Effects of leptin and orexin-A on food intake and feeding related hypothalamic neurons

The lateral hypothalamic area (LHA) and the ventromedial hypothalamic nucleus (VMH) have historically been implicated in ingestive behavior, energy balance and body mass regulation. The LHA is more closely associated with the initiation of eating; whereas the VMH mediates the cessation of eating. The parvocellular part of the paraventricular nucleus (pPVN) is also included in the suppressing mechanism. Recently, two hypothalamic peptides, orexin-A and orexin-B, localized in the posterior and lateral hypothalamic perifornical region were discovered in the rat brain and they increase food intake. Leptin, a protein encoded by an obesity gene, expressed in adipose tissue and released into the blood also affects food intake. Orexin and leptin receptors have been localized in the LHA, pPVN, and VMH. The purpose of this study was to measure food intake in the rat in response to leptin and orexin-A; and to determine their electrophysiological effects on feeding related hypothalamic neurons. Results clearly show that leptin suppresses food intake whereas orexin-A increases food intake. These differences are associated with leptin and orexin-A modulatory effects on LHA, pPVN, and VMH glucose responding neurons. In the LHA, leptin inhibits a larger proportion of both glucose-sensitive neurons (GSNs) and non-GSNs. In the pPVN, leptin increases more GSNs in comparison to non-GSNs. Whereas in the VMH, leptin increases the activity of glucoreceptor neurons (GRNs) in comparison to non-GRNs. Orexin-A had opposite effects: increases activity of GSNs more than the non-GSNs in the LHA and significantly suppresses GRNs in the VMH. In the pPVN, orexin-A had no observable effects on neurons that have a low density of orexin 2 receptors. Results are discussed in terms of hypothalamic neural circuits that are sensitive to endogenous food intake inducing and reducing substances.     

妊娠、分娩以及泌乳期大鼠下丘脑中食欲素及其受体表达的变化

目的 观察大鼠下丘脑中食欲素(Orexin)及其受体(OX1R、OX2R)在妊娠、分娩以及泌乳期表达的变化,以探讨Orexin与生殖功能之间的关系.方法 通过竞争性逆转录多聚酶链式反应(Competitive RT-PCR)和免疫组织化学方法测定大鼠下丘脑中Orexin前体(Prepro-OX)、Orexin-A、OX1R和OX2R在妊娠、分娩以及泌乳期的表达.结果 Orexin-A和OX1R阳性神经元主要分别存在于大鼠下丘脑外侧区(LHA)以及妊娠和泌乳期大鼠的下丘脑室旁核 (PVN)和视上核(SON).泌乳第1d的Prepro-Orexin mRNA和OX1R的表达水平明显高于妊娠后期和泌乳期.OX2R的表达在生殖各时期之间没有明显改变.结论 Orexin可能参与大鼠泌乳早期的生殖功能调节,下丘脑的PVN及SON可能是其重要的作用部位.     

Orexin-A inputs onto visuomotor cell groups in the monkey brainstem

Orexin-A, synthesized by neurons of the lateral hypothalamus helps to maintain wakefulness through excitatory projections to nuclei involved in arousal. Obvious changes in eye movements, eyelid position and pupil reactions seen in the transition to sleep led to the investigation of orexin-A projections to visuomotor cell groups to determine whether direct pathways exist that may modify visuomotor behaviors during the sleep-wake cycle. Histological markers were used to define these specific visuomotor cell groups in monkey brainstem sections and combined with orexin-A immunostaining. The dense supply by orexin-A boutons around adjacent neurons in the dorsal raphe nucleus served as a control standard for a strong orexin-A input. The quantitative analysis assessing various functional cell groups of the oculomotor system revealed that almost no input from orexin-A terminals reached motoneurons supplying the singly-innervated muscle fibers of the extraocular muscles in the oculomotor nucleus, the omnipause neurons in the nucleus raphe interpositus and the premotor neurons in the rostral interstitial nucleus of the medial longitudinal fasciculus. In contrast, the motoneurons supplying the multiply-innervated muscle fibers of the extraocular muscles, the motoneurons of the levator palpebrae muscle in the central caudal nucleus, and especially the preganglionic neurons supplying the ciliary ganglion received a strong orexin input. We interpret these results as evidence that orexin-A does modulate pupil size, lid position, and possibly convergence and eye alignment via the motoneurons of multiply-innervated muscle fibres. However orexin-A does not directly modulate premotor pathways for saccades or the singly-innervated muscle fibre motoneurons.     

