The responses of hypothalamic NPY and OBRb mRNA expression to food deprivation develop during the neonatal-prepubertal period and exhibit gender differences in rats

Neuropeptide Y (NPY) is an important hypothalamic orexigenic neuropeptide that acts in the brain. It has been established that the fasting-induced up-regulation of NPY expression is mainly caused by a reduction in the activity of leptin, which is a hormone secreted by adipose tissue. We have reported that in female rats hypothalamic NPY mRNA expression does not respond to fasting during the early neonatal period, but subsequently becomes sensitive to it later in the neonatal period. In this study, we compared the developmental changes in the responses of NPY and leptin expression to fasting between male and female rats during the neonatal to pre-pubertal period. Fasting was induced by maternal deprivation during the pre-weaning period (postnatal days 10 and 20) and by food deprivation during the post-weaning period (postnatal day 30). Hypothalamic NPY mRNA expression was not affected by fasting on postnatal day 10, whereas it was increased by fasting on postnatal day 20 and 30 in both males and females. On the other hand, the serum leptin level was decreased by fasting at all examined ages in both sexes. Namely, hypothalamic NPY mRNA expression was not correlated with the reduction in the serum leptin level at postnatal day 10 in either sex. Under the fasted conditions, the hypothalamic NPY mRNA levels of the males were higher than those of the females on postnatal days 20 and 30, whereas no such differences were observed under the normal nourishment conditions. The serum leptin levels observed under the fasted conditions did not differ between males and females at any examined age. These results suggest that some hypothalamic NPY functions develop during the neonatal period and that there is no major difference between the sexes with regard to the time when NPY neurons become sensitive to fasting. They also indicate that hypothalamic NPY expression is more sensitive to under-nutrition in male rats than in female rats, at least during the pre-pubertal period.     

Changes in the responsiveness of serum leptin and hypothalamic neuropeptide Y mRNA levels to food deprivation in developing rats

Neuropeptide Y (NPY) is an important orexigenic peptide that acts in the brain. The increase in hypothalamic NPY mRNA expression induced by fasting is mainly caused by a decrease in the effects of leptin. We investigated the developmental changes in the sensitivities of leptin and hypothalamic neuropeptide Y to fasting. Hypothalamic NPY mRNA levels were increased by fasting in postnatal days 15 and 25 rats, but not in postnatal day 5 rats. Serum leptin levels were decreased by fasting in rats at all ages (days 5, 15, and 25). In addition, hypothalamic OB-Rb mRNA levels were decreased by fasting in postnatal day 25 rats, but not in postnatal day 5 or 15 rats. Although the percentage of fating-induced decrease in the serum leptin level was larger in the postnatal day 15 rats than in the postnatal day 25 rats, the percentage of increase in the hypothalamic NPY mRNA level in the postnatal day 15 rats was smaller than that in the postnatal day 25 rats. There was a strong inverse correlation between serum leptin levels and hypothalamic NPY mRNA levels in the postnatal day 25 rats, whereas no significant correlation was found between these parameters in the postnatal day 5 or 15 rats. These findings indicate that the sensitivity of hypothalamic NPY mRNA expression to food deprivation and hypoleptinemia has developed by postnatal day 25.     

Changes in the responsiveness of hypothalamic prokineticin 2 mRNA expression to food deprivation in developing female rats

Prokineticin 2 (PK2) is highly expressed in several regions of the central nervous system, including the hypothalamus. Recently, it has been suggested that PK2 plays a role in appetite regulation. In adult male rodents, the administration of PK2 decreased food intake, and PK2 mRNA expression was reduced by food deprivation. Usually, the changes in the expression levels of appetite-regulating factors induced in response to fasting are not fully established during the neonatal period. Thus, we investigated the developmental changes in hypothalamic PK2 mRNA expression and the alterations in hypothalamic PK2 mRNA expression induced by fasting during the pre-pubertal period in female rats. The changes in hypothalamic neuropeptide Y (NPY) mRNA expression were also examined because NPY is a potent appetite regulatory factor. Hypothalamic PK2 mRNA expression was extremely high during the early neonatal period (postnatal day (PND) 5) compared with that observed during subsequent periods (PND15, 25, and 42), while hypothalamic NPY mRNA expression did not differ among any of the examined periods. A fasting-induced reduction in hypothalamic PK2 mRNA expression was observed on PND5, but no fasting-induced increase in hypothalamic NPY mRNA expression was seen during the same period. In addition, the fasting-induced reduction in hypothalamic PK2 mRNA expression observed on PND5 was more marked than that seen on PND25. These results suggest that the sensitivity of hypothalamic PK2 expression to undernutrition develops during the early neonatal period, when the responses of other appetite regulatory factors to such pressures remain immature.     

