Fred J. Karsch

Neuroendocrine basis of seasonal reproduction

Publisher Summary This chapter discusses the strategy of seasonal breeding, the role of photoperiod in timing the annual reproductive cycle, the hypothalamo-pituitary mechanisms that mediate photoperiodic regulation of estrous cyclicity, and the photoperiodic pathway to luteinizing hormone (LH) pulse generator. To understand how photic input to the LH pulse generator leads to seasonal changes in gonadal activity, the sequence of endocrine events that normally leads to ovulation during the estrous cycle of the ewe must be considered. These preovulatory events occur during a 2–3 day follicular phase and include a precipitous drop in progesterone, a progressive rise in tonic LH secretion, a sustained increase in estradiol secretion, and the LH surge. The pivotal step in this sequence is the sustained increase in tonic LH secretion. A great deal of insight has been gained into the complex interplay between the neural and endocrine response systems that underlie the seasonal reproductive process in the short-day breeding ewe. Specifically, light cues activate retinal photoreceptors and are transmitted via a monosynaptic tract to the suprachiasmatic nuclei of the hypothalamus. After interacting with the circadian system, the photic information is relayed to the pineal gland that transduces the neural message into a hormonal signal in the form of a circadian rhythm of melatonin secretion. The pattern of this melatonin signal, which is interpreted as inductive or suppressive, sets the frequency of the LH pulse generator and determines the capacity of this neural oscillator to respond to the negative feedback action of estradiol. The resulting changes in the episodic pattern of gonadotropin secretion, in turn, dictate whether or not estrous cycles can occur.

Endotoxin Inhibits the Reproductive Neuroendocrine Axis While Stimulating Adrenal Steroids: A Simultaneous View from Hypophyseal Portal and Peripheral Blood

This study was designed to test the hypothesis that systemic immune challenge with endotoxin inhibits the reproductive axis centrally by suppressing GnRH pulsatile release into hypophyseal portal blood. Using alert, normally behaving, ovariectomized ewes, we sampled hypophyseal portal blood at 10-min intervals beginning 4 h before and continuing 10 h after endotoxin (400 ng/kg, iv bolus, n = 6) or saline (vehicle, iv, n = 6). Simultaneous jugular samples for measurement of LH, cortisol, and progesterone were taken, and core body temperature was monitored by telemetry. Saline had no effect on any of the parameters in control ewes. In contrast, endotoxin dramatically inhibited the reproductive neuroendocrine axis coincident with stimulating the adrenal steroids, cortisol and progesterone, and elevating body temperature. Mean GnRH collection rate and GnRH pulse amplitude were suppressed (pre- vs. 7 h postendotoxin: collection rate 0.93 ± 0.31 vs. 0.34 ± 0.13 pg/min; amplitude 4.13 ± 1.33 vs. 1.30 ± 0.41 pg/m...

Pineal Melatonin Mediates Photoperiodic Control of Pulsatile Luteinizing Hormone Secretion in the Ewe

Seasonal breeding in the ewe is regulated by photoperiod through a pineal-dependent mechanism. Changes in the ability of estradiol to inhibit tonic LH secretion are critical. During anestrus, this ovarian steroid gains the ability to slow the frequency of pulsatile LH secretion through an action on the brain. Exposure of ovariectomized, estradiol-implanted ewes to short photoperiods during summer anestrus revealed that daylength can control LH pulse frequency. After removal of estradiol, LH pulse frequency still differed between long- and short-day ewes, suggesting photoperiodic modulation of LH and presumably GnRH secretion independent of gonadal steroids. Significantly, the effects of daylength expressed both in the presence and the absence of estradiol failed to occur in pinealectomized ewes. Long-term infusions of melatonin, given in physiological patterns to pinealectomized ewes, mimicked the effects of photoperiod on pineal-intact ewes. Specifically, a pattern of melatonin characteristic of that in short days (16-hour night-time rise) led to an increase in LH pulse frequency to a breeding season rate. Conversely, melatonin infusions typifying a long-day pattern (8-hour night-time rise) produced an anestrous pulse pattern. Pituitary sensitivity to GnRH was not reduced in sheep which were reproductively suppressed by photoperiod or melatonin treatments. These observations support the conclusion that day-length acts through pineal melatonin secretion to regulate a neural LH pulse generator which, by changing the frequency of GnRH pulses, determines the ewes seasonal reproductive state.

