Development and validation of brief scales to measure collectivism, religiosity, racial pride, and time orientation in urban African American women.

This article describes the development and pilot-testing of brief scales to measure four cultural constructs prevalent in urban African American women. Internal consistency and temporal stability were assessed in two convenience samples (n=47 and n=25) of primarily lower-income African American women. All scales performed well: collectivism alpha=.93, r=.85, p<.001); religiosity (alpha=.88, r=.89, p<.001); racial pride (alpha=.84, r=.52, p<.001); present time orientation (alpha=.73, r=.52, p<.01) and future time orientation (alpha=.72, r=.54, p=.07).

Central, but not peripheral, glucose-sensing mechanisms mediate glucoprivic suppression of pulsatile luteinizing hormone secretion in the sheep.

Changes in glucose availability are proposed to modulate pulsatile GnRH secretion, and at least two anatomical sites, the liver and hindbrain, may serve as glucose sensors. The present study determined the relative importance of these putative glucose-sensing areas in regulating pulsatile LH secretion in the sheep. Our approach was to administer the antimetabolic glucose analog, 2-deoxy-D-glucose (2DG) into either the hepatic portal vein or the fourth ventricle in gonadectomized females in which LH pulse frequency was high. In the first study, a catheter was placed in the ileocolic vein to determine the effects of local injection of 2DG into the hepatic portal system on the release of LH. After monitoring the pattern of LH secretion for 4 h, 2DG (250 mg/kg) was infused (500 microl/min) into the liver for 2 h. For comparison, animals were also given the same dose of 2DG into a jugular vein for 2 h. Administration of 2DG into either the hepatic portal or jugular vein reduced LH pulse frequency to the same extent. Infusion of the lower dose (50 mg/kg) locally into the hepatic portal vein did not affect plasma LH profiles. Collectively, these results are interpreted to indicate that the liver does not contain special glucose-sensing mechanisms for the glucoprivic suppression of LH pulses. In the second study, 2DG (5 mg/kg) was infused (50 l/min) for 30 min into the fourth ventricle or lateral ventricle. During the subsequent 4-h sampling period, pulsatile LH secretion was significantly suppressed, but there was no significant difference in LH pulse frequency between sites of infusion. Peripheral 2DG concentrations were not detectable after either fourth or lateral ventricle infusions, indicating that the 2DG had acted centrally to suppress LH pulses. Plasma cortisol concentrations increased more in animals infused with 2DG into the fourth ventricle than in those infused into the lateral ventricle, suggesting that 2DG infused into lateral ventricle is transported caudally into the fourth ventricle and acts within the area surrounding the fourth ventricle. Overall, these findings suggest that an important glucose-sensing mechanism is located circumventricularly in the fourth ventricle. Moreover, the liver does not appear to play an important role in detecting glucoprivic action of 2DG to suppress pulsatile LH secretion.

Regulation of pulsatile luteinizing hormone secretion by insulin in the diabetic male lamb.

This study tested the hypothesis that LH secretion is modulated by insulin and that the responsiveness to hypoinsulinemia is enhanced by sex steroids. The model was the developing male lamb (12-26 wk of age) rendered diabetic by chemically induced necrosis of insulin-secreting tissue (streptozotocin). Our approach was to monitor LH secretion under diabetic conditions, with or without insulin supplementation, either in the presence or in the absence of gonadal steroids. The first experiment determined if chronic insulin supplementation could sustain LH secretion in diabetic lambs. After documentation of the induced diabetic condition, twice-daily treatment with a long-acting insulin preparation (Lente) minimized diabetes-induced hyperglycemia, sustained growth, and maintained LH pulse frequency at levels comparable to pre-diabetic conditions. A second experiment evaluated the acute regulation of LH secretion by insulin. Twenty-four hours of insulin withdrawal decreased LH pulse frequency, increased circulating glucose levels, increased the concentration of plasma non-esterified fatty acids (NEFAs), and increased urinary output of ketones. LH pulse frequency continued to decline after 96 h of insulin withdrawal. By contrast, 24 h of insulin re-supplementation increased LH pulse frequency, reduced circulating glucose and NEFA concentrations, decreased plasma cortisol, and reduced urinary output of ketones. After 96 h of insulin re-supplementation, LH pulse frequency increased further, to levels comparable with those before insulin withdrawal. A third experiment determined if the effects of insulin withdrawal on LH secretion are influenced by the presence of gonadal steroids. The same individuals were treated with a physiologic dose of estradiol (Silastic capsule, s.c.) and subsequently monitored for changes in LH secretion in the presence and in the absence of exogenous insulin. Prior to insulin withdrawal, estradiol decreased both LH pulse frequency and pulse amplitude. Moreover, after 96 h of insulin withdrawal, estradiol potentiated the decline in LH pulse frequency (47% reduction in LH pulse frequency in the presence of estradiol versus 26% reduction in LH pulse frequency in the absence of estradiol). These findings support the contention that insulin and/or insulin-dependent changes in glucose availability modulate LH(GnRH) pulse frequency, and that such effects are potentiated by, but not dependent upon, gonadal steroids.

