Ontention of antisera against a hypothalamic decapeptide (luteinizing hormone/follicle stimulating hormone releasing hormone) which stimulates the release of pituitary gonadotropins and development of its radioimmunoassay

Using the classical approach, a decapeptide was synthesized with the structure of porcine luteinizing hormone/follicle stimulating hormone releasing hormone reported by Matsuo, H., Baba, Y., Nair, R. M. G., Arimura, A. and Schally, A. V. (1971) Biochem. Biophys. Res. Commun. 43, 1393–1399. As already reported, this peptide was capable of inducing in vitro the release of luteinizing hormone and follicle stimulating hormone from rat pituitary glands. A specific antiserum against luteinizing hormone/follicle stimulating hormone releasing hormone has been generated in the guinea pig and this allowed the development of a radioimmunoassay for this peptide. The antisera, at a final dilution of to depending on the antiserum used, were able to bind 35% of the ¹³¹I-labelled antigen. The sensitivity of this assay method was 50 pg of luteinizing hormone/follicle stimulating hormone releasing hormone. The following substances did not cross-react: oxytocin, lysine-vasopressin, synthetic thyroid stimulating hormone releasing hormone, ovine luteinizing hormone, follicle stimulating hormone and prolactin. Des-Trp³ luteinizing hormone/follicle stimulating hormone releasing hormone, pyroglutamyl-histidyl-tryptophan and seryl-tyrosyl-glycyl-leucyl-arginyl-prolyl-glycinamide, exhibited flatter curves than luteinizing hormone/follicle stimulating hormone releasing hormone with a cross-reactivity of about . Using this method, luteinizing hormone/follicle stimulating hormone releasing hormone was assayed in extracts of the sheep stalk-median eminence and of the hypothalamus and in jugular vein blood from a normal ram and from normal male rats, from cyclic ewe and from hypophysectomized ram and rats. It was concluded that luteinizing hormone/follicle stimulating hormone releasing hormone is present in hypothalamic extracts and in plasma of sheep and rat.     

Desensitization of testicular ornithine decarboxylase to gonadotropin releasing hormone and gonadotropic hormones

Prior exposure of the testis to gonadotropin releasing hormone, luteinizing hormone or follicle stimulating hormone caused the testis refractory to these hormones in terms of ornithine decarboxylase activity at 24 h. Luteinizing hormone caused desensitization in the Leydig cells while the levels of ornithine decarboxylase in the seminiferous tubules were unaltered. In gonadotropin releasing hormone desensitized testis all the other treated compounds namely, luteinizing hormone, follicle stimulating hormone, prostaglandin F2 alpha, norepinephrine and cyclic AMP caused stimulation of ornithine decarboxylase activity. The testis desensitized with LH responded to cyclic AMP and norepinephrine whereas prostaglandin E2 or gonadotropin releasing hormone caused less stimulation of ornithine decarboxylase activity. These results indicate that testicular desensitization to gonadotropin releasing hormone and luteinizing hormone is not due to a post cyclic AMP block.     

Luteinising hormone,follicle stimulating hormone and gonadotropin releasing hormone immunoreactivity in two insects: Locusta migratoria migratoroides R&F and Sarcophaga bullata (Parker)

Summary

Materials immunologically related to luteinising hormone (LH), follicle stimulating hormone (FSH) and the gonadotropin releasing hormone (GnRH) were localised in cerebral tissue of Locusta migratoria and Sarcophaga bullata by means of the peroxidase-antiperoxidase method. Several polyclonal and a monoclonal antisera were used. From the third larval instar a positive reaction was observed in cells located in several parts of the brain. Each antiserum reacted with a constant number of well defined cells and nerve fibers. No differences between sexes were observed.     

The ability of prolactin to change the sensitivity of the pituitary of the lactating rat to luteinising hormone releasing hormonein vitro

The ability of prolactin to influence the responsiveness of the lactating rat pituitary to luteinising hormone releasing hormone has been examinedin vitro. The pituitary responsivenessin vivo to luteinising hormone releasing hormone decreased as a function of increase in the lactational stimulus. Prolactin inhibited the spontaneousin vitro release of luteinising hormone and follicle stimulating hormone to a small extent, from the pituitary of lactating rats with the suckling stimulus. However, it significantly inhibited the release of these two hormones from luteinising hormone releasing hormone-stimulated pituitaries. The responsiveness of pituitaries of rats deprived of their litter 24 h earlier, to luteinising hormone releasing hormone was also inhibited by prolactin, although minimal. It was concluded that prolactin could be influencing the functioning of the pituitary of the lactating rat by (a) partially suppressing the spontaneous release of gonadotropin and (b) inhibiting the responsiveness of the pituitary to luteinising hormone releasing hormone.     

