Corpus luteum function in hysterectomized and unilaterally hysterectomized ewes treated with gonadotropin-releasing hormone

Whitmore, Diana L.

13 March 1995

Graduation date: 1995

Corpus luteum

Luteinizing hormone releasing hormone

Ewes -- Fertility

Genetic variation in food intake and GnRH neurons in female white-footed mice Peromyscus leucopus /

Mahoney, Tara Penny Florina.

January 2009

Thesis (Honors)--College of William and Mary, 2009. / Includes bibliographical references (leaves 31-35). Also available via the World Wide Web.

Development of the induced gonadotropin surge mechanism in the prepubertal heifer

Maze, Timothy D.

January 2002

Thesis (Ph. D.)--West Virginia University, 2002. / Title from document title page. Document formatted into pages; contains viii, 71 p. : ill. (some col.). Vita. Includes abstract. Includes bibliographical references (p. 61-70).

The role of ß-catenin in the gonadotrope transcriptional network interactions with SF1 and TCF /

Binder, April Kay.

January 2009

Thesis (Ph. D.)--Washington State University, December 2009. / Title from PDF title page (viewed on Dec. 16, 2009). "School of Molecular Biosciences." Includes bibliographical references.

Seasonal cycle of gonadal steroidogenesis and the effects of luteinizing hormone and luteinizing hormone releasing hormone on the in vitro and in vivo steroidal secretions in monopterus albus /

Chʻen, Hui.

January 1900

Thesis (M. Phil.)--University of Hong Kong, 1989.

Transcriptional regulation of the human gonadotropin-releasing hormone(GnRH) II and GnRH receptor genes

Hoo, L. C., 何麗莊.

January 2003

published_or_final_version / abstract / toc / Zoology / Doctoral / Doctor of Philosophy

Luteinizing hormone releasing hormone.

Hormone receptors.

Genetic regulation.

Molecular cloning and characterization of gonadotropin-releasing hormone receptors in the black seabream (Mylio macrocephalus)

李景耀, Lee, King-yiu.

January 2001

published_or_final_version / Zoology / Master / Master of Philosophy

Molecular cloning.

Sparidae - Genetics.

Characterization of two chicken gonadotropin releasing hormone-II genes in goldfish, Carassius Auratus

戚賜聰, Chik, Chi-chung, Stanley.

January 1999

published_or_final_version / Zoology / Master / Master of Philosophy

Luteinizing hormone releasing hormone.

Chickens - Genetics.

Goldfish - Genetics.

Rapid effects of estrogen on intracellular calcium levels in adult GnRH neurons

Romano, Nicola, n/a

January 2009

The gonadotropin-releasing hormone (GnRH) neurons of the hypothalamus are the principal regulators of reproductive function and are strongly modulated by estrogen (E₂). Several studies indicate that E₂ is able to influence GnRH neurons, both with "classical" long-term transcriptional effects, and with rapid non-transcriptional effects. One most interesting action of E₂ is that of modulating intracellular calcium concentration [Ca�⁺]I: this has been shown to happen in many different cell types, including embryonic models of GnRH neurons. The aim of this project was to evaluate if these rapid effects of E₂ on [Ca�⁺]I also happen at the level of adult GnRH neurons. In order to study the acute effects of E₂ on calcium dynamics, a novel transgenic mouse line was generated, that allows real-time measurement of [Ca�⁺]I selectively in GnRH neurons in an acute brain slice preparation. Using this mouse line, our group has previously shown that these cells show spontaneous activity in the form of Ca�⁺ transients. A first set of experiments was designed to define the effects of E₂ on spontaneous activity. E₂ was found to modulate [Ca�⁺]I in a activity-dependent manner: it increased the frequency of [Ca�⁺]I transients in about 50% of GnRH neurons with low spontaneous activity, whereas it decreased the frequency of the transients in more than 80% spontaneously active GnRH neurons. Different experiments were then performed in order to determine the molecular pathways that generates these opposite effects. The inhibitory effect was reproduced by the membrane-impermeable compound E2-6-BSA, indicating that it happens through a membrane receptor. The E₂ isomer l7α-estradiol was also able to reproduce the inhibitory effect of E₂, suggesting the involvement of some non-classical receptor. This is also confirmed by the presence of this effect in estrogen-receptor β (ER-β) knock-out mice, which exclude the involvement of this receptor. The stimulatory effect was found to be generated through a novel, indirect mechanism. It cannot be reproduced by E2-6-BSA nor by l7α-estradiol, and it is still present in the ER-β knock-out mice. The stimulation, though, can be reproduced in about 50% of cells with an ER-α selective agonist. As this receptor is not present in GnRH neurons, an indirect mechanism must be generating the stimulatory effect. Blockage of action potential mediated synaptic transmission with tetrodotoxin (TTX) did not block E₂ effects, but blockage of non-action potential mediated GABAergic transmission using the GABA[A] selective blocker gabazine completely abolished them. Our hypothesis is therefore that E₂ stimulates the generation of [Ca�⁺]I transients through estrogen-receptor a (ER-α) located in the terminals of GABAergic afferents. This modulation, in turn, is able to determine release of Ca�⁺ from IP₃-sensitive intracellular stores. To confirm this, we applied exogenous GABA to the neurons and found that it was able to initiate [Ca�⁺]I transients. Furthermore, removal of tonic GABAergic tone with gabazine was able to block spontaneous activity. To further analyse the effects of E₂, Ca�⁺ imaging experiments were performed together with cell-attached patch clamp electrophysiological recordings in order to correlate the electrical activity with the calcium activity. Simultaneous recordings revealed a strong correlation between [Ca�⁺]I transients and bursts of action currents in adult GnRH neurons. E₂ was able to increase the electrical activity of GnRH neurons with low spontaneous activity, and inhibit that of highly active ones. Application of GABA to GnRH neurons resulted in increased firing, accompanied by an increase in [Ca�⁺]I. These observations provide evidence for a complex mechanism of E₂ action on adult GnRH neurons, that may be important for the generation of the pulsatile release of this hormone.

