Changes of characteristics of preoptic neurons and NA metabolism in hypothalamus of ground squirrel (Citelleus Dautieus) in different seasons and hibernating phases

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Changes of characteristics of preoptic neurons and NA metabolism in hypothalamus of ground squirrel (Citelleus Dautieus) in different seasons and hibernating phases

The unit firing activities of neurons in the preoptic area (POA) of ground squirrel hypothalamic tissue slices were recorded and the metabolism of NA in hypothalamus was measured with high performance liquid chromatography (HPLC). Thermosensitivity, proportions, the critical temperature (Tc) and the lowest temperature (TL) of firing activity of the above-mentioned neurons, and NA metabolism in hypothalamus were compared in different seasons and hibernating phases. In comparison with that in summer euthermar, it was shown that (i) the percentage and thermosensitivity of the POA neurons varied respectively in the hibernating phases; (ii) TL and Tc of the POA neurons in winter, both euthermar and hibernation, were markedly decreased; (iii) the POA neurons in hibernation became much more sensitive to NA, and the response of cold-sensitive neurons to NA changed from inhibiting pattern in summer to exciting one in hibernation; (iv) the contents and metabolism of NA in hypothalamus decreased significantly in the entering phase and deep hibernation phase, while the metabolism of NA increased remarkably in the arousal phase. These changes might explain the regulatory mechanism how ground squirrel actively decreases body temperature (Tb) in entering into hibernation and quickly recovers body temperature in arousal phase. Project supported by the National Natural Science Foundation of China (Grant Nos. 39230060 and 39570100)     

2010 Carl Ludwig Distinguished Lectureship of the APS Neural Control and Autonomic Regulation Section: Central neural pathways for thermoregulatory cold defense

Central neural circuits orchestrate the homeostatic repertoire to maintain body temperature during environmental temperature challenges and to alter body temperature during the inflammatory response. This review summarizes the research leading to a model representing our current understanding of the neural pathways through which cutaneous thermal receptors alter thermoregulatory effectors: the cutaneous circulation for control of heat loss, and brown adipose tissue, skeletal muscle, and the heart for thermogenesis. The activation of these effectors is regulated by parallel but distinct, effector-specific core efferent pathways within the central nervous system (CNS) that share a common peripheral thermal sensory input. The thermal afferent circuit from cutaneous thermal receptors includes neurons in the spinal dorsal horn projecting to lateral parabrachial nucleus neurons that project to the medial aspect of the preoptic area. Within the preoptic area, warm-sensitive, inhibitory output neurons control heat production by reducing the discharge of thermogenesis-promoting neurons in the dorsomedial hypothalamus. The rostral ventromedial medulla, including the raphe pallidus, receives projections form the dorsomedial hypothalamus and contains spinally projecting premotor neurons that provide the excitatory drive to spinal circuits controlling the activity of thermogenic effectors. A distinct population of warm-sensitive preoptic neurons controls heat loss through an inhibitory input to raphe pallidus sympathetic premotor neurons controlling cutaneous vasoconstriction. The model proposed for central thermoregulatory control provides a platform for further understanding of the functional organization of central thermoregulation.     

Participation of GABAergic Mechanisms of Hypothalamus Ventrolateral Preoptic Area in Regulation of Sleep and Wakefulness and Temperature Homeostasis in the Pigeon <Emphasis Type="Italic">Columba livia</Emphasis>

A comparative analysis of awakening, somnogenic, and thermoregulating effects of agonists and antagonists of GABAA,B-receptors after microinjections to neuronal populations of ventrolateral preoptic area (VLPA) of hypothalamus was carried out for the first time in representatives of the avian class (pigeon). It has bee established that: (1) VLPA of hypothalamus contains populations of neurons differing by their function and representation of receptor types and participating in control of wakefulness, sleep, and thermoregulation; (2) executive GABA_A-ergic mechanisms of maintenance of the slow-wave sleep (SWS) are located predominantly in the caudal part of the hypothalamic VLPA; (3) GABA_A,B-ergic mechanisms of control of thermal homeostasis are located predominantly in the caudal part of VLPA. It is suggested that the maintenance of SWS depends on an increase of activity of inhibitory GABAergic VLPA mechanisms leading to inactivation of neuronal networks of wakefulness outside VLPA and on a reduction of activity of the stimulatory aminergic systems present in the preoptic area and outside it.     

