Hypothalamic receptors of sex hormones in the mechanism of the sexual differentiation of the brain in rats

Studies have been made on the content of receptors of estradiol (E2) and testosterone (T) in cytoplasmic and nuclear fractions of the hypothalamus of male and female rats during neonatal development, as well as in adult females after androgenization in neonatal period and adult males castrated within 3 days of postnatal life. It was shown that both E2 and T are present in the blood serum of male and female newborn rats. In female hypothalamus, only E2 receptors were found, whereas in males both types of receptors were revealed, their content being higher than in females. In adult animals subjected to changes in the level of sex hormones in the blood during early neonatal period, changes in concentration of the receptors in the hypothalamic centres of regulation of tonic and cyclic secretion of gonadotropins were found. The data obtained presumably reveal the role of receptors of sex hormones in sex differentiation of the brain.     

Differential effects of the perinatal steroid environment on three sexually dimorphic parameters of the rat brain

Gonadectomy of male rats was performed at 0, 6-7 (6h), 12-13 (12h), or 24 h postnatally in order to examine the influence of testosterone exposure on sexual differentiation of the brain. The indices examined were: the volume of the sexually dimorphic nucleus of the preoptic area (SDN-POA) and luteinizing hormone (LH) and follicle-stimulating hormone (FSH) titers following estradiol benzoate (EB) and progesterone (P) administration. Control animals were sham-operated at 0 h and gonadectomized at 29 days of age (sham). A decrease in the percentage of males with elevated plasma LH levels following P was found with increasing delay before gonadectomy. Significant (P less than 0.001) differences existed in the amplitude of plasma LH titers 5 h following P administration between sham, 0 h, and 6 h groups. Follicle-stimulating hormone was also elevated in all neonatally gonadectomized male groups following P administration, but there was no difference between the groups. Volume of the SDN-POA was significantly (P less than 0.001) smaller in all gonadectomized males when compared to that of sham-operated males, but no differences existed between males gonadectomized at the different hours postpartum. In female rats gonadectomized at 0 h (F0h), LH levels were elevated 5 h following P, but only to a magnitude of 36% of that of sham-operated controls (P less than 0.001). Volume of the SDN-POA of the F0h group was significantly reduced (P less than 0.05) when compared to that of sham females. Thus, in males, the presence of the tests prenatally may be responsible for the initiation of masculinization of LH release mechanisms and the SDN-POA, but both require further androgen exposure for their completion. In addition, the LH and FSH regulating systems show a differential sensitivity to the steroid hormone environment during development that shapes the animal's response to steroid as an adult.     

A Working Module for the Neurovascular Unit in the Sexually Dimorphic Nucleus of the Preoptic Area

The neurovascular unit (NVU) can be conceptualized as a functional entity consisting of neurons, astrocytes, pericytes, and endothelial and smooth muscle cells that operate in concert to affect blood flow to a very circumscribed area. Although we are currently in a “golden era” of bioengineering, there are, as yet, no living NVUs-on-a-chip modules available and the development of a neural chip that would mimic NVUs is a seemingly lofty goal. The sexually dimorphic nucleus of the preoptic area (SDN-POA) is a tiny brain structure (between 0.001~0.007 mm³ in rats) with an assessable biological function (i.e., male sexual behavior). The present effort was undertaken to determine whether there are identifiable NVUs in the SDN-POA by assessing its vasculature relative to its known neural components. First, a thorough and systematic review of thousands of histologic and immunofluorescent images from 201 weanling and adult rats was undertaken to define the characteristics of the vessels supplying the SDN-POA: its primary supply artery/arteriole and capillaries are physically inseparable from their neural elements. A subsequent immunofluorescent study targeting α-smooth muscle actin confirmed the identity of an artery/arteriole supplying the SDN-POA. In reality, the predominant components of the SDN-POA are calbindin D28k-positive neurons that are comingled with tyrosine hydroxylase-positive projections. Finally, a schematic of an SDN-POA NVU is proposed as a working model of the basic building block of the CNS. Such modules could serve the study of neurovascular mechanisms and potentially inform the development of next generation bioengineered neural transplants, i.e., the construct of an NVU neural chip.     