Diurnal variation in CSF orexin-A in healthy male subjects

STUDY OBJECTIVE: Orexin-A is hypothesized to promote wakefulness, and we examined whether cerebrospinal fluid (CSF) orexin-A levels are higher during the waking period in man. DESIGN: Within-subjects, repeated-measures design with balanced ordering of sampling at approximately 5 AM and 5 PM. PARTICIPANTS: Eight healthy young males. MESUREMENTS: CSF orexin-A levels and standard polysomnography. RESULTS: Orexin-A levels during the sleep period were 4% higher than during the waking period (314.9 pg/ml versus 302.8 pg/ml, p < 0.03). Sleep period orexin-A levels were negatively correlated with REM sleep as a percentage of total sleep time (p < 0.05). The day and night levels of orexin-A were strongly correlated within subjects (r = 0.97; p < 0.0001) even though the samples were collected 1-2 weeks apart. CONCLUSIONS: Orexin-A levels in lumbar CSF are slightly higher at 5 AM than at 5 PM. Because orexin release is thought to be highest during the waking period, this observation was unexpected and may reflect a long delay between the release of orexin and its appearance in lumbar CSF. Orexin-A levels vary moderately between subjects, but are quite consistent within the same subject. Thus, for the diagnostic evaluation of narcolepsy, the time of CSF collection should have little impact.     

不同刺激方式对大鼠穹窿周区orexin-A表达的形态学研究

目的:Orexin-A是一种来自下丘脑的具有神经兴奋作用的多肽,含orexin-A的神经细胞主要分布于下丘脑穹窿周区,该群神经元与摄食、睡眠、内脏活动等的调控有关。但如何活化该群神经元尚无有效途径。方法:为了搞清该神经元的激活状态和反应特性,本文采用五种不同的刺激方式,利用免疫组织化学染色和灰度测量相结合的方法对大鼠穹窿周区orexin-A的表达进行了分析。动物分为五组,三组动物分别行禁食1,2和3d,另外两组分别腹腔注射胰岛素和2-脱氧-D-葡萄糖(2-DG),五组动物的饮水量保持正常。结果:五种刺激方式引发的orexin-A表达主要集中于穹窿周区,各组间orexin-A阳性细胞数无明显区别;但进一步灰度分析显示禁食2d组细胞染色最深,与禁食1d组、3d组和对照组相比有明显的统计学差异(P0.05),胰岛素组和2-DG组与对照组相比没有明显差别。结论:orexin-A的细胞合成与刺激方式密切相关,禁食2d较之其它方式更能促进orexin-A神经元的活化和进一步的生物合成。     

Inhibition of ghrelin-induced feeding in rats by pretreatment with a novel dual orexin receptor antagonist

Orexin-A and -B, and ghrelin are potent orexigenic peptides. The effects of ACT462206, a novel dual orexin receptor antagonist (DORA), on ghrelin-induced feeding were examined in adult male Wistar rats. Hyperphagia induced by the intracerebroventricular (icv) administration of ghrelin was significantly suppressed for at least 2 h by pretreatment with icv administration of DORA. A marked increase was observed in the number of neurons showing Fos immunoreactivity in the paraventricular nucleus, arcuate nucleus and lateral hypothalamic area (LHA), 90 min after icv administration of ghrelin. Pretreatment with DORA significantly decreased the number of Fos-immunoreactive (IR) neurons; however, Fos immunoreactivity remained significantly increased. Double-immunostaining for Fos and orexin-A showed that many orexin-A-IR neurons in the LHA coexisted with Fos immunoreactivity after icv administration of ghrelin, but their number was reduced significantly by DORA pretreatment. These results suggest that centrally administered ghrelin may activate the orexinergic and non-orexinergic pathways responsible for the regulation of feeding.     