Endocrine Alterations That Underlie Endotoxin-Induced Disruption of the Follicular Phase in Ewes

Abstract Two experiments were conducted to investigate endocrine mechanisms by which the immune/inflammatory stimulus endotoxin disrupts the follicular phase of the estrous cycle of the ewe. In both studies, endotoxin was infused i.v. (300 ng/kg per hour) for 26 h beginning 12 h after withdrawal of progesterone to initiate the follicular phase. Experiment 1 sought to pinpoint which endocrine step or steps in the preovulatory sequence are compromised by endotoxin. In sham-infused controls, estradiol rose progressively from the time of progesterone withdrawal until the LH/FSH surges and estrous behavior, which began ∼48 h after progesterone withdrawal. Endotoxin interrupted the preovulatory estradiol rise and delayed or blocked the LH/FSH surges and estrus. Experiment 2 tested the hypothesis that endotoxin suppresses the high-frequency LH pulses necessary to stimulate the preovulatory estradiol rise. All 6 controls exhibited high-frequency LH pulses typically associated with the preovulatory estradiol rise. As in the first experiment, endotoxin interrupted the estradiol rise and delayed or blocked the LH/FSH surges and estrus. LH pulse patterns, however, differed among the six endotoxin-treated ewes. Three showed markedly disrupted LH pulses compared to those of controls. The three remaining experimental ewes expressed LH pulses similar to those of controls; yet the estradiol rise and preovulatory LH surge were still disrupted. Our results demonstrate that endotoxin invariably interrupts the preovulatory estradiol rise and delays or blocks the subsequent LH and FSH surges in the ewe. Mechanistically, endotoxin can interfere with the preovulatory sequence of endocrine events via suppression of LH pulsatility, although other processes such as ovarian responsiveness to gonadotropin stimulation appear to be disrupted as well.

New insights regarding glucocorticoids, stress and gonadotropin suppression

This review highlights our recent work investigating the inhibitory effects of acute, physiologic stress-like increases in cortisol on reproductive neuroendocrine activity in sheep, the mechanisms responsible for this suppression, and the relevance of enhanced glucocorticoid secretion to stress-induced inhibition of gonadotropin secretion in this species. Initial studies established that cortisol rapidly suppresses pulsatile luteinizing hormone secretion. In ovariectomized ewes, this inhibition reflects the reduction of pituitary responsiveness to gonadotropin-releasing hormone mediated by the type II glucocorticoid receptor, rather than the suppression in hypothalamic gonadotropin-releasing hormone release. Studies in ovary-intact ewes, however, uncovered an alternative mode of cortisol action. During the follicular phase of the estrous cycle, cortisol reduces luteinizing hormone pulse frequency, most likely via the inhibition of gonadotropin-releasing hormone pulsatility. Recent preliminary evidence in ovariectomized ewes demonstrates increased cortisol secretion is essential for disruption of pulsatile luteinizing hormone secretion in response to a psychosocial stress. Taken together, our observations reveal diverse inhibitory actions of cortisol on gonadotropin secretion and that this glucocorticoid is not only sufficient, but necessary for suppression of reproductive neuroendocrine activity in response to certain types of stress.

Evidence for short or ultrashort loop negative feedback of gonadotropin-releasing hormone secretion.

The present studies tested the hypothesis that either short or ultrashort loop negative feedback regulation of gonadotropin-releasing hormone (GnRH) secretion occurs in the ewe. As part of ongoing studies investigating the regulation of follicle-stimulating-hormone secretion, we obtained the unexpected result that a GnRH antagonist (Nal-Glu) may stimulate GnRH secretion. In that experiment, hypophyseal portal blood was collected from five short-term ovariectomized ewes at 5-min intervals for 6 h before and 6 h after intravenous injection of Nal-Glu (10 micrograms/kg body weight). An increase in GnRH pulse frequency in association with the blockade of luteinizing hormone (LH) release was evident in 3 of the 5 animals. To determine if an effect of Nal-Glu on episodic GnRH secretion would be more evident in an animal model in which low-frequency pulses of GnRH prevail, the study was repeated in six ewes in the midluteal phase of the estrous cycle and six ovariectomized ewes bearing estradiol and progesterone implants to suppress GnRH release (artificial luteal model). In luteal-phase ewes, administration of Nal-Glu was followed by an increase in GnRH pulse frequency, pulse size and the secretion of GnRH between pulses, and by a blockade of LH release. In ovariectomized ewes treated with estradiol and progesterone, Nal-Glu administration also stimulated GnRH and inhibited LH secretion. Our finding that the GnRH antagonist stimulated GnRH secretion is consistent with the hypothesis that endogenous GnRH may influence its own release via either a short or ultrashort loop feedback mechanism.