estrogen

metabolism

calcium in the body

luteinizing hormone releasing hormone

Rapid effects of estrogen on intracellular calcium levels in adult GnRH neurons

Romano, Nicola, n/a

January 2009

The gonadotropin-releasing hormone (GnRH) neurons of the hypothalamus are the principal regulators of reproductive function and are strongly modulated by estrogen (E₂). Several studies indicate that E₂ is able to influence GnRH neurons, both with "classical" long-term transcriptional effects, and with rapid non-transcriptional effects. One most interesting action of E₂ is that of modulating intracellular calcium concentration [Ca�⁺]I: this has been shown to happen in many different cell types, including embryonic models of GnRH neurons. The aim of this project was to evaluate if these rapid effects of E₂ on [Ca�⁺]I also happen at the level of adult GnRH neurons. In order to study the acute effects of E₂ on calcium dynamics, a novel transgenic mouse line was generated, that allows real-time measurement of [Ca�⁺]I selectively in GnRH neurons in an acute brain slice preparation. Using this mouse line, our group has previously shown that these cells show spontaneous activity in the form of Ca�⁺ transients. A first set of experiments was designed to define the effects of E₂ on spontaneous activity. E₂ was found to modulate [Ca�⁺]I in a activity-dependent manner: it increased the frequency of [Ca�⁺]I transients in about 50% of GnRH neurons with low spontaneous activity, whereas it decreased the frequency of the transients in more than 80% spontaneously active GnRH neurons. Different experiments were then performed in order to determine the molecular pathways that generates these opposite effects. The inhibitory effect was reproduced by the membrane-impermeable compound E2-6-BSA, indicating that it happens through a membrane receptor. The E₂ isomer l7α-estradiol was also able to reproduce the inhibitory effect of E₂, suggesting the involvement of some non-classical receptor. This is also confirmed by the presence of this effect in estrogen-receptor β (ER-β) knock-out mice, which exclude the involvement of this receptor. The stimulatory effect was found to be generated through a novel, indirect mechanism. It cannot be reproduced by E2-6-BSA nor by l7α-estradiol, and it is still present in the ER-β knock-out mice. The stimulation, though, can be reproduced in about 50% of cells with an ER-α selective agonist. As this receptor is not present in GnRH neurons, an indirect mechanism must be generating the stimulatory effect. Blockage of action potential mediated synaptic transmission with tetrodotoxin (TTX) did not block E₂ effects, but blockage of non-action potential mediated GABAergic transmission using the GABA[A] selective blocker gabazine completely abolished them. Our hypothesis is therefore that E₂ stimulates the generation of [Ca�⁺]I transients through estrogen-receptor a (ER-α) located in the terminals of GABAergic afferents. This modulation, in turn, is able to determine release of Ca�⁺ from IP₃-sensitive intracellular stores. To confirm this, we applied exogenous GABA to the neurons and found that it was able to initiate [Ca�⁺]I transients. Furthermore, removal of tonic GABAergic tone with gabazine was able to block spontaneous activity. To further analyse the effects of E₂, Ca�⁺ imaging experiments were performed together with cell-attached patch clamp electrophysiological recordings in order to correlate the electrical activity with the calcium activity. Simultaneous recordings revealed a strong correlation between [Ca�⁺]I transients and bursts of action currents in adult GnRH neurons. E₂ was able to increase the electrical activity of GnRH neurons with low spontaneous activity, and inhibit that of highly active ones. Application of GABA to GnRH neurons resulted in increased firing, accompanied by an increase in [Ca�⁺]I. These observations provide evidence for a complex mechanism of E₂ action on adult GnRH neurons, that may be important for the generation of the pulsatile release of this hormone.

estrogen

metabolism

calcium in the body

luteinizing hormone releasing hormone