Ontogeny of androgen receptor expression in the ovine fetal central nervous system and pituitary

In fetal sheep, circulating androgens influence fetal stress responsiveness and the timing of parturition. Nevertheless, little is known about the presence and development of androgen receptors (ARs) in the fetal brain. The present study was undertaken to test the hypothesis that expression of androgen receptor occurs in fetal brain and pituitary, and that the abundance of the AR is ontogenetically regulated. We isolated mRNA from pituitary, hypothalamus, hippocampus, and brainstem in fetal sheep that were 80, 100, 120, 130, and 145-day gestation, and 1 and 7 days postnatal (n = 4–5 per group). Using real-time RT-PCR, we measured mRNA expression levels of the receptor in these brain regions and pituitary. In a separate study, we isolated protein from the same brain regions in fetal sheep that were 80 (n = 3), 120 (n = 4), and 145 (n = 4) days. AR mRNA expression in hypothalamus increased in late gestation, starting at 145 days, and increasing progressively after birth. A trend of increasing AR protein in hypothalamus was not significant. AR mRNA expression in pituitary was elevated after 80 days gestation, but with no further increases or decreases in late gestation, while AR protein increased significantly at the end of gestation. In hippocampus and brainstem AR mRNA was constant throughout the latter half of gestation, and AR protein was below the sensitivity of our Western blot assay. We conclude that the fetal brain and pituitary are target sites for circulating androgens or androgen precursors in fetal plasma, and we speculate that the increase in hypothalamic action of androgens immediately prior to birth might be integral to the timing of parturition.     

Ontogeny of androgen receptor expression in the ovine fetal central nervous system and pituitary

In fetal sheep, circulating androgens influence fetal stress responsiveness and the timing of parturition. Nevertheless, little is known about the presence and development of androgen receptors (ARs) in the fetal brain. The present study was undertaken to test the hypothesis that expression of androgen receptor occurs in fetal brain and pituitary, and that the abundance of the AR is ontogenetically regulated. We isolated mRNA from pituitary, hypothalamus, hippocampus, and brainstem in fetal sheep that were 80, 100, 120, 130, and 145-day gestation, and 1 and 7 days postnatal (n=4-5 per group). Using real-time RT-PCR, we measured mRNA expression levels of the receptor in these brain regions and pituitary. In a separate study, we isolated protein from the same brain regions in fetal sheep that were 80 (n=3), 120 (n=4), and 145 (n=4) days. AR mRNA expression in hypothalamus increased in late gestation, starting at 145 days, and increasing progressively after birth. A trend of increasing AR protein in hypothalamus was not significant. AR mRNA expression in pituitary was elevated after 80 days gestation, but with no further increases or decreases in late gestation, while AR protein increased significantly at the end of gestation. In hippocampus and brainstem AR mRNA was constant throughout the latter half of gestation, and AR protein was below the sensitivity of our Western blot assay. We conclude that the fetal brain and pituitary are target sites for circulating androgens or androgen precursors in fetal plasma, and we speculate that the increase in hypothalamic action of androgens immediately prior to birth might be integral to the timing of parturition.     

Developmental and aging change of orexin-A and -B immunoreactive neurons in the male rat hypothalamus

Orexin/hypocretin is indicated to affect various physiological functions and behaviors, such as energy balance, feeding, wake–sleep cycle, stress response, and reproduction. This study investigated postnatal development and aging changes of the orexin neuron in the male rat hypothalamus. The brain tissue of rats from 1 week to 24 months old was analyzed by immunohistochemistry for two forms of orexin peptides, orexin-A and -B. The number of immunoreactive cells for each age group was counted and the immunoreactive intensity was also analyzed in order to reveal the changes in the number of expressing cells and the relative amount of the peptides. The number of orexin immunoreactive cells increased from postnatal 2 weeks to maturation, then slightly decreased and stabilized until the age of 8 months old, but it was significantly decreased by 24 months old. The intensity of the immunoreaction followed almost the same pattern. Our findings demonstrate that orexin neurons are increased during maturation and then are significantly decreased during the period from 8 to 24 months old, indicating an involvement of orexin in the physiological changes in rat aging such as energy balance, sleep, stress response, and reproduction.     

