Divergent effects of acute and chronic monosodium L-glutamate treatment on the anterior and posterior parts of the arcuate nucleus

Forebrain projections of arcuate neurokinin B neurons demonstrated by anterograde tract-tracing and monosodium glutamate lesions in the rat

Neurokinin B (NKB) and kisspeptin receptor signaling are essential components of the reproductive axis. A population of neurons resides within the arcuate nucleus of the rat that expresses NKB, kisspeptin, dynorphin, NK3 receptors and estrogen receptor alpha (ERalpha). Here we investigate the projections of these neurons using NKB-immunocytochemistry as a marker. First, the loss of NKB-immunoreactive (ir) somata and fibers was characterized after ablation of the arcuate nucleus by neonatal injections of monosodium glutamate. Second, biotinylated dextran amine was injected into the arcuate nucleus and anterogradely labeled NKB-ir fibers were identified using dual-labeled immunofluorescence. Four major projection pathways are described: (1) local projections within the arcuate nucleus bilaterally, (2) projections to the median eminence including the lateral palisade zone, (3) projections to a periventricular pathway extending rostrally to multiple hypothalamic nuclei, the septal region and BNST and dorsally to the dorsomedial nucleus and (4) Projections to a ventral hypothalamic tract to the lateral hypothalamus and medial forebrain bundle. The diverse projections provide evidence that NKB/kisspeptin/dynorphin neurons could integrate the reproductive axis with multiple homeostatic, behavioral and neuroendocrine processes. Interestingly, anterograde tract-tracing revealed NKB-ir axons originating from arcuate neurons terminating on other NKB-ir somata within the arcuate nucleus. Combined with previous studies, these experiments reveal a bilateral interconnected network of sex-steroid responsive neurons in the arcuate nucleus of the rat that express NKB, kisspeptin, dynorphin, NK3 receptors and ERalpha and project to GnRH terminals in the median eminence. This circuitry provides a mechanism for bilateral synchronization of arcuate NKB/kisspeptin/dynorphin neurons to modulate the pulsatile secretion of GnRH.

Calorie restriction alters physical performance but not cognition in two models of altered neuroendocrine signaling

A major neuroendocrinological effect of calorie restriction (CR) is induction of neuropeptide Y (NPY) in the arcuate nucleus (ARC). Aside from its appetite-stimulating effects, NPY is thought to be involved in the modulation of behavioral processes including anxiety and learning and memory. In the present study physical fitness, anxiety, and learning/memory-related tasks were assessed in mice lacking NPY or a functional ARC after dietary manipulation by CR. Physical fitness was improved by CR when measured by inclined screen and rotarod, and this diet effect was not affected by NPY or ARC status. As has been observed previously, the NPY knockout mice displayed heightened anxiety in an open field. This phenotype was not fully recapitulated in the ARC-lesioned model. CR affected neither total locomotor activity in the open field nor thigmotaxic behavior in these models. Neither NPY nor CR had a significant effect on Morris water maze performance; however, ARC-damaged mice were unable to learn the task, and this deficit was not corrected by CR. We conclude that despite established effects of CR on ARC signaling, our results suggest a mechanistic separation between the two where behavior is concerned.

Changes in open-field activity and novelty-seeking behavior in periadolescent rats neonatally treated with monosodium glutamate

Monosodium glutamate (MSG) treatment of neonatal rodents leads to degeneration of the neurons in the arcuate nucleus, inner retinal layers and various other brain areas. It also causes various changes in the motor activity, sensory performance and learning abilities. We have previously shown that MSG treatment delays the appearance of some reflexes during neurobehavioral development and leads to temporary changes in reflex performance and motor coordination. Investigation of novelty-seeking behavior is of growing importance for its relationship with sensitivity to psychomotor stimulants. Perinatal administration of numerous toxic agents has been shown to influence novelty-seeking behavior in rats, but little is known about the influence of neonatal MSG treatment on the novelty-seeking behavior. The aim of the present study was to compare changes in locomotor, spontaneous exploratory and novelty-seeking behavior in periadolescent rats neonatally treated with MSG. Newborn rats were treated with 4 mg/g MSG subcutaneously on postnatal days 1, 3, 5, 7 and 9. Open-field behavior was tested at 2, 3, 4, 6 and 8 weeks of age. We found that MSG administration led to only temporary increases in locomotor behavior, which was more pronounced during the first few postnatal weeks, followed by a subtle hypoactivity at 2 months of age. Novelty-seeking was tested in four 5-min trials at 3 weeks of age. Trial 1 was in an empty open-field, two identical objects were placed in the arena during trial 2 and 3, and one of them was replaced to a novel object during trial 4. We found that the behavioral pattern of MSG-treated rats was the opposite in all tested signs in the novelty exploration test compared to control pups. In summary, our present study shows that neonatal MSG treatment leads to early temporary changes in the locomotor activity followed by hypoactivity at 2 months of age. Furthermore, MSG-treated rats show a markedly disturbed novelty-seeking behavior represented by altered activity when subjected to a novel object.

