treatment with hormones in vivo. Primary cultures of purified parenchymal and sinusoidal cells were established and were found to secrete different sets of proteins. The addition of estradiol-17β to cultures of parenchymal cells from either male or female frogs induces the synthesis and secretion of vitellogenin and two other polypeptides. Furthermore, the synthesis and secretion of polypeptides normally produced by parenchymal cells are curtailed as a result of estrogen treatment. Addition of glucocorticoids to a similar population of cells produces an increase in the synthesis and secretion of polypeptides, one of which is serum albumin. These results demonstrate that every parenchymal cell is responsive to two different classes of steroid hormones, estrogens and glucocorticoids, and in response to these hormones the same cells can synthesize and secrete alternate sets of polypeptides.     

Development of gonadotropes may involve cyclic transdifferentiation of growth hormone cells

The cyclic rise in expression of anterior pituitary gonadotropins coincides with the appearance of cells sharing gonadotropic and somatotropic phenotypes. To learn more about possible factors that regulate the origin of this cell type, we studied the time of appearance of cells that co-expressed growth hormone (GH) and gonadotropins and estrogen receptors during the estrous cycle and compared this timing with known changes in regulatory hormones or their receptors. The first event in this cell population is an increase in expression of estrogen receptor (ER)beta by GH cells from estrus to metestrus suggesting that estrogen may mediate this early change. Expression of GH mRNA rises rapidly from metestrus to mid-cycle. The rise is seen first in GH cells and then in cells with luteinizing hormone (LH) antigens. These data suggest that, early in the cycle, cells bearing GH and growth hormone releasing hormone (GHRH) receptors begin to produce LH and gonadotropin releasing hormone (GnRH) receptors. Early in proestrus, there is an increase in cells with GH and follicle-stimulating hormone (FSH) suggesting that this set of multipotential cells develops later than GH-LH cells. This fits with earlier studies showing the later rise in expression of FSH mRNA. Collectively these data suggest that the anterior pituitary contains a subset of GH cells that have the capacity to respond to multiple releasing hormones and support more than one system.     

Vitellogenin Incorporation into Oocytes of Rainbow Trout, Oncorhynchus mykiss, in Vitro: Effect of Hormones on Denuded Oocytes

An in vitro culture procedure to measure vitellogenin (VTG) incorporation into oocytes without follicle cell layers was developed using oocytes of the rainbow trout, Oncorhynchus mykiss . Oocytes incorporated VTG specifically and linearly for up to 24 hr. The maximum incorporation observed was 314 μg/24 hr/oocyte, using vitellogenic (3.6 mm diameter) oocytes.
The effect of hormones was examined by adding insulin, growth hormone, prolactin, gonadotropins (GTH-I, GTH-II), thyroid hormones, testosterone, estradiol-17β, or 17α, 20β-dihydroxy-4-pregnen-3-one to the medium. The results indicated that insulin and thyroxine stimulated uptake of VTG by 13% and 12%, respectively. Insulin specifically stimulated VTG incorporation and did not cause any change in background uptake of insulin. The lack of an effect of gonadotropins hormones on denuded oocytes suggests that the previously observed stimulation of VTG incorporation into follicle cell-enclosed oocytes in vivo and in vitro by GTH-I is most likely mediated by the somatic cells of the ovarian follicle.     

Surface structure changes of rat adipocytes during lypolysis stimulated by various lypolysis stimulated by various lypolytic agents

A qualitative and quantitative electron microscopic study was performed on rat adipocytes during stimulation of lipolysis by various agents. Scanning electron microscopy of control cells revealed a spherical cell with a textured glycocalyx surface exhibiting small irregular projections. Globular surface evaginations or protrusions measuring 8-18 μM in diameter were seen on cell hemispheres, and there was an average of one protrusion for every two hemispheres examined. Distribution analysis showed that 60 percent of the hemispheres had no protrusions, and 25, 10, and 5 percent of the hemispheres had one, two or three protrusions, respectively. Thin-section and freeze- fracture electron microscopy of the protrusions showed a small triglyceride droplet surrounded by a thin cytoplasmic rim that was continuous with the main cytoplasmic matrix. The glycocalyx coating and plasma membrane extended from the cell surface onto, and over, the protrusion. Scanning microscopy of cells stimulated by lipolytic agents, including epinephrine, adrenocorticotropic hormone, theophylline, and dibutyryl cyclic AMP, revealed a dose-dependent increase in the number of protrusions per cell hemisphere. Maximal concentrations of lipolytic hormones cuase an average 2.5-fold increase in the number of protrusions per hemisphere without changing the average size of the protrusions. Only 40 percent of the stimulated cell hemispheres exhibited no protrusions; over 15 percent of the cells contained three or more; and a number of the protrusions were multilobulate. Insulin prevented the increase in the number of protrusions and the change in distribution caused by the lipolytic hormones but did not prevent the increase caused by theophylline and dibutryl cyclic AMP. The data suggest that the protrusions are a structural feature of the cell and may be related to the lypolytic pathway. These observations may help explain some of the discrepant biochemical data relating to hormonal stimulation of lipolysis.     