下丘脑室旁核外源性orexin-A对肥胖大鼠摄食的影响及NPY受体信号的调控

目的:探讨饮食诱导肥胖(DIO)大鼠神经肽Y(NPY)受体信号通路是否参与下丘脑室旁核(PVN)外源性注射食欲素A(orexin-A)对摄食和葡萄糖敏感(GS)神经元兴奋性的调控。方法:采用荧光免疫组织化学实验观察PVN中orexin-A受体(即食欲素1型受体,OX1R)和NPY受体Y5(NPY-5R)的表达;采用单细胞外放电记录观察orexin-A对PVN内GS神经元兴奋性的影响;分别于SD大鼠和DIO大鼠PVN埋置套管,经套管注射orexinA、OX1R拮抗剂SB-334867和NPY-5R拮抗剂CGP-71683,观察大鼠0~2 h和0~4 h摄食量。结果:DIO大鼠PVN中OX1R和NPY-5R的表达显著高于SD大鼠。Orexin-A抑制PVN内葡萄糖抑制性(GI)神经元,兴奋葡萄糖兴奋性(GE)神经元,但是orexin-A对GS神经元的兴奋或抑制效应可被NPY-5R拮抗剂CGP-71683部分阻断,且与SD大鼠相比,orexin-A对DIO大鼠PVN内GS神经元兴奋或抑制效应更加明显。PVN内注射orexin-A可增加SD大鼠和DIO大鼠摄食量。但是orexin-A诱导的促摄食效应被NPY-5R拮抗剂CGP-71683部分阻断。与SD大鼠相比,orexin-A诱导的促摄食效应在DIO大鼠中更加明显。结论:PVN内外源性注射orexin-A可能主要通过OX1R信号通路参与大鼠摄食和GS神经元兴奋性调控,NPY-5R信号也参与了该过程调控,在DIO大鼠中更敏感。     

Orexin-A immunoreactive cells and fibers in the central nervous system of the axolotl brain and their association with tyrosine hydroxylase and serotonin immunoreactive somata

Orexin-A-like immunoreactivity in the axolotl brain was investigated by immunohistochemistry. Immunoreactive somata formed a single group in the hypothalamus, but were distributed beyond several nuclei, namely, the ventral aspect of the nucleus preopticus posterior, dorsal aspect of the nucleus suprachiasmaticus and anterior aspect of the pars ventralis hypothalami. Immunoreactive fibers were distributed throughout the brain from the olfactory bulb to the spinal cord except the cerebellum. The densest immunoreactive fibers were seen in the medial forebrain bundle and caudal lateral forebrain bundle. The largest number of immunoreactive puncta were seen in the mesencephalic tectum in addition to the hypothalamus. Immunoelectron microscopic analysis revealed the presence of synaptoid connections of immunoreactive fibers on neuronal somata in the tectum. The function of the mesencephalic system in the urodele seems to be sensory integration, suggesting that the orexin-A nervous system is associated with the modulation of sensory inputs. Orexin-A immunoreactive puncta were also observed on catecholaminergic and serotonergic somata. In view of the restricted somatic distribution in the hypothalamus, wide distribution of fibers throughout the central nervous system (CNS), and intimate association with monoaminergic somata, the orexin nervous system in the axolotl CNS is similar to those of other vertebrates, suggesting that this system is essential for brain functions throughout vertebrates.     

Experimental vertical transmission of Borna disease virus in the mouse

Summary. We demonstrated the experimental vertical transmission of Borna disease virus (BDV) in pregnant BALB/c mice. Giessen strain He/80 of BDV was used in the present study. Six six-week-old mice were inoculated intraperitoneally with 10⁵ 50% tissue culture infective doses (TCID50), and were bred immediately. Four pregnant mice were sacrificed under anaesthesia on the 10th and 14th days after vaginal plug formation. Nine newborns from two maternal mice were sacrificed under anaesthesia on the 7th day after birth. Positive signals with RT-nested PCR techniques for BDV p24-RNAs were seen in the fetuses, placentas and brains of all newborn mice. No immunopositivities for BDV p40 were found in the fetuses or placentas at 10 days gestation. BDV p40 immunopositivities were found in neurons of the fetal brains and in decidual cells of the placentas at 14 days gestation. They were also found in neurons of the brains of newborn mice. At 10 days gestation, no positive signals for BDV p40 sense or antisense riboprobes were seen in the fetal brains or placentas. Positive signals were found in neurons of the fetal brains and decidual cells of the placentas at 14 days gestation. Positive signals for BDV p40 sense and antisense riboprobes were found in almost all neurons throughout the brains of nine newborn mice. These results suggest that persistent infection with BDV in newborn mice may be induced by vertical transmission during gestation.Received August 2, 2002; accepted March 22, 2003 Published online June 5, 2003     