Onset of the hormone-sensitive perinatal period for sexual differentiation of the sexually dimorphic nucleus of the preoptic area in female rats

The volume of the sexually dimorphic nucleus of the preoptic area (SDN-POA) of the rat brain is severalfold larger in males than in females. The volume of the SDN-POA can be influenced significantly by the hormonal milieu during the perinatal "critical period" of sexual differentiation of the brain. The purpose of the present study was to determine the onset of this period of sexual differentiation of the SDN-POA. Pregnant rats received no treatment or were injected subcutaneously with oil on day 17, 18, or 20, or testosterone (T;5 mg) on days 16-22 of gestation. On postnatal day 15, unilateral SDN-POA volumes from female offspring prenatally exposed to testosterone on day 16 or 17 were not different from values of control (untreated or oil-injected) offspring. Female offspring from mothers treated with testosterone on day 18, 19, or 20 of gestation showed a significant and similar increase in SDN-POA volume over values from control animals. SDN-POA volumes from female offspring exposed to testosterone on day 21 or 22, although larger than those of controls, were not different statistically. We conclude that with the specific paradigm used in this study SDN-POA development is insensitive prior to day 18 of gestation, the day on which the onset of the hormone-sensitive period occurs.     

Sexual experience interacts with steroid exposure to shape the partner preferences of rats

A three-phase experiment manipulated sexual experience and hormone exposure (perinatally and in adulthood) in female rats housed individually from weaning so as to limit peripubertal social and sexual experience. Noncontact partner preference for a male or estrous female rat was measured both before and after sexual experience, first while rats were under the influence of circulating testosterone propionate (TP) and later after priming them with ovarian hormones (estradiol benzoate and progesterone; EB & P). When implanted with TP capsules and tested while sexually naive, all groups of female rats preferred females to males without differing statistically. However, following three sexual experience sessions with estrous females, differences emerged between the masculinized and control groups in the magnitude of their female-directed preference, with masculinized females demonstrating a significantly greater preference for estrous females. Sexual experience with male rats under EB & P did not result in a significant shift in preference in any group. Histological assessment indicated that the volume of the sexually dimorphic nucleus of the preoptic area (SDN-POA) was increased by exposure to TP postnatally, and SDN-POA volume correlated positively with partner preference scores but only when rats were both sexually experienced and exposed to circulating TP in adulthood. These results suggest that sexual experience interacts with steroid exposure to shape partner preference.     

A simplified method for the preparation of rat thyroxine-binding prealbumin. Factors influencing its circulating level

Rat thyroxine-binding prealbumin (TBPA) was isolated in three simple steps by means of a serum precipitation by a 5% phenol solution and two consecutive semi-preparative polyacrylamide gel electrophoreses. The overall yield was 15% and the TBPA preparation contained less than 1% impurities. In addition a monospecific antiserum was raised in the rabbit. In polyacrylamide gel, rat TBPA, as with its human counterpart, migrated anodally to albumin while in agarose gel, its electrophoretic mobility was similar to that of albumin. Serum TBPA measured in adult male Wistar rats did not exhibit a circadian rhythm. However, a significant 13% decrease was observed between 9 and 15 h, followed by the restoration of the initial value by 21 h. TBPA concentration was measured in 1-, 15- and 28-day-old male and female pups as well as in adult rats. The level of this protein increased from 1 to 28 days of age and did not display any sexual difference. Yet, while TBPA concentrations in adult males were similar to those recorded in the 28-day-old pups, for adult females, they returned to the levels measured in the 1-day-old pups.     

