Leptin and ghrelin levels in colostrum, milk and blood plasma of sows and pig neonates during the first week of lactation.

Radioimmunology was used to determine leptin and ghrelin levels in sow colostrum and milk in relation to those in sow and neonatal pig blood plasma and to the body weight of piglets during the first week of lactation. The highest concentration of leptin was found in colostrum on the second day of lactation (69.3 ± 6.3 ng/mL). Leptin concentrations in sow plasma were significantly lower than in colostrum/milk (2.19 ± 0.9 ng/mL, P = 0.7692) and were stable in the first 7 days of lactation. Total and active ghrelin concentrations in colostrum/milk were stable in the measured time points (6734 ± 261 pg/mL, P = 0.3397; 831 ± 242 pg/mL, P = 0.3988, respectively). Total ghrelin concentrations in sow plasma were lower than in colostrum/milk. These results indicate that pigs follow a unique species-specific pattern of leptin and ghrelin synthesis, release and existence, and that the mammary gland is an important source of leptin and ghrelin contained in colostrum/milk.

The influence of ovarian factors on the somatostatin-growth hormone system during the postnatal growth and sexual development in lambs.

The aim of the study was to elucidate the effects of ovarian hormones on somatostatin in the hypothalamic neurons and growth hormone (GH) secretion during the postnatal growth and development of sheep. The study was performed on 9-week-old (infantile) lambs that were ovary-intact (OVI) or ovariectomized (OVX) at 39 days of age, and on 16-week-old (juvenile) lambs that were OVI or OVX at 88 days of age. Hormones in neurons and somatotropic cells were assayed with immunohistochemistry and radioimmunoassay. Following ovariectomy, immunoreactive somatostatin was more abundant (p<0.05) in the hypothalamus of infantile lambs, whereas in juvenile lambs it was more abundant (p<0.05) in the periventricular nucleus but reduced (p<0.01) in the median eminence. In contrast to somatostatin in the hypothalamus, the content of immunoreactive GH in the hypophysis was less in OVX infantile lambs, but greater in OVX juvenile lambs (p<0.05). Basal blood serum concentrations of GH were greater (p<0.05) in OVX infantile lambs, whereas in OVX juvenile lambs, mean and basal concentrations of GH and amplitude of GH pulses were less than in OVI lambs (p<0.05). The postnatal increase in body weight was greatest in middle-late infancy (p<0.01). The body weight did not differ (p>0.05) between OVI and OVX lambs. In conclusion, ovarian factors may inhibit the GH secretion in infantile lambs but enhance the GH secretion in juvenile lambs. Transition to puberty, as related to the growth rate, appears to be due mainly to change in gonadal influence on the somatostatin neurosecretion. A stimulation of somatostatin output in the median eminence by gonadal factors in infancy is followed by a stimulation of somatostatin accumulation after infancy. Thus, ovarian factors modulate mechanisms within the somatotropic system of lambs to synchronize the somatic growth with sexual development.

The influence of salsolinol on dopaminergic system activity within the mediobasal hypothalamus of anestrous sheep: a model for studies on the salsolinol-dopamine relationship.

Salsolinol with its derivatives has been considered as a potential neurotoxin for the dopaminergic system in the human and rat brain. Investigating a sheep model for studies on the action of salsolinol within the central nervous system we examined whether this compound is able to affect the hypothalamic neuroendocrine dopaminergic (NEDA) system during its high seasonal activity, when sheep entered to anestrus under the long day conditions. Therefore, salsolinol was infused into the third ventricle of the brain in combination with the in vivo push-pull perfusion of the mediobasal hypothalamus/median eminence (MBH/ME). The effects of this drug on either perfusate noradrenaline (NA) or plasma prolactin concentration were also studied. The infusion of salsolinol resulted in rapid and permanent diminution in dopamine (DA) release into the extracellular spaces of the MBH/ME up to an undetectable level and in the 57% decrease in DA metabolite 3,4-dihydroxyphenylacetic acid concentration, compared to the control. This effect of salsolinol was accompanied by the significant enhancement of the pituitary prolactin release into circulation. The concentration of other DA metabolite, homovanillic acid, as well as NA in the MBH/ME was not affected. Thus, our results in the anestrous sheep underline the role played by salsolinol as a neuromodulator for the hypothalamic NEDA system and as a signal transmitter for the pituitary prolactin release. We suggest that the hypothalamic NEDA system of anestrous sheep during its high secretory activity may be set as a model for studies on the salsolinol-dopamine relationship.