Fat storage is partially dependent on vagal activity and insulin secretion of hypothalamic obese rat

Hypothalamic MSG-obese rats show hyperinsulinemia and tissue insulin resistance, and they display intense parasympathetic activity. Current analysis investigates whether early subdiaphragmatic vagotomy prevents tissue insulin sensitivity impairment in adult obese MSG-rats. Hypothalamic obesity was induced by MSG (4 mg/g BW), daily, from birth up to 5 days. Control animals receiving saline solution. On the 30th day rats underwent bilateral subdiaphragmatic vagotomy or sham surgery. An intravenous glucose tolerance test (i.v.GTT) was performed when rats turned 90 days old. Total white fat tissue (WAT) from rat carcass was extracted and isolated; the interscapular brown fat tissue (IBAT) was weighed. Rather than blocking obesity, vagotomy reduced WAT and IBAT in MSG-obese rats when the latter were compared to sham MSG-rats. High blood fasting insulin and normal glucose levels were also observed in MSG-obese rats. Although glucose intolerance, high insulin secretion, and significant insulin resistance were recorded, vagotomy improved fasting insulinemia, glucose tolerance and insulin tissue sensitivity in MSG-obese rats. Results suggest that increased fat accumulation is caused, at least in part, by high blood insulin concentration, and enhanced parasympathetic activity on MSG-obese rats.

Effects of the neonatal treatment with monosodium glutamate on myenteric neurons and the intestine wall in the ileum of rats

BACKGROUND

The neonatal administration of a 4 mg/g dose of monosodium glutamate (MSG) to rodents leads to neuronal death in the hypothalamus arcuate nucleus, which leads in turn to obesity in the adult animal. However, few studies have investigated the effects on the enteric nervous system. This study evaluated the effects of the neonatal administration of MSG on the frequency and morphometry of the myenteric as well as the ileum wall morphometry of adult Wistar male rats.

METHODS

Whole-mount preparations of ileum samples were stained by the Giemsa or NADH-diaphorase histochemical methods. For histological processing, hematoxylin and eosin staining was used.

RESULTS

The treatment with MSG led to obesity, as shown by the higher values for Lee's index and the weights of periepididimal and retroperitoneal adipose tissues. The Giemsa staining revealed a significantly larger neuronal density in the MSG group, which is explained by smaller physical growth and a reduction in the weight of the small intestine. The mean neuronal profile did not change between groups. The NADH-diaphorase-positive neuronal subpopulation kept its neuronal density but its average cellular profile was reduced in the MSG group. A morphometric analysis of the intestinal wall, muscular layer, villi, and intestinal crypts showed that their characteristics did not change.

CONCLUSIONS

The treatment with MSG did not cause alteration of the total myenteric population of the ileum, but it influenced the NADH-diaphorase-positive subpopulation. From the maintenance of the morphometric parameters of the ileum intestinal wall, we inferred that intestinal function was preserved in obese animals.

Development of neurological reflexes and motor coordination in rats neonatally treated with monosodium glutamate

Monosodium glutamate (MSG) treatment of neonatal rats causes neuronal degeneration in various brain areas and leads to several neurochemical, endocrinological and behavioral alterations. However, relatively little is known about the development of neurological reflexes and motor coordination of these animals. Therefore, the aim of the present study was to examine the neurobehavioral development of newborn rats treated with MSG. Rats received MSG at postnatal days 1, 3, 5, 7, and 9. Appearance of neural reflexes and reflex performance as well as motor coordination were examined for 5 weeks after birth. The efficacy of MSG treatment was confirmed by histological examination of the arcuate nucleus. We found that MSG treatment delayed the appearance of forelimb placing, forelimb grasp and righting reflexes, besides the retarded somatic development. The treated pups performed surface righting in significantly longer times. Also, worse performance was observed in the foot-fault and rota-rod tests. However, MSG-treated rats reached control levels by the end of the fifth postnatal week. These results show that MSG treatment does not cause permanent alterations in the neurobehavioral development, only delays the appearance of some reflexes and leads to temporary changes in reflex performance and motor coordination signs.

