Jane E. Robinson scite author profile

The luteinizing hormone-releasing hormone (LHRH) system of the sheep brain was examined by light microscopic immunocytochemistry with thick, unembedded sections. We compared the distribution and morphology of LHRH cells and their fibers in intact and ovariectomized anestrous ewes, and in breeding season ewes during the mid-luteal phase of their estrous cycle. In all animals, a majority of LHRH neurons were found in the medial preoptic area adjacent to the organum vasculosum of the lamina terminalis. These cells formed a continuum rostrally with immunoreactive neurons in the diagonal band of Broca and medial septum and caudally with cells in the ventrolateral anterior hypothalamus and lateral hypothalamus. Relatively few cells (1-2%) were seen in the arcuate nucleus or its vicinity. Preoptic LHRH neurons project to the tubero-infundibular sulcus of the median eminence by at least two routes: a major ventrolateral projection above the optic tract in the anterior and lateral hypothalamus, and a less prominent periventricular pathway along the third ventricle. LHRH fibers were also observed in a number of extrahypothalamic regions, including the medial amygdala and the accessory olfactory bulb. Immunoreactive LHRH neurons in the sheep exhibited a complex light microscopic morphology unlike that seen in LHRH cells of any other species to date. LHRH cells with extensive, branching processes were frequently found in clusters with close somatic appositions between neighboring cells. Multiple thin protuberances emanated from the soma of many immunoreactive neurons. Immunoreactive fibers with beaded varicosities often were intimately associated with both cell bodies and their dendritic processes. Morphometric analyses revealed that preoptic LHRH neurons in three of four mid-luteal phase ewes had a shorter total dendritic length than those neurons in either intact or ovariectomized anestrous ewes, but this difference between breeding season and anestrous ewes was not statistically significant. Evidence for possible seasonal and/or steroid-induced alterations in the morphology of LHRH neurons must be documented by further studies, including immunocytochemical observations at an ultrastructural level.

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Distribution of Estrogen Receptor-Immunoreactive Cells in the Preoptic Area of the Ewe: Co-Localization with Glutamic Acid Decarboxylase but Not Luteinizing Hormone-Releasing Hormone

Herbison

1993

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Using immunocytochemical techniques we have examined the distribution of cells containing estrogen receptors (ERs) in the preoptic and anterior hypothalamic regions of short-term (1 week) ovariectomized ewes. Subsequent double-labelling experiments examined the co-localization patterns of ER and luteinizing hormone-releasing hormone (LHRH) or glutamic acid decarboxylase (GAD) immunoreactivities. ER-immunoreactive (-IR) cells were identified throughout the central and medial aspects of the preoptic area in a continuum which begins at the level of the organum vasculosum of the lamina terminalis and terminates in the caudal anterior hypothalamic area. A conspicuous sub-population of densely clustered ER-IR cells was identified within this distribution extending from the central region of the preoptic area into the bed nucleus of the stria terminalis. ER-IR cells were also identified in the ventrolateral septum and supraoptic nuclei. Double-labelling experiments showed that although rostral LHRH neurons were surrounded by ER-IR cells, they did not themselves possess ER immunoreactivity. In marked contrast, we estimate that approximately 40% of GAD-IR cells in the central aspect of the medial preoptic area are immunoreactive for the ER and that these cells account for nearly 30% of all ER-IR cells in this region. These results indicate that, in common with other species, LHRH neurons in the ewe do not possess ERs and suggest therefore, that these neurons are unlikely to be modulated directly by circulating estrogens. However, large numbers of adjacent GABA neurons possess ERs and may comprise a major neuronal population mediating gonadal steroid input to LHRH neurons.