Differential effect of orexins (hypocretins) on serotonin release in the dorsal and median raphe nuclei of freely behaving rats

Orexin (hypocretin)-containing neurons in the perifornical hypothalamus project to widespread regions of the brain, including the dorsal and median raphe nuclei [Peyron C, Tighe DK, van den Pol AN, de Lecea L, Heller HC, Sutcliffe JG, Kilduff TS (1998) Neurons containing hypocretin (orexin) project to multiple neuronal systems. J Neurosci 18:9996-10015; Wang QP, Koyama Y, Guan JL, Takahashi K, Kayama Y, Shioda S (2005) The orexinergic synaptic innervation of serotonin- and orexin 1-receptor-containing neurons in the dorsal raphe nucleus. Regul Pept 126:35-42]. Orexin-A or orexin-B was infused by reverse microdialysis into the dorsal raphe nucleus or median raphe nucleus of freely behaving rats, and extracellular serotonin was simultaneously collected by microdialysis and analyzed by high-performance liquid chromatography. We have found that orexin-A produced a dose-dependent increase of serotonin in the dorsal raphe nucleus, but not in the median raphe nucleus. However, orexin-B elicited a small but significant effect in both the dorsal raphe nucleus and median raphe nucleus. Orexins may have regionally selective effects on serotonin release in the CNS, implying a unique interaction between orexins and serotonin in the regulation of activities including sleep-wakefulness.     

Expression of organic anion transporters 1 and 3 in the ovine fetal brain during the latter half of gestation

Development and maturation of the fetal brain is critical for homeostasis in utero, responsiveness to fetal stress and, in ruminants, control of the timing of birth. In the sheep, as in the human, the placenta secretes estrogen and other signaling molecules into both the fetal and maternal blood, molecules whose entry or exit across the blood–brain barrier is likely to be facilitated by transporters. The purpose of this study was to test the hypothesis that the ovine fetal brain expresses organic anion transporters, and that the expression of these transporters varies as a function of brain region and fetal gestational age. Brains and pituitaries were collected at the time of sacrifice from fetal and newborn sheep at 80, 100, 120, 130, 145 days gestation and on the first day of postnatal life (parturition in sheep is at approximately 147 days gestation). Hypothalamus, medullary brainstem, cerebellum, and pituitary were processed for mRNA extraction and synthesis of cDNA (4–5/group). Real-time PCR analysis of OAT1 and OAT3 expression revealed significant expression of both genes in all of the tissues tested. In hypothalamus and cerebellum, there were statistically significant increases in the expression of one or both genes towards the end of gestation. In medullary brainstem and pituitary, the levels of expression were relatively unchanged as there were no statistically significant changes with developmental age. We conclude that the ovine fetal brain expresses both OAT1 and OAT3, that the pattern of expression suggests an increasing role for these transporters in the physiology of the developing fetal brain as the fetus nears the time of spontaneous parturition.     

Nuclear organization of orexinergic neurons in the hypothalamus of a lar gibbon and a chimpanzee

Employing orexin-A immunohistochemical staining we describe the nuclear parcellation of orexinergic neurons in the hypothalami of a lar gibbon and a chimpanzee. The clustering of orexinergic neurons within the hypothalamus and the terminal networks follow the patterns generally observed in other mammals, including laboratory rodents, strepsirrhine primates and humans. The orexinergic neurons were found within three distinct clusters in the ape hypothalamus, which include the main cluster, zona incerta cluster and optic tract cluster. In addition, the orexinergic neurons of the optic tract cluster appear to extend to a more rostral and medial location than observed in other species, being observed in the tuberal region in the anterior ventromedial aspect of the hypothalamus. While orexinergic terminal networks were observed throughout the brain, high density terminal networks were observed within the hypothalamus, medial and intralaminar nuclei of the dorsal thalamus, and within the serotonergic and noradrenergic regions of the midbrain and pons, which is typical for mammals. The expanded distribution of orexinergic neurons into the tuberal region of the ape hypothalamus, is a feature that needs to be investigated in other primate species, but appears to correlate with orexin gene expression in the same region of the human hypothalamus, but these neurons are not revealed with immunohistochemical staining in humans. Thus, it appears that apes have a broader distribution of orexinergic neurons compared to other primate species, but that the neurons within this extension of the optic tract cluster in humans, while expressing the orexin gene, do not produce the neuropeptide.     