Central action of insulin regulates pulsatile luteinizing hormone secretion in the diabetic sheep model.

This study tested the hypothesis that central mechanisms regulating luteinizing hormone (LH) secretion are responsive to insulin. Our approach was to infuse insulin into the lateral ventricle of six streptozotocin-induced diabetic sheep in an amount that is normally present in the CSF when LH secretion is maintained by peripheral insulin administration. In the first experiment, we monitored cerebrospinal fluid (CSF) insulin concentrations every 3-5 h in four diabetic sheep given insulin by peripheral injection (30 IU). The insulin concentration in the CSF was increased after insulin injection, and there was a positive relationship between CSF and plasma concentrations of insulin (r = 0.80, P < 0.01). In the second experiment, peripheral insulin administration was discontinued, and the sheep received either an intracerebroventricular (i.c.v.) infusion of insulin (12 mU/day in 2.4 ml saline) or saline (2.4 ml/day) for 5 days (n = 6) in a crossover design. The dose of insulin (i.c.v.) was calculated to approximate the increase in CSF insulin concentration found after peripheral insulin treatment. To monitor LH secretory patterns, blood samples were collected by jugular venipuncture at 10-min intervals for 4 h on the day before and 5 days after the start of i.c.v. insulin infusion. To monitor the increase in CSF insulin concentrations, a single CSF sample was collected one and four days after the start of the central infusion. The i.c.v. insulin infusion increased CSF insulin concentrations above those in saline-treated animals (P < 0.05) and maintained them at or above the peak levels achieved after peripheral insulin treatment. Central insulin infusion did not affect peripheral (plasma) insulin or glucose concentrations. LH pulse frequency in insulin-treated animals was greater than that in saline-treated animals (3.5 +/- 0.2 vs. 2.3 +/- 0.3 pulses/4 h, P < 0.01), but it was less than that during peripheral insulin treatment (4.8 +/- 0.2 pulses/4 h, P < 0.01). Our findings suggest that physiologic levels of central insulin supplementation are able to increase pulsatile LH secretion in diabetic sheep with low peripheral insulin. These results are consistent with the notion that central insulin plays a role in regulating pulsatile GnRH secretion.

Central inhibition of gonadotropin-releasing hormone secretion in the growth-restricted hypogonadotropic female sheep.