Hypothalamic resistin immunoreactivity is reduced by obesity in the mouse: co-localization with alpha-melanostimulating hormone

Resistin is a new adipokine expressed in mouse, rat and human adipose tissue. Resistin may be an important link between obesity and insulin resistance, though this controversial view is complicated by the discovery of multiple sites of resistin expression, including human macrophages, placenta and pancreas. In previous studies we demonstrated that the mouse hypothalamo-pituitary system was also a site of resistin production. Pituitary resistin is developmentally regulated, reduced in the ob/ob mouse and severely down-regulated by food deprivation (24 h). An unexpected finding was that hypothalamic resistin mRNA remained unaffected by fasting. The present experiments examined the localization and possible regulation of hypothalamic resistin protein. Using immunohistochemistry we observed a complex network of resistin+ fibres extending rostrally from the arcuate nucleus of the hypothalamus (ARC) to the preoptic area. Labelled cell bodies occurred only in the ARC and in a periventricular region of the dorsal hypothalamus. Hypothalamic resistin immunoreactivity (ir) was unaffected by fasting (48 h) or by a high fat diet, but the periventricular staining was greatly increased in the lactating mouse. Marked reductions in resistin+ fibres were seen in brain tissue from: (a) ob/ob mice, (b) young mice made underweight for their age by raising them in large litters (20 pups per litter) and (c) mice with hypothalamic lesions induced by monosodium glutamate (MSG) or gold thioglucose (GTG). We speculate that the resistin-ir deficit in genetically obese mice, and in severely underweight mice, could be due to low or absent leptin. In contrast, though MSG- and GTG-treated mice have high levels of circulating leptin, in the presence of excessive visceral fat deposits, we hypothesize that damage to the ARC destroys the resistin+ cell bodies. This latter supposition led us to an additional hypothesis, that resistin-ir would be contained in neurons expressing the proopiomelanocortin (POMC) gene. This proved to be correct. Double label immunofluorescence histochemistry revealed that alpha-MSH-ir, a marker for POMC neurons, was co-localized with resistin-ir. In conclusion, our data reveal a second example of an adipocytokine co-localized with a hypothalamic neuropeptide. We reported previously that leptin was co-localized with oxytocin and vasopressin. RT-PCR analysis confirmed that resistin mRNA is readily detectable in ARC, but further work is required to determine whether the resistin gene is expressed in POMC neurons or if resistin is specifically accumulated by these cells. Nonetheless, our data suggest that the hypothalamus is a target tissue for resistin.

Resistin expression and regulation in mouse pituitary

Resistin, a new adipocytokine, is expressed in human, rat and mouse adipose tissue. Its putative role as a mediator of insulin resistance is controversial. We hypothesized that resistin, in common with leptin, has multiple roles in non-adipose tissues. Using reverse transcription polymerase chain reaction (RT-PCR) we show that the resistin gene (Retn) is expressed in mouse brain (hypothalamus and cortex) and pituitary gland. Immunohistochemistry revealed resistin protein in the arcuate nucleus and pituitary gland. Semi-quantitative RT-PCR analysis indicated that Retn mRNA is developmentally regulated in the pituitary. Expression was lowest at birth, increased abruptly between postnatal days 14 and 25 (four-fold; P<0.001), and declined thereafter. This peak in pituitary Retn mRNA was unaffected by early weaning but was abolished by neonatal treatment with monosodium glutamate, suggesting that the basal hypothalamus regulates pituitary Retn. Although the role(s) of endogenous resistin in mouse brain and pituitary remains to be determined, it may be distinct from its controversial involvement in insulin resistance. Our data suggest that local resistin expression could have functional implications during prepubertal maturation of the hypothalamic-pituitary system.

