Nesfatin-1 influences the excitability of glucosensing neurons in the hypothalamic nuclei and inhibits the food intake

Nesfatin-1 is a recently discovered neuropeptide that has been shown to decrease food intake after lateral, third, or fourth brain ventricle, cisterna magna administration, or PVN injection in ad libitum fed rats. With regards to the understanding of nesfatin-1 brain sites of action, additional microinjection studies will be necessary to define specific nuclei, in addition to the PVN, responsive to nesfatin-1 to get insight into the differential effects on food intake. In the present study, we evaluated nesfatin-1 action to modulate food intake response upon injection into the specific hypothalamic nuclei (PVN, LHA and VMN) in freely fed rats during the dark phase. We extend previous observations by showing that the nesfatin-1 (50 pmol) injected before the onset of the dark period significantly reduced the 1 to 5 h cumulative food intake in rats cannulated into the PVN, LHA, but not in rats cannulated into the VMN. Glucosensing neurons located in the hypothalamus are involved in glucoprivic feeding and homeostatic control of blood glucose. In order to shed light on the mechanisms by which nesfatin-1 exerts its satiety-promoting actions, we examined the effect of nesfatin-1 on the excitability of hypothalamic glucosensing neurons. Nesfatin-1 excited most of the glucose-inhibited (GI) neurons and inhibited most of the glucose-excited (GE) neurons in the PVN. Of 34 GI neurons in the LHA tested, inhibitory effects were seen in 70.6% (24/34) of GI neurons. The main effects were excitatory after intra-VMN administration of nesfatin-1 in GE neurons (27/35, 77.1%). Thus, our data clearly demonstrate that nesfatin-1 may exert at least a part of its physiological actions on the control of food intake as a direct result of its role in modulating the excitability of glucosensing neurons in the PVN, LHA and VMN.     

The Lateral Hypothalamic Area: Peculiarities of Aging and the Effect of Chronic Electrical Stimulation on the Lifespan in Rats

Age-related morphological and functional changes in the lateral hypothalamic area (LHA) were studied in experiments on young adult (6-8 months) and old (26-28 months) male Wistar rats. It was found that during aging the neuronal density in the LHA decreased, and significant qualitative destructive and dystrophic changes in the neuronal population developed. The background impulse activity of LHA neuronal units, the mass background electrical activity recorded from this structure, and the Na⁺, K⁺-ATPase activity decreased during aging. In old rats, the rate of LHA self-stimulation was lower, and the range of reinforcing current amplitudes, which provided self-stimulation intensity close to the maximum, was narrower than in adult animals. Chronic electrical LHA stimulation in old rats ensured an increase in the lifespan and maximum life expectancy in these animals. In addition, the lifespan positively correlated with the duration of LHA stimulation. It is concluded that lowering of the functional activity of the LHA neural systems is one of the substantial aspects of the aging process, and activation of this structure in old animals by its chronic electrical stimulation can exert a geroprotective effect.     

Bradykinin, morphine and naloxone interaction on the sensorimotor cortical neuron level

In experiments on awake rabbits the effect of bradykinin, morphine and naloxone (applied by means of microiontophoresis) on sensomotor cortical neurons was studied. Bradykinin increased the discharge frequency in the majority of neurons. Morphine inhibited the neuronal activity. Bradykinin had no activating effect in the presence of morphine. Naloxone eliminated morphine depressing effect and restored the neuronal reaction to bradykinin. According to the data obtained it is suggested that bradykinin interacts with opiate receptors in the brain.     

Effect of morphine on the concentration of monoamines in the emotiogenic zones of the hypothalamus in adult and old rats

The content of monoamines in the emotiogenic hypothalamic zones has been shown to noticeably change with aging of rats. The level of noradrenaline and serotonin increased in the ventromedial nucleus of the hypothalamus, while the concentration of noradrenaline increased in the lateral hypothalamic zone. Single i.p. injections of 10 mg/kg morphine evoked qualitatively different shifts in the monoamine concentrations in the hypothalamic emotiogenic zones of the rats of different ages: the level of dopamine increased in adult animals, while the levels of noradrenaline and serotonin dropped in old rats. It is supposed that in old age the effect of morphine on dopaminergic structures in the emotiogenic hypothalamic zones becomes more moderate, whereas that on the noradrenergic and serotonergic structures is facilitated. The age-related specificities of the morphine effect on the monoaminergic regulation of the emotiogenic hypothalamic zones can determine considerable modifications of a psychotropic effect of the drug in old age.     