Key roles of the histaminergic system in sleep-wake regulation

Histamine plays an important role in mediating wakefulness in mammals. Based on the findings from gene-manipulated mice, we provide several lines of evidence showing the roles of the histaminergic system in the somnogenic effects of prostaglandin (PG) D2 and adenosine, and in the arousal effects of PGE2 and orexin. PGD2 activates DP1 receptors (R) to promote sleep by stimulating them to release adenosine. The released adenosine activates adenosine A2AR and subsequently excites the ventrolateral preoptic area (VLPO), one of the sleep centers in the anterior hypothalamus. VLPO neurons then send inhibitory signals to downregulate the histaminergic tuberomammillary nucleus (TMN), which contributes to arousal. A1R is expressed in histaminergic neurons of the rat TMN. Adenosine in the TMN inhibits the histaminergic system via A1R and promotes non–rapid eye movement sleep. Conversely, both endogenous PGE2 and orexin activate the histaminergic system through EP4R and OX-2R, respectively, to promote wakefulness via histamine H1R. Furthermore, the arousal effect of ciproxifan, H3R antagonist, depends on the activation of histaminergic systems. These findings indicate that VLPO and TMN regulate sleep and wakefulness by means of a “flip-flop” mechanism operating in an anti-coincident manner during sleep–wake state transitions.

     

Lateral septal projections onto tubero-infundibular neurons in the hypothalamus of the guinea pig

Efferent projections of the lateral septal nucleus (LS) to the preoptic area and the hypothalamus were identified in 20 female guinea pigs after iontophoretic injection of the anterograde axonal tracer Fluoro-Ruby. Tubero-infundibular (TI) neurons of the preoptic area and the hypothalamus were retrogradely labeled after intracardiac injection of Granular Blue or Fluoro-Gold. Magnocellular neurons of the supraoptic and paraventricular nuclei were also labeled. The double labeling procedure allowed an estimation of the extent of the direct relationship between LS efferents and TI neurons. Contacts between lateral septal fibers and TI cell bodies were mainly observed at the light-microscopical level in the preoptic area. A group of labeled fibers coursing along the third ventricle established sparse connections with hypothalamic periventricular TI neurons. A few appositions was observed in the infundibular (arcuate) nucleus, suggestive of a monosynaptic regulation of TI neurons by a septo-arcuate tract. Close association with labeled magnocellular neurons was also noted at the edge of the supraoptic and paraventricular nuclei. The sparse but direct connections between LS and TI neurons may be involved in the neuroendocrine functions of the LS.     

Substance P-related peptides in the hypothalamus of Amphibia

Summary The occurrence of Substance P-(SP)-related peptides in the hypothalamus of three species of Amphibia (newt, clawed, toad, frog) was studied immunohistochemically employing the indirect immunofluorescence method or a double-step technique (indirect immunofluorescence followed by the peroxidase-antiperoxidase complex method). SP-like immunopositive fibers are seen throughout the hypothalamus. They are especially abundant in the preoptic area and in the outer zone of the median eminence, suggesting a role of SP-related peptides in the hypothalamo-hypophysial regulation in these animals. Some SP-like neurons are seen in the posterior hypothalamus and in the preoptic area. In the newt, such SP-like immunopositive neurons occur frequently in the preoptic periventricular grey.Work performed under the C.N.R. project Biologia della Riproduzione     

The Role of Steroid Modulation of Amino Acid Transmitters in the Regulation of Female Reproduction

