Disruption of GnRH pulses by anti-GnRH serum and phentolamine obliterates pulsatile LH but not FSH secretion in ovariectomized rabbits.

It has been hypothesized that the secretion of gonadotropins, i.e. luteinizing hormone (LH) and follicle-stimulating hormone (FSH), is driven by a synchronized neural network ('pulse generator'). This network, regulated in part by alpha-adrenergic activity, ultimately generates bursts of hypothalamic gonadotropin-releasing hormone (GnRH) release. In this study, we used the push-pull (PP) perfusion technique in ovariectomized rabbits to investigate three aspects of the ('GnRH/gonadotropin pulse generator') hypothesis. The objectives were to determine: (1) if plasma LH and FSH pulses occur concomitantly with mediobasal hypothalamic (MBH-) GnRH pulses, (2) changes in the patterns of pulsatile LH and FSH secretion when pulsatile MBH GnRH signals are interrupted by either local immunoneutralization of GnRH or intravenous infusion of the alpha-adrenergic antagonist phentolamine (PHEN, 4 mg/kg BW), and (3) whether third cerebroventricular (3VT-) GnRH patterns reflect neuronal GnRH release from the MBH. We found that while both plasma LH and FSH patterns were pulsatile, MBH GnRH pulses were significantly coupled only with LH pulses (94% coincidence). Both the local immunoneutralization of MBH GnRH pulses and the PHEN-induced suppression of MBH GnRH pulses obliterated the pulsatile secretion of LH, but not FSH. Neither MBH GnRH nor plasma LH or plasma FSH pulses were concurrent with 3VT GnRH pulses. However, the PP perfusion of the 3VT appeared to alter the pulsatile release of MBH GnRH and pituitary LH. The results support the hypothesis that in the absence of ovarian signals, the 'pulse generator' is maintained by tonic alpha-adrenergic input and that a 'cellular unity' of MBH GnRH release (GnRH pulses) drives the gonadotrophs to secrete LH in pulses. In contrast, the pulsatile release of FSH appears to involve additional nonovarian regulatory events to those controlling LH secretion.

The short-duration response to apomorphine: implications for the mechanism of dopaminergic effects in parkinsonism.

The pharmacological basis of the short-duration response to dopaminergic stimulation in parkinsonism is not completely understood. Whereas it is generally assumed that the response reflects concurrent dopamine receptor occupancy, it is also possible that receptor activation triggers events that outlast the time that receptors are occupied by agonist. To distinguish between these two possibilities, we administered apomorphine, a mixed D1-D2 agonist with rapid equilibration between plasma and brain, to patients with parkinsonism. The clinical response to apomorphine injections lagged behind peak plasma concentrations and persisted beyond the time plasma concentrations following ineffective doses. We conclude that dopaminergic stimulation triggers effects that outlast the period of receptor occupancy by agonist. Understanding these steps may offer new pharmacological therapies for parkinsonism.

L-dopa pharmacokinetics in plasma and cisternal and lumbar cerebrospinal fluid of monkeys.

The pharmacokinetics of levodopa (L-dopa) in plasma and in cisternal and lumbar cerebrospinal fluid (CSF) were studied in Rhesus monkeys that were given 2- to 3-hour intravenous infusions of L-dopa. Steady-state L-dopa concentrations in cisternal CSF correlated well with plasma levels, and yielded a CSF:plasma ratio of 0.17. The disappearance of L-dopa from plasma and cisternal CSF compartments fits an open, two-compartment pharmacokinetic model. Although slower, the distribution and elimination half-lives for L-dopa from cisternal CSF (8.9 and 49.2 minutes, respectively) were of a similar magnitude to those from plasma (4.9 and 33.2 minutes, respectively). If cisternal CSF reflects brain extracellular fluid, then plasma pharmacokinetics of L-dopa are a reasonable approximation of those in the brain. In contrast to cisternal CSF, the disappearance of L-dopa from lumbar CSF fits an open, one-compartment model with an elimination half-life of 100 minutes. This indicates that the lumbar CSF compartment is unsuitable for investigation of the pharmacokinetics of L-dopa in the brain.