Modulation of neuronal impulse activity of the anterior hypothalamus as a functional basis of the mechanisms underlying hypothalamic control

We examined the neuronal activity of hypothalamic neurons in acute experiments on cats under ketamine anesthesia. Using glass microelectrodes, we extracellularly recorded the impulse activity (IA) of neurons of the anterior hypothalamus in the absence of controlled influences (background IA, BIA) and after stimulation of evolutionary heterogeneous zones of the brain cortex projecting to the hypothalamus (hippocampal CA3 area, pyriform, cingular, and proreal gyri). Electrical 5-sec-long stimuli were applied with frequencies of 12, 30, or 100 sec⁻¹. In another experimental series, we recorded changes in the IA of hypothalamic neurons induced by visceral stimuli (heating or cooling by 7°C of the foot pad, cooling of the body of the animal, and infusions of 5% glucose, 0.2% NaCl, 3.0% NaCl, or phenylephrine in the carotid artery), modeling in such a way shifts of the constants of homeostasis within physiological limits. We also compared the parameters of neuronal BIA and stimulation-influenced IA in equal epochs of the analysis and classified the types of BIA. About 50% of the cells of the total studied sampling of hypothalamic neurons responded by a considerable modulation of their BIA with a significant change in the frequency in the course of and after stimulations of the above-mentioned modalities. In some neurons after cortical or visceral stimulation, a significant transformation of the temporal structure of the IA with no changes in the mean frequency occurred. We hypothesize that stimulation-induced transformation of the IA pattern with preservation of the mean discharge frequency can be one of the modes of encoding of information necessary for triggering of one efferent reaction or another, which are controlled by the hypothalamus. Examination of the BIA parameters of subcortical neurons, as well as comparison of the parameters of such an activity with the localization of cells and with the modality of stimulation that leads to modification of the IA, should allow one to reveal reasons for the formation and modification of the IA on neurons of the anterior hypothalamus. Since functional peculiarities of the neurons correlate with their BIA pattern, such data can provide an insight into the functional bases of the neurophysiological mechanisms underlying regulatory functions of the hypothalamus. Neirofiziologiya/Neurophysiology, Vol. 37, Nos. 5/6, pp. 463–474, September–December, 2005.     

The fos proto-oncogene protein:regulation by morphine in the rat hypothalamus

Mechanisms by which opiates alter neuronal functions, including neuroendocrine functions, are not well defined. We have previously demonstrated that morphine rapidly and transiently increases expression of the proto-oncogene c-fos in the rat caudate-putamen. This regulation of the c-fos gene by morphine may represent a portion of the intracellular cascade coupling activation of opiate receptors on the cell surface to subsequent alterations in neuropeptide gene expression. In the present study, we have focussed on effects of morphine on c-fos expression in the ventromedial hypothalamus, which contains estrogen-concentrating neurons and a large number of neurons expressing the opioid proenkephalin and Proopiomelanocortin. The hypothalamus has been identified as a "final common pathway" between the remainder of the central nervous system and the pituitary gland. As a marker for c-fos expression, we have detected pp50 c-fos (FOS) protein immunocytochemically, using a polyclonal antibody to the M peptide of FOS, and revealed an intense nuclear stain in many neurons. Labeled nuclei were drawn by camera lucida from 12 matched sections (one side only) covering the rostral and middle levels of the ventromedial nucleus of six rats given morphine and six given phosphate buffered saline. Morphine treatment significantly increased the number and density of immuno-labeled nuclei in the ventromedial nucleus, but not in the arcuate nucleus. These results suggest effects of morphine (directly or indirectly) on neurons in the ventromedial hypothalamic nucleus, despite the relative absence of morphine receptors in this nucleus. These results may also provide an anatomical basis for neuroendocrine alterations following morphine treatment.     