Orexin neuronal changes in the locus coeruleus of the aging rhesus macaque

Orexin neuropeptides regulate arousal state and excite the noradrenergic locus coeruleus (LC), so it is plausible that an age-related loss of orexin neurons and projections to the LC contributes to poor sleep quality in elderly humans and nonhuman primates. To test this hypothesis we examined orexin B-immunoreactivity in the lateral hypothalamic area (LHA) and the LC of male rhesus macaques (Macaca mulatta) throughout the life span. Orexin perikarya, localized predominantly in the LHA, showed identical distribution patterns irrespective of age. Similarly, orexin neuron number and serum orexin B concentrations did not differ with age. In contrast, orexin B-immunoreactive axon density in the LC of old animals was significantly lower than that observed in the young or adult animals. Furthermore, the age-related decline was associated with a significant decrease in tyrosine hydroxylase (TH) mRNA in the LC, despite no change in TH-immunoreactive neuron number. Taken together, these data suggest that age-related decreases in excitatory orexin innervation to the noradrenergic LC may contribute to the etiology of poor sleep quality in the elderly.     

Morphological study of orexin neurons in the hypothalamus of the Long-Evans rat,with special reference to co-expression of orexin and NADPH-diaphorase or nitric oxide synthase activities

Orexins, novel neuropeptides, are exclusively localized in the hypothalamus and implicated in the regulation of a variety of activities, including food intake and energy balance. Nitric oxide (NO), an unconventional neurotransmitter, is widely present in numerous brain regions including the hypothalamus, and has similar physiological roles to those of the orexins. The present study was undertaken to examine the distribution of orexin neurons and the presence of neuronal nitric oxide synthase (nNOS) in the orexin neurons to clarify whether NO interacts with the orexins in the neuronal regulation activities in the Long-Evans rat. We used two double-labeling methods: nicotinamide adenine dinucleotide phosphate-diaphorase (NADPH-d) histochemistry in combination with orexin immunohistochemistry, and double-labeling fluorescent immunohistochemistry for orexin and nNOS. The majority of the orexin immunoreactive neurons were localized mainly in the areas of the dorsomedial hypothalamic nucleus (DMN), the dorsal part of the perifornical nucleus (PEF) and lateral hypothalamic area. The orexin immunoreactive cell bodies were medium in size, and triangular, round, elliptic, and fusiform in shape. The sizes and shapes of orexin neurons in the different parts were similar. Cell bodies coexpressing the orexin and nNOS or NADPH-d were present in the areas of the DMN and the PEF, and the nerve fibers containing orexin and nNOS were distributed in the DMN and PEF, arcuate nucleus (ARN) and ventromedial hypothalamic nucleus (VMH). These results provide morphological evidence that there exists a population of nNOS- or NADPH-d-/orexin-coexpressing neurons in the orexinergic cell group in the hypothalamus, and taken together with previous findings, suggest that NO may play a role in the mechanisms by which orexin neurons regulate food intake and energy balance.     

Enhanced release of adenosine in rat hind paw following spinal nerve ligation: involvement of capsaicin-sensitive sensory afferents