Generation of hypophysiotropic activity in hypothalamic extracts in vitro.

The luteinizing hormone (LH) and follicle stimulating hormone (FSH) releasing activity, as well as the prolactin (PRL) release-inhibiting activity were measured in both neutral aqueous, and acid ethanolic extracts of rat hypothalami. LH and FSH-releasing activities were detectable only in the latter type of extract, whereas PRL release-inhibiting activity appeared in both. Neutral ultrafiltrates of the neutral extracts contained no gonadotropin releasing activity, however, acidification of the filtration medium induced its appearance. PRL release was inhibited by both neutral and acid filtrates. These results suggest that LH and FSH releasing factor(s) may be stored in the hypothalamus in an inactive form from which the active peptide is generated in vitro under acid conditions; however, this does not appear to be true for the component(s) responsible for the inhibition of PRL release.     

Differential actions of GnRH and rat hypothalamic extracts in release of hypophysial FSH and LH in vitro.

A study was made of the separate patterns of luteinizing hormone (LH) and follicle stimulating hormone (FSH) release from isolated rat pituitary tissue evoked by synthetic gonadotropin releasing hormone (GnRH) or female hypothalamic extracts (HE), respectively, in a continuous perifusion system. Under defined conditions, gonadotropin release from hemipituitaries was relatively stable and reproducible. Absolute levels of LH and FSH release evoked by HE in terms of their GnRH content were always greater than those following exposure to synthetic GnRH at varying doses. Synthetic GnRH released more FSH than LH. In contrast, the HE released slightly higher levels of LH than FSH. The data suggest that the female rat hypothalamus contains substances other than GnRH, capable of releasing both LH and FSH. It is possible that such unidentified components can modify the hypophysial action of GnRH, resulting in particular circumstances in a differential release of LH and FSH.     

Multifarious effects of estrogen on the pituitary gonadotrope with special emphasis on studies in the ovine species

The gonadotrope is a complex cell that expresses receptors for gonadotropin releasing hormone (GnRH) and estrogen. It has synthetic machinery for the production of 3 gonadotropin subunits which are assembled into two gonadotropins, luteinising hormone (LH) and follicle stimulating hormone (FSH). The production and secretion of LH and FSH are differentially regulated by GnRH and estrogen. Patterns of secretion of LH are dictated by the pulsatile release of GnRH from the median eminence as well as the feedback effects of estrogen. The means by which estrogen plays such an important role in the regulation of LH and FSH is reviewed in this chapter, with emphasis on work that has been done in the sheep. Estrogen regulates the second messenger systems in the gonadotrope as well as the number of GnRH receptors and the function of ion channels in the plasma membrane. Estrogen also regulates gene expression in these cells. Additionally, GnRH appears to regulate the level of estrogen receptor in the ovine gonadotrope, so there is substantial cross-talk between the signalling pathways for GnRH and estrogen. No clear picture has emerged as to how estrogen exerts a positive feedback effect on the gonadotrope and it is suggested that this might be forthcoming from more definitive studies on the way that estrogen regulates the second messenger systems and the trafficking of secretory vesicles.     

Effect of rabbit doe-litter separation on 24-hour changes of luteinizing hormone,follicle stimulating hormone and prolactin release in female and male suckling pups

Background  

The daily pattern of nursing of the rabbit pup by the doe is the most important event in the day for the newborn and is neatly anticipated by them. Such anticipation presumably needs a close correlation with changes in hormones that will allow the pups to develop an appropriate behavior. Although a number of circadian functions have been examined in newborn rabbits, there is no information on 24-h pattern of gonadotropin release or on possible sex-related differences in gonadotropin or prolactin (PRL) release of pups. This study examined the 24-h changes of plasma luteinizing hormone (LH), follicle stimulating hormone (FSH) and prolactin (PRL) in 11 days old suckling female and male rabbits left with the mother or after short-term (i.e., 48 h) doe-litter separation.     