A mixture of the "antiandrogens" linuron and butyl benzyl phthalate alters sexual differentiation of the male rat in a cumulative fashion

Prenatal exposure to environmental chemicals that interfere with the androgen signaling pathway can cause permanent adverse effects on reproductive development in male rats. The objectives of this study were to 1) determine whether a documented antiandrogen butyl benzyl phthalate (BBP) and/or linuron (an androgen receptor antagonist) would decrease fetal testosterone (T) production, 2) describe reproductive developmental effects of linuron and BBP in the male, 3) examine the potential cumulative effects of linuron and BBP, and 4) investigate whether treatment-induced changes to neonatal anogenital distance (AGD) and juvenile areola number were predictive of adult reproductive alterations. Pregnant rats were treated with either corn oil, 75 mg/kg/day of linuron, 500 mg/kg/day of BBP, or a combination of 75 mg/kg/day linuron and 500 mg/kg/day BBP from gestational Day 14 to 18. A cohort of fetuses was removed to assess male testicular T and progesterone production, testicular T concentrations, and whole-body T concentrations. Male offspring from the remaining litters were assessed for AGD and number of areolae and then examined for alterations as young adults. Prenatal exposure to either linuron or BBP or BBP + linuron decreased T production and caused alterations to androgen-organized tissues in a dose-additive manner. Furthermore, treatment-related changes to neonatal AGD and infant areolae significantly correlated with adult AGD, nipple retention, reproductive malformations, and reproductive organ and tissue weights. In general, consideration of the dose-response curves for the antiandrogenic effects suggests that these responses were dose additive rather than synergistic responses. Taken together, these data provide additional evidence of cumulative effects of antiandrogen mixtures on male reproductive development.     

NELL2 participates in formation of the sexually dimorphic nucleus of the pre-optic area in rats

Formation of the sexually dimorphic nucleus of the pre-optic area (SDN-POA) in the rat hypothalamus shows a sexually differential development of neurons. Volume of the SDN-POA in males is much bigger than that in females which is because of a neuroprotective effect of estradiol converted from circulating testosterone during a critical period of brain development. We found that neural epidermal growth factor-like like-2 (NELL2), a neural tissue-enriched protein, is a potential downstream target of estrogen. In this study, we examined a possible role of NELL2 in the development of the SDN-POA and in the normalcy of sexual behavior in the male rats. NELL2 was expressed and co-localized with estrogen receptor alpha in the SDN-POA. A blockade of NELL2 synthesis in the brain during postnatal day 0 (d0) to d4 by an intracerebroventricular injection of an antisense NELL2 oligodeoxynucleotide, resulted in a decrease in volume of the SDN-POA in males. Interestingly, it reduced some components of the male sexual behavior such as mounting and intromission, but not the sexual partner preference in adulthood. In vitro study using the hippocampal neuroprecursor HiB5 cells showed that NELL2 has a protective effect from a cell death condition. These data suggest that a relevant expression of NELL2 in the neonatal brain is important for the estrogen-induced normal development of the SDN-POA and the normalcy of sexual behavior in male rats.     

Effects of polyamines on the release of gonadotropin-releasing hormone and gonadotropins in developing female rats

Polyamines, putrescine (PUT), spermidine (SPD), spermine (SPM), and agmatine (AGM), are polycationic amines related to multiple cell functions found in high concentrations during the development of hypothalamus and pituitary. In previous works, we demonstrated that alpha-difluoromethylornithine (DFMO), an inhibitor of polyamines biosynthesis, induced a delay in puberty of female rats, accompanied by high, sustained follicle-stimulating hormone (FSH) levels during the infantile period. Also, DFMO treatment induced changes in polyamine concentration both in hypothalamus and pituitary of rats, mainly a decrease of PUT and SPD, an increase in SPM, and no change in AGM. In the present work, we investigated the direct effects of polyamines on the secretion of hypothalamic GnRH and pituitary gonadotropins in 6- and 15-day-old female rats. In 6-day-old animals, in vitro incubations with PUT, SPD, and AGM of hypothalami or anterior pituitaries were able to inhibit GnRH, FSH, and leutinizing hormone (LH) secretion, respectively. SPM showed a nonspecific transient inhibitory effect on FSH. When challenged with either high K(+) (hypothami) or GnRH (pituitaries), the tissues incubated in the presence of polyamines showed no differences when compared with their controls. No effects of polyamines in 15-day-old rats in either tissue were observed. Pituitary cell cultures of 6-day-old animals incubated with DFMO for 4 days showed a significant increase in FSH, but not in LH. We conclude that high PUT, SPD, and AGM levels during the first 10 days of life are important for the development of the hypothalamic-hypophyseal unit, probably related to an inhibitory effect on GnRH and gonadotropins. Therefore, polyamine participation, especially PUT and SPD, is of importance in the regulation of GnRH and gonadotropin secretion in the neonatal and infantile periods, critical stages in the establishment of sexual differentiation.     