Developmental changes in the hypothalamic mRNA levels of prepro-orexin and orexin receptors and their sensitivity to fasting in male and female rats

Orexin, which is also called as hypocretin (Hcrt), a product of the prepro-orexin (pp-orexin//Hcrt) gene, affects various physiological and behavioral functions, such as the sleep-wake cycle and appetite. The developmental changes in the hypothalamic mRNA levels of pp-prexin and the orexin receptors OX1R and OX2R and their sensitivity to fasting were evaluated in both male and female rats. During development, hypothalamic pp-orexin/Hcrt mRNA expression increased in both male and female rats, whereas hypothalamic OX1R mRNA expression decreased in both sexes. In addition, hypothalamic OX2R mRNA expression increased in male rats, but did not change in female rats. Fasting did not affect hypothalamic pp-orexin/Hcrt mRNA expression in either sex. Hypothalamic OX1R mRNA expression was increased by fasting in the prepubertal period (postnatal days 20 and 30) in female rats, but was not affected by fasting in males. In male rats, hypothalamic OX2R mRNA expression was decreased by fasting during the neonatal period (postnatal day 10), but not the prepubertal period (postnatal days 20 and 30). In females, hypothalamic OX2R mRNA expression was also decreased by fasting; however, the fasting-induced downregulation of hypothalamic OX2R expression persisted until postnatal day 20. These results indicate that the developmental patterns of components of the orexin system and their sensitivity to fasting during the neonatal and prepubertal periods only differ slightly between the sexes. These differences might be involved in the development of some physiological and behavioral functions.     

Prenatal exposure to glucocorticoids affects body weight,serum leptin levels,and hypothalamic neuropeptide-Y expression in pre-pubertal female rat offspring

Glucocorticoid secretion is a key endocrine response to stress. It has been reported that prenatal stress induces long-lasting alterations in body weight regulation systems, which persist after the stress has ceased. In this study, the long-term effects of prenatal glucocorticoid exposure on body weight changes and the expression of appetite-regulating factors were examined in female rats. Pregnant rats were given normal drinking water (control) or dexamethasone (1 μg/mL) dissolved in drinking water (DEX) from day 13 of pregnancy until delivery. Then, the body weight change, serum leptin levels, and hypothalamic NPY mRNA levels of their offspring were examined. The DEX dams gained significantly less body weight during pregnancy than the control dams. The DEX dams’ offspring exhibited a significantly lower birth weight than the offspring of the control dams, and the same was true for body weight at postnatal days 20 and 28. The offspring of the DEX dams displayed significantly higher serum leptin levels and significantly lower hypothalamic NPY mRNA levels compared with the offspring of the control dams. Significant inverse correlations were detected between body weight and the serum leptin level, and between the serum leptin level and the hypothalamic NPY mRNA level. On the other hand, a significant positive correlation was detected between body weight and the hypothalamic NPY mRNA level. These results indicate that leptin production is increased in a long-lasting manner in offspring exposed to glucocorticoids during the prenatal period and that this results in attenuated body weight gain and hypothalamic NPY expression during the pre-pubertal period.     

Developmental changes in hypothalamic toll-like-receptor 4 mRNA expression and the effects of lipopolysaccharide on such changes in female rats

