Fos Immunoreactivity In Brain Research Articles

Effect of Melanotan‐II on Brain Fos Immunoreactivity and Oxytocin Neuronal Activity and Secretion in Rats

Melanocortins stimulate the central oxytocin systems that are involved in regulating social behaviours. Alterations in central oxytocin have been linked to neurological disorders such as autism, and melanocortins have been proposed for therapeutic treatment. In the present study, we investigated how systemic administration of melanotan-II (MT-II), a melanocortin agonist, affects oxytocin neuronal activity and secretion in rats. The results obtained show that i.v., but not intranasal, administration of MT-II markedly induced Fos expression in magnocellular neurones of the supraoptic (SON) and paraventricular nuclei (PVN) of the hypothalamus, and this response was attenuated by prior i.c.v. administration of the melanocortin antagonist, SHU-9119. Electrophysiological recordings from identified magnocellular neurones of the SON showed that i.v. administration of MT-II increased the firing rate in oxytocin neurones but did not trigger somatodendritic oxytocin release within the SON as measured by microdialysis. Our data suggest that, after i.v., but not intranasal, administration of MT-II, the activity of magnocellular neurones of the SON is increased. Because previous studies showed that SON oxytocin neurones are inhibited in response to direct application of melanocortin agonists, the actions of i.v. MT-II are likely to be mediated at least partly indirectly, possibly by activation of inputs from the caudal brainstem, where MT-II also increased Fos expression.

Mapping brain Fos immunoreactivity in response to water deprivation and partial rehydration: Influence of sodium intake

Water deprivation (WD) followed by water intake to satiety, produces satiation of thirst and partial rehydration (PR). Thus, WD–PR is a natural method to differentiate thirst from sodium appetite. WD–PR also produces Fos immunoreactivity (Fos-ir) in interconnected areas of a brain circuit postulated to subserve sodium appetite. In the present work, we evaluated the effect of sodium intake on Fos-ir produced by WD–PR in brain areas operationally defined according to the literature as either facilitatory or inhibitory to sodium intake. Isotonic NaCl was available for ingestion in a sodium appetite test performed immediately after a single episode of WD–PR. Sodium intake decreased Fos-ir in facilitatory areas such as the lamina terminalis (particularly subfornical organ and median preoptic nucleus), central amygdala and hypothalamic parvocellular paraventricular nucleus in the forebrain. Sodium intake also decreased Fos-ir in inhibitory areas such as the area postrema, lateral parabrachial nucleus and nucleus of the solitary tract in the hindbrain. In contrast, sodium intake further increased Fos-ir that was activated by water deprivation in the dorsal raphe nucleus, another inhibitory area localized in the hindbrain. WD–PR increased Fos-ir in the core and shell of the nucleus accumbens. Sodium intake reduced Fos-ir in both parts of the accumbens. In summary, sodium intake following WD–PR reduced Fos-ir in most facilitatory and inhibitory areas, but increased Fos-ir in another inhibitory area. It also reduced Fos-ir in a reward area (accumbens). The results suggest a functional link between sodium intake and the activity of the hindbrain–forebrain circuitry subserving reward and sodium appetite in response to water deprivation.

Temporal dissociation between sodium depletion and sodium appetite appearance: Involvement of inhibitory and stimulatory signals

Our aim was to analyze the participation of inhibitory and stimulatory signals in the temporal dissociation between sodium depletion (SD) induced by peritoneal dialysis (PD) and the appearance of sodium appetite (SA), particularly 2h after PD, when the rats are hypovolemic/natremic but SA is not evident. We investigated the effects of bilateral injections of the serotonin (5-HT) receptor antagonist, methysergide, into the lateral parabrachial nucleus (LPBN) on hypertonic NaCl and water intake 2h vs. 24h after PD. We also studied plasma renin activity (PRA) and aldosterone (ALDO) concentration 2h vs. 24h after PD. Additionally, we combined the analysis of brain Fos immunoreactivity (Fos-ir) with the detection of double immunoreactivity in 5HT and oxytocinergic (OT) cells 2h after PD. Bilateral LPBN injections of methysergide (4μg/200nl at each site) increased NaCl intake when tested 2h after PD compared to controls. We found a significant increase in PRA and ALDO concentration after PD but no differences between 2 and 24h after PD. We also found for the first time a significant increase 2h after PD in the number of Fos-ir neurons in the brainstem nuclei that have been shown to be involved in the inhibition of SA.In summary, the results show that 5HT-mechanisms in the LPBN modulate sodium intake during the delay of SA when the renin angiotensin aldosterone system (RAAS) is increased. In addition, the activation of brainstem areas previously associated with the satiety phase of SA is in part responsible for the temporal dissociation between SD and behavioral arousal.