Neonatal phenobarbital imprinting of rat hepatic microsomal testosterone hydroxylations

The effects of neonatally administered phenobarbital (PB) on adult rat hepatic microsomal metabolism of testosterone were examined in 60-, 90-, and 120-day-old animals. Phenobarbital-induced imprinting was evident at all ages; however, female rats appeared to be more susceptible to the neonatal effects of phenobarbital than did male rats. In 60-day-old female rats, increased testosterone 2α-hydroxylase activity was observed in microsomes from noninduced rats, whereas decreased testosterone oxidation at all positions except 2α and 15β was observed in microsomes from Aroclor 1254-induced rats. The decreased oxidation of testosterone at specific sites in response to Aroclor 1254 induction was quite dramatic, decreasing the activities to near or below control levels. By contrast, phenobarbital-treated 60-day-old males exhibited approximately a twofold increase in Aroclor 1254-induced 16α and 2α-hydroxylase activities. The pattern of changes in testosterone metabolism observed in phenobarbital-treated animals was different at both 90 and 120 days from that at 60 days. Only minor alterations in the oxidation of testosterone were observed in 90-day-old animals of either sex. In 120-day-old animals the greatest effects of neonatal phenobarbital exposure were on Aroclor 1254–induced 16β-hydroxylase activities. In induced female rats 16β-hydroxylase activity was again decreased to noninduced levels, while in induced male rats a fourfold increase in this activity was observed. These results demonstrate that neonatal exposure to phenobarbital can alter both constitutive and Aroclor 1254–induced testosterone metabolism in adult rats and that the effects of neonatal phenobarbital exposure are age and sex differentiated.     

Neutralization of gonadotropin-releasing hormone in neonatal rats with permanent impairment of the hypothalamic-pituitary-testicular axis

Males rats were passively immunized at 5 days of age with a single 0.25 ml i.p. injection of gonadotropin-releasing hormone (GnRH) antiserum. Control animals were given an equal volume of normal rabbit serum (NRS). Serial blood determinations of gonadotropins, testosterone and dihydrotestosterone (DHT) were obtained at intervals ranging from early in life through adult life. Gonadotropin secretion was reduced (P less than 0.025) up to 35 days of age. Androgen secretion (testosterone) was reduced (P less than 0.05) at 10 and 33 days of age. When hCG was given to 54-day-old (young adult), and 100-day-old and 15-month-old animals, testosterone concentrations were similar in both experimental and control groups 1 h after hCG stimulation. As adults, basal gonadotropins were the same in both groups; however, after GnRH stimulation, the GnRH antiserum-treated groups showed an increased gonadotropin response when compared to the NRS control group. In order to determine whether there was an alteration in steroid feedback, other animals were castrated at adult age (approximately 100 days old), and exogenous testosterone was given in increasing increments. However, serum gonadotropins decreased similarly in treated and control groups. These data indicate that a single injection of GnRH antiserum early in life decreased gonadotropin secretion temporarily during prepubertal sexual development and caused a permanent alteration in hypothalamic-pituitary-testicular function.     