The effect of intracerebroventricular infusions of ghrelin and/or short fasting on the gene expression and immunoreactivity of somatostatin in the hypothalamic neurons and on pituitary growth hormone in prepubertal female lambs. Morphological arguments.

The effect of exogenous ghrelin on somatostatin distribution in the ruminant's hypothalamus has not been yet determined. The aim of the present study was to investigate the consequence of central infusion of ghrelin and/or short fasting on the secretory activity of the somatostatin/GH system in prepubertal female sheep. Animals were randomly divided into three groups, two standard fed and one fasted for 72 h. One standard group and one fasted group were infused icv with vehicle, while the remaining standard group was infused with ghrelin (25 µl/120 µl/h). Infusions were performed for 6 h during three consecutive days; blood samples were collected during the "day 0" (before the infusion) and "day 3" Immediately after the experiment the sheep were slaughtered. Parts of the brains were fixed in situ for further immunohistochemical analysis The remaining brains were frozen for RT-PCR analysis. Fasting and ghrelin infusion elicited the same kind of changes in the secretory activity of the somatostatin/GH system compared to standard fed sheep. The expression of somatostatin mRNA and ir somatostatin in the PEV nucleus and ir stores in the median eminence increased in both these groups compared to standard fed sheep (P<0.001). The population of ir GH pituitary cells decreased (P<0.001), the mean GH plasma concentrations increased in all fasted and ghrelin infused animals between day 0 and day 3 of infusions (P<0.05) compared to the standard fed group. It can be suggested that ghrelin takes part in the mechanisms linking the nutritional status of an organism with an activity of the somatotrophic axis on the level of the CNS by stimulating GH release through suppression of the somatostatin output.

Differential endocrine response in rams to intracerebroventricular infusion of genistein.

The intracerebroventricular infusions of genistein (total 40 mug) were made in male sheep (November) to test its influence on melatonin, growth hormone (GH) and luteinizing hormone (LH) secretion. The analysis of the results encompassed 3 similar periods: before the infusion (afternoon hours) the first (evening hours) and the second (night hours) halves of the treatment. The night plasma concentration of melatonin in genistein-infused rams was significantly lower than that noted during the respective period in vehicle-infused rams. Plasma GH concentration increased significantly in both vehicle- and genistein-infused rams during the night hours, as compared with the concentrations noted during the afternoon and evening, however, genistein significantly stimulated the amplitude of GH pulses in these latter. The LH concentration was significantly lower during the second part of genistein treatment, than in vehicle-infused rams. The frequency and amplitude of LH pulses clearly tended to decrease following genistein infusion. In conclusion, genistein, acting at the central nervous system level in sexually active rams is able to reduce the secretion of melatonin and LH and has also a slight stimulatory effect on the amplitude of GH pulses.

The neuroendocrine events during the ovine growth-promoted maturation: the developmental importance of hypophysiotrophic action of somatostatin in ewes.

The comparison of hypothalamic somatostatin (SRIH)-neuronal systems, hypophyseal somatotroph populations and growth hormone (GH) blood plasma patterns among developmental stages, from infancy until puberty, may help to describe the nature of the hypothalamo-hypophyseal mechanisms underlying the changes in GH on the systemic level leading to the somatic, that is growth and sexual maturity in sheep. The aim of this study was to elucidate (i) developmental importance of hypophysiotrophic action of SRIH, (ii) precise time of maturation of this action and (iii) photoperiodic regulation of the postnatal ontogeny in ewes. The central and peripheral activity of the SRIH-GH axis is described through a sequence of histomorphological and functional changes in Merino ewes born after the summer solstice. The actual time of puberty of these animals was delayed until the following breeding season, when the sheep were 14-month old. Histomorphometric examinations have been made in 21 infantile (preweanling, 12-week old), prepubertal (15- and 22-week old), peripubertal (30- and 52-week old) and pubertal (63-week old) ovary-intact sheep. Functional examinations of the GH plasma levels were determined every 1-2 weeks during the period from the 12th to 63rd week of age. The highest GH level was observed at the 13th week of age, on the beginning of the breeding season. The fluctuations in the GH level just after the winter and summer solstice were detected as the one and only deviation from a rule of uniformly low GH concentrations observed until puberty. The age of the fall in serum GH levels corresponded with the postweaning period and the beginning of the phase of the lower daily live-weight gains (growth rate). Thus, the development of GH secretion was finished before the 15th week of age, that is together with the ending of the transitional infantile/prepubertal period, whereas the maturational processing within the hypothalamo-hypophyseal unit prolonged after the 15th week of age until 22 weeks of age and concerned the role of SRIH as the hypophysiotrophic factor regulating somatic maturation, i.e. attenuating growth. Altogether, the pattern of GH secretion during weaning is important for the shift between infancy and prepuberty depended upon an intensive growth and defined as growth maturation. The maturation of the SRIH-GH axis is finished by 22 weeks of age, independently of photoperiodic influences, whereas the neuroendocrine mechanisms to integrate somatic, that is growth and sexual maturation, are seasonal in nature in the ewe. Our observations confirm the hypothesis of the inherent endogenous rhythm controlling somatic maturation in the sheep.