Growth retardation induced by dietary restriction results in hypogonadotropism, and thus, puberty is delayed. The present studies determined 1) whether reduced LH secretion in the growth-retarded condition is due to a reduction in the frequency and/or in the amplitude of GnRH secretion, and 2) whether the mechanism regulating LH secretion is being actively inhibited via central mechanisms. To determine whether GnRH pulse frequency and/or amplitude are reduced during growth restriction, blood samples were simultaneously collected from pituitary portal blood for GnRH and from jugular blood for LH determinations over a 4-h period in ovariectomized lambs (52 wk of age) that were either growth restricted (28 kg; n = 8) or growing normally (60 kg; n = 7). As expected, the growth-restricted females were hypogonadotropic and exhibited a long LH interpulse interval compared with the normally growing females. However, although the GnRH interpulse interval was longer in the growth-restricted lambs compared with that in the normally growing lambs, the pattern of GnRH secretion did not directly correspond with that of LH secretion in the growth-restricted group. In addition, high amplitude GnRH pulses that coincided with LH pulses and small, low amplitude GnRH pulses without a concomitant LH pulse occurred. The second study tested the hypothesis that diet-induced hypogonadotropism is the result of actively inhibited central mechanisms by investigating the effects of the nonspecific central nervous system inhibitor, sodium pentobarbital, on pulsatile LH secretion in the growth-restricted lamb. Serial blood samples were collected from 11 ovariectomized lambs that were maintained at weaning weight (approximately 20 kg) by reduced diet. After a 4-h pretreatment period, six of the lambs were anesthetized with sodium pentobarbital for 4 h; the other five lambs were untreated and served as controls. Pentobarbital anesthesia reduced the LH interpulse interval (increased the frequency) and increased mean LH levels. These findings suggest that during growth restriction hypogonadotropism arises from a central inhibition of GnRH neurons and is manifest as a decrease in both frequency and amplitude of GnRH pulses.

Glucose availability modulates the timing of the luteinizing hormone surge in the ewe.

To determine if glucose availability modulates the timing of the positive feedback action of oestrogen on gonadotropin secretion, we monitored the estradiol-induced luteinizing hormone (LH) surge in sheep (n = 5/group) made transiently hypoglycemic by insulin. Experiment 1 determined an effective insulin treatment, one which would depress tonic LH secretion. Two injections of insulin (5 IU/kg iv) 4 h apart were found to induce extended hypoglycemia (10-13 h) and to decrease the LH pulse frequency for 8 h (5.0 +/-0.32 pulses/4 h before versus 2.5+/-0.34 pulses/4 h after insulin; P<0.05; mean +/- SEM). Using this same paradigm, experiment 2 determined the influence of the transient hypoglycemia on the LH surge mechanism. In control sheep, estradiol (subcutaneous implants at hour 0) evoked an LH surge with a latency period of 12.4+/-0.5 h. When insulin was administered either before (hours -4 and 0) or after the estradiol stimulus (hours 4 and 8, or 12 and 16), the onset of the LH surge was delayed to 29.0+/-2.4 h (average of all three time groups, P <0.05). Infusion of glucose from hours 12-30, along with insulin, prevented hypoglycemia and restored the normal timing of the oestrogen-induced LH surge to that of controls (15.4+/-0.93 h, P>0.05). These findings suggest that not only is the tonic mode of LH secretion sensitive to metabolic fuel availability, but the surge mode of LH secretion is as well.

Paraventricular norepinephrine release mediates glucoprivic suppression of pulsatile luteinizing hormone secretion.

Restriction of glucose availability by 2-deoxyglucose (2DG) suppresses pulsatile LH release. The aim of the present study was to determine whether norepinephrine (NE) release in the paraventricular nucleus (PVN) is involved in the glucoprivic suppression of LH secretion in ovariectomized rats. Twelve days after ovariectomy, animals were stereotaxically implanted with a guide cannula for microdialysis in the PVN. Two days later, the PVN was perfused continuously with Ringer's solution or Ringer's solution containing a catecholamine synthesis inhibitor, alpha-methyl-p-tyrosine (100 microM), through a microdialysis probe inserted in the guide cannula 2 h before the beginning of sampling, which lasted 3 h. Blood samples were collected every 6 min through an atrial cannula, and dialysates were collected every 20 min. One hour after the beginning of sampling, 2DG (400 mg/kg BW) was administered iv through the atrial cannula. Paraventricular NE levels significantly increased immediately after 2DG injection (P < 0.05), and both mean LH concentrations and the frequency of LH pulses decreased. By contrast, when alpha-methyl-p-tyrosine was administered into the PVN, 2DG did not produce an increase in paraventricular NE, and no depression of LH secretion occurred. These results suggest that the PVN mediates the glucoprivic suppression of LH pulses via the release of NE.

Reduction of glucose availability suppresses pulsatile luteinizing hormone release in female and male rats.

