The Gonadotropin-Releasing Hormone (GnRH) Neuronal Population Is Normal in Size and Distribution in GnRH-Deficient and GnRH Receptor-Mutant Hypogonadal Mice (original) (raw)
Related papers
2008
Hypothalamic GnRH neurons are essential for initiation and regulation of reproductive function. In addition to pituitary gonadotrope stimulation, activity of GnRH through its receptor (GnRHR) has been suggested to include autocrine regulation of the GnRH neuron. Two hypogonadal mouse strains, the Gnrh1 mutant (hpg) mice and Gnrhr mutant mice were used to investigate the potential role of GnRH signaling in the proper development and maintenance of GnRH neurons. Immunocytochemical analysis of heterozygous hpg mice revealed a GnRH neuron population that was normal in size and distribution, indicating no effect from reduced Gnrh1 gene dosage on the neurons themselves. To visualize GnRH neurons in homozygous GnRH-deficient hpg mice, heterozygous hpg mice were crossed with GnRH-green fluorescent protein (GFP) transgenic mice with targeted expression of the GFP reporter gene in GnRH neurons. Analysis of forebrains of homozygous hpg/GFP-positive mice immunostained for GFP revealed a normal population size and appropriate distribution of GnRH neurons in hpg mice, with immunoreactive neuronal processes present at the median eminence. Similarly, adult mice deficient in functional GnRHR possessed a full complement of GnRH neurons in the basal forebrain that was indistinguishable from the distribution of GnRH neurons in their wild-type counterparts. Moreover, hpg/GFP neurons retained the ability to generate spontaneous bursts of action potential firing activity, suggesting that GnRH peptide is not required for this function. These data establish that autocrine-paracrine GnRH-signaling is not a prerequisite for the developmental migration of GnRH neurons into the brain or for the projection of GnRH neurosecretory axons.
Annals of The New York Academy of Sciences, 2011
In the pituitary of mammals, the GnRH receptor (GnRHR) plays crucial roles in the neuroendocrine control of reproductive function. This receptor is specifically expressed by the gonadotrope cells scattered among the five other endocrine cell types constituting the anterior pituitary; it is also expressed in other organs, such as the gonads and brain where its function is not well defined. To gain insight into GnRHR function, distribution, and regulation, several transgenic approaches have been developed using a range of reporter genes under the control of the mouse, rat, or ovine GnRHR gene (Gnrhr) promoters. Comprehensive reviews of the literature, together with recent results obtained in our laboratory, illustrate how these transgenic models highlight the endocrine as well as the neural facet of GnRHR function. In this review, the endocrine aspect will be discussed with regard to the pituitary and gonad function, whereas the neural aspect will be discussed with regard to hippocampal formation and the oculomotor pathway, the latter constituting an unpreviously described site of Gnrhr promoter activity. These approaches should help elucidate the properties of the mammalian GnRH system.
Journal of Neuroendocrinology, 2008
Normal migration of the gonadotrophin-releasing hormone (GnRH) neurones during early development, from the olfactory region to the hypothalamus, is crucial for reproductive development in all vertebrates. The establishment of the GnRH system includes tangential migration of GnRH perikarya as well as extension of GnRH fibres to various areas of the central nervous system (CNS). The exact spatio-temporal nature of this process, as well as the factors governing it, are not fully understood. We studied the development of the GnRH system and the effects of GnRH knockdown using a newly developed GnRH3:EGFP transgenic zebrafish line. We found that enhanced green fluorescent protein is specifically and robustly expressed in GnRH3 neurones and fibres. GnRH3 fibres in zebrafish began to extend as early as 26 h post-fertilisation and by 4–5 days post-fertilisation had developed into an extensive network reaching the optic tract, telencephalon, hypothalamus, midbrain tegmentum and hindbrain. GnRH3 fibres also innervated the retina and projected into the trunk via the spinal cord. GnRH3 perikarya were observed migrating along their own fibres from the olfactory region to the preoptic area (POA) via the terminal nerve ganglion and the ventral telencephalon. GnRH3 cells were also observed in the trigeminal ganglion. The establishment of the GnRH3 fibre network was disrupted by morpholino-modified antisense oligonucleotides directed against GnRH3 causing abnormal fibre development and pathfinding, as well as anomalous GnRH3 perikarya localisation. These findings support the hypothesis that GnRH3 neurones migrate from the olfactory region to the POA and caudal hypothalamus. Novel data regarding the early development of the GnRH3 fibre network in the CNS and beyond are described. Moreover we show, in vivo, that GnRH3 is an important factor regulating GnRH3 fibre pathfinding and neurone localisation in an autocrine fashion.