Hypothalamic pro-inflammatory cytokine expression exhibits a weaker response to lipopolysaccharides (LPS) during the early neonatal period than during the later developmental period. Although toll-like receptor 4 (TLR4), which recognizes bacterial molecules, activates pro-inflammatory cytokine responses, the developmental changes in hypothalamic TLR4 expression have not been evaluated. In this study, the hypothalamic TLR4 mRNA levels of saline-injected and LPS-injected rats were measured during the neonatal, pre-pubertal, and post-pubertal periods. The rats’ hypothalamic TLR4 mRNA levels gradually increased from the neonatal to pubertal period and were altered by the injection of LPS at all examined ages (postnatal day (PND) 5, 15, 25, and 42). LPS injection resulted in decreased hypothalamic TLR4 mRNA expression at PND5, whereas it increased hypothalamic TLR4 mRNA expression at PND15, 25, and 42. After the injection of LPS, the hypothalamic mRNA levels of the pro-inflammatory cytokines interleukin (IL)-1β, tumor necrosis factor α, and IL-6 were attenuated during the early developmental period and increased acutely on PND42. The expression profiles of these pro-inflammatory cytokines exhibited similar, but not entirely consistent, changes to those displayed by TLR4 during the developmental period. Hypothalamic TLR4 mRNA expression gradually increased throughout the developmental period, whereas the mRNA expression levels of the pro-inflammatory cytokines increased acutely at PND42. Thus, it is assumed that hypothalamic TLR4 hypoactivity contributes to the low sensitivity of pro-inflammatory cytokines to LPS during the early developmental period.     

The effects of prenatal undernutrition and postnatal high-fat diet on hypothalamic Kiss1 mRNA and serum leptin levels

Prenatal undernutrition and postnatal overnutrition increase the risk of some metabolic disorders in adulthood, and hypothalamic leptin resistance makes an important contribution to these effects. Leptin plays important roles in the maintenance of reproductive function, and its actions might be partially mediated by kisspeptin, which is a potent positive regulator of gonadotropin-releasing hormone. In this study, the effects of prenatal undernutrition and postnatal overnutrition on reproductive parameters and sexual maturation during the peripubertal period were evaluated. Rats subjected to prenatal undernutrition (IUGR) and fed a postnatal high-fat diet (HFD) (n = 7) exhibited 40% higher serum leptin levels and 30% lower hypothalamic Kiss1 (the gene encoding kisspeptin) mRNA levels than those subjected to prenatal undernutrition (IUGR) and fed a normal diet (n = 7). No such HFD-induced postnatal alterations were observed in the rats fed a normal diet during the prenatal period (control) (n = 7 per group). Although the consumption of the HFD did not affect the serum luteinizing hormone levels or body weight of the IUGR or control rats, it did promote vaginal opening in both groups (evaluated in 14 rats per group). These findings indicate that hypothalamic leptin resistance might occur in IUGR-HFD rats, but these changes do not influence downstream effectors of the reproductive endocrinological system. They also suggest that the relationships between nutritional conditions, body weight, reproductive factors, and sexual maturation are complex.     

Fasting-induced increases of arcuate NPY mRNA and plasma corticosterone are blunted in the rat experienced neonatal maternal separation

This study was conducted to examine the effects of neonatal maternal separation on the hypothalamic expression of feeding peptides in later life. Pups in maternal separation (MS) groups were separated from their dam for 3 h daily from postnatal day (PND) 1-14, while pups in non-handled (NH) groups were left undisturbed. Rats were sacrificed on PND 60 to examine the gene expression of neuropeptide Y (NPY) and pro-opiomelanocortin (POMC) in the hypothalamic arcuate nucleus by mRNA in situ hybridization. Half of the rats from each group were food-deprived for 48 h before sacrifice. POMC mRNA expression increased in the free fed MS group compared with the free fed NH group. Food deprivation significantly decreased the arcuate POMC mRNA level in both groups. Body weight gain, basal levels of plasma corticosterone, leptin, and arcuate NPY mRNA were not modulated by experience of neonatal maternal separation. However, fasting-induced increases of plasma corticosterone and arcuate NPY expression were blunted in MS rats. These results suggest that neonatal maternal separation may increase the basal expression level of arcuate POMC mRNA, while inhibit the fasting-induced expression of arcuate NPY mRNA, later in life. Lastly, the altered expression of arcuate NPY mRNA, but not of arcuate POMC mRNA, appeared to be related with altered activity of the hypothalamic-pituitary-adrenal gland axis in offspring by neonatal maternal separation.     