Effect of neonatal androgenization on the testosterone feedback sensitivity in adult rats in two lighting conditions

Neonatally androgenized and intact adult male Wistar rats received daily, during 1 week, either testosterone propionate or sesame oil injections in periodic or constant light. Serum and pituitary gonadotropins and hypothalamic LHRH were measured. In periodic light, neonatal androgenization did not change the serum concentration or pituitary contents of gonadotropins, or the hypothalamic content of LHRH. Testosterone injections decreased serum concentration and pituitary content of gonadotropin of intact rats but failed to decrease the pituitary gonadotropin content of neonatally androgenized rats. In constant light, serum FSH was decreased in neonatally androgenized rats. Testosterone injections decreased both serum LH and FSH concentrations of intact rats but only serum LH of androgenized rats. Pituitary gonadotropin and hypothalamic LHRH contents remained unchanged. We conclude that neonatal androgenization renders the male rat hypothalamo-pituitary axis more resistant to changes of testosterone concentration in adulthood. Constant light did not sensitize the neonatally androgenized rats to testosterone, but on the contrary, testosterone injections were less effective in constant than in periodical light.     

The effect of neonatal exposure to diethylstilbestrol, genistein, and zearalenone on pituitary responsiveness and sexually dimorphic nucleus volume in the castrated adult rat.

The neonatal hormone environment determines the sexually differentiated pattern of brain growth. Estrogens, derived from intracerebral aromatization of testosterone, promote male sexual central nervous system (CNS) development. Developing animals may also encounter estrogens from plant, fungal, and xenobiotic sources (environmental estrogens). The purpose of this study was to assess the effects of environmental estrogens on the physiology and morphology of the hypothalamus and pituitary. Neonatal rats received injections of either corn oil, 0.1 microgram diethylstilbestrol (DES), 100 micrograms genistein (G100), 1000 micrograms genistein (G1000), 100 micrograms zearalenone (Z100), or 1000 micrograms zearalenone (Z1000) on Days 1-10 of life and were castrated on Day 21. On Day 42, right heart catheters were placed, GnRH (50 ng/kg) was administered, and blood was sampled for LH at 0, 5, 10, 15, and 30 min. Females exposed neonatally to DES, G1000, Z100, and Z1000 showed significantly decreased pituitary responsiveness to GnRH, whereas G100 increased GnRH-induced LH secretion. Males exposed neonatally to G100 also showed increased pituitary response to GnRH, and the remaining estrogen-exposed groups of males exhibited either decreased tonic LH or attenuated GnRH-stimulated LH secretion. The animals were killed by decapitation on Day 49. Volumes of the sexually dimorphic nucleus of the preoptic area (SDN-POA) of the exposed groups were compared. In females, DES, G1000, and Z1000 increased SDN volume; Z100 and G100 had no effect. There was no difference in SDN size among the male groups. These data show that exposure to environmental estrogens early in development alters postpubertal pituitary response to GnRH and "androgenizes" the SDN-POA.     

Anogenital distance and umbilical cord testosterone level in newborns in Zaria, Northern Nigeria

The anogenital distance (AGD) is the distance between the anus and the base of the penis in males and anus to fourchette (AF) distance in females and is a sexually dimorphic index that, on average, is twice as great in males as in females, so it is used as an indicator of appropiate masculine development. In this study, the anogenital distance (AGD) and anthropometric measurements such as birth weight, birth length, head circumference and placenta weight of 200 newborns (100 male, 100 female) were taken and umbilical cord serum was assayed for testosterone concentration using Radioimmunoassay (Microwell). Data obtained were analysed using Student t-test and Pearson's Correlation Analysis as applicable. Results revealed that mean total anogenital distance was 22.53±0.70mm, and it was significantly higher in males: 31.11±0.64mm than in females: 13.89±0.26mm and we observed that there was positive correlation between birth weight and AGD in females. In males head circumference correlated positively with AGD. The mean cord testosterone concentration was 2.78±0.30ng/ml in males and 2.09±0.22ng/ml in females and did not have any significant correlation with anogenital distance. It was concluded that AGD of the population studied, though high was not significantly higher than AGD in other parts of the world and umbilical cord testosterone level did not have any significant effect on AGD. Keywords: Anogenital distance, Ethnicity, Umbilical cord testosterone, Anthropometry.     