Effect of neonatal treatment with monosodium glutamate on dopaminergic and L-DOPA-ergic neurons of the medial basal hypothalamus and on prolactin and MSH secretion of rats

The effect of neonatal treatment with monosodium L-glutamate (MSG) on the dopaminergic systems of the medial basal hypothalamus has been investigated using tyrosine hydroxylase (TH) and aromatic L-amino acid decarboxylase (AADC) immunocytochemistry. Changes in plasma levels of prolactin (PRL) and alpha-melanocyte-stimulating hormone (MSH) have also been determined in intact and in MSG-treated rats after inhibition of TH by alpha-methyl-p-tyrosine (alpha-MpT) or without inhibition of enzyme activity. Monosodium glutamate resulted in a 40% reduction in the number of TH immunopositive tuberoinfundibular neurons, but no change in the number of AADC-positive tuberoinfundibular nerve cells, indicating that this reduction has occurred mainly in TH-positive but AADC-negative elements, i.e., in L-DOPA-ergic neurons. In contrast, MSG did not cause changes in the number of TH and AADC immunoreactive neurons of the periventriculohypophysial and tuberohypophysial dopaminergic systems, and it did not influence basal plasma PRL levels. alpha-methyl-p-tyrosine has increased plasma PRL concentrations in both control and MSG-treated rats of both sexes, but significantly higher responses were detected in females. None of the treatments had any effect on plasma MSH level. These findings suggest that MSG affects primarily L-DOPA-ergic neurons located in the ventrolateral part of the arcuate nucleus, but not dopaminergic neurons situated in the dorsomedial part of the arcuate nucleus; neither PRL nor MSH secretion is altered by MSG; a significant sex difference exists in the pituitary PRL response to inhibition of TH, and this response is not affected by MSG.

Efeito da vagotomia troncular em ratos injetados na fase neonatal com glutamato monossódico: estudo biométrico

Obesidade hipotalâmica pode ocorrer em humanos e pode ser reproduzida, experimentalmente, por lesão do VMH em ratos. Esta obesidade pode ser revertida por vagotomia troncular (VT), devido à redução da ingestão alimentar e da insulinemia mediada pelo nervo vago. Experimentalmente, a injeção de MSG causa lesão em nível de ARC. O objetivo deste trabalho é avaliar os efeitos do MSG em ratos e se VT os altera. Estudou-se 52 ratos Wistar machos, divididos em dois grupos de 26 animais, um submetido à injeção de MSG na fase neonatal e outro à de solução salina. Aos 30 dias de vida, após nova divisão, obteve-se: grupo MSG, submetido à VT (VTMSG), e outro à laparotomia (LAPMSG); grupo SALINA, submetido à VT (VTSAL), e outro à laparotomia (LAPSAL). Obteve-se peso, CNA e índice de Lee. O consumo alimentar foi obtido dos 30 aos 90 dias de vida. Aos 90 dias, após eutanásia, mensurou-se peso, CNA, índice de Lee e gordura perigonadal. Análise estatística foi realizada pelo "t de Student". Constatou-se que o MSG provoca redução do CNA e aumento do índice de Lee aos 30 dias de vida, e provoca redução do peso e do CNA, aumento do índice de Lee e da gordura perigonadal aos 90 dias e aumento do consumo alimentar dos 30 aos 90 dias de vida. A VT provoca redução do peso, do índice de Lee e da gordura perigonadal, e tendência à redução do CNA no rato injetado com MSG. A VT provoca redução de consumo alimentar nos primeiros 30 dias de pós-operatório, mas com tendência a maior consumo nos 30 dias subseqüentes. Conclui-se que o MSG injetado na fase neonatal provoca aumento do consumo alimentar e da adiposidade e causa redução da estatura e do peso do animal dos 30 aos 90 dias de vida. E que a VT, realizada aos 30 dias de vida, provoca redução do consumo alimentar nos primeiros 30 dias de pós-operatório, da adiposidade e do peso.