Developmental changes in hypothalamic oxytocin and oxytocin receptor mRNA expression and their sensitivity to fasting in male and female rats

Oxytocin (OT) affects the central nervous system and is involved in a variety of social and non-social behaviors. Recently, the role played by OT in energy metabolism and its organizational effects on estrogen receptor alpha (ER-α) during the neonatal period have gained attention. In this study, the developmental changes in the hypothalamic mRNA levels of OT, the OT receptor (OTR), and ER-α were evaluated in male and female rats. In addition, the fasting-induced changes in the hypothalamic mRNA levels of OT and the OTR were evaluated. Hypothalamic explants were taken from postnatal day (PND) 10, 20, and 30 rats, and the mRNA level of each molecule was measured. Hypothalamic OT mRNA expression increased throughout the developmental period in both sexes. The rats’ hypothalamic OTR mRNA levels were highest on PND 10 and decreased throughout the developmental period. In the male rats, the hypothalamic mRNA levels of ER-α were higher on PND 30 than on PND 10. On the other hand, no significant differences in hypothalamic ER-α mRNA expression were detected among the examined time points in the female rats, although hypothalamic ER-α mRNA expression tended to be higher on PND 30 than on PND 10. Significant positive correlations were detected between hypothalamic OT and ER-α mRNA expression in both the male and female rats. Hypothalamic OT mRNA expression was not affected by fasting at any of the examined time points in either sex. These results indicate that hypothalamic OT expression is not sensitive to fasting during the developmental period. In addition, as a positive correlation was detected between hypothalamic OT and ER-α mRNA expression, these two molecules might interact with each other to induce appropriate neuronal development.     

Leptin Regulation of Agrp and Npy mRNA in the Rat Hypothalamus

Agouti-related protein (AGRP) is synthesized in the same neurones in the arcuate nucleus as neuropeptide Y (NPY), another potent orexigenic peptide. AGRP antagonizes the action of alpha-melanocyte stimulating hormone, a derivative of pro-opiomelanocortin (POMC) at the hypothalamic MC4 receptor to increase food intake. Although leptin has been shown to regulate Agrp/Npy and Pomc-expressing neurones, there are differences with respect to Agrp regulation in leptin receptor-deficient mice and rats. Unlike the obese leptin receptor-deficient db/db mouse, which exhibits upregulation of Agrp mRNA expression in the medial basal hypothalamus (MBH) compared to lean controls, the obese leptin receptor-deficient (faf; Koletsky) rat does not exhibit upregulation of Agrp expression. To determine whether this represents a general difference between leptin receptor-deficient mice and rats, neuropeptide gene expression was analysed in the MBH of lean and obese rats segregating for a different leptin receptor mutation, Leprfa (Zucker). Fasting in lean rats (+/fa) for 72 h significantly increased Agrp and Npy mRNA expression, and decreased Pomc mRNA expression as detected by a sensitive solution hybridization/S1 nuclease protection assay. Npy mRNA levels were significantly increased in fed obese fa/fa compared to lean rats, and further increased in the obese animals after fasting. In contrast, Agrp mRNA levels did not differ between fed lean and fed obese rats, and fasting did not significantly change Agrp levels in obese rats. To determine whether the change in Agrp expression that occurs with food deprivation in lean rats could be prevented by leptin replacement, Sprague-Dawley rats were fasted and infused via subcutaneous osmotic micropumps for 48 h with either saline or recombinant mouse leptin. Fasting significantly increased Agrp and Npy, and decreased Pomc mRNA levels. Leptin infusion almost completely reversed these changes such that there was no significant difference between the levels in the fasted rats and those that were fed ad libitum. Thus, in fasted lean rats, Agrp and Npy are upregulated in parallel when leptin levels fall and are downregulated by leptin infusion. By contrast, the absence of a functional leptin receptor results in the upregulation of Npy but not Agrp mRNA.     

Nutritional regulation of hypothalamic leptin receptor gene expression is defective in diet-induced obesity