The effects of opiate agonists on growth hormone and prolactin release in rats

Various opioid receptor agonists, including Met5-enkephalin amide, Leu5-enkephalin amide, [D-Ala]2-Met5-enkephalin amide, [D-Ala]2-Leu5-enkephalin amide, morphine sulfate, d-methadone hydrochloride, and l-methadone hydrochloride were administered to adult male rats by subcutaneous injection. All opioid receptor agonists except Leu5-enkephalin amide significantly stimulated growth hormone and prolactin release. Naloxone and naltrexone blocked the hormone stimulatory effects of the opioids and both naloxone and naltrexone, when administered alone, significantly reduced serum growth hormone and prolactin concentrations. The dopaminergic agonist apomorphine, but not the alpha-adrenergic agonist clonidine, blocked opiate stimulation of prolactin. Morphine sulfate caused growth hormone release in rats pretreated with alpha-methyl-p-tryosine, a catecholamine synthesis inhibitor. Cholinergic agonists, physostigmine and pilocarpine, antagonized the growth hormone and prolactin release induced by morphine sulfate. The data suggest that the opiates stimulate prolactin via an interaction with catecholaminergic neurons controlling prolactin release and stimulate growth hormone via a mechanism independent of alpha-adrenergic or general catecholaminergic influence. The mechanism through which cholinergic agonists act to inhibit opiate agonist stimulation of growth hormone is presently unknown.     

大鼠下丘脑外侧区内微量注射胃动素对胃窦运动和迷走背核复合体神经元电活动的影响

采用清醒大鼠胃运动记录和玻璃微电极记录神经元活动的实验方法 ,研究下丘脑外侧区 (lateralhy pothalamicarea,LHA)微量注射胃动素 (motilin) ,对清醒大鼠胃窦运动和对麻醉大鼠迷走背核复合体 (dorsalvagalcomplex ,DVC)中胃扩张敏感神经元电活动的调节作用。LHA内微量注射胃动素 (0 37nmol/ 0 5 μl)可使胃窦运动增强 76 2 9± 4 0 9% (P <0 0 1)。DVC中 6 0个胃扩张 (gastricdistention ,GD)敏感神经元中 ,39(6 5 % )个GD刺激引起电活动增强 ,2 1(35 % )个电活动减弱 ,分别称之为GD兴奋型神经元和GD抑制型神经元。双侧LHA微量注射胃动素 0 37nmol/ 0 5 μl,14个GD抑制型神经元中有 12个单位放电频率增加 4 4 35± 7 89% (P <0 0 1) ;2 4个GD兴奋型神经元中有 15个单位放电频率减少 7 17± 7 89% (P <0 0 5 )。结果提示 ,中枢胃动素可能通过LHA-DVC-迷走神经实现对胃窦运动的调控     

Effects of narcotic opiates and serotonin on the electrical behavior of neurons in the guinea pig myenteric plexus

Action potentials were recorded extracellularly from spontaneously firing neurons in the myenteric plexus of the guinea pig ileum. Morphine, which inhibits acetylcholine release from the myenteric plexus, inhibited the spontaneous electrical activity of about half the cells studied, while serotonin elevated the firing rate of these cells. Units not stimulated by serotonin were not inhibited by morphine or levorphanol. Morphine also prevented the increase in firing rate caused by serotonin. These effects of morphine were stereospecific and blocked by naloxone, and are therefore considered to be specific opiate effects. This study demonstrates opposing effects of narcotic opiates and serotonin on the electrical activity of serotoninoceptive neurons in the myenteric plexus.     