Acute administration of estrogen suppresses LH secretion without altering GnRH release in ovariectomized rhesus macaques.

The pattern of hypothalamic gonadotropin-releasing hormone (GnRH) release was examined during estrogen (E)-induced suppression of plasma luteinizing hormone (LH) in ovariectomized (OVX) rhesus macaques. In Expt. 1, 4 OVX macaques were fitted with a jugular catheter and a push-pull cannula (PPC) directed into the median eminence (ME). Push-pull perfusion (PPP) was initiated 10 h before and continued for 10 h after subcutaneous estradiol benzoate (EB) injection (42 micrograms/kg b.wt.). In Expt. 2, 4 additional monkeys were subjected to local intrahypothalamic perfusion with estradiol-17 beta (E2, 3 microM) for the last 10 h of a 20-h PPP. In Expt. 2, OVX animals were challenged with 5 micrograms exogenous GnRH 3 h before and 8 h after EB injection to test for changes in altered LH release. Integrated 10-min ME perfusate and intermittent 10- or 60-min peripheral plasma samples were assayed for GnRH and LH by radioimmunoassay and bioassay, respectively. In addition, 2 other OVX macaques that received similar ME-PPC placement were sacrificed 2 days after the completion of a PPP for immunocytochemical labeling of GnRH neurons at the perfusion site. The results show that after EB, hypothalamic GnRH (MBH-GnRH) release remained unaltered while LH levels declined rapidly (Expt. 1). Similarly, intrahypothalamic perfusion of E2 failed to change the pattern of MBH-GnRH release in any of 4 monkeys (Expt. 2). Conversely, plasma LH release in response to exogenous GnRH was greatly reduced after EB (Expt. 3).(ABSTRACT TRUNCATED AT 250 WORDS)

Collection and quality of rhesus monkey semen.

Electroejaculation is an accepted method of semen collection from nonhuman primates. Although both penile and rectal probe stimulation techniques have been used, there has been a general lack of consistency and detail regarding their application. This report describes the collection, processing, and evaluation of rhesus monkey semen contrasting two methods of penile electroejaculation: 1) a constant-voltage method where stimulus current is a variable and 2) a constant-current method where stimulus current is operator-controlled. The constant-current method was the more efficient procedure, requiring a lower stimulus current for successful electroejaculation. The influence on semen quality of potentially toxic agents used in the procedure, surgical glove powder and electrolyte cream, was tested; both were detrimental as measured by motility loss. No correlation was found between coagula volume and sperm numbers. The intra- and interanimal variability in semen samples from six monkeys was also evaluated. Penile electroejaculation, combined with control of stimulus current, provides a consistent, successful, and humane method for the collection of semen in the rhesus monkey.

Suppression of mediobasal hypothalamic gonadotropin-releasing hormone and plasma luteinizing hormone pulsatile patterns by phentolamine in ovariectomized rhesus macaques.

In gonadectomized animals, pulses of LH are secreted concurrently with pulsatile hypothalamic GnRH and it is hypothesized that pulses of GnRH are either driven or modulated by episodes of catecholamine release. The objective of this study was to determine if the alpha-adrenergic antagonist phentolamine (PHEN) can simultaneously block the release of GnRH and LH in ovariectomized (OVX) rhesus macaques. In Exp 1, simultaneous peripheral blood and mediobasal hypothalamic push-pull perfusion (PPP) samples were collected remotely at 10-min intervals for 24 h via a swivel/tether device in eight conscious, freely moving OVX rhesus monkeys. Phentolamine was continuously infused iv for 6 h at the rate of 4 mg/kg BW.h in five animals and 20 mg/kg BW.h in three animals. Infusion started at 6 h after the commencement of PPP. Sampling of PPP and blood continued for 12 h after the cessation of PHEN infusion. Exp 2 was carried out to determine if PHEN affects pituitary responsiveness to exogenous GnRH under conditions similar to those in Exp 1. Exogenous GnRH (5 micrograms, iv) was injected as a single bolus at 10-h intervals before, during, and after either a saline (4 ml/h for 6 h) infusion or, 3 weeks later, a PHEN infusion (4 mg/kgBW.h for 6 h) in three OVX females. The results of Exp 1 show that pulsatile patterns of hypothalamic GnRH and LH were either dampened or abolished by PHEN infusion. During the recovery period after PHEN infusion, pulse amplitudes of LH were enhanced, but pulse amplitudes of endogenous GnRH did not differ, as compared to those of corresponding LH and GnRH before infusion of PHEN. Data from Exp 2 suggested that the alpha-adrenergic blocking agent had no effect on the pituitary LH response to exogenous GnRH administration. These results directly support the hypothesis that adrenergic neuronal activities are critical for the pulsatile release of hypothalamic GnRH which governs the pulsatile release of LH in gonadectomized animals.