Neural transplants. effects On startle responses in neonatally MSG-treated rats

Neonatal monosodium glutamate (MSG) treatment has been associated with dysfunctions in stress responses. Therefore, the present study aimed at examining the acoustic startle response (ASR) in MSG-treated rats and the effects of fetal neural transplantation. Male and female rats were given MSG (4 mg/g) or saline on alternate days from days 2-10 after birth. To determine whether fetal transplants could reverse behavioral impairments observed in MSG-treated rats, at 12 days of age MSG-treated rats received either arcuate nucleus (AN), cortical fetal grafts, or sham surgery into the third ventricle. ASR amplitude was measured at 35-40 days of age, and again in adulthood. MSG produced the expected decrease in the density of hypothalamic neuropeptide Y (NPY) and tyrosine hydroxylase (TH) in the AN area. Corticotropin-releasing factor (CRF) neurons/fibers were not affected by MSG. Pituitary atrophy was observed in all MSG rats. We report a permanent increase in the amplitude and reduction in short-term habituation of ASR in all MSG-treated rats. No effect was observed on long-term habituation in male rats. Cortical, but not AN tissue significantly reduced the magnitude of ASR in MSG animals. The results are discussed in terms of the central pathways mediating ASR, in particular hypothalamo-amygdala connections. It is considered that nonspecific factors mediate recovery produced by cortical tissue grafts, as observed in other models of neural transplantation.

The intergeniculate leaflet does not mediate the disruptive effects of constant light on circadian rhythms in the rat

Prolonged constant light exposure causes disruptions in circadian rhythms, resulting in splitting of circadian activity rhythms in hamsters and arrhythmicity in rats. Hamsters with lesions of the thalamic intergeniculate leaflet do not exhibit constant light-induced disruptions in rhythmicity. We have shown that circadian rhythms of rats with monosodium glutamate-induced neurotoxic damage to visual pathways persist under constant light, and hypothesized that monosodium glutamate damaged the retinogeniculate pathway, thus preventing constant light-induced arrhythmicity. The present study demonstrates, however, that the intergeniculate leaflet does not mediate these effects in rats. Rats with bilateral electrolytic intergeniculate leaflet lesions showed the same rate of disruption of circadian temperature rhythms as did sham-operated animals, housed under constant light. We also show that, unlike intergeniculate leaflet-lesioned rats, rats treated neonatally with monosodium glutamate exhibit neuropeptide Y fiber staining in the suprachiasmatic nucleus, indicating that the geniculohypothalamic tract is functionally intact following monosodium glutamate treatment. Taken together, these data demonstrate that the disruption of circadian rhythms during constant light exposure is not mediated directly via the geniculohypothalamic tract in rats. Whether this disruption in rhythmicity results from effects of constant light exposure on the circadian pacemaker, or is a direct effect of light on body temperature, is unknown. Retinal or collicular damage in monosodium glutamate-treated rats may render these animals insensitive to the disruptive effects of constant light.

Neonatal hypothalamic c-fos expression in an excitotoxicity-induced model of precocious puberty

We have used immunocytochemical detection of c-fos expression (FOS-like immunoreactivity, FLI) to establish the site of action of monosodium glutamate (MSG) in neonatal rats in a model of lesion-induced precocious puberty. The primary target appears to be the hypothalamic arcuate nucleus (ARC) but other circumventricular organs (CVO) are also affected (e.g. subfornical organ). Single injections of MSG (1-4 mg/g single dose, postnatal day 2 (P2)) which result in precocious puberty induce an area of edema, surrounded by a ring of FLI in the basal hypothalamus. In contrast, a maximal sub-lethal dose of NMDA (N-methyl-D-aspartate; 3 mg/kg) which produces a different pattern of ARC FLI, without edema, has no effect on puberty. Multiple doses of MSG (4 mg/g P2, P4, P6, P8), consistent with severe ARC damage and resultant sterility, markedly attenuates the FLI response by P8, with no visible edematous reaction following the final injection. In efforts to block the effect of MSG, pretreatment with the NMDA receptor-specific antagonist MK-801 (dizocilpine maleate) prevented the appearance of edema, as well as the onset of precocious puberty. However, MK-801 did not completely eliminate the FLI, but transformed the pattern of staining so that the original edematous area now contained many FOS-positive cells. This remaining MSG-induced FLI could not be eliminated by higher doses of MK-801 or by the non-NMDA antagonist DNQX (6,7-dinitroquinoxaline-2,3-dione). The combination of MK-801 and DNQX was also ineffective. MK-801 or DNQX had no effect on FLI when injected alone (i.e., without MSG) or in combination. The receptor which mediates MSG-induced c-fos expression, in the presence of MK-801 or DNQX, needs to be identified. We conclude, in conjunction with our previous work, that MSG induces precocious sexual maturation via an MK-801-sensitive mechanism associated with an edematous response of the basal hypothalamus. Whether the appearance of edema is indicative of an excitotoxic action of MSG, resulting in the removal of neurons inhibitory to sexual maturation, remains to be established.