Morphine-induced effects on the hypothalamic stimulation-evoked emotional/behavioral reactions and peculiarities of abstinent syndrome in adult and old rats

Experiments were carried out on adult young (6- to-9-month-old) and old (28- to-30-month-old) rats. The effects of a single i.p. injection of morphine on self-stimulation of the lateral hypothalamic region and on active avoidance responses evoked by stimulation of the ventromedial hypothalamic nucleus were studied. In a separate series of the experiments we studied age-related specificities of the abolition syndrome after a course of intraventricular injections of morphine. In most old rats single injections of morphine resulted in intensification of self-stimulation, while in most adult rats such injections suppressed this reaction. In old animals injections of morphine resulted in more pronounced increases in the threshold and latency of the active avoidance responses, as compared with similar changes in adult rats. Natural abolition of a 15-day-long course of injections of morphine resulted in the development of a characteristic abstinent syndrome that was more intensively manifested in old rats. Our results show that “hedonic” and anti-aversive effects of morphine increase with aging; this phenomenon probably facilitates the development of morphine dependence in old organisms.     

Neurons in the rat lateral hypothalamic area integrate information from the gastric vagal nerves and the cerebellar interpositus nucleus

Previous investigations have demonstrated that the neuronal activity in the lateral hypothalamic area (LHA) is respectively modulated by afferent inputs from the gastric vagal nerves innervating the upper gastrointestinal tract, as well as the cerebellar interpositus nucleus (IN). The aim of this study was to examine whether the gastric vagal and cerebellar IN inputs converge onto single LHA neurons in rats, especially those sensitive to glycemia. Of the 114 LHA neurons recorded, 60 (52.6%) and 51 (44.7%) responded to gastric vagal and cerebellar IN stimulation, respectively. Of the 60 LHA neurons responsive to gastric vagal stimulation, 30 also responded to the cerebellar IN stimulus, indicating a convergence of gastric vagal and cerebellar inputs onto single hypothalamic cells. When the gastric vagal nerves and cerebellar IN were stimulated simultaneously, a summation of the responses was observed in all 6 neurons tested. Moreover, of 24 neurons that responded to both the gastric vagal and cerebellar IN stimuli, 15 (62.5%) were identified as glycemia-sensitive. These results demonstrate that the visceral information transmitted by the gastric vagal nerves and the somatic information forwarded by the cerebellar IN converge onto single LHA neurons, especially those sensitive to glycemia. The findings also suggest that integration of somatic-visceral responses related to short-term feeding regulation may take place in the LHA.     

Hypothalamic galanin is up-regulated during hyperphagia and increased body weight gain induced by disruption of signaling in the ventromedial nucleus

Disruption of signaling in the ventromedial nucleus (VMN) by colchicine (COL) produces transient (4 days) hyperphagia and weight gain. Microinjection of galanin into various hypothalamic sites stimulates feeding, so we tested the hypothesis that galanin is up-regulated in COL-treated rats by analyzing galanin concentrations in micropunched hypothalamic sites. Galanin was increased in the paraventricular nucleus on Days 1 through 4 after COL-injection. Galanin was also elevated in three other hypothalamic sites, the dorsomedial nucleus, lateral hypothalamic area, and perifornical hypothalamus, on Days 2-4 and in the lateral preoptic area, on Day 1 only. In the median eminence-arcuate nucleus and amygdala an initial decrease on Day 1 was followed by a then progressive increase through Day 4. These increases occurred despite marked elevations in blood insulin and leptin, hormones known to suppress hypothalamic galanin. When COL- or saline-treated rats were injected intracerebroventricularly with galanin, it stimulated feeding further in the hyperphagic COL-treated rats, but the relative response over basal consumption was similar in both COL-treated and control rats. These results in VMN disrupted rats suggest that neurochemical rearrangements, including increased availability of galanin, may contribute to the hyperphagia and increased weight gain; additionally, it seems that neurons in the VMN normally exert a restraint on galanin signaling.     