Manipulation of androgens causes different energetic responses to cold in 60- and 40-day-old male rats

Previous studies suggested that adults respond differently than pubertal male rats to cold stress. To test the role of androgens in this difference, we adrenalectomized and replaced with corticosterone either 60- or 40-day-old male rats, then sham gonadectomized (Intact), gonadectomized (GDX), or GDX and replaced with testosterone (T; GDX+T) or dihydrotestosterone (DHT). One-half remained at room temperature (RT), and one-half lived in cold for 5 days. Cold reduced T in adult but not in pubertal Intacts. In 60-day-old rats, GDX with or without T replacement had minor effects on body weight (BW) and food intake (FI) at RT and cold. In 40-day-old rats at RT, androgens had slight effects; however, androgens affected almost all variables in cold. Separation of 40-day-old T-treated rats into two groups (moderate T levels, 1.4 ng/ml; high T levels, 1.9 ng/ml) revealed major differences between the groups. Moderate T (and DHT) prevented cold-induced loss of BW and increased FI. No T and high T induced decreased BW and FI in cold. We conclude that at 40 days of age, partial resistance to stress-induced reduction of T and high sensitivity to small changes in T have markedly positive effects on threatened energy balance.     

Early postnatal androgenization imprints selective changes in the action of estrogens in the rat uterus.

Exposure of animals perinatally to some hormonally active agents may imprint permanent changes on the action of related hormones. The present study investigated the effects of early postnatal androgenization on various genomic responses to estrogen in the uterus of prepubertal rats. Female rats were androgenized at postnatal ages of 1, 5, or 13 days with a single s.c. injection of testosterone propionate. At the age of 21 days, the animals were stimulated with estrogens. The uteri of androgenized and control rats were analyzed morphometrically to measure genomic parameters of estrogen stimulation in the uterus. The results demonstrate that early postnatal androgenization does not equally affect all uterine cell types and that the effects of androgenization change according to the age at androgenization. The dissociation between the various responses according to the time of androgenization suggests that there are critical ages at which the uterine cell types that respond to estrogens can be altered permanently by imprinting. The finding of changes in the action of estrogen induced by androgenization at older than neonatal ages in the rat suggests that similar changes may occur in humans exposed to androgens during their extrauterine life. This result also points to the need for further studies using the rhesus monkey because of its close resemblance to the human with respect to female reproductive physiology.     

Stereological evaluation and Golgi study of the sexual dimorphisms in the volume,cell numbers,and cell size in the medial preoptic nucleus of the rat

The medial preoptic nucleus (MPN) and the sexually dimorphic nucleus of the preoptic area (SDN-POA) stand out as prominent sexually dimorphic cell groups of the rat brain. However, quantitative data on sex-related differences in these nuclei in the adult rat are confined to their volume. We have used stereological methods and Golgi-impregnated material to examine whether, in young adult rats, the sexual dimorphism in the volume of the MPN, including its divisions, and of the SDN-POA, reflect similar differences in the number and size of their neurons. We found that the total number of neurons in all MPN divisions is higher and the mean somatic volume larger in males than in females. In addition, the total dendritic length of MPN neurons is greater, but the dendritic spine density is smaller, in males than in females. Likewise, in the SDN-POA the total number and size of its neurons is greater in males than in females. The sex differences in all quantitative parameters evaluated accounted for the larger volume of the MPN and SDN-POA in males relative to females. In addition, the MPN neuropil also displays sex-related differences in its volume, and these differences closely match those detected for the volume of each MPN division. It deserves to be emphasised that the numerical density of neurons was the only parameter found to be significantly higher in females than in males in all MPN divisions and in the SDN-POA. Our results show that the MPN and the SDN-POA display sex differences in the volume, total number of neurons, and size of neuronal cell bodies and dendritic trees. Furthermore, they also indicate that the neuropil is critical for the establishment of sexual dimorphism in the size of the MPN.     