Effects of estrogen on hypothalamic gonadotropin-releasing hormone release in castrated male rhesus macaques.

The evidence that hypothalamic gonadotropin-releasing hormone (GnRH) release increases during the estrogen-induced luteinizing hormone (LH) surge in castrated female macaques and that estrogen induces a similar LH surge in the male suggests that either sexual differentiation of GnRH secretion does not exist or that changes in brain GnRH are not critical for ovulation. We tested this hypothesis by using the push-pull perfusion (PPP) technique to monitor GnRH release in the mediobasal hypothalamus continuously from 10 h before to 50 h after estrogen injection in 9 castrated male rhesus macaques. Blood sampling and PPP were performed with monkeys freely moving in their own cage by using a specially designed swivel/tethering system. PPP samples were collected every 10 min and analyzed for GnRH concentration by radioimmunoassay. Blood samples were collected every hour and plasma LH was measured by bioassay. Estradiol benzoate (EB, 42 micrograms/kg, b. wt.) was subcutaneously injected after 10 h of initial PPP. The PPP was continued for 10 h after EB in 4 and 50 h after EB in 5 monkeys. Hypothalamic GnRH patterns were analyzed by the Pulsar algorithms. The results show that during the 10 h after EB, plasma LH declined rapidly, reaching low or non-detectable levels by 7-9 h, while hypothalamic GnRH releasing patterns did not change during this period (n = 9). In contrast, estrogen enhanced GnRH level and pulse amplitude, but not pulse frequency, several hours before mean peripheral plasma LH increased from suppressed values (n = 4).(ABSTRACT TRUNCATED AT 250 WORDS)

Chronic push-pull brain perfusion in unrestrained rhesus macaques.

A system was developed to permit perfusion of local brain regions and simultaneous peripheral blood sampling in free-moving caged monkeys. The system comprises a calvarial headpiece that contains multiple push-pull cannulas (PPC), a flexible stainless steel tether, a four-channel fluid swivel, and a surgical procedure for simultaneous multisite brain cannulation. Rhesus macaques were fitted surgically with an indwelling jugular catheter and PPC directed into the third ventricle, median eminence, and preoptic area. These animals were tethered for periods of 14-70 h during which brain perfusates and peripheral blood samples were collected at 10- to 30-min intervals through the tether-swivel assembly. Levels and pulsatile patterns of gonadotropin-releasing hormone in 10-min perfusate samples and luteinizing hormone and cortisol in sequential plasma samples were quantified by specific radioimmunoassays. The normal endocrine profiles in these animals suggest that this system provides a valuable method to study patterns of neurosecretions in an unrestrained simian.

Loss of enhanced nocturnal growth hormone secretion in aging rhesus males.