Central estrogen-like effect of genistein on growth hormone secretion in the ewe.

The present study tested a hypothesis, whether plant-derived genistein influences the secretion of growth hormone (GH) in ewes, acting directly within the central nervous system (CNS). Starting six weeks after ovariectomy, ewes were infused intracerebroventricularly with genistein (n = 5) or 17beta-estradiol (n = 5), both in a total dose of 40 microg/400 microl/4 h, or with a vehicle (control, n = 5). All infusions were performed from 10:00 AM to 2:00 PM and blood samples were collected from 8:00 AM to 8:00 PM at 10-min intervals. Five genistein- and three vehicle-infused ewes were slaughtered the following morning. The plasma GH concentration was assayed by the radioimmunoassay method, and immunoreactivity of GH in the adenohypophysis was determined by immunohistochemistry. In genistein-infused ewes, mean plasma GH concentration was significantly higher during the whole period of infusion than the concomitant concentration in vehicle-infused ewes. However, examining data within group, GH secretion rose gradually, reaching a significant value during the second phase of genistein infusion. In 17beta-estradiol-infused animals, a significant increase in GH concentration was noted during the first two hours of the infusion, in comparison with vehicle-infused and also in comparison with genistein-infused ewes. Although a gradual increase in basic GH secretion continued in all treated groups during the afternoon and evening, mean plasma GH concentrations in genistein- and 17beta-estradiol-infused ewes were still significantly higher than in the vehicle-infused. The percentage of GH-positive cells in the adenohypophysis and the density of immunoreactive material in these cells decreased significantly in genistein-infused ewes, compared to the control, indicating diminished hormone storage. In conclusion, genistein as 17beta-estradiol, is an effective stimulator of GH secretion in ewes and may exert its effect at the level of the CNS.

Does prolactin influence the hypothalamo-pituitary GnRH-LH system in preovulatory-phase ewes?

The effects of prolonged infusions of prolactin (PRL) into the third ventricle of the brain of cycling ewes on the secretory activity of hypothalamic GnRH neurons and pituitary LH cells in the pars distalis during the proestrous day were studied. Mature Blackhead ewes were infused with vehicle (control, n=5) or with prolactin (200 mug/day, n=5) during 4 consecutive days prior to the next spontaneous ovulation. The dose of PRL was infused each day in 4 series of 50 mug/100 mul/h at 30-min. intervals, from 8.30 to 14.00 h. The animals were slaughtered on the 16th (proestrous) day of the estrous cycle immediately after the last infusion and their brains were fixed in situ. Plasma samples were collected for 6 h at 10 min. intervals, on days 12 (before the infusions) and 16 of the cycle. The distribution pattern, number and morphology of GnRH neurons in vehicle- and PRL-infused ewes were found to be similar and typical for the proestrous phase of the cycle. The immunoreactive (ir) GnRH stores in the median eminence were high and similar in both groups. There were no differences between control and PRL-treated ewes in the number or features of irLH cells. The area fraction and optical density for irLH cells and mRNA LHbeta-expressing cells did not differ between control and experimental groups. Irrespective of the kind of infusion, changes in LH secretion during the estrous cycle were similar in control and PRL-infused ewes. Mean plasma LH concentrations were higher (p<0.001) on day 16 compared to day 12 of the cycle. There were no differences in plasma LH concentrations or in the parameters of pulsatile LH secretion between groups. In conclusion, repeated, several-hour-long infusions of PRL into the CNS prior to the next spontaneous ovulation in ewes has no direct effect on the secretory activity of GnRH neurons, and/or the synthesis, accumulation, or tonic release of LH from the pituitary gonadotrophs.