Dopaminergic projections to the forebrain arising from the mesencephalic ventral tegmentum modulate information processing in cortical and limbic sites. The lateral hypothalamus is crucial for the coordination of behavioral responses to interoceptive cues. The presence of a hypothalamic input to the ventral tegmental area has been known for some time, but the organization of this pathway has received little attention. Among the neuropeptides found in the hypothalamus are the orexins, which are selectively expressed in the lateral hypothalamus and adjacent perifornical area and are critically involved in homeostatic regulatory processes, including arousal and feeding. We examined the anatomical relationships between orexin and dopamine neurons in rats, with particular attention to characterizing the lateral hypothalamic projection to midbrain dopamine neurons.Iontophoretic deposits of the retrograde tracer FluoroGold into the ventral tegmental area revealed a large number of retrogradely-labeled cells that formed a band extending from the medial perifornical area arching dorsally over the fornix and then ventrolaterally into the lateral hypothalamus; approximately 20% of these cells expressed orexin A-like immunoreactivity. Moreover, axons that were anterogradely labeled from the lateral hypothalamus were seen throughout the ventral tegmental area, and were often in close proximity to the dendrites and somata of dopamine neurons. Dopamine and orexin fibers were found to codistribute in the medial prefrontal cortex; orexin fibers were present in lower density in the medial shell of the nucleus accumbens, and the central and posterior basolateral nuclei of the amygdala.We conclude that the lateral hypothalamic/perifornical projection represents an anatomical substrate by which interoceptive-related signals may influence forebrain dopamine function.     

Quinolinate induces selective loss of melanin-concentrating hormone neurons,rather than orexin neurons,in the hypothalamus of mice and young rats

Orexins are neuropeptides produced in the lateral hypothalamus and implicated in regulation of sleep-wake cycle. Selective loss of orexin neurons is found in the brain of patients with narcolepsy, but the mechanisms of this pathological change are unclear. A previous study showed that excessive stimulation of N-methyl-d-aspartate (NMDA) receptors by quinolinic acid (QA) caused selective loss of orexin neurons in rat hypothalamic slice culture. Here we examined QA toxicity on orexin neurons and melanin-concentrating hormone (MCH) neurons in vivo. Contrary to the expectation, injection of QA (60 and 120 nmol) into the lateral hypothalamus of male C57BL/6 mice caused selective loss of MCH neurons rather than orexin neurons, and this toxicity of QA was attenuated by MK-801, an NMDA receptor antagonist. Selective loss of MCH neurons with preserved orexin neurons was observed even when GABA_A receptor antagonists such as bicuculline and picrotoxin were injected with QA. A significant decrease in the number of orexin neurons was induced when QA injection was performed in the dark phase of diurnal cycle, but the degree of the decrease was still lower than that in the number of MCH neurons. Finally, QA (60 nmol) induced selective loss of MCH neurons also in young rats at 3–4 weeks of age. These results do not support the hypothesis that acute excitotoxicity mediated by NMDA receptors is responsible for the pathogenesis of narcolepsy.     

Hypothalamus of the human fetus

The organization of the human hypothalamus was studied in 31 brains aged from 9 weeks of gestation (w.g.) to newborn, using immunohistochemistry for parvalbumin, calbindin, calretinin, neuropeptideY, neurophysin, growth associated protein GAP43, synaptophysin and glycoconjugate, 3-fucosyl-N-acetyl-lactosamine. Morphogenetic periods 9–10 and 11–14 w.g. are characterized by differentiating structures of the lateral hypothalamic zone, which give rise to the lateral hypothalamus (LH) and posterior hypothalamus. The perifornical nucleus differentiates at 18 w.g., from LH neurons which remain anchored in the perifornical position while most of the LH cells are displaced laterally. A transient supramamillary nucleus was apparent at 14 w.g. but not after 16 w.g. As the ventromedial nucleus differentiated at 13–16 w.g., three principal parts; the ventrolateral, the dorsomedial and the shell were revealed by distribution of calbindin, calretinin and GAP43 immunoreactivity. Morphogenetic periods 15–17, 18–23 and 24–33 w.g. are characterized by differentiation of the hypothalamic core, in which calbindin positive neurons revealed the medial preoptic nucleus at 16 w.g. abutted laterally by the intermediate nucleus. The dorsomedial nucleus was clearly defined at 10 w.g. and consisted of compact and diffuse parts, an organization that was lost after 15 w.g. Differentiation of the medial mamillary body into lateral and medial was seen at 13–16 w.g. Morphogenetic period after 34 w.g. was marked by differentiation of midline zone structures including suprachiasmatic, arcuate and paraventricular nuclei. The findings of the present study provide for a better understanding of the structural organization of the adult human hypothalamus, produce new evidence for homologies with the better studied rat hypothalamus and underpin staging system for fetal human hypothalamic development.