SYNOPSIS. The amino acid transmitters can be placed in two generalcategories, excitatory and inhibitory. This discussion focuseson the role of the inhibitory transmitter GAB A and the excitatoryamino acids aspartate and glutamate in the control of gonadotropinsecretion and reproductive behavior. GABAergic neurotransmissionin the preoptic area inhibits gonadotropin secretion via directsynaptic contact with LHRH neurons and possibly through presynapticinhibition of noradrenergic fibers that stimulate LH release.In the arcuate-median eminence, GABA acting at GABAA receptorsincreases gonadotropin release by inhibiting a currently unidentifiedinhibitory interneuron. In regard to reproductive behavior,GABA acting in the preoptic area inhibits female sexual receptivitywhereas GABA in the mediobasal hypothalamus and the midbraincentral gray facilitates this behavior. The effects of GABAon reproductive behavior do not appear to be secondary to actionson defensive or locomotor behavior. Gonadal steroids modulateactivity at the GABAA receptor in a highly complex manner andthese effects may be involved in the role GABA plays in controllinggonadotropin secretions as well as behavior. The excitatory amino acids also affect gonadotropin secretion,exerting a stimulatory effect both in the preoptic area andat the level of the median eminence. When a specific antagonistfor one of the excitatory amino acid receptors is infused intothe preoptic area or when an excitatory amino acid receptoragonist is infused into the mediobasal hypothalamus, femalesexual behavior is inhibited. There have only been limited reportsof steroid modulation of excitatory amino acid neurotransmission.     

NADPH-diaphorase, nitric oxide synthase, and tyrosine hydroxylase in the diencephalon of the Rhodeus sericeus (Cyprynidae:Teleostei)

The presence and distribution of nitric oxide synthase (NOS)-like neurons as well as tyrosine hydroxylase-immunoreactive (TH) neurons was studied in the diencephalon of the cypriniform teleost Rhodeus sericeus. The anatomical relationships between tyrosine hydroxylase (TH)- and nitric oxide synthase (NOS)-containing cells were visualized both by NOS-immunohistochemistry and NADPH-histochemistry. Immunohistochemical labeling and morphological studies were performed on the same sections. The results reported in this paper show that both a NOS and TH activity are present in the preoptic region, posterior tuberculum, paraventricular organ and hypothalamus of R. sericeus. Putative nitrergic neurons were identified in all major hypophysiotrophic nuclei of the R. sericeus brain using both NADPH-d histochemistry and nNOS immunohistochemistry. In the preoptic region, nitrergic neurons were found in both the parvocellular and the magnocellular nuclei. Within these nuclei, the distribution of NADPH-d reactivity was similar to that of nNOS immunoreactivity. However, we found no evidence of colocalization of NADPH-d and nNOS in consecutive sections. NOS- and TH-containing neurons were observed in all the nuclei under study (hypothalamus, posterior tuberculum, ventral thalamus) and telencephalon (preoptic region), although most neurons showing the coexistence of both substances were mainly located in the preoptic nucleus and hypothalamus, some labelled neurons were found in the posterior tuberculum. Most of the cerebrospinalliquor-contacting cells (LCNs) in diencephalic periventricular area of R. sericeus were TH-immunoreactive. Also, a large number ofnitrergic small LCNs distributed throughout the third ventricle were observed in these regions. The data obtained supports the existence of a nitrergic circumventricular system in teleost. LCNs in R. sericeus are thought to be involved in osmoregulatory functions as osmosensitive neurons. Due to their chemical properties, NO produced by these cells might play an important role in the maintenance and regulation of CSF homeostasis through the modulation of cerebral blood flow.     

Gonadotropin-releasing hormone (GnRH) pathways and reproductive control in elasmobranchs

Synopsis Immunoreactive (ir) gonadotropin-releasing hormone (GnRH) is localized in many neurons of the terminal nerve (TN) and midbrain tegmentum, while few ir-cells are observed in the preoptic area and ventral hypothalamus. The paucity of preoptic ir-cells may relate to an unusual feature of the elasmobranch pituitary, i.e. a lack of portal control of gonadotropin-producing cells. TN and midbrain GnRH-ir neurons may be major sources of GnRH used to modulate or otherwise control both pituitary and brain cells via delivery through the systemic circulation. These ir-nuclei also appear to directly innervate CNS regions (the preoptic area, habenula and clasper control area of the spinal cord) involved in sexual functions. Important regulatory mechanisms, represented by interactions between GnRH pathways and sex-steroid concentrating neurons, are likely to occur in the preoptic area, habenula and midbrain tegmentum.     