Effects of intracerebroventricular infusion of genistein on the secretory activity of the GnRH/LH axis in ovariectomized ewes.

Phytoestrogens, plant derived estrogen like-compounds exert numerous effects on the reproductive functions of animals. The present study was designed to demonstrate if exogenous genistein infused during the breeding season into the third ventricle of the brain of ovariectomized ewes could affect the secretory activity of the GnRH/LH axis. Two-year-old ovariectomized ewes (n=8) were infused with vehicle (control, n=3) or genistein (10 microg/100 microl/h, n=5) into the third ventricle. The infusions were done from 10.00 to 14.00 h and blood samples collection was performed this day up to 20.00 h and next day from 8.00 to 10.00 h. The animals were slaughtered, thereafter. Immunoreactive (IR) GnRH neurons in the hypothalamus and LH cells in the adenohypophysis were localized by immunohistochemistry. Messenger RNA analyses were performed by nonisotope in situ hybridization using sense and anti-sense riboprobes produced from beta subunits of LH cDNA clones. Plasma LH concentrations were measured by radioimmunoassay. Immunohistochemical analysis revealed that genistein infusion affected the morphology of GnRH neurons evoking a visualization of long axons in the GnRH perikarya and visibly diminished IR GnRH stores in the median eminence. The number of IR LH cells and IR material stored in the adenohypophyses increased in genistein-infused animals, which was confirmed by statistical analysis (P<0.001). The in situ hybridization analyses showed in these ewes the increase of mRNA LHbeta hybridization signal. The changes in LH release in response to genistein infusion had a biphasic character: it decreased within 6 h after infusion and increased 24 h later. Mean concentration of LH and amplitude of pulses measured from the beginning of infusion up to end of the experiment were significantly higher (P<0.05) in genistein-infused ewes compared to vehicle-treatment. In conclusion, our data show that genistein, a phytoestrogen, may effectively modulate GnRH and LH secretion in OVX ewes by acting directly on the CNS. The biphasic character of the LH response is similar to that of estradiol during the breeding season in the ewes.

Effective stimulation of daily LH secretion by the combined treatment with melatonin and naloxone in luteal-phase ewes.

This study was designed to test the hypothesis that melatonin would intensify daily LH release after central blockade of the opiate receptors in sexually active ewes. The intracerebroventricular infusions of vehicle (control), melatonin, naloxone and melatonin in combination with naloxone were made in ewes in the luteal phase of the estrous cycle, from 2:00 P.M. to 5:00 P.M. Blood samples were collected from 11:00 A.M. to 8:00 P.M. at 10-min intervals. The mean plasma LH concentrations were measured before, during and after the infusions. The frequency and amplitude of LH pulses were determined during the whole experimental period. The LH concentrations recorded during melatonin or naloxone infusions were significantly higher than the concomitant concentration in vehicle-infused animals. The mean LH pulse amplitude in melatonin- and naloxone-treated ewes was also significantly higher than in controls. The LH concentration measured during the combined infusion of melatonin and naloxone was significantly higher than that during vehicle infusion. The LH concentration recorded in turn after the treatment was significantly higher than the concomitant concentrations in vehicle-, melatonin- and naloxone-infused animals. The mean LH pulse amplitude in this group was significantly higher than in the vehicle-infused group. These results indicate that blockade of the opiate receptors within the CNS facilitated effective stimulation of daily LH secretion by exogenous melatonin. In conclusion, a relationship between melatonin and endogenous opioid peptides may be crucial in enabling melatonin to exhibit stimulatory action on LH secretion during the luteal phase of the estrous cycle in ewes.

Genistein, a phytoestrogen, effectively modulates luteinizing hormone and prolactin secretion in ovariectomized ewes during seasonal anestrus.