Biological characteristics of the peptides α and β isolated from bovine seminal plasma

The bull seminal plasma peptides α andβ have been examined for their biological properties. While both the peptides were able to inhibit the human chorionic gonadotropin-dependent uterine response in the mouse, α alone exhibits the property of suppressing post-castrational rise in gonadotropin in appropriate animal models. This suggests that the peptideβ must be acting directly on the ovary to suppress estrogen production and, consequently, the uterine weight increase. Such a possibility was confirmed when α andβ were examined by the coupled bioassay which is capable of discriminating between pituitary feedback factors and those acting directly on the gonad. In a test system designed to examine chronic effects, both α andβ showed evidence of acting directly on the ovary to inhibit human menopausal gonadotropin-induced estrogen production. Such a direct action could not be correlated with the relative potencies of these peptides when examined for their follicle stimulating hormone-receptor binding inhibitor and lutinizing hormone-receptor binding inhibitor activities.     

Correlation of seasonal changes in sperm output with endocrinological changes in the adult male bonnet monkey,Macaca radiata

We have examined the monthly variations in sperm output and attempted to correlate the profiles of endocrine hormones secreted with the sperm counts throughout the year in the adult male bonnet monkey. As previously reported, there was a distinct spurt in sperm output beginning September through December months. A concomitant increase in serum testosterone and prolactin concentrations were also noted during September through November (mid and post-monsoon season). Although there was a marked increase in gonadotropin releasing hormone stimulated testosterone secretion, the peak testosterone concentrations post gonadotropin releasing hormone injection did not vary significantly (P > 0.05) throughout the year. Basal serum follicle stimulating hormone concentrations did not vary significantly (P > 0.05) during April to June months compared to September-November months. Serum inhibin concentration remained unaltered throughout the year, except in the month of March. The results of this study provide evidence for annual rhythms in prolactin and testosterone secretion and a distinct seasonality in the sperm output of the adult male bonnet monkey, but the pituitary responsiveness to exogenous gonadotropin releasing hormone remains unaltered throughout the year. Because of the existence of seasonality as noted in the present study, future studies which utilize the adult male bonnet monkey as an experimental model need to take into consideration the seasonal effects on reproductive function in this species.     

Gonadotropin releasing hormone in first trimester human placenta: Isolation,partial characterisation andin vitro biosynthesis

Using a specific radioimmunoassay for gonadotropin releasing hormone, the presence of gonadotropin releasing hormone like material in the first trimester human placenta has been demonstrated. The material has been partially characterized using carboxy methyl cellulose chromatography, high pressure gel permeation chromatography and reverse phase C18 high pressure liquid chromatographic analysis. Analysis for bioactivity revealed that placental gonadotropin releasing hormone is much more active than synthetic gonadotropin releasing hormone inin vitro rat pituitary lutinising hormone release assay.In vitro biosynthetic studies using labelled precursors and immunoaffinity chromatography indicated that first trimester human placenta synthesizes gonadotropin releasing hormone like material.     

Speculations on Structural Relationships between the Hypothalamic Releasing Factors of Pituitary Hormones

RECENTLY, hypothalamic releasing factors have been isolated from two different species (porcine and ovine) and their structures elucidated^1–5. These factors stimulate the secretion of pituitary hormones and have been shown to be small polypeptides. Thyrotropin releasing factor (TRF) for both species is the tripeptide pyroglutamyl-histidyl-proline amide (pGlu-His-Pro-amide)^1,2. TRF acts on pituitary thyrotrophs to stimulate the secretion of thyroid stimulating hormone (TSH). The structure of a hypothalamic factor which stimulates the secretion of the pituitary gonadotropins, luteinizing hormone (LH) and follicle stimulating hormone (FSH) has been determined. This gonadotropin releasing factor, referred to as LRF, is a decapeptide and, like TRF, has both terminals blocked; in both species its primary sequence is pGlu-His-Trp-Ser-Tyr-Gly-Leu-Arg-Pro-Gly-amide^3–5.     