Availability of a rich source of sodium during the perinatal period programs the fluid balance restoration pattern in adult offspring

Osmoregulatory mechanisms can be vulnerable to electrolyte and/or endocrine environmental changes during the perinatal period, differentially programming the developing offspring and affecting them even in adulthood. The aim of this study was to evaluate whether availability of hypertonic sodium solution during the perinatal period may induce a differential programming in adult offspring osmoregulatory mechanisms. With this aim, we studied water and sodium intake after Furosemide–sodium depletion in adult offspring exposed to hypertonic sodium solution from 1week before mating until postnatal day 28 of the offspring, used as a perinatal manipulation model [PM-Na group]. In these animals, we also identified the cell population groups in brain nuclei activated by Furosemide–sodium depletion treatment, analyzing the spatial patterns of Fos and Fos–vasopressin immunoreactivity.In sodium depleted rats, sodium and water intake were significantly lower in the PM-Na group vs. animals without access to hypertonic sodium solution [PM-Ctrol group]. Interestingly, when comparing the volumes consumed of both solutions in each PM group, our data show the expected significant differences between both solutions ingested in the PM-Ctrol group, which makes an isotonic cocktail; however, in the PM-Na group there were no significant differences in the volumes of both solutions consumed after Furosemide–sodium depletion, and therefore the sodium concentration of total fluid ingested by this group was significantly higher than that in the PM-Ctrol group.With regard to brain Fos immunoreactivity, we observed that Furosemide–sodium depletion in the PM-Na group induced a higher number of activated cells in the subfornical organ, ventral subdivision of the paraventricular nucleus and vasopressinergic neurons of the supraoptic nucleus than in the PM-Ctrol animals. Moreover, along the brainstem, we found a decreased number of sodium depletion-activated cells within the nucleus of the solitary tract of the PM-Na group.Our data indicate that early sodium availability induces a long-term effect on fluid drinking and on the cell activity of brain nuclei involved in the control of hydromineral balance. These results also suggest that availability of a rich source of sodium during the perinatal period may provoke a larger anticipatory response in the offspring, activating the vasopressinergic system and reducing thirst after water and sodium depletion, as a result of central osmosensitive mechanism alterations.

Effect of Complete Maternal and Littermate Deprivation on Morphine-Induced Fos-Immunoreactivity in the Adult Male Rat Brain

Previous research has demonstrated that rats reared in isolation from their dam and littermates show altered behavioral responsiveness to both natural and drug-mediated rewards. This study examined the effects of complete maternal deprivation through the use of artificial rearing on neural activation after acute morphine exposure in adulthood. Male rats were either artificially reared (AR) or maternally reared (MR) from postnatal day 5 to 21. In adulthood (4 mo old), rats received a single injection of morphine sulfate (10 mg/kg) or equivolume saline 2 h before perfusion and brain extraction. Neural activation was quantified using Fos immunohistochemistry. Analyses of several brain regions revealed a consistent pattern of differences between AR and MR rats. Specifically, relative to MR rats, AR rats showed significantly greater morphine-induced Fos-immunoreactivity in brain regions associated with the mesocorticolimbic "reward" pathway. These results support the hypothesis that functional activity in reward neurocircuitry can be altered by early life experience.