Glucose availability controls reproductive activity through modulation of LH secretion. The aim of the present study was to determine whether the glucoprivic suppression is potentiated by gonadal steroids and if glucoprivic suppression of pulsatile LH release is sexually differentiated. Pulsatile LH secretion was examined in rats after peripheral (jugular) administration of the competitive inhibitor of glycolysis, 2-deoxyglucose (2DG). Fourteen days after gonadectomy, blood samples were collected every 6 min for 3 h. One hour after the onset of sampling, 2DG was administered peripherally (200, 400, or 800 mg/kg BW, iv), and food intake was determined after 2DG injection in gonadectomized males and females in the presence or absence of sex steroids (testosterone or estradiol). To test the ability of the pituitary to produce LH under glucoprivic conditions, LHRH was injected every 30 min for 2.5 h in ovariectomized (OVX) rats 30 min after treatment with 400 mg/kg 2DG. At all peripheral doses of 2DG in females and at the middle and high doses of 2DG in males, mean plasma LH and LH pulse frequency decreased (P < 0.05) in the presence of steroids. However, in the absence of sex steroids, the lowest dose in females and the middle dose in males were not effective. Pituitary function appeared normal, because increases in mean plasma LH in response to the exogenous LHRH occurred in OVX rats treated with the middle dose of 2DG. Food intake significantly (P < 0.05) increased after 2DG injection in all groups except estrogen-treated OVX females at the low and high doses of 2DG. These findings suggest that glucoprivic suppression of LH pulses is potentiated by gonadal steroids in both sexes. Moreover, the hypothalamo-hypophyseal axis of the female rat seems to be more sensitive to the decreased glucose availability induced by 2DG than that of the male.

Suppression of luteinizing hormone pulses by restriction of glucose availability is mediated by sensors in the brain stem.

The availability of metabolic fuels such as glucose is known to influence reproductive function. Peripheral administration of 2-deoxyglucose (2DG), a competitive inhibitor of glycolysis, inhibits pulsatile LH secretion in the rat and growth-retarded lamb. We hypothesized that such glucoprivic suppression of LH secretion is mediated by the lower brain stem, because studies of both ingestive and reproductive behavior implicate lower brain stem structures, such as the area postrema, as a site that is sensitive to glucose availability. In the present study, the effect of a 2DG infusion, targeted to the fourth ventricle, on pulsatile LH secretion was examined in male rats. The males were castrated or castrated and immediately implanted with testosterone. Blood samples were collected through an indwelling atrial cannula every 6 min for 4 h for LH determination. After the first hour of blood sampling, 2DG (4 or 40 mg/kg) was infused into the fourth ventricle at a flow rate of 0.2 microliter/min through a cannula that had been stereotaxically implanted 1 week before sampling. The high dose of 2DG (40 mg/kg), but not the low dose (4 mg/kg), suppressed pulsatile LH secretion and increased food intake in both castrated and testosterone-treated castrated rats. LH secretion and food intake were not affected by the infusion of xylose (40 mg/kg) as an isoosmotic control. The site specificity of the 2DG treatment was confirmed by histological examination after an isovolumetric infusion of dye (0.2 microliter/min). These results suggest that glucose availability could influence LH secretion as well as feeding through a central sensor in the lower brain stem and are consistent with the idea that the area postrema might be an important glucosensor involved in the modulation of LH secretion.

Metabolic interfaces between growth and reproduction. V. Pulsatile luteinizing hormone secretion is dependent on glucose availability.