Effects of Nandrolone Stimulation on Testosterone Biosynthesis in Leydig Cells

Anabolic androgenic steroids (AAS) are among the drugs most used by athletes for improving physical performance, as well as for aesthetic purposes. A number of papers have showed the side effects of AAS in different organs and tissues. For example, AAS are known to suppress gonadotropin‐releasing hormone, luteinizing hormone, and follicle‐stimulating hormone. This study investigates the effects of nandrolone on testosterone biosynthesis in Leydig cells using various methods, including mass spectrometry, western blotting, confocal microscopy and quantitative real‐time PCR. The results obtained show that testosterone levels increase at a 3.9 μM concentration of nandrolone and return to the basal level a 15.6 μM dose of nandrolone. Nandrolone‐induced testosterone increment was associated with upregulation of the steroidogenic acute regulatory protein (StAR) and downregulation of 17a‐hydroxylase/17, 20 lyase (CYP17A1). Instead, a 15.6 µM dose of nandrolone induced a down‐regulation of CYP17A1. Further in vivo studies based on these data are needed to better understand the relationship between disturbed testosterone homeostasis and reproductive system impairment in male subjects. J. Cell. Physiol. 231: 1385–1391, 2016. © 2015 The Authors. Journal of Cellular Physiology Published by Wiley Periodicals, Inc.     

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.     

Chorionic Gonadotropin and Its Receptor Are Both Expressed in Human Retina,Possible Implications in Normal and Pathological Conditions

Extra-gonadal role of gonadotropins has been re-evaluated over the last 20 years. In addition to pituitary secretion of luteinizing hormone (LH) and follicle stimulating hormone (FSH), the CNS has been clearly identified as a source of hCG acting locally to influence behaviour. Here we demonstrated that human retina is producing this gonadotropin that acts as a neuroactive molecule. Müller glial and retinal pigmented epithelial (RPE) cells are producing hCG that may affects neighbour cells expressing its receptor, namely cone photoreceptors. It was previously described that amacrine and retinal ganglion (RGC) cells are targets of the gonadotropin releasing hormone that control the secretion of all gonadotropins. Therefore our findings suggest that a complex neuroendocrine circuit exists in the retina, involving hCG secreting cells (glial and RPE), hCG targets (photoreceptors) and hCG-release controlling cells (amacrine and RGC). The exact physiological functions of this circuit have still to be identified, but the proliferation of photoreceptor-derived tumor induced by hCG demonstrated the need to control this neuroendocrine loop.     

重复制动应激对雌性大鼠下丘脑-垂体-卵巢轴的影响

目的: 探索重复制动应激对雌性大鼠下丘脑-垂体-卵巢轴的影响。方法: 40只SD雌鼠随机分为两组(n=20),对照组和实验组,一组正常饲养,一组采取递增负荷束缚应激,每天置于束缚器内制动应激一次(从上午9:00开始),第1日制动2 h,以后采用递增负荷,每日增加0.5 h,持续两周,通过检测体重、脏器系数、动情周期、性激素、病理和相关基因的表达探索其对下丘脑-垂体-卵巢轴的危害。结果: 重复制动应激使雌性大鼠体重下降、动情周期延长,卵巢和子宫的脏器系数和形态发生改变,利用qPCR技术对其相关基因检测,发现下丘脑促性腺激素释放激素、垂体促性腺激素释放激素受体、促卵泡生成素和促黄体生成素mRNA的表达显著下降,卵巢促卵泡生成素和黄体生成素受体 mRNA的表达显著上升,卵巢和子宫雌激素受体mRNA的表达显著下降。结论: 重复制动应激可能通过干扰下丘脑-垂体-卵巢轴的内分泌调节作用,使动情周期紊乱,从而损伤雌性动物的性腺和生殖内分泌功能。     

Further study of effects of synthetic peptides on identifiable giant neurones of an African giant snail (Achatina fulica Férussac)