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Prenatal Programming of Reproductive Neuroendocrine Function: Fetal Androgen Exposure Produces Progressive Disruption of Reproductive Cycles in Sheep

et al. 2003

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In the agonadal, androgenized ewe testosterone before birth produces a precocious pubertal rise in circulating LH and abolishes the LH surge mechanism. The present study tested two predictions from this model in the ovary-intact female: 1) prenatal androgen exposure produces early ovarian stimulation; and 2) despite early ovarian stimulation, progestogenic cycles would not occur because of the abolition or disruption of the LH surge. Pregnant ewes were injected with testosterone propionate twice per week from either d 30-90 (T60 group; 100 mg/injection) or d 60-90 (T30 group; 80 mg/injection) of gestation (term, 147 d). Control ewes received no injections. At birth, the androgenized and control lambs were divided into two groups: ovary-intact to determine the effects of prenatal androgen on the timing of puberty and subsequent ovarian function, and ovariectomized to assess the timing of the pubertal decrease in sensitivity to estrogen negative feedback and the subsequent increase in LH. Neonatally orchidectomized, estrogen-treated males were included for comparison of the timing of this pubertal rise in LH secretion. Neuroendocrine puberty (determined on the basis of LH increase) was advanced in the androgenized females to a similar age as in males. Repeated progesterone cycles of the same duration and number occurred in the ovary-intact ewes, and they began at the same time as for control females, thus negating both predictions. Differences appeared during the second breeding season, when reproductive cycles were either absent (T60) or disrupted (T30 group). Our findings reveal that exposure to androgens in utero causes a progressive loss of cyclic function in adulthood.

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Fetal Programming: Prenatal Androgen Disrupts Positive Feedback Actions of Estradiol but Does Not Affect Timing of Puberty in Female Sheep1

Sharma¹,

Herkimer²,

West³

et al. 2002

106

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We studied the impact of prenatal androgen exposure on the timing of onset of puberty, maintenance of cyclicity in the first breeding season, and the LH surge mechanism in female sheep. Pregnant sheep were injected with testosterone propionate (100 mg i.m.) twice each week from Day 30 to Day 90 (D30-90) or from Day 60 to Day 90 (D60-90) of gestation (term = 147 days). Concentrations of plasma progesterone and gonadotropins were measured in blood samples collected twice each week from control (n = 10), D60-90 (n = 13), and D30-90 (n = 3) animals. Rate of weight gain and initiation of estrous behavior were also monitored. After the first breeding season, when the animals entered anestrus, competency of the gonadotropin surge system to respond to estradiol positive feedback was tested in the absence or presence of progesterone priming for 12 days. Prenatally androgenized females had similar body weight gain and achieved puberty (start of first progestogenic cycle) at the same time as controls. Duration of the breeding season and the number of cycles that occurred during the first breeding season were similar between control and prenatally androgenized sheep. In contrast, prenatal exposure to androgens compromised the positive feedback effects of estradiol. Onset of LH/FSH surges following the estradiol stimulus was delayed in both groups of androgenized ewes compared with the controls in both the absence and presence of progesterone priming. In addition, the magnitude of LH and FSH surges in the two animals that surged in the D30-90 group were only one third and one half, respectively, of the magnitudes observed in the control and D60-90 groups. The present findings indicate that disruption of the surge system can account for the fertility problems that occur during adulthood in prenatally androgenized sheep.

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Jane E. Robinson

Neuroendocrine Basis of Seasonal Reproduction

Immunocytochemical localization of luteinizing hormone‐releasing hormone (LHRH) pathways in the sheep brain during anestrus and the mid‐luteal phase of the estrous cycle

Distribution of Estrogen Receptor-Immunoreactive Cells in the Preoptic Area of the Ewe: Co-Localization with Glutamic Acid Decarboxylase but Not Luteinizing Hormone-Releasing Hormone

Prenatal Programming of Reproductive Neuroendocrine Function: Fetal Androgen Exposure Produces Progressive Disruption of Reproductive Cycles in Sheep

Fetal Programming: Prenatal Androgen Disrupts Positive Feedback Actions of Estradiol but Does Not Affect Timing of Puberty in Female Sheep1

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