To test the hypothesis that mechanisms controlling the secretion of LH are modulated by glucose availability, the acute effects of glucoprivation were studied. The model was the gonadectomized male lamb raised on a limited diet of artificial milk. The approach was to monitor LH secretion before and after the administration of a competitive antagonist of glucose metabolism, 2-deoxyglucose (2DG). We first determined whether LH secretion was influenced by glucose availability by administering 2DG at several doses. Peripheral administration of the glucose antagonist (240 and 480 mg/kg 2DG, single iv injection) transiently decreased LH pulse frequency, but not LH pulse amplitude. By contrast, LH secretion (frequency or amplitude) was not affected by lower doses (60 or 120 mg/kg) of the glucose antagonist. A second study was conducted to determine whether either the pituitary gland or the GnRH neurosecretory system per se is directly affected by short term glucoprivation. The competency of the pituitary was assessed by administering GnRH during the time when LH secretion is suppressed by pharmacological glucose blockade. Similarly, the function of the GnRH neurosecretory system was assessed by administering a GnRH secretagogue (N-methyl-D,L-aspartate) under the same glucoprivic conditions. In response to an optimized iv dose of 2DG, LH pulse frequency decreased. However, in lambs that received either GnRH or N-methyl-D,L-aspartate during the period of glucoprivation, LH pulse frequency was sustained at levels comparable to those before 2DG was given. To determine whether the effect of glucoprivation was central in origin, the glucose antagonist was administered into the lateral cerebral ventricle at 1/100th the doses used peripherally. Central administration of 2DG, independent of dose, transiently decreased LH pulse frequency, but not pulse amplitude. However, unlike the case with peripheral injection, plasma glucose values did not change after the administration of any dose of 2DG tested centrally. These findings indicate that glucose availability in the developing sheep influences LH secretion. Moreover, based upon analysis of LH pulse frequency, glucoprivation does not directly impair either the pituitary gland or the GnRH neurosecretory system. Collectively, these results suggest that glucose availability affects LH secretion by acting within the central nervous system at a detection site(s) peripheral to the GnRH neuron.

Hypothalamic versus pituitary stimulation of luteinizing hormone secretion in the prepubertal female lamb.

Glutamate and aspartate have been hypothesized to function as neurotransmitters in the regulation of the gonadotropin-releasing hormone (GnRH) neurosecretory system. We, therefore, determined if hypothalamic stimulation of luteinizing hormone (LH) secretion in the intact prepubertal female lamb could be achieved by intravenous injection of N-methyl-D,L-aspartate (NMA), a glutamate agonist. A pilot study determined a dose of NMA that would induce physiologic pulses of LH (GnRH). Subsequently, we compared the ability of NMA with exogenous GnRH to induce ovulation in the prepubertal lamb when administered chronically. Eighteen prepubertal lambs (21 weeks of age, 34.2 +/- 1.5 kg body weight) were treated intravenously with either NMA (2 mg/kg, n = 6) or GnRH (68 ng/injection or approximately 2 ng/kg, n = 6) for 3 days, every 2 h on day 1 and every 1 h on days 2 and 3, or received no treatment (controls, n = 6). Gonadotropin surges were detected only in GnRH-treated lambs (5/6 lambs, onset = 54.0 +/- 4.5 h from the start of study, mean +/- SE). Compared to 83% of GnRH injections inducing LH pulses, only 47% of NMA injections induced LH pulses. Because each injection of NMA did not induce a pulse of LH, a second experiment was performed in an attempt to optimize the LH response to NMA. Ten prepubertal lambs (25 weeks of age) were injected every 2 h for 24 h with higher doses of NMA, either 4 mg/kg (n = 5) or 16 mg/kg (n = 5).(ABSTRACT TRUNCATED AT 250 WORDS)

Metabolic interfaces between growth and reproduction. IV. Chronic pulsatile administration of growth hormone and the timing of puberty in the female sheep.