Leptin action in the hypothalamus plays a critical role in maintaining normal food intake and body weight. Hyperleptinaemia is associated with obesity in humans and animal models, suggesting a state of leptin resistance. Although the mechanism of leptin resistance is not clearly understood, alterations in leptin receptor (Ob-R) gene expression have been proposed as a potential mechanism mediating modifications in leptin action in obesity and during changes in nutritional status (fed/fasted). The current study examined the effects of diet-induced obesity (DIO) made by feeding rats a high fat diet for 9 weeks, and nutritional status on levels of long form (Ob-Rb) and total (Ob-Rtot) Ob-R mRNA expression in the hypothalamus. In the fed state, hypothalamic Ob-Rb mRNA and Ob-Rtot mRNA levels were similar in DIO and control standard chow fed rats (SC) despite hyperleptinaemia in DIO rats. However, although an overnight fast moderately increased hypothalamic Ob-Rb mRNA levels in SC rats, fasting did not increase Ob-Rb mRNA levels in DIO rats. To address the possibility that elevated leptin concentration in DIO rats may mediate an alteration in OB-R mRNA levels, we examined the effects of adenovirus-mediated hyperleptinaemia on Ob-R gene expression in SC rats. Despite substantially elevated plasma and cerebrospinal fluid concentrations of leptin, hypothalamic Ob-R mRNA levels were similar in both groups. In conclusion, the current study demonstrates that DIO is associated with a loss of nutritional regulation of hypothalamic Ob-R mRNA levels, and that hyperleptinaemia is not sufficient to alter Ob-R mRNA expression.     

Changes in responsiveness of appetite, leptin and hypothalamic IL-1β and TNF-α to lipopolysaccharide in developing rats

In addition to its role as a regulator of energy homeostasis, leptin plays a pivotal role in some immune/inflammatory responses. Synthesis and secretion of leptin are increased under immune stress conditions, and increased leptin may participate in the development of anorexia and fever. These actions are partially mediated by up-regulation of hypothalamic IL-1β. Leptin also protects against immune stress-induced lethality. On the other hand, the response and roles of leptin to immune stress conditions in the neonatal period have scarcely been examined. We hypothesized that 1. the response of leptin to immune stress would be suppressed in the early neonatal period, 2. hyporesponse of leptin in the early neonatal period would attenuate the anorectic response and increase the lethal rate under immune stress conditions and 3. supplementation of leptin in the early neonatal period would increase the anorectic response, whereas it would decrease the lethal rate under immune stress conditions. To test these hypotheses, we first examined the developmental changes in the responses of leptin and hypothalamic proinflammatory cytokines, i.e., IL-1β and TNF-α, to LPS-induced immune stress in female rats. We also examined the developmental changes in the anorectic response and lethality rate under LPS-induced immune stress conditions. Five- and 15-day-old rats showed no leptin response and a weak hypothalamic IL-1β response to LPS when compared with 25- and 42-day-old rats. Fifteen-day-old rats showed low anorectic responses and high lethality rates when compared with 25- and 42-day-old rats under LPS-induced immune stress conditions. We then examined whether administration of leptin affected the response to the anorectic and lethal effects of LPS in 15-day-old rats. Administration of leptin further attenuated body weight after LPS injection, but not after saline injection. On the other hand, administration of leptin did not affect survival rate. In addition, hypothalamic IL-1β mRNA levels were not affected by leptin administration. In conclusion, the absence of a leptin response may act to prevent immune stress-induced anorexia during the early neonatal period.     

Disruption in neuropeptide Y and leptin signaling in obese ventromedial hypothalamic-lesioned rats

Electrolytic lesions placed in the ventromedial hypothalamus (VMH) of rats induce instant hyperphagia and excessive weight gain. Since neuropeptide Y (NPY) is a potent hypothalamic orexigenic signal, and leptin secreted by adipocytes regulates NPY output, we tested the hypothesis that altered NPYergic-leptin signaling may underlie hyperphagia in VMH-lesioned rats. VMH-lesioned rats exhibiting hyperphagia and excessive weight gain in a time-related fashion were sacrificed on days 2, 7, and 21 post-surgery. Quite unexpectedly, NPY concentrations in the hypothalamic paraventricular nucleus (PVN), a major site of NPY release for stimulation of feeding, and in other sites, such as the dorsomedial nucleus, lateral hypothalamic area and median eminence-arcuate nucleus decreased, with the earliest diminution occurring on day 2 in the PVN only. In vitro basal and K⁺-evoked NPY release from the PVN of VMH-lesioned rats was significantly lower than that of controls. Analysis of hypothalamic NPY gene expression showed that although the daily decrease in NPY mRNA from 0800 to 2200 h occurred as in control rats, NPY mRNA concentrations were markedly reduced at these times in the hypothalami of VMH-lesioned rats. Leptin synthesis in adipocytes as indicated by leptin mRNA levels was also profoundly altered in VMH-lesioned rats. The daily pattern of increase in adipocyte leptin mRNA at 2200 h from 0800 h seen in controls was abolished, higher levels of leptin gene expression at 2200 h were maintained at 0800 h. The pattern of increase in serum leptin and insulin levels diverged in VMH-lesioned rats. Serum insulin concentration increased to maximal on day 2 and remained at that level on day 21-post-lesion; serum leptin levels on the other hand, increased slowly in a time-related fashion during this period. These results demonstrate that hyperphagia and excessive weight gain in VMH-lesioned rats are associated with an overall decrease in hypothalamic NPY and augmented leptin signaling to the hypothalamus. The divergent time course of increases in serum leptin and insulin levels suggest independent mechanisms responsible for their augmented secretion, and neither these hormones nor VMH lesions altered the daily rhythm in NPY gene expression. These observations underscore the existence of an independent mechanism controlling the daily rhythm in hypothalamic NPY gene expression and suggest that leptin feedback action requires an intact VMH.     