Effect of central urotensin II on heart rate, blood pressure and brain Fos immunoreactivity in conscious rats

Central administration of urotensin II (UII) increases heart rate (HR), cardiac contractility, and plasma levels of epinephrine and glucose. To investigate the mechanisms causing these responses we examined the effects of i.c.v. administration of rat UII (10 μg) on the sympatho-adrenal and pituitary–adrenal axes in conscious rats, and we mapped the brain sites activated by UII by immunohistochemically detecting Fos expression. In six conscious rats i.c.v. UII, but not vehicle, increased HR significantly 60–90 min after treatment and increased plasma glucose at 60 and 90 min, both indicators of increased epinephrine release. Plasma corticosterone levels were significantly elevated 90 min after i.c.v. UII. Conscious rats, given i.c.v. UII ( n=12) and killed after 100 or 160 min, showed increased Fos-immunoreactivity (Fos-IR) in the nucleus of the solitary tract and the central nucleus of the amygdala (CeA) at both time points, compared with vehicle ( n=11). In UII-treated rats, Fos-IR in the paraventricular nucleus of the hypothalamus (PVN) was significantly elevated at 160 min, but not 100 min, compared with vehicle. There were no increases in Fos-IR in the rostral ventrolateral medulla or the A5 cell group, areas associated with sympathetic outflow to the adrenal gland. In summary, i.c.v. UII increased HR and plasma glucose and corticosterone in conscious rats. UII increased Fos-IR in the CeA and PVN, but over a longer time course in the latter. These findings indicate that UII acts on specific brain nuclei to stimulate the hypothalamo-pituitary–adrenal axis and to stimulate adrenal sympathetic nerve activity.

The effect of urocortin on ingestive behaviours and brain Fos immunoreactivity in mice.

The influence of urocortin (UCN) on ingestive behaviours and brain neural activity, as measured immunohistochemically by the presence of Fos protein, was determined in mice. Rat UCN was administered by continuous intracerebroventricular (ICV) or subcutaneous (SC) infusion. ICV infusion of UCN (100 ng/h, 14 days) transiently reduced daily food and water intakes (days 1-4) but body weight was reduced from day 2 into the post-infusion period. Sodium intake was reduced from day 3 to the end of infusion. SC infusion of UCN caused similar but smaller reductions in food and water intakes and body weight, without change in sodium intake. In separate experiments, Fos immunoreactivity was increased in several brain nuclei known to be involved in the control of body fluid and energy homeostasis, e.g. central nucleus of the amygdala, median preoptic nucleus, bed nucleus of the stria terminalis and arcuate nucleus. Increased Fos expression was similar for ICV and SC infusions when measured on days 2-3 or 6-7 of infusion. In conclusion, increases of brain activity by UCN may be associated with stimulation of adrenocorticotrophic hormone release and sympathetic nervous activity, but increases may also indicate suppression of ingestive behaviours by stimulating central inhibitory mechanisms located in areas known to control body fluid and energy homeostasis.

Appearance of central dipsogenic mechanisms induced by dehydration in near-term rat fetus

Cellular dehydration of central osmoreceptors evokes an integration of behavioral (i.e. drinking) and endocrinologic (i.e. arginine vasopressin secretion) responses to maintain body fluid balance. These osmoregulatory mechanisms have been intensely investigated in adult models. However, there has been limited research of the fetal development of neural mechanisms regulating responses to dehydration. Although behavioral and neuroendocrine responses to dehydration have been demonstrated in utero in precocial species (e.g. ovine), there has been no study to date demonstrating that these responses develop before the neonatal period of altricial species (e.g. rat). This study is the first to use the near-term rat fetus to investigate the effects of maternal subcutaneous hypertonic (2 M NaCl) or isotonic (0.15 M NaCl) saline injection on fetal plasma osmolality and brain FOS-immunoreactivity (FOS-ir). Maternal subcutaneous hypertonic saline significantly increased maternal and fetal plasma osmolality to similar levels (328±6 and 326±6 mosM/kg, respectively). In response to plasma hypertonicity, maternal and fetal brain FOS-ir increased significantly in the regions including the lamina terminalis, and the supraoptic and paraventricular nuclei (SON and PVN) of the hypothalamus. Together, these data indicate that central mechanisms for dipsogenic and arginine vasopressin secretory responses to hypertonicity are present and responsive in the fetal rat brain at near-term gestation. However, differences between fetal and maternal FOS-ir mapping suggest that fetal osmoreceptor development is not yet completed near term.