Recovery of hypothalamic NMDA-induced c-fos expression following neonatal glutamate (MSG) lesions

The neonatal brain is susceptible to neurotoxic insult. In a previous report we showed that a single neonatal injection of MSG, known to cause damage in the arcuate nucleus (ARC), induces a precocious yet otherwise normal puberty in female rats. We have examined this ability of the medial basal hypothalamus (MBH) to recover from an excitotoxic insult using the immediate-early gene c-fos as a developmental marker of ARC response to glutamate receptor stimulation with N-methyl-D-aspartate (NMDA). Groups of neonatal (postnatal day (PD) 2) pups were injected with MSG, then stimulated on subsequent days (PD 3-29) with NMDA, known to induce c-fos expression in ARC. Computer-assisted densitometry was used to quantify Fos-like immunoreactivity (FLI) profiles in ARC. Pups treated neonatally with saline (PD 2) showed a robust, age-specific expression of FLI in the ARC following NMDA treatment. The FLI response was absent in the days immediately following an MSG lesion but subsequently recovered up to 75% of maximum by PD 16. Almost full recovery was seen by PD 29. We also examined the ability of the ARC to recover following chronic MSG treatment (PD 2-8), known to induce extensive hypothalamic damage. These pups displayed an unusual response to subsequent NMDA injection, consisting of 5 min cycles of hyper- and hypoactivity. Stimulation with NMDA revealed only a 50% recovery of FLI even at PD 29. In both treatment groups (acute vs. chronic MSG) the zone of recovery (i.e., reappearance of FLI) was initiated close to the third ventricle and with time radiated towards the periphery of the ARC. Some cells which reacquired FLI in the ARC following lesions presented a highly irregular condensed nuclear morphology. We conclude that the recovery of hypothalamic function (i.e., onset of puberty) after a neonatal MSG lesion is coincident with the reappearance of a normal pattern of c-fos expression in response to NMDA stimulation.

Neonatal monosodium glutamate treatment prevents effects of constant light on circadian temperature rhythms of adult rats

Housing rats under continuous illumination (LL) disrupts circadian rhythms controlled by a pacemaker located in the hypothalamic suprachiasmatic nucleus (SCN). The neural mechanisms underlying this effect are not well understood. The present study examined the effects of LL on circadian rhythms and on light-induced expression of Fos protein in the SCN, intergeniculate leaflet (IGL), and ventrolateral geniculate nucleus (vLGN) in adult rats treated neonatally with monosodium glutamate (MSG). Such treatment is known to lead to acute degeneration of retinal ganglion cells. Despite degeneration of the optic nerve, neonatal MSG treatment (2 mg/g SC on postnatal days 1,3,5,7, and 9) had no effect on daily temperature rhythms in the adult animal under a light-dark cycle. However, the disintegration of circadian rhythms under LL conditions observed in adult rats treated neonatally with 10% saline was prevented in MSG-treated rats. Furthermore, neonatal MSG treatment attenuated light-induced expression of Fos protein in the IGL and vLGN, but not in the SCN. These data suggest that neonatal MSG treatment alters the response of the circadian system to LL and that cells within the IGL/vLGN region may mediate this response.

A possible role of glutamate in the aging process

Glutamate (Glu) is considered here for its possible role as a naturally occurring mammalian 'age inducing' substance. The existence of 'Glu elicited headaches', may serve as an indication that Glu could negatively affect the human adult CNS. The prevalence of Glu induced headaches was found to be 28.8% in a study population of 201 subjects. Circumstantial similarities between brain aging and Glu toxicity are presented in the paper. Finally, it is mentioned that Vitamin E is partially effective in blocking Glu induced headaches.

Transplantation of fetal growth hormone-releasing factor-immunoreactive neurons into the ventricular system of adult MSG-treated rats

Fetal (17-18 days of gestation) mediobasal hypothalamic tissue (MBH) was transplanted into the third ventricle of adult, male rats which had been treated neonatally with monosodium glutamate (MSG). MSG treatment caused a marked reduction of growth hormone-releasing factor-like-immunoreactive (GRF-i) perikarya in the arcuate nucleus and GRF-i fibers in the median eminence (ME), as compared to littermate controls. When normal fetal MBH was transplanted into the third ventricle of MSG recipients, numerous GRF-i perikarya were located within the graft four weeks following surgery