Persistent Effects of Maternal Deprivation on HPA Regulation Can Be Reversed By Feeding and Stroking, But Not By Dexamethasone

Maternal deprivation of neonatal rats for 24 h has immediate and persistent effects on hypothalamic-pituitary-adrenal (HPA) regulation. Immediately after deprivation corticosterone (CORT) is elevated. The primary purpose of our experiments was to determine if, by preventing this CORT elevation, the persistent effects could be reversed. In experiment 1, pups were injected with dexamethasone at the onset of the 24-h deprivation period on postnatal day 11 to suppress the rise in CORT. In experiment 2 some aspects of maternal behaviour known to suppress CORT levels were mimicked during deprivation from postnatal days 11-12. The pups were either: (1) left undisturbed; (2) stroked periodically; or (3) stroked and episodically fed. At postnatal day 20 basal and stress-induced adrenocorticotrophic hormone (ACTH) and CORT levels were measured as well as brain mineralocorticoid (MR) and glucocorticoid receptors (GR). Neonatal rats receiving dexamethasone prior to the onset of the deprivation on day 11 did not differ on day 20 from deprived pups that were exposed to elevated CORT levels. There were no detectable changes in the non-deprived pups that were treated with dexamethasone. In contrast, feeding and stroking during the period of deprivation obliterated the persistent effects both with regard to the reduced ACTH response and the decreased GR mRNA in hippocampus and hypothalamus. Stroking alone appears to have no influence. In conclusion, the persistent reduction of the ACTH response to mild stress and the decrease of GR mRNA is not mediated by deprivation-induced elevations in CORT, but appears to be reversible by reinstating specific aspects of the dam's nurturing behaviour.     

Postnatal development of orexin/hypocretin in rats

We examined developmental changes of orexins/hypocretins and their receptors (OX1R and OX2R) in the rat hypothalamus from postnatal day 0 to 10 weeks, using in situ hybridization histochemistry for the prepro-orexin, OX1R and OX2R mRNAs and immunohistochemistry for orexin-A and orexin-B. The prepro-orexin mRNA was weakly detected in the lateral hypothalamic area (LHA) from days 0 to 15. Orexin-A- and -B-like immunopositive cells and fibers were not detected from days 0 to 10, but they were observed after day 15. The prepro-orexin mRNA in the LHA markedly increased between days 15 and 20. The OX1R mRNA was detected in the ventromedial hypothalamic area (VMH) at day 0. The OX2R mRNA was not detected in the paraventricular nucleus (PVN) at days 0 and 1, but weakly observed on day 5. The OX1R mRNA in the VMH and OX2R mRNA in the PVN gradually increased throughout the postnatal period. Next, we examined the effects of milk deprivation and intraperitoneal (i.p.) administration of leptin on the hypothalamic prepro-orexin mRNA in pups. Although 24-h milk deprivation did not affect the level of the prepro-orexin mRNA at days 5 and 10, i.p. administration of leptin from days 0 to 3 caused a significant increase in the prepro-orexin mRNA on days 5 and 10. These results suggest that the development of orexins may be associated with developmental changes such as increase of leptin, weaning, feeding and sleep/wakefulness states.     