Changes in pain threshold and lumbar spinal cord immediate-early gene expression induced by paced and nonpaced mating in female rats

Vaginocervical stimulation (VCS) received during mating is known to induce analgesia and to suppress FOS-immunoreactivity (FOS-IR) in lumbar spinal cord. However, it is not known whether this suppression of FOS-IR reflects inhibition of afferent nociceptive input. The present studies examined whether two immediate-early gene (IEG) products, FOS and Egr-1, covary with nociception by comparing both responses in estrous females that received mating stimulation known to induce varying amounts of FOS-IR in brain. Ovariectomized steroid-treated rats were mated under conditions in which they paced or did not pace sexual contacts with males until receiving 5 or 15 intromissions. Control groups received mounts-without-intromission only from males or remained in their homecages. In experiment I, paced mating resulted in a significant overall suppression of FOS-IR in the lumbar 6 (L6) spinal segment compared to nonpaced and mounts only stimulation. This reduction occurred specifically among paced females receiving five intromissions. In contrast, significant elevations above homecage levels were seen in paced females given 15 intromissions, all nonpaced females, and mounts only animals. The numbers of Egr-1-immunoreactive (Egr-1-IR) cells increased equally above homecage levels in all male-exposed females. In experiment II, females that received five intromissions (paced or nonpaced) showed significant increases in tail-flick latency (TFL) within 5 s (time 0) after mating, while females receiving 15 intromissions showed hyperalgesia (15 nonpaced) or no change (15 paced) in TFL throughout 90 s postmating. Additional females tested immediately after receiving two ejaculations showed analgesia. Paced mating, though more effective than nonpaced mating in suppressing FOS-IR, did not influence the appearance of VCS-induced analgesia. We conclude that the suppression of FOS-IR by paced mating is not related to mating-induced analgesia.

Effect of intracerebroventricular and intravenous insulin on Fos-immunoreactivity in the rat brain

The potential central neural substrate for the sympathoexcitatory effect of insulin was investigated in conscious rats using Fos expression as an index of neural activity. Fos immunoreactivity in the hypothalamus and brainstem was compared in rats infused with intracerebroventricular (i.c.v.) insulin or saline for 60 min. The insulin had no effect on Fos expression in any brain nuclei. Likewise, a 90-min intravenous infusion of insulin (euglycemic) had no effect on brain Fos immunoreactivity. However, when blood glucose was allowed to decrease, Fos expression did increase in the arcuate nucleus and in the brainstem. These data do not provide any evidence to support the idea that insulin can act within the central nervous system to increase sympathetic nervous outflow.

Fos immunoreactivity in the rat brain following consummatory elements of sexual behavior: a sex comparison

In the present study a comparison was made between the distribution of Fos immunoreactivity in the brain of female and male rats following successive elements of sexual behavior. The distribution of Fos immunoreactivity following either mounting, eight intromissions or one or two ejaculations was compared with that in control animals. In both females and males, Fos immunoreactivity was induced in the medial preoptic nucleus, posteromedial part of the bed nucleus of the stria terminalis, posterodorsal part of the medial amygdala, and the parvicellular part of the subparafascicular thalamic nucleus. In addition, Fos immunoreactivity in females was induced in the ventrolateral part and the most caudoventral part of the ventromedial nucleus of the hypothalamus and in the premammillary nucleus. Differences between females and males were detected in the phases of sexual activity that resulted in Fos immunoreactivity in these brain areas, allowing more insight in the nature of the sensory and hormonal stimuli leading to the induction of Fos immunoreactivity. The posteromedial bed nucleus of the stria terminalis appears to be involved in chemosensory investigation, while specific distinct subregions are only activated following ejaculation. In addition, the parvicellular subparafascicular nucleus and the lateral part of the posterodorsal medial amygdala appear to be involved in the integration of viscero-sensory input. The neural circuitries underlying sexual behavior in males and females appear to be similar in terms of integration of sensory information. In males the medial preoptic nucleus may be regarded as the brain area where the integration of sensory and hormonal stimulation leads to the onset of male sexual behavior, while in females the ventrolateral part of the ventromedial hypothalamic nucleus appears to have this function. In addition, Fos immunoreactivity was distributed in distinct clusters in subregions within various brain areas in males and females. This was observed especially in the posteromedial bed nucleus of the stria terminalis and posterodorsal medial amygdala, but also in the parvicellular subparafascicular nucleus, ventromedial hypothalamic nucleus and ventral premammillary nucleus. It appears that relatively small subunits within these nuclei seem to be concerned with the integration of sensory and hormonal information and may play a critical role in sexual behavior.