Elevated Fos-like immunoreactivity in the brains of postpartum female prairie voles, Microtus ochrogaster

This study investigated the expression of the protein product of the immediate early gene c-fos in the brains of female prairie voles (Microtus ochrogaster) in association with pregnancy and postparturient activities including maternal behavior, lactation and postpartum estrus. Fos expression was assessed in female voles that were late in pregnancy, nonpregnant or at one of three different times postpartum (0-8, 12-24, and 24-48 h, respectively). A significant increase in the number of cells displaying Fos immunoreactivity (Fos-ir) was observed during the 0-8 h and 12-24 h postpartum time periods in the accessory olfactory bulbs, medial preoptic area, hypothalamus (specifically, the supraoptic nucleus, ventro-medial hypothalamus, and paraventricular nucleus), lateral septum, bed nucleus of the stria terminalis, and primary somatosensory area of the brain. The number of Fos-ir cells decreased after 24 h postpartum. There were no significant changes in Fos-ir cell numbers in the primary olfactory bulbs, hippocampus, or caudate putamen. The neural activation of the medial preoptic area, accessory olfactory bulbs, hypothalamus, and bed nucleus is consistent with reports in rats of Fos induction associated with the onset of maternal behavior. In voles postpartum estrous behavior begins and ends 0-12 h after parturition. Maternal behavior, including lactation, is initiated at the same time but persists for several weeks. The highest Fos-ir cell numbers reported here coincide with the timing of postpartum estrous behavior in this species.     

Histamine-immunoreactive neurons in the hypothalamus of cats

The localization of histaminergic neurons in the cat brain was determined immunohistochemically with an antibody against histamine. We found that histamine-immunoreactive neurons are observed exclusively in the posterior hypothalamus of colchicine treated cats. The larger group of neurons was found in the ventrolateral part of the posterior hypothalamus, including the tuberomammillary nucleus. Histamine-positive neurons were also observed in the supramammillary area and adjacent posterior hypothalamic area, as well as in the peri- and premammillary regions. In addition, numerous histamine immunoreactive fibers were detected, not only in the posterior hypothalamus, but also in other brain areas, such as the preoptic area of the anterior hypothalamus.     

Peripheral ghrelin interacts with orexin neurons in glucostatic signalling

Ghrelin interactions with glycemia in appetite control as well as the potential mechanisms involving the orexin and melanin-concentrating hormone (MCH) neurons in the orexigenic ghrelin signals were investigated by using a specific anti-ghrelin antibody (AGA). Our results confirm that peripheral ghrelin is an important signal in meal initiation and appetite. Employing immunohistochemistry techniques, we found that c-fos positive neurons in the lateral hypothalamus (LH) and perifornical area (PFA) increased after insulin or 2-deoxyglucose administration. Moreover, we have also demonstrated that peripheral ghrelin blockade by the AGA, reduces the orexigenic signal induced by insulin and 2-DG administration probably partly producing a decrease of c-fos immunoreactivity in the LH and PFA as well as a lower activation of orexin neurons. In contrast, the c-fos positive MCH neurons were not apparently affected. In summary, our findings suggest that peripheral ghrelin plays an important role in regulatory "glucostatic" feeding mechanisms by means of its role as a "hunger" signal affecting the LH and PFA areas, which may contribute to energy homeostasis through orexin neurons.     