Neonatal Treatment with a Pegylated Leptin Antagonist Induces Sexually Dimorphic Effects on Neurones and Glial Cells,and on Markers of Synaptic Plasticity in the Developing Rat Hippocampal Formation

The present study aimed to better understand the role of the neonatal leptin surge, which peaks on postnatal day (PND)9–10, on the development of the hippocampal formation. Accordingly, male and female rats were administered with a pegylated leptin antagonist on PND9 and the expression of neurones, glial cells and diverse markers of synaptic plasticity was then analysed by immunohistochemistry in the hippocampal formation. Antagonism of the actions of leptin at this specific postnatal stage altered the number of glial fibrillary acidic protein positive cells, and also affected type 1 cannabinoid receptors, synaptophysin and brain‐derived neurotrophic factor (BDNF), with the latter effect being sexually dimorphic. The results indicate that the physiological leptin surge occurring around PND 9–10 is critical for hippocampal formation development and that the dynamics of leptin activity might be different in males and females. The data obtained also suggest that some but not all the previously reported effects of maternal deprivation on hippocampal formation development (which markedly reduces leptin levels at PND 9–10) might be mediated by leptin deficiency in these animals.     

Temporal changes in the expression of brain-derived neurotrophic factor mRNA in the ventromedial nucleus of the hypothalamus of the developing rat brain

Brain-derived neurotrophic factor (BDNF) is a member of the neurotrophin family, which is important for the growth, differentiation, and survival of neurons during development. We have performed a detailed mapping of BDNF mRNA in the neonatal rat brain using a quantitative in situ hybridization technique. At postnatal day (PND) 4, hypothalamic structures showed only modest expression of BDNF mRNA, with the exception of the ventromedial nucleus (VMN), where expression was higher than that detected in the hippocampus. Abundant BDNF mRNA was also found in the bed nucleus of the anterior commissure, retrosplenial granular cortex, and the posteroventral part of the medial amygdaloid nucleus. Messenger RNAs encoding other neurotrophins, including nerve growth factor (NGF) and neurotrophin-3 (NT-3) and the BDNF receptor trkB, were not selectively localized in neonatal VMN. During subsequent developmental stages, BDNF mRNA expression in the VMN changed dynamically, peaking at PND 4 and falling to minimal levels in the adult brain. In contrast, the low levels of BDNF mRNA observed in the CA3 region of the hippocampus increased to adult levels following PND 10. As the VMN undergoes sexual differentiation, we compared BDNF, NGF, NT-3, and trkB mRNA expression in the VMN in males and females at embryonic day 20 and PND 4, but found no differences between them. These results suggest that localized and high level expression of BDNF mRNA in the neonatal VMN plays an important role in its neural organization and functional development.     

Ontogeny and Sexual Differentiation of Somatostatin Biosynthesis and Secretion in the Hypothalamic Periventricular-Median Eminence Pathway

The biosynthesis of somatostatin (SRIH) in the hypothalamic periventricular nucleus (PeN) is sexually differentiated in neonatal and adult rats by virtue of the organizational and activational actions, respectively, of sex steroid hormones. Little information exists, however, on the normal pattern of maturation of these neurones or on how the sexually differentiated biosynthesis may relate to ontogenetic changes in somatostatin secretion during the neonatal and pubertal periods of development. Hence in the present study we determined the postnatal developmental profile of SRIH mRNA and peptide levels in the PeN–median eminence (ME) pathway as well as SRIH secretion, using an acute explant preparation, from the day of birth, through puberty and into adulthood in male and female rats. The results demonstrate that: (1) developmental sex differences in SRIH biosynthesis in PeN neurones occurred in an orderly cascade with differences observed for mRNA expression at postnatal day 5, for peptide content in the perikarya at postnatal day 10 and for peptide content in the nerve terminal (ME) by postnatal day 25; (2) sex differences in SRIH release were not evident prior to postnatal day 40; and (3) the developmental profile of SRIH biosynthesis in PeN neurones is unique compared with other hypothalamic (ventromedial nucleus) and extrahypothalamic (parietal cortex) populations. Specific developmental changes in the biosynthetic and secretory activity of the hypothalamic SRIH PeN–ME pathway may have a functional importance in the maturation of hypothalamic SRIH pathways involved in the regulation of GH secretion.