Through binding with estrogen receptors, phytoestrogens, plant-derived estrogen-like compounds, affect numerous reproductive functions. It is not known whether these compounds are capable of evoking effective changes in luteinizing hormone (LH) and prolactin (PRL) secretion in ewes by acting directly within the central nervous system (CNS). The hypothesis studied was that genistein, infused for several hours into the third ventricle, could immediately affect LH and PRL secretion in ovariectomized (OVX) ewes during seasonal anestrus. Two doses of genistein, 1 microg/100 microl/h (total 4 microg, n = 7) and 10 microg/100 microl/h (total 40 microg, n = 7), were infused intracerebroventricularly from 12.00 to 16.00 h and blood samples were collected from 8.00 to 20.00 h at 10-min intervals. Randomly selected ewes were infused with a vehicle (control, n = 5). The mean plasma LH concentration in control ewes was significantly (p < 0.01) higher during infusion of the vehicle than before the infusion. It remained on an insignificantly changed level after the infusion. The frequency of LH pulses in control ewes did not differ significantly before, during, or after vehicle infusion. In ewes infused with a lower dose of genistein, plasma LH concentrations decreased significantly (p < 0.001) after the infusion, as compared with the values noted before and during genistein infusion. Only a tendency towards a decrease in LH pulse frequency occurred after infusion of a lower dose of genistein. In ewes infused with a higher dose of genistein, the plasma LH concentration decreased significantly (p < 0.01) after phytoestrogen administration as compared with the values noted before and during infusion. The frequency of LH pulses was also significantly (p < 0.01) lower after genistein administration. Because the changes in PRL secretion were more dynamic in response to genistein infusion, the statistical analysis included 2-hour periods. The mean plasma PRL concentration in control animals was significantly enhanced (p < 0.01) only during the first 2-hour period of sampling. After that it decreased and remained on an unchanged level up to the end of sampling. Similar changes in PRL secretion were observed in both experimental groups before genistein infusion. In contrast, significant (p < 0.01 to p < 0.001) increases in PRL concentration were noted regularly during and shortly after the genistein infusion in either low-dose or high-dose genistein-infused ewes, compared with the concentrations noted before genistein treatment. Plasma PRL concentrations during and after genistein infusion in both experimental groups were also significantly higher than the control (p < 0.01 to p < 0.001). The presented data demonstrate that genistein, a phytoestrogen, may effectively modulate LH and PRL secretion in OVX ewes by acting within the CNS.

Influence of dietary fatty acids composition, level of dietary fat and feeding period on some parameters of androgen metabolism in male rats.

The aim of the present study was to determine the effect of the composition of dietary fatty acids, the duration of feeding period and dietary fat level on androgen metabolism in male rats. One hundred and twelve Wistar rats were divided into 18 groups which were fed three diets containing different types of fat (rapeseed [R], palm [P] and fish [F] oil) at either normal fat level (w/w; 5%) or high fat level (20%) during one, three or six weeks. Blood plasma level of androgen (testosterone+dihydrotestosterone) and testicular activity of 17beta-hydroxysteroid dehydrogenase (17beta-HSD) were investigated. In addition, androgen content in cytosol of the heart, the target organ, was measured. Androgen concentration in both blood plasma and heart cytosol extracts was measured by radioimmunoassay. The activity of 17Beta-HSD was expressed as a conversion of [3H]androstendione to [3H]testosterone in soluble fraction of gonadal homogenates. Plasma androgen concentration was influenced by a type of dietary fat (p<0.05). The highest plasma level of androgen was observed in animals fed R diets rich in unsaturated fatty acids. Significantly lower androgen concentration was demonstrated in rats fed P diets rich in saturated fatty acids. Only the feeding period factor significantly influenced androgen content in cytosol fraction of heart muscle cells (p<0.01). A positive correlation was found between plasma androgen concentration in plasma and cytosol fraction of the heart muscle cells (r=0.63, p<0.001). The feeding period (p<0.001) and dietary fat type (p<0.05) significantly affected the activity of 17beta-HSD. The least 17beta-HSD activity was observed in animals consuming the P-20% diet for six weeks. In summary, dietary fat type and feeding period, but not fat level, significantly affected both testosterone production and testosterone uptake by the target organ in male rats. It was found that a rapeseed diet rich in unsaturated fatty acids stimulated the testicular function in rats.