Diurnal levels of Fos immunoreactivity are elevated within hypocretin neurons in lactating mice

The hypocretins modulate arousal via actions across multiple terminal fields. Thus, alterations in hypocretin neurotransmission may contribute to altered sleep patterns observed during lactation. This study examined whether lactation is associated with alterations in the number of hypocretin neurons and in diurnal Fos-immunoreactivity within hypocretin neurons in female mice. Alterations in Fos-immunoreactivity were also examined within two hypocretin terminal regions; the medial preoptic area and the locus coeruleus. Fos-immunoreactivity was increased within hypocretin neurons and the medial preoptic area in lactating females. No differences were observed in the number of hypocretin neurons or in Fos-immunoreactivity within the locus coeruleus.     

Interactions of reproductive steroids, osmotic pressure, and glucose on thermosensitive neurons in preoptic tissue slices

The preoptic area contains thermosensitive neurons, thought to be important in thermoregulation, and steroid-sensitive neurons, thought to be involved in reproduction. The preoptic area also contains osmosensitive neurons, considered important in water balance, and glucosensitive neurons, thought to function in the regulation of glucose. If these various neurons belong to separate populations, one might predict that most osmosensitive, glucosensitive, and steroid-sensitive neurons constitute the population of temperature-insensitive neurons rather than thermosensitive neurons. To test this hypothesis, single unit activity was recorded in preoptic tissue slices prepared from male rats. In addition to temperature changes, neuronal responses were examined with various perfusion media containing testosterone or estradiol (30 pg/mL), low glucose (1.0 mM), and increased osmotic pressure (309 mosmol/kg). It was found that the steroid-sensitive, osmosensitive, and glucosensitive neurons were not confined to the temperature-insensitive neurons; but that nearly half of the thermosensitive neurons responded to these nonthermal stimuli. This lack of specificity was also observed between osmosensitive and glucosensitive neurons; however, most of the steroid-sensitive neurons were highly specific for either estradiol or testosterone. Although these findings do not suggest a strong functional specificity for preoptic neurons, they do support studies emphasizing interactions between regulatory systems.     

Newborn GnRH neurons in the adult forebrain of the ring dove

The preoptic area of the hypothalamus is a key area that produces gonadotrophin-releasing hormone (GnRH). In birds, the chicken GnRH-I-form neurons are responsible for the hypothalamus-pituitary-gonadal system, which controls reproduction. In the ring dove, electrolytic lesion in the adult hypothalamus induces neurogenesis. In this study, we determined whether adult neurogenesis is involved in repairing GnRH neurons, specifically by generating newborn cells exhibiting GnRH-I immunoreactive properties. We selectively applied electrolytic lesions to three different regions of the diencephalon, including the preoptic area, which contains GnRH-I neurons, and identified new cells (BrdU-positive cells) that co-labeled with GnRH-I-immunoreactive cells. The BrdU⁺/GnRH⁺ double labeled cells were then confirmed with confocal laser analysis. In brains of both male and female ring doves we found new neurons at the lesion site of the preoptic region that were GnRH-I immunoreactive. However, the total number of GnRH neurons in the lesioned brains was less than that of sham-lesioned brains. When two other regions of the diencephalon that contain GnRH-I neurons were damaged, no recruitment of new GnRH-I neurons was detected. The rate of neurogenesis depends on the bird's reproductive phase when the lesion was applied. We found BrdU⁺/GnRH⁺ double-labeled cells almost exclusively during the pre-laying phase when birds are engaged in active courtship that leads to egg laying. Our observations suggest that recruitment of GnRH immunoreactive new neurons is restricted to the hypothalamic region and is sensitive to the reproductive stage of the birds.     

Neuronal interactions between galanin-like-peptide- and orexin- or melanin-concentrating hormone-containing neurons