Enhanced nocturnal release of GH is decreased with aging in man, a change that may implicate GH in a general decline in anabolic metabolism associated with aging. The aim of this study was to determine whether nonhuman primates experience an age-related reduction in plasma GH levels by comparing the 24-h patterns of GH secretion in unrestrained young and aged male rhesus monkeys. Six young (8 yr old) and six aged (22+ yr old) intact rhesus males were fitted with indwelling jugular catheters, cranial platforms, and stainless steel cable tethers. Catheters passed from a swivel device at the top of each cage through a wall to an adjoining room. On four occasions, 1.0-ml blood samples were obtained from each male every 20 min for 24 h for plasma GH RIA. Plasma GH data were analyzed by the PULSAR program to detect hormone peaks. Mean 24-h plasma GH was less (P less than 0.0005) in aged males [0.84 +/- 0.04 ng/ml (+/-SEM)] than in young males (1.37 +/- 0.09 ng/ml). Likewise, the amplitudes of GH pulses were less (P less than 0.001) in aged males than in young males. Although no circadian pattern of GH concentrations was apparent in either age group, young males displayed more (P less than 0.05) nocturnal GH pulses (5.73 +/- 0.41 pulses/12 h) than those occurring during lights-on (3.09 +/- 0.32 pulses/12 h). The numbers of GH pulses in aged males (4.00 +/- 0.63 pulses/12 h) were similar to those in young males during lights-on, but aged males showed fewer (P less than 0.05) nocturnal GH pulses (4.27 +/- 0.47 pulses/12 h) than did young males. The duration of GH pulses in aged males (53.6 +/- 5.0 min) was similar to that in young males (50.6 +/- 5.0 min) during lights-off. Young males showed an extended (P less than 0.001) GH pulse duration (88.8 +/- 8.8 min) during lights-on that was not evident in aged males (66.2 +/- 5.4 min). These data demonstrate that unrestrained young rhesus males experience an enhanced nocturnal release of GH in terms of pulse frequency, and as in humans, this enhanced nocturnal release of GH is diminished with age. In addition, rhesus males experience, as do humans, a reduction in circulating GH levels as a function of age.

The androgen status of aging male rhesus macaques.

Whether the rhesus male experiences changes in the dynamics of testosterone (T) and LH secretion with age was investigated in six young (6-8 yr old; 7-12 kg) and six aged (22+ yr old; 9-11 kg) intact rhesus males. Each male was fitted with an indwelling jugular catheter, which was attached to a cranial platform and stainless steel cable tether. Catheters passed from a swivel device at the top of each cage through a wall to an adjoining room. On four occasions, 1.0-ml blood samples were obtained from each male every 20 min for 24 h for plasma T RIA and plasma LH bioassay. Plasma T and LH data were analyzed by the PULSAR program to detect hormone peaks. Mean 24-h plasma T levels were similar in young and aged males as were the pulse amplitudes of T; however, the pulsatile pattern of T concentrations was different between young and aged males. Young males displayed a marked nocturnal increase in both T concentration and number of T pulses. Aged males demonstrated a significant nocturnal elevation of plasma T concentration, but displayed a significant nocturnal diminution in both concentration and numbers of T pulses compared with young males at night. Although LH concentrations and the total number of LH pulses per 24 h were similar in young and aged males, marked age-related alterations were evident in the pulsatile pattern of LH levels. Unlike young males, aged males failed to display a daytime reduction in the number of LH pulses. Our data point to coexistent changes in hypothalamic sensitivity to the negative feedback effects of T and testicular responsiveness to LH as a function of age in the rhesus macaque.

Release rates of catecholamines, GABA and beta-endorphin in the preoptic area and the mediobasal hypothalamus of the rhesus monkey in push-pull perfusates: correlation with blood hormone levels.

Push-pull cannulae were implanted into the preoptic area and into the mediobasal hypothalamic median eminence complex of ovariectomized rhesus monkeys. After recovery, perfusion of the implanted areas was performed over a period of 56 h before and following estradiol benzoate treatment. This treatment results in a drop of LH levels followed by an increase. Catecholamine (norepinephrine, epinephrine and dopamine) concentrations in perfusates collected at 15 min intervals fluctuated tremendously prior to treatment with the estrogen. These fluctuations were largely reduced in perfusates of both structures following the estrogen treatment. They reoccurred at the time of increasing LH levels. beta-endorphin and GABA concentrations were also measured in the perfusates of both structures. Occasional secretory bursts were observed without any obvious relation to the estrogen treatment. It is concluded that catecholamine release in the preoptic area and in the mediobasal hypothalamic median eminence complex is of a pulsatile nature in ovariectomized rhesus monkeys. This pulsatility is largely reduced or abolished following estrogen treatment. The reduced pulsatility may bear a signal character for the release of LH.