Loss of morphine hyperphagia following neonatal monosodium glutamate treatment in rats

Morphine stimulates food intake in mildly-deprived and nondeprived rats. Neonatal administration of monosodium glutamate (MSG) destroys the medial-basal hypothalamus and other circumventricular organs, including cells containing beta-endorphin that project to other hypothalamic nuclei proposed in the modulation of morphine hyperphagia. Food intake of MSG-treated and control rats were assessed following vehicle and morphine (1.0-5.0 mg/kg, sc) treatment in a mild (5h) food deprivation paradigm. Morphine hyperphagia was found to be absent in MSG-treated rats, although they responded normally to mild deprivation following vehicle treatment. These results add to the types of ingestive deficits observed in the MSG-treated rat, and suggest that the circumventricular system in general, and opioid medial-basal hypothalamic cells in particular may be implicated in morphine hyperphagia.     

Background impulse activity of neurons of the fastigial cerebellar nucleus of intact and labyrinthectomized rats under conditions of vibration

In acute experiments on nembutal-anesthetized (40 mg/kg, i.p.) albino rats, we recorded extracellularly and analyzed the background impulse activity (BIA) of neurons of the fastigial nucleus of the cerebellum. Experiments were carried out on intact and labyrinthectomized rats in the norm and after long-lasting (up to 15 days) influence of general vertical vibration (60 Hz, 0.4 mm, 2-h-long everyday sessions). Distributions of the neurons according to the level of regularity of BIA, dynamics of spike trains, pattern of histograms of interspike intervals (ISIs), and different frequency ranges of BIA were plotted; the mean frequency of this activity and the coefficient of variation of ISIs were also calculated. Possible mechanisms of the effects of long-lasting vibration of different durations on the BIA generated by neurons of the fastigial cerebellar nucleus in intact animals and after switching off of labyrinth afferent inputs are discussed. Neirofiziologiya/Neurophysiology, Vol. 38, No. 1, pp. 32–39, January–February, 2006.     

Hyperthermia induced by morphine administration to the VTA of the rat brain: an effect dissociable from morphine-induced reward and hyperactivity

Morphine action at opiate receptors in the ventral tegmental area (VTA) of the rat brain has been implicated in the production of increased locomotor activity and in morphine's rewarding properties. In the present experiments, bilateral administration of morphine (18 micrograms tapped into the tips of 28 gauge cannulae) into the VTA resulted in an increase in body temperature in rats. This effect was both reversed and blocked by a systemic injection of the opiate receptor blocker, naloxone, suggesting that it was due to morphine action at opiate receptors. The neuroleptic, pimozide, injected systemically four hours prior to morphine administration completely blocked the increased locomotor activity but had no effect on the hyperthermia. These data demonstrate that the hyperthermia was not brought about by the increased physical activity. Furthermore, these results suggest that while morphine-induced reward and increased locomotor activity may be mediated by an interaction of morphine and the ascending mesolimbic dopamine system, the hyperthermia is not. In an additional experiment, the effect of systemic injections of the central neurotransmitter receptor antagonists, scopolamine, phenoxybenzamine, and methergoline, on the hyperthermia induced by morphine in the VTA was investigated. Only the serotonin antagonist, methergoline, attenuated the hyperthermia.     

Morphine inhibits TRH-induced intestinal transit increases

The current study examined the effects of intraperitoneal (IP) and intracisternal (IC) administration of the opiate agonist, morphine, and an opioid, central beta-endorphin, on thyrotropin releasing hormone (TRH)-induced small intestinal transit increases. Anesthetized rats, 14-day and older, were studied to determine age-related differences. Results showed that in all age groups IP morphine (2 mg/kg) blocked TRH (15 μg)-induced increases in transit of a charcoal bolus. Morphine 1 μg and beta-endorphin 1 μg administered IC in 0.6 μl failed to block TRH (10 μg)-induced increases in intestinal transit in 14-day-old rats. However, both morphine and beta-endorphin 1 μg IC blocked TRH-induced increases in adult rats. Dose-response studies demonstrated that higher doses (> 1 μg) of morphine IC were required to block TRH-induced increases in preweaning rats.     