Galanin-like peptide (GALP) is a novel orexigenic neuropeptide that is recently isolated from the porcine hypothalamus. GALP-containing neurons predominantly locate in the hypothalamic arcuate nucleus (ARC). The expression of GALP mRNA within the ARC is increased after the administration of leptin. GALP-containing neurons express leptin receptor and contain alpha-melanocyte-stimulating hormone. We have recently reported that neuropeptide Y (NPY)- and orexin-containing axon terminals are in close apposition with GALP-containing neurons in the ARC. In addition, GALP-containing neurons express orexin-1 receptor (OX1-R). Thus, GALP may function under the influence of leptin and orexin. However, the target neurons of GALP have not yet been clarified. To clarify the neuronal interaction between GALP-containing and other feeding regulating neurons, double-immunostaining method using antibodies against GALP- and orexin- or melanin-concentrating hormone (MCH) was performed in the rat lateral hypothalamus (LH). GALP-immunoreactive fibers appeared to project to the LH around the fornix. They were also found from the rostral to the caudal part of the ARC, paraventricular nucleus (PVH), stria terminalis (BST), medial preoptic area (MPA), and lateral septal nucleus (LSV). Moreover, GALP-like immunoreactive nerve fibers were directly contacted with orexin- and melanin-concentrating hormone (MCH)-like immunoreactive neurons in the LH. Our findings strongly suggest that GALP-containing neurons interact with orexin- and/or MCH-containing neurons in the lateral hypothalamus and that it participates in the regulation of feeding behavior in harmony with other feeding-regulating neurons in the hypothalamus.     

Visualizing sexual dimorphism in the brain

Sexually dimorphic behaviors are likely to involve neural pathways that express the androgen receptor (AR). We have genetically modified the AR locus to visualize dimorphisms in neuronal populations that express AR. Analysis of AR-positive neurons reveals both known dimorphisms in the preoptic area of the hypothalamus and the bed nucleus of the stria terminalis as well as novel dimorphic islands in the basal forebrain with a clarity unencumbered by the vast population of AR-negative neurons. This genetic approach allows the visualization of dimorphic subpopulations of AR-positive neurons along with their projections and may ultimately permit an association between neural circuits and specific dimorphic behaviors.     

Acoustic modulation of neural activity in the preoptic area and ventral hypothalamus of the green treefrog (Hyla cinerea)

Summary Responses of neurons in the preoptic area and ventral hypothalamus to conspecific mating calls or white noise bursts were examined in male green treefrogs (Hyla cinerea) during different seasons. In the winter, 34.3% of preoptic neurons and 46.7% of ventral hypothalamic cells demonstrated significant changes in activity level during presentation of a conspecific mating call. In contrast, only 13.3% of preoptic units and 16.7% of ventral hypothalamic cells responded to the white noise. The percentage of preoptic and hypothalamic units responding to the advertisement call did not differ significantly during the summer breeding season. Type I units exhibited a dramatic increase in activity during acoustic stimulation followed by a rapid return to baseline activity levels after stimulus offset. Type II cells showed a robust activity increase during stimulation, but maintained an intermediate activity level after stimulus offset. In the preoptic area, a third response type exhibited suppressed activity during acoustic stimulation. Although seasonal condition did not alter the percentage of acoustically responsive units within either nucleus, the proportion of Type I units in the ventral hypothalamus was greatest during the summer.Abbreviations MC mating call - NS no stimulus - POA preoptic area - VH ventral hypothalamus - WN white noise     

Physiological properties of hypothalamic MCH neurons identified with selective expression of reporter gene after recombinant virus infection

Neurons that synthesize melanin-concentrating hormone (MCH) may modulate arousal and energy homeostasis. The scattered MCH neurons have been difficult to study, as they have no defining morphological characteristics. We have developed a viral approach with AAV for selective long-term reporter gene (GFP) expression in MCH neurons, allowing the study of their cellular physiology in hypothalamic slices. MCH neurons showed distinct membrane properties compared to other neurons infected with the same virus with a cytomegalovirus promoter. Transmitters of extrahypothalamic arousal systems, including norepinephrine, serotonin, and the acetylcholine agonist muscarine, evoked direct inhibitory actions. Orexigenic neuropeptide Y was inhibitory by pre- and postsynaptic mechanisms; an anorexigenic melanocortin agonist had no effect. In contrast, the hypothalamic arousal peptide hypocretin/orexin evoked a direct inward current and increased excitatory synaptic activity and spike frequency in the normally silent MCH neurons. Together, these data support the view that MCH neurons may integrate information within the arousal system in favor of energy conservation.