In vivo gonadotropin-releasing hormone release and serum luteinizing hormone measurements in ovariectomized, estrogen-treated rhesus macaques.

The push-pull perfusion technique was used to measure GnRH release in unanesthetized female rhesus macaques (Macaca mulatta) and to examine the dynamic relationship between GnRH release and LH levels during the estrogen-induced LH surge. Each ovariectomized macaque was anesthetized and stereotaxically fitted with a push-pull cannula directed into the median eminence (ME). After at least 1 week of recovery, each animal received an estradiol benzoate (E2B) injection (42 micrograms/kg BW) or an oil (OIL) injection and underwent push-pull perfusion of the ME and blood sampling for at least 5 h between 28 and 56 h postinjection. Continuous 10-min push-pull perfusates were collected and prepared for GnRH RIA. Peripheral venous blood samples were obtained either hourly or every 10 min, and serum LH levels were determined by Leydig cell bioassay. GnRH release was detectable and pulsatile in areas in or adjacent to the ME or arcuate nucleus. In eight OIL monkeys, GnRH pulses were regular (approximately one pulse every 60 min) and of low amplitude (14.7 +/- 12.0 pg), with a mean GnRH release rate of 4.0 +/- 1.7 pg/10 min. In five E2B-treated monkeys, GnRH release during the rising phase of the LH surge occurred as an apparent burst of high amplitude GnRH pulses. The mean GnRH release rate (37.5 +/- 17.9 pg/10 min) and mean GnRH pulse amplitude (170.0 +/- 90.0 pg) during the 5 h before the peak LH level in E2B-treated monkeys were greater than OIL values (P less than 0.025, mean release; P less than 0.05, mean amplitude). Within individual E2B-treated monkeys, hourly mean GnRH release rates were significantly correlated with LH levels during the ascending limb of the LH surge (r = 0.75 +/- 0.11; P less than 0.025). We have concluded that an increase in GnRH neurosecretion occurs in E2B-treated monkeys and that it is associated with generation of the LH surge. On the basis of our observations, we hypothesize that the primate hypothalamus, through changes in GnRH secretion, actively participates in the E2B-induced LH surge.

Pulsatile secretion of luteinizing hormone during the menstrual cycle of rhesus macaques.

The secretion of LH, PRL, and cortisol was investigated in 4 sexually mature female rhesus macaques with cardiac catheters protected by tethers. Based on endocrine parameters, all 4 of the animals ovulated within 2 months from the time they were tethered, and regular menstrual cycles of 24-34 days were observed. The catheters remained patent for 6-12 months without reposition or repair. Plasma levels of 2 stress-labile hormones, PRL and cortisol, showed diurnal fluctuations comparable to those observed in untethered animals. The frequency of LH secretory episodes was determined by measuring bioactive LH in blood samples collected at 10-min intervals in the follicular phase and at 15-min intervals in the luteal phase of the menstrual cycle. In 10 trials during the follicular phase, we estimated that an average of between 14 and 15 LH pulses occurred every 12 h. The interpulse interval ranged between 20-80 min and averaged 50 min. No change in pulse frequency was observed across the follicular phase. The number of LH pulses decreased after ovulation, and by the end of the luteal phase, the interpulse interval was 4-6 h. One example during the preovulatory LH surge revealed the high frequency, high amplitude nature of LH secretion at that time. Our experience indicates that tethered animals with cardiac catheters show no hormonal indications of stress and represent the best available model for studies requiring frequent and prolonged access to the vascular system. Our data suggest that peripheral LH fluctuations in rhesus monkeys, as in other mammals, are pulsatile, and the frequency of these pulsatile episodes changes with different phases of the menstrual cycle, presumedly in response to varying stimuli to the pituitary from the brain.