Estrogen uptake capacity of individual pituitary cell types from male and female rats one, fourteen and fifty days after castration

A quantitative autoradiographic technique was combined with immunocytochemical staining to compare 3H-estrogen uptake in individual pituitary cell types 1, 14 or 50 days after castration in both male and female rats. Silver grains were counted over nuclei of immunocytochemically stained cells and means were computed for each cell type. The order of labelling intensity for all groups was gonadotropes greater than or equal to lactotropes = somatotropes greater than thyrotropes = corticotropes. In male rats 3H-estrogen uptake capacity in all of these cell types remained unchanged over the post-castration interval. Only gonadotropes from female rats demonstrated a significant change in estrogen uptake capacity over the intervals examined. Uptake in these cells increased by 137% between 1 and 50 days after ovariectomy. At both 14 and 50 days post-ovariectomy, gonadotropes concentrated significantly more radioactive label than either lactotropes or somatotropes. One day after castration, gonadotropes from females concentrated less 3H-estrogen than males while at 50 days after castration they concentrated significantly more than gonadotropes from male rats.     

Parenchymal cells purified from Xenopus liver and maintained in primary culture synthesize vitellogenin in response to estradiol-17β and serum albumin in response to dexamethasone

Xenopus liver was disaggregated by perfusion with collagenase. The released cells were separated according to their equilibrium densities on gradients of Metrizamide. Highly purified populations of parenchymal cells, sinusoidal cells, and melanocytes were obtained. All the parenchymal cells in an animal, before, during, and after hormone stimulation, are contained within a single density peak and subpopulations are not observed. Normal female parenchymal cells are less dense than normal male cells and estrogen stimulation causes a decrease in the peak density of the parenchymal cell population. Electron microscopic examination revealed the appearance and disappearance of lipid vacuoles in parenchymal cells following estrogen treatment. We hypothesize that the changing lipid content of these cells accounts for the shift in cell density. Immunofluorescent staining revealed that all liver parenchymal cells contain either vitellogenin or serum albumin, depending upon the prior treatment with hormones in vivo. Primary cultures of purified parenchymal and sinusoidal cells were established and were found to secrete different sets of proteins. The addition of estradiol-17β to cultures of parenchymal cells from either male or female frogs induces the synthesis and secretion of vitellogenin and two other polypeptides. Furthermore, the synthesis and secretion of polypeptides normally produced by parenchymal cells are curtailed as a result of estrogen treatment. Addition of glucocorticoids to a similar population of cells produces an increase in the synthesis and secretion of polypeptides, one of which is serum albumin. These results demonstrate that every parenchymal cell is responsive to two different classes of steroid hormones, estrogens and glucocorticoids, and in response to these hormones the same cells can synthesize and secrete alternate sets of polypeptides.     

Persistence of immunoreactive TRH and GnRH in long-term primary anterior pituitary cultures

Intact anterior pituitary tissue and primary anterior pituitary cultures were stained with 1:30,000 anti-TRH and 1:10,000 anti-GnRH using the peroxidase antiperoxidase immunocytochemical technique. Stains applied to serial ultrathin sections of intact pituitaries showed that TRH immunoreactivity could be localized in secretory granules of thyrotropes, gonadotropes and corticotropes whereas GnRH immunoreactivity was found only in gonadotropes and corticotropes. Long-term primary pituitary cultures were studied to remove the anterior pituitary cells from hypothalamic influences. In these cell populations both TRH and GnRH immunoreactivity persisted. In addition, quantification of the stained cells at the light microscopic level demonstrated that the volume fraction of TRH and GnRH immunoreactive cells remained constant up to 3 weeks of culture. Studies of serial ultrathin sections through cells from these cultures showed TRH or GnRH localized in secretory granules of cells that contained LH and ACTH, but not TSH. Both liquid and solid phase immunoabsorption specificity controls were used to validate the immunocytochemical stains. These studies suggest that the pituitary TRH and GnRH immunoreactivities may not be completely of hypothalamic origin, but may also be endogenous to a subpopulation of unique multihormonal pituitary cells.     

Immunohistochemical evidence for the presence of glucokinase in the gonadotropes and thyrotropes of the anterior pituitary gland of rat and monkey.

A recent report provides new evidence for the presence of glucokinase (GK) in the anterior pituitary. In the present study, immunohistochemistry was used to identify the cells containing GK in the pituitary of rats and monkeys. In rats, GK was detected as a generalized cytoplasmic staining in a discrete population of cells in the anterior pituitary. In colocalization experiments, the majority of cells expressing follicle-stimulating hormone (FSH) or luteinizing hormone (LH) also contained GK. In addition to the gonadotropes, GK was observed in a subpopulation of corticotropes and thyrotropes. GK was not detected in cells expressing growth hormone or prolactin. In monkeys, GK was also observed in a discrete population of cells. Intracellular distribution differed from the rat in that GK in most cells was concentrated in a perinuclear location that appeared to be associated with the Golgi apparatus. However, similar to rats, colocalization experiments showed that the majority of cells expressing FSH or LH also contained GK. In addition to the gonadotropes, GK was observed in a subpopulation of corticotropes and thyrotropes. In the monkey, only a few cells had generalized cytoplasmic staining for GK. These experiments provide further evidence for the presence of GK in the anterior pituitary. Although some corticotropes and thyrotropes contained GK, the predominant cell type expressing GK was gonadotropes. In view of the generally accepted role of GK as a glucose sensor in a variety of cells including the insulin-producing pancreatic beta-cells as the prototypical example, it is hypothesized that hormone synthesis and/or release in pituitary cells containing GK may be directly influenced by blood glucose.     