1. Effects of the following peptides at 10(-4) M on identifiable giant neurones of Achatina fulica Férussac were examined: physalaemin, eledoisin, bradykinin, neurokinin A, neurokinin B, neuromedin B, gastrin releasing peptide decapeptide (neuromedin C), gastrin releasing peptide (14-27), cholecystokinin tetrapeptide, cholecystokinin octapeptide, thyrotropin releasing hormone, Arg-vasotocin, gamma-melanocyte stimulating hormone. 2. The six neurones tested were as follows: PON (periodically oscillating neurone), TAN (tonically autoactive neurone), RAPN (right anterior pallial neurone), d-RPLN (dorsal-right parietal large neurone), VIN (visceral intermittently firing neurone) and d-VLN (dorsal-visceral large neurone). 3. Of the peptides examined, only Arg-vasotocin at 10(-4) M produced the excitatory effects on PON, VIN and d-VLN. Physalaemin showed slight inhibitory effects on TAN; this substance was sometimes almost ineffective on the neurone. 4. The other peptides examined were completely ineffective on all of the neurones tested.     

Module dynamics of the GnRH signal transduction network

We analyse computational modules of a frequency decoding signal transduction network. The gonadotropin releasing hormone (GnRH) signal transduction network mediates the biosynthesis and release of the gonadotropins, luteinizing hormone (LH) and follicle stimulating hormone (FSH). The pulsatile pattern of GnRH production by the hypothalamus has a critical influence on the release and synthesis of gonadotropins in the pituitary. In humans, slower pulses lead to the expression of the beta-subunit of the LH protein and cause anovulation and amenorrhea. Higher frequency pulses lead to expression of the alpha subunit and a hypogonadal state. The frequency sensitivity is a consequence of the structure of the GnRH signal transduction network. We analyse individual components of this network, organized into three network architectures, and describe the frequency-decoding capabilities of each of these modules. We find that these modules are comparable to simple circuit elements, some of which integrate and others which perform as frequency sensitive filters. We propose that the cell computes by exploiting variation in the time scales of protein activation (phosphorylation) and gene expression.     

Basal and estradiol-induced release of gonadotropins in dairy cows with naturally occurring ovarian cysts

A study was conducted to identify relationships between serum sex steroid concentrations and release of gonadotropins in dairy cows with ovarian cysts. Cows with ovarian cysts were grouped according to sex steroid profiles as being under estrogenic (n = 6) or low steroid (n = 6) influence. All cows were submitted to a sampling and treatment protocol to 1) record basal pulsatile release of gonadotropins and 2) determine whether luteinizing hormone (LH) or follicle stimulating hormone (FSH) was released after sequential administration of exogenous estradiol and gonadotropin releasing hormone (GnRH) treatments were given 30 h apart. Basal LH was higher in the estrogen-influence group (P < 0.05). There were no differences between groups in basal FSH concentrations or frequency and amplitude of pulsatile LH or FSH release. Only one of the twelve cows, an individual from the low steroid group, had a preovulatory-like surge of gonadotropins after exogenous estradiol. All cows released LH and FSH in response to GnRH treatment, with no differences between groups. These results show that 1) there is considerable variation in pulsatile release of gonadotropins in cows with ovarian cysts, even among individuals with similar sex steroid profiles, and 2) suggest that a factor in the persistence, and perhaps initiation, of the cystic condition is refractoriness to the positive feedback effect of estradiol on gonadotropin release.     

Thyroid stimulating hormone upregulates secretion of cathepsin B from thyroid epithelial cells

Constant levels of thyroid hormones in the blood are principal requirements for normal vertebrate development. Their release depends on the regulated proteolysis of thyroglobulin which is extracellularly stored in the follicle lumen under resting conditions. Thyroglobulin is proteolytically degraded to a major part in lysosomes, but in part also extracellularly leading to the release of thyroxine. Extracellularly occurring lysosomal enzymes are most probably involved in the proteolytic release of thyroxine. In this study we have analyzed the secretion of cathepsin B by thyroid follicle cells (primary cells as well as FRTL-5 cells) and its regulation by thyroid stimulating hormone, which stimulated the secretory release of the proenzyme as well as of mature cathepsin B. Within one to two hours of stimulation with thyroid stimulating hormone, the cathepsin B activity associated with the plasma membrane increased significantly. This increase correlated closely with the localization of lysosomes in close proximity to the plasma membrane of cultured thyrocytes as well as with the thyroxine liberating activity of thyrocyte secretion media. These observations indicate that thyroid stimulating hormone induces the secretion of cathepsin B, which contributes to the extracellular release of thyroxine by thyrocytes.