Mechanisms for Ovarian Cycle Disruption by Immune/inflammatory Stress

This review summarizes highlights of our experiments investigating mechanisms, mediators and sites by which endotoxin disrupts reproductive neuroendocrine activity and interferes with the estrous cycle of sheep. Endotoxin, or lipopolysaccharide (LPS), is a commonly used model for immune and inflammatory stress. When administered to ovary-intact ewes, endotoxin interrupts the follicular phase of the cycle by interfering with several steps in the preovulatory chain of endocrine events. One such step is the development of high frequency LH pulses, which provide an essential stimulus for the preovulatory increase in estradiol secretion from the ovarian follicle. Follow-up experiments in ovariectomized ewes demonstrate that endotoxin inhibits pulsatile LH secretion at both the hypothalamic and pituitary levels, suppressing pulsatile GnRH secretion and reducing pituitary responsiveness to GnRH. This disruption of GnRH and LH pulsatility is mediated by pathways that include the synthesis of prostaglandins and cortisol, both of which are increased by endotoxin. It is postulated that a prostaglandin-mediated pathway disrupts the cycle during immune and inflammatory stress, whereas a separate cortisol-mediated pathway reinforces this disruption and also participates more generally in suppressing cyclicity during other stressful situations that activate the hypothalamo-pituitary-adrenal axis.

Neuroendocrine control of follicle-stimulating hormone (FSH) secretion. I. Direct evidence for separate episodic and basal components of FSH secretion

Continuous sampling of hypophyseal portal blood from unrestrained sheep is providing an unprecedented means for measuring and defining the characteristics of the secretory profile of GnRH. With this method, GnRH has been shown to be released in discrete pulses lasting 5–8 min, with the amplitude of some pulses exceeding 50-fold. Although the relationship between these pulses and the accompanying pulses of LH measured in the jugular vein are unambiguous, the relationship of GnRH pulses to the release of FSH has not been well defined due to the longer clearance of FSH. In previous studies we have shown that hypophyseal portal blood, in addition to serving as a source material for hypothalamic secretions, provides a means to define secretory patterns of pituitary hormones. Because of this we hypothesized that the GnRH-FSH secretory relationships would be easier to define in hypophyseal portal than in jugular vein blood before the secretory products are subjected to dispersion and clearance in circulation. To...

Determinants of Puberty in a Seasonal Breeder

Publisher Summary This chapter focuses on the determinants of puberty in a seasonal breeder. The evolution of seasonal breeding, natures contraceptive influences the time when fertility is first attained in the young female. Puberty occurs only during the breeding season. Thus, not only must the developing seasonal breeder be able to determine when she is sufficiently mature to begin reproductive cycles, she must also be able to determine when during the year onset of fertility will produce young during the spring and summer. The production of high-frequency luteinizing hormone (LH) pulses is clearly the pivotal force driving the transition into adulthood in the lamb. Therefore, further understanding of the timing of sexual maturation in this seasonal breeder depends upon ones ability to unravel how developmental and environmental signals modify the activity of the system generating pulsatile LH secretion by the pituitary. Based upon the work conducted in the adult and the patterns of LH observed in the lamb, there is little reason to suspect that the pubertal increase in LH pulse frequency in the young female sheep reflects anything other than an increase in frequency of the gonadotropin-releasing hormone (GnRH) pulse generator. The pubertal increase in LH pulses is occasioned by a lessening of negative feedback control of the GnRH pulse generator. The common neuroendocrine feature underlying the onset of puberty and the onset of the breeding season is the increase in GnRH pulse generator activity.

Cortisol reduces gonadotropin-releasing hormone pulse frequency in follicular phase ewes: Influence of ovarian steroids

Stress-like elevations in plasma glucocorticoids suppress gonadotropin secretion and can disrupt ovarian cyclicity. In sheep, cortisol acts at the pituitary to reduce responsiveness to GnRH but does not affect GnRH pulse frequency in the absence of ovarian hormones. However, in ewes during the follicular phase of the estrous cycle, cortisol reduces LH pulse frequency. To test the hypothesis that cortisol reduces GnRH pulse frequency in the presence of ovarian steroids, the effect of cortisol on GnRH secretion was monitored directly in pituitary portal blood of follicular phase sheep in the presence and absence of a cortisol treatment that elevated plasma cortisol to a level observed during stress. An acute (6 h) cortisol increase in the midfollicular phase did not lower GnRH pulse frequency. However, a more prolonged (27 h) increase in cortisol beginning just before the decrease in progesterone reduced GnRH pulse frequency by 45% and delayed the preovulatory LH surge by 10 h. To determine whether the gonadal steroid milieu of the follicular phase enables cortisol to reduce GnRH pulse frequency, GnRH was monitored in ovariectomized ewes treated with estradiol and progesterone to create an artificial follicular phase. A sustained increment in plasma cortisol reduced GnRH pulse frequency by 70% in this artificial follicular phase, in contrast to the lack of an effect in untreated ovariectomized ewes as seen previously. Thus, a sustained stress-like level of cortisol suppresses GnRH pulse frequency in follicular phase ewes, and this appears to be dependent upon the presence of ovarian steroids.