Puberty in the female lamb is accompanied by an increased frequency of LH pulses, and during normal development this is preceded by a decline in GH. Conversely, in the growth-retarded lamb, when LH levels are depressed by low nutrition, GH secretion is elevated. Based upon this inverse relationship, we tested the hypothesis that GH may act as a metabolic signal from the brain to inhibit the secretion of LH, and that the decline in GH times puberty. Our approach was to extend high circulating GH levels far beyond the early postnatal period, in a physiological pattern and level, in an attempt to block the pubertal LH rise. To evaluate the pattern of LH as a continuous variable under conditions of constant estradiol negative feedback, the gonadotropin was measured in blood samples collected by jugular venipuncture twice weekly; the lambs were ovariectomized and treated chronically with estradiol (Silastic capsule) beginning at 3 weeks of age. Nine lambs served as untreated controls, and 7 were infused iv with pituitary-derived bovine GH (bGH) between 5 and 28 weeks of age. A programmable backpack infusion pump delivered bGH as hourly pulses, with a total dose of 18 micrograms/kg.24 h, to maintain a physiological pattern and level of GH. At various ages, blood samples were collected at 12-min intervals for 6 h to monitor patterns and levels of peripheral LH and GH. Circulating GH in untreated and treated lambs averaged 7.7 +/- 1.5 ng/ml over a 6-h period at 4 weeks of age and declined to 1.1 +/- 0.2 ng/ml by 19 weeks in the untreated lambs; in contrast, bGH-infused lambs averaged 10.4 +/- 0.9 ng/ml at 19 weeks. Although body weights did not differ, back fat depth and quantity of perirenal fat were reduced in bGH-treated females compared to that in controls. Moreover, insulin-like growth factor-I levels were higher in bGH-treated compared with control lambs, and the bGH-treated lambs exhibited glucose intolerance, thus confirming that infused bGH was biologically active. Neuroendocrine sexual maturity, however, was not different in bGH-treated and control lambs, and it occurred at 21-22 weeks of age. The results do not support our hypothesis that decreasing GH secretion is a requirement for puberty in the sheep. Moreover, unlike in children with delayed puberty, exogenous bGH did not advance normal puberty in the lamb.(ABSTRACT TRUNCATED AT 400 WORDS)

Prenatal androgens time neuroendocrine sexual maturation.

The present study determined whether exposure to gonadal steroids in utero dictates the postnatal control of gonadotropin secretion in the lamb. There is a marked sex difference in the timing of neuroendocrine sexual maturation in sheep; while male lambs undergo a reduction in sensitivity to inhibitory gonadal steroid feedback by 10 weeks of age, females remain hypersensitive until 30 weeks. The hypothesis was tested that prenatal androgens advance the time of the decrease in feedback sensitivity, and hence the pubertal increase in pulsatile gonadotropin secretion. Pregnant ewes were injected each week with 100 mg testosterone cypionate im from 30-90 days of gestation (term is approximately 150 days). Five female lambs were born with masculinized external genitalia (penis and scrotum). These females, together with eight androgenized males, eight control males, and eight control females, were gonadectomized at 2 weeks of age and implanted with a Silastic capsule of estradiol to produce a constant steroid feedback signal. Blood samples were collected twice weekly to monitor trends in LH secretion. For determination of LH pulse frequency, samples were collected frequently (every 12 min for 4 h) at various intervals between 5 and 32 weeks of age. In males, a sustained increase in LH from biweekly blood samples, indicative of reduced sensitivity to inhibitory steroid feedback, began at 10.1 +/- 1.4 weeks (mean +/- SE) of age in control males and at 5.4 +/- 0.1 weeks in androgenized males. By contrast, control females remained hypersensitive much longer as evidenced by the delay in the LH rise until 27.2 +/- 0.8 weeks. The response of the five androgenized females was intermediate; LH increased at 4, 7, 16, 20, and 21 weeks of age with an early increase of LH being associated with more pronounced masculinization of the genitalia. Patterns of pulsatile LH secretion reflected differences in serum LH measured from biweekly blood samples. For example, at 20 weeks of age, before the pubertal LH rise in female lambs, no pulses were evident in control females, whereas LH pulse frequency averaged 1.6 +/- 0.7 pulses/4 h in androgenized females. At this age, postpubertal males had 2.8 +/- 0.5 LH pulses/4 h. These results lead to the conclusion that in the sheep, prenatal androgens can masculinize patterns of gonadotropin secretion, and that the timing of reproductive neuroendocrine maturation after birth is programmed by androgens in utero.

Metabolic interfaces between growth and reproduction. III. Central mechanisms controlling pulsatile luteinizing hormone secretion in the nutritionally growth-limited female lamb.