Molecular Brain Research, 1997
To examine whether an ultrashort feedback mechanism of gonadotropin-releasing hormone (GnRH) operates at the level of gene transcription, we studied the effects of GnRH analogs on GnRH promoter activity and GnRH mRNA level in hypothalamic GT1-1 neuronal cells. Treatment of GT1-1 cells with buserelin, a GnRH agonist, or native GnRH for 24 h significantly decreased GnRH promoter activity and its mRNA level, whereas that with GnRH antagonists, antide or [D-Phe2,D-Ala6]-GnRH, showed no effect. The inhibitory effects of buserelin on GnRH gene transcription and GnRH mRNA level were dose-related, and a significant inhibition was observed in cells treated with buserelin at concentrations higher than 0.1 microM. Time-course experiments showed that significant decreases in GnRH promoter-driven luciferase activity and GnRH mRNA level were observed within 12 h and sustained up to 48 h. Moreover, treatment with GnRH agonist for 12 h significantly decreased the transcription rate of the mouse GnRH gene, as revealed by nuclear run-on transcription assay. The promoter analysis with the 5'-deletional constructs demonstrated that cis-acting elements important for GnRH autoregulation by GnRH agonist reside within -854 bp upstream from the transcription start site. These data clearly demonstrate that GnRH can exert autocrine regulation at the level of GnRH gene transcription.
Autocrine Regulation of Gonadotropin-Releasing Hormone Secretion in Cultured Hypothalamic Neurons
Endocrinology, 1999
Episodic hormone secretion is a characteristic feature of the hypothalamo-pituitary-gonadal system, in which the profile of gonadotropin release from pituitary gonadotrophs reflects the pulsatile secretory activity of GnRH-producing neurons in the hypothalamus. Pulsatile release of GnRH is also evident in vitro during perifusion of immortalized GnRH neurons (GT1-7 cells) and cultured fetal hypothalamic cells, which continue to produce bioactive GnRH for up to 2 months. Such cultures, as well as hypothalamic tissue from adult rats, express GnRH receptors as evidenced by the presence of high-affinity GnRH binding sites and GnRH receptor transcripts. Furthermore, individual GnRH neurons coexpress GnRH and GnRH receptors as revealed by double immunostaining of hypothalamic cultures. In static cultures of hypothalamic neurons and GT1-7 cells, treatment with the GnRH receptor antagonist, [D-pGlu 1 , D-Phe 2 , D-Trp 3,6 ]GnRH
Recent Discoveries on the Control of GnRH Neurons in Nonhuman Primates
Journal of Neuroendocrinology, 2010
Since Ernst Knobil proposed the concept of the GnRH pulse-generator in the monkey hypothalamus 3 decades ago, we have made significant progress in this research area with cellular and molecular approaches. First, an increase in pulsatile GnRH release triggers the onset of puberty. However, the question of what triggers the pubertal increase in GnRH is still unclear. GnRH neurons are already mature before puberty, but GnRH release is suppressed by a tonic GABA inhibition. Our recent work indicates that blocking endogenous GABA inhibition with the GABA A receptor blocker, bicuculline, dramatically increases kisspeptin release, which plays an important role in the pubertal increase in GnRH release. Thus, an interplay between the GABA, kisspeptin, and GnRH neuronal systems appears to trigger puberty. Second, cultured GnRH neurons derived from the olfactory placode of monkey embryos exhibit synchronized intracellular calcium, [Ca 2+ ] i , oscillations and release GnRH in pulses at ~60 min intervals after 14 days in vitro (div). During the first 14 div GnRH neurons undergo maturational changes from no [Ca 2+ ] i oscillations and little GnRH release to the fully functional state. Recent work also shows GnRH mRNA expression increases during in vitro maturation. This mRNA increase coincides with significant demethylation of a CpG island in the GnRH 5′-promoter region. This suggests epigenetic differentiation occurs during GnRH neuronal maturation. Third, estradiol causes rapid, direct, excitatory action in GnRH neurons and this estradiol action appears to be mediated through a membrane receptor, such as GPR30.