Hypothalamic orexin--a neurons are involved in the response of the brain stress system to morphine withdrawal

Both the hypothalamus-pituitary-adrenal (HPA) axis and the extrahypothalamic brain stress system are key elements of the neural circuitry that regulates the negative states during abstinence from chronic drug exposure. Orexins have recently been hypothesized to modulate the extended amygdala and to contribute to the negative emotional state associated with dependence. This study examined the impact of chronic morphine and withdrawal on the lateral hypothalamic (LH) orexin A (OXA) gene expression and activity as well as OXA involvement in the brain stress response to morphine abstinence. Male Wistar rats received chronic morphine followed by naloxone to precipitate withdrawal. The selective OX1R antagonist SB334867 was used to examine whether orexins' activity is related to somatic symptoms of opiate withdrawal and alterations in HPA axis and extended amygdala in rats dependent on morphine. OXA mRNA was induced in the hypothalamus during morphine withdrawal, which was accompanied by activation of OXA neurons in the LH. Importantly, SB334867 attenuated the somatic symptoms of withdrawal, and reduced morphine withdrawal-induced c-Fos expression in the nucleus accumbens (NAc) shell, bed nucleus of stria terminalis, central amygdala and hypothalamic paraventricular nucleus, but did not modify the HPA axis activity. These results highlight a critical role of OXA signalling, via OX1R, in activation of brain stress system to morphine withdrawal and suggest that all orexinergic subpopulations in the lateral hypothalamic area contribute in this response.     

Postnatal development of the hypothalamic ventromedial nucleus: neurons and synapses

1. In this report the postnatal differentiation of the hypothalamic ventromedial nucleus (VMN) was studied. The main maturational changes detected at the fine structural level occurred between 10 and 20 days of postnatal life. 2. In 5-day-old rats the majority of neurons was undifferentiated, with rudimentary cytoplasmic organelles. Dendritic profiles presented an empty appearance due to an electron-lucent matrix and scarce content of organelles. 3. At 10 days there was a significant proliferation of cytoplasmic organelles in the perikaryon, mainly of those involved in protein biosynthesis as the rough endoplasmic reticulum (RER) and the Golgi complex. 4. After 20 days of age the VMN neurons acquired the cytological appearance of adult neurons, with well-organized RER, Golgi complexes, and pleomorphic mitochondria. Concurrent with these changes, there was a marked development of other organelles in the neuropil, which was accompanied by an increase in synaptic density and differentiation of their subsynaptic structures.     

Hypothalamic Monoaminergic Activity in 11-Week-Old Cold-Exposed Female Lean (Fa/Fa) and Obese (fa/fa) Zucker Rats

We previously reported that serotonergic activity was reduced in the ventromedial hypothalamic nucleus (VMN) of obese vs. lean male Zucker rats. To verify that this reduction was associated with genotype rather than gender, we measured monoamines and their major metabolites in hypothalamic nuclei of ll-week-old female lean (Fa/Fb) and obese (fa/fb) Zucker rats. In addition, since the thermic response to cold is reported to differ between lean and obese rats, some rats were also exposed to 9° or 22° C for 2h to determine if cold exposure altered hypothalamic monoaminergic activity. As in males, levels of 5-hydroxyindoleacetic acid [5-HIAA; major metabolite of serotonin (5-HT)] and the ratio of 5-HIANS-HT were lower in the VMN of obese vs. lean females (P = 0.008, 0.001, respectively). S-HIANS-HT was also reduced in the paraventricular (PVN) and suprachiasmatic nuclei (SCN) of the obese compared to the lean females. Cold exposure significantly stimulated brown fat mitochondria1 GDP binding in lean but not obese rats. Similarly, levels of norepinephrine, dopamine (DA), 5-HIAA, and 5-HT in the PVN, and 5-HIAA in the SCN increased in cold-exposed lean but not obese rats. In contrast, VMN and preoptic 3,4-dihydroxyphenylacetic acid (DOPAC; major metabolite of DA) increased in the cold-exposed obese but not lean animals. We conclude that: (1) the blunted peripheral response to cold in obese vs. lean Zucker rats is accompanied by altered hypothalamic monoaminergic activity, the physiological role of which needs further evaluation; and 2) depressed VMN serotonergic activity is associated with the obese genotype (fa/fa) rather than gender and as such may contribute to the reduced sympathetic and enhanced parasympathetic outflow from the VMN .