Neonatal treatment of male rats with a gonadotropin-releasing hormone antagonist results in altered function of the pituitary-testicular axis in adult age

In most mammals, pituitary-testicular hormone secretion is very active during the perinatal period, but the physiological significance of this function for later pituitary-gonadal interactions and sexual maturation is largely unknown. Short-term neonatal treatment with gonadotropin-releasing hormone (GnRH) antagonist results in delayed sexual maturation and infertility in male rats. We have now extended our earlier findings and studied in more detail the pituitary-gonadal function in adult rats after such neonatal treatment. In this study, the pituitary-testicular activity of newborn male rats was temporarily blocked by treatment with a GnRH antagonist analogue (N-Ac-4-Cl-D-Phe1, 4-Cl-D-Phe2, D-Trp3, D-Phe6, des-Gly10-GnRH-D-alanylamide; Organon 30039; 2 mg/kg s.c. twice daily) on Days 1-5 of life. Timing of puberty was slightly delayed in the treated rats (average: 2 days, p less than 0.05), as determined by the age of the balano-preputial separation. In adult rats (90-110 days), only 3 of the 17 rats treated neonatally with GnRH antagonist were fertile (14 of 17 controls, p less than 0.01), despite normal circulating androgen levels. Pituitary and serum follicle-stimulating hormone (FSH) levels were slightly but consistently elevated (20-30%; p less than 0.05) in antagonist-treated animals, whereas luteinizing hormone (LH) levels (both immunoreactive and bioactive) were unaffected. The pituitary contents of GnRH receptors were increased in antagonist-treated animals 85 +/- 6.6 (mean +/- SEM, n = 19) vs. 58 +/- 4.1 fmol/gland in controls (n = 20; p less than 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)     

Potent GnRH agonists containing L-amino acid derivatives in the six position

New agonists related to gonadotropin-releasing hormone (GnRH) have been synthesized that are comparable in potency to the GnRH and its superagonists for release of LH and estrus suppression without substitutions with D- or unnatural amino acids in position 6. We now report a series of L-beta-aspartyl-6 GnRH analogs containing only naturally occurring L-amino acids in the whole sequence, exhibiting considerable in vivo biological activity. Dose and time dependent LH release capability of the different analogs in adult male mice, estrus suppression comparisons and blockade of ovulation in female rats are given. The incorporation of L-Asp-OMe and L-Asp-OBzl in position 6 of GnRH resulted in the most potent GnRH agonists (to 12-20xGnRH potency) in this series inducing a biphasic biological response similar to the D-amino acid-6 substituted superactive GnRH analogs. A correlation between the LH releasing potencies of the analogs and their HPLC retention times was also investigated. Peptide synthesis were achieved using either solid phase or solution phase methodology.     

Effects of galanin-like peptide (GALP) on locomotion, reproduction, and body weight in female and male mice

Galanin-like peptide (GALP) has been implicated in the neuroendocrine regulation of both feeding and reproduction. In male rodents and primates, intracerebroventricular (icv) infusions of GALP stimulate luteinizing hormone (LH) release, induce Fos expression in brain areas implicated in feeding and reproduction, and affect food intake and body weight in rodents. In gonad-intact and castrated male rats, icv administration of GALP also stimulates male sexual behavior. While the effects of GALP on male physiology and behavior are well documented, no studies have addressed such a role of GALP in females. We tested the effects of icv GALP infusions on LH release, locomotor activity, motor control, and body weight regulation in adult ovariectomized female mice hormonally primed with estradiol benzoate and progesterone. In addition, sexually-experienced male and female mice were treated with GALP and tested for sexual behavior. In females, GALP reduced open-field locomotor activity, the ability to maintain grip on an accelerating rotarod, and 24-h body weight in a dose-dependent manner. GALP also increased LH secretion in female mice, an effect that was blocked by pre-treatment with Antide, a gonadotropin-releasing hormone (GnRH) type-1 receptor antagonist. GALP infusions slightly decreased the occurrence of lordosis behavior in female mice and significantly increased the latencies with which females displayed receptivity. Unlike previous reports in male rats, GALP inhibited male sexual behavior in mice. Our data indicate that in female mice, GALP stimulates LH release via GnRH, and decreases body weight, motor control, and locomotor activity via GnRH-independent pathways. Furthermore, our sexual behavior and locomotor findings suggest species-specific differences in the mechanism and/or location of GALP action in the brains of rats and mice.