Journal of Endocrinology, 2006
Gonadotropin-releasing hormone receptor I (GnRHR I) has been localized to the limbic system of the rat brain, although the functional consequences of GnRH signaling through these receptors is unknown. In this paper, we characterize the expression of GnRHR I in the human hippocampus and cortex, and the functionality of GnRHR I in human neuroblastoma cells. Robust GnRHR I immunoreactivity was detected in the cell body as well as along the apical dendrites of pyramidal neurons in the CA2, CA1, and end plate, but was clearly lower in the subiculum of the hippocampus. Immunolabeling was also evident in cortical neurons, including those located in the entorhinal cortex and occipitotemporal gyrus but was not observed within the granular layer of the dentate gyrus. No differences in immunohistochemical staining were observed between control and Alzheimer’s disease brain. GnRHR I mRNA and protein (mature, immature, and other variant) expression was detected in human neuroblastoma cells (M17,...
General and Comparative Endocrinology, 1998
In the teleost fish, Haplochromis burtoni, three gonadotropin-releasing hormone (GnRH) peptides and their corresponding cDNA sequences and full-length genes have previously been reported. Here we describe the ontogeny of mRNA expression for these three GnRH forms in H. burtoni. Each of the three forms has been shown to have a distinct spatial expression pattern in the adult brain. 5Ser 8 6GnRH (the releasing form) is expressed exclusively in the hypothalamus, 5His 5 Trp 7 Tyr 8 6GnRH is expressed in the midbrain mesencephalon, and 5Trp 7 Leu 8 6GnRH is expressed in the terminal nerve area of the telencephalon. Previous work in other animals has shown that GnRH-containing neurons in the preoptic area arise from the olfactory placode and that these cells migrate into their final positions in the brain during early development. By using molecular probes to identify the cell types expressing distinct GnRH forms, our data are consistent with the migration of both 5Ser 8 6GnRH and 5Trp 7 Leu 8 6GnRH neurons from the placode to their appropriate adult locations in the brain. In contrast, we show that 5His 5 Trp 7 Tyr 8 6GnRH neurons arise from the germinal zone of the third ventricle. By using in situ hybridization with digoxigenin-labeled cRNA probes, 5His 5 Trp 7 Tyr 8 6GnRH mRNA was first evident at day 4, 5Trp 7 Leu 8 6GnRH mRNA at day 8, and 5Ser 8 6GnRH mRNA at day 14. However, by using the reverse-transcriptase polymerase chain reaction (RT-PCR), all three GnRH mRNAs were found in whole embryos at day 4 of the 14 days of embryogenesis. This striking difference may be due to the greater sensitivity of RT-PCR compared with in situ hybridization. Alternatively, it is possible that 5Ser 8 6GnRH and 5Trp 7 Leu 8 6GnRH are expressed outside the brain during early development and only later inside the brain.
In vitro paradigms for the study of GnRH neuron function and estrogen effects
Annals of the New York Academy of Sciences, 2003
The elaboration of in vitro paradigms has enabled direct study of GnRH secretion and the regulation of this process. Common findings using different models are the pulsatile nature and calcium-dependency of GnRH secretion, the excitatory effect of glutamate, and the inhibitory or excitatory effect of GABA. Among the different paradigms, the fetal olfactory placode cultures exhibit the unique property of migration in vitro and may retain the capacity to undergo maturational changes in vitro. The short-term incubation of hypothalamic explants obtained at different ages enables one to study developmental changes as well. Estrogens may have important roles in the regulation of GnRH function and can act indirectly via the neighboring neuronal/glial apparatus and directly on GnRH neurons at the cell body and terminal levels. A direct effect is supported by the recent localization of ERalpha and ERbeta transcripts in GnRH neurons using most paradigms. Discrepant effects of estrogens on GnR...