Activation of translation in pituitary gonadotrope cells by gonadotropin-releasing hormone

The neuropeptide GnRH is a central regulator of mammalian reproductive function produced by a dispersed population of hypothalamic neurosecretory neurons. The principal action of GnRH is to regulate release of the gonadotropins, LH and FSH, by the gonadotrope cells of the anterior pituitary. Using a cultured cell model of mouse pituitary gonadotrope cells, alphaT3-1 cells, we present evidence that GnRH stimulation of alphaT3-1 cells results in an increase in cap-dependent mRNA translation. GnRH receptor activation results in increased protein synthesis through a regulator of mRNA translation initiation, eukaryotic translation initiation factor 4E-binding protein, known as 4EBP or PHAS (protein, heat, and acid stable). Although the GnRH receptor is a member of the rhodopsin-like family of G protein-linked receptors, we show that activation of translation proceeds through a signaling pathway previously described for receptor tyrosine kinases. Stimulation of translation by GnRH is protein kinase C and Ras dependent and sensitive to rapamycin. Furthermore, GnRH may also regulate the cell cycle in alphaT3-1 cells. The activation of a signaling pathway that regulates both protein synthesis and cell cycle suggests that GnRH may have a significant role in the maintenance of the pituitary gonadotrope population in addition to directing the release of gonadotropins.     

Mouse ovarian granulosa cells produce urokinase-type plasminogen activator, whereas the corresponding rat cells produce tissue-type plasminogen activator

It is well established that rat ovarian granulosa cells produce tissue plasminogen activator (tPA). The synthesis and secretion of the enzyme are induced by gonadotropins, and correlate well with the time of follicular rupture in vivo. We have found that in contrast, mouse granulosa cells produce a different form of plasminogen activator, the urokinase-type (uPA). As with tPA synthesis in the rat, uPA production by mouse granulosa cells is induced by gonadotropins, dibutyryl cAMP, and prostaglandin E2. However, dexamethasone, a drug which has no effect on tPA synthesis in rat cells inhibits uPA synthesis in the mouse. Results of these determinations made in cell culture were corroborated by examining follicular fluid, which is secreted in vivo predominantly by granulosa cells, from stimulated rat and mouse ovarian follicles. Rat follicular fluid contained only tPA, and mouse follicular fluid only uPA, indicating that in vivo, granulosa cells from the two species are secreting different enzymes. The difference in the type of plasminogen activator produced by the rat and mouse granulosa cells was confirmed at the messenger RNA level. After hormone stimulation, only tPA mRNA was present in rat cells, whereas only uPA mRNA was found in mouse cells. Furthermore, the regulation of uPA levels in mouse cells occurs via transient modulation of steady-state levels of mRNA, a pattern similar to that seen with tPA in rat cells.     

Postcastration rise in plasma gonadotropins is blocked by a luteinizing hormone-releasing hormone antagonist

The dependence of the acute increases in plasma gonadotropins following castration on luteinizing hormone-releasing hormone (LHRH) was assessed with the use of a potent LHRH antagonist [ALHRH; (Nac-L-Ala1,p-Cl-D-Phe2,D-Trp3,6) LHRH]. Blood samples were collected from male and female rats at the time of castration and 2, 4, 8, 12, 24 and 48 h following and plasma gonadotropin levels were determined. Immediately following castration (diestrus I for females) animals received one of the following treatments: females-vehicle, 100 micrograms ALHRH, 50 micrograms estrogen benzoate (EB), or 100 micrograms ALHRH + 50 micrograms EB; males-vehicle, 100 micrograms ALHRH, 500 micrograms testosterone propionate (TP), or 100 micrograms ALHRH + 500 micrograms TP. ALHRH blocked the selective increase in plasma follicle-stimulating hormone (FSH) observed in female rats as well as the parallel increases in both gonadotropins seen in male rats following castration. Administration of EB or ALHRH + EB to females significantly suppressed both gonadotropins compared with control levels. However, EB alone did not completely block the rise in plasma FSH in females. In males, all three treatments significantly suppressed the increases in both gonadotropins when compared with control levels. These data demonstrate that hypothalamic LHRH plays an essential role in the acute elevations of plasma gonadotropins following castration in rats. In addition, these data suggest that the selective rise of FSH in females is dependent on LHRH stimulation of pituitary gonadotropes.