Growth retardation induced by dietary restriction in the lamb results in a low frequency of episodic LH secretion and, thus, delayed puberty. Such lambs respond normally to physiological doses of GnRH, indicating that the pituitary gland can function adequately during diet-induced hypogonadotropism. The current studies investigated central mechanisms underlying diet-induced hypogonadotropism. The first aim was to determine whether the hypothalamic GnRH secretory system is capable of normal function. The initial approach was to compare hypothalamic GnRH content between lambs on a restricted diet with low LH pulse frequency (less than 1 pulse/4 h; n = 5) and lambs on an ad libitum diet with high LH pulse frequency (4.5 +/- 0.4 pulses/4 h; n = 5). RIA of extracts of preoptic area and mediobasal hypothalamus/median eminence tissue blocks revealed no differences in GnRH content between lambs on a restricted diet and those on an ad libitum diet. The second approach was to determine if LH secretion could be induced by chemical stimulation of neuronal function with N-methyl-D,L-aspartate (NMA), an excitatory amino acid agonist. Initially, a single iv bolus of NMA was given to hypogonadotropic lambs on a restricted diet. There was a dose-dependent immediate rise in serum LH concentrations. All lambs responded to the highest dose (5.0 mg/kg BW; n = 6), and four of five lambs responded to the intermediate dose (1.0 mg/kg). No lambs responded to the lowest dose (0.2 ng/kg), despite a normal response to GnRH (2.5 ng/kg BW, iv). In a second experiment, hypogonadotropic lambs on a restricted diet were treated with repeated injections of NMA (5 mg/kg BW, iv) at either hourly intervals (n = 6) or every 3 h (n = 6). Each NMA injection induced a LH pulse in both treatment regimens over the entire 7-h experimental period. Thus, the nutritionally growth-limited lamb is capable of sustained production of LH pulses, which, we presume, reflect GnRH secretion. The second aim was to test the hypothesis that endogenous opioid mechanisms inhibit LH secretion during nutritionally induced hypogonadotropism, because opioid pathways are a poor inhibitory regulator of LH secretion in the normally developing sheep, even in the absence of ovarian steroids. We were unable to detect any effects of the opiate antagonist naloxone on LH secretion in the nutritionally growth-limited lamb. We conclude that central mechanisms controlling the release, rather than synthesis, of GnRH are limiting LH secretion when sexual maturation is delayed by growth retardation. Moreover, opioid inhibition is not the primary reason for hypogonadotropism during dietary restriction.

Metabolic interfaces between growth and reproduction. I. Nutritional modulation of gonadotropin, prolactin, and growth hormone secretion in the growth-limited female lamb.

The acute and long term effects of dietary restrictions on gonadotropin secretion were studied in ovariectomized female lambs. Nutritionally growth-restricted lambs which were chronically maintained at a body weight comparable to that at weaning (approximately 20 kg) became hypogonadotropic, exhibiting a low frequency of episodic LH discharges. Repeated administration of physiological doses of GnRH to these females at hourly intervals produced corresponding LH pulses, leading to the hypothesis that the dietary-induced hypogonadotropism arises from a deficiency in endogenous GnRH release, rather than an inability of the pituitary gland to secrete gonadotropins in response to hypothalamic stimulation. In such growth-restricted females receiving a single meal daily, initiation of ad libitum feeding led to a spontaneous LH pulse within 1 h. After 14 days of increased food intake, hourly LH pulses were evident; a marked reduction in LH pulse frequency was associated with the return to limited nutrition. No effects on pulse amplitude were evident. Changes in circulating FSH followed a pattern similar to that for LH, namely an increase in concentration with improved nutrition and a decrease with reduced nutrition. The rate of response of FSH secretion to these alterations in nutrition was slower than that for LH. PRL levels were not altered by changes in nutrition, and a clear annual rhythm of secretion was observed. GH concentrations changed inversely with the level of nutrition; high secretion was associated with periods of restricted feeding, and low secretion with increased nutrition. These findings indicate that dietary restriction in the developing female lamb depresses gonadotropin secretion without reducing other anterior pituitary gland secretions, such as PRL and GH. That these changes occur in the absence of the ovaries implies that metabolic and growth-related modulation of neuroendocrine function can occur independently of changes in sensitivity to the feedback actions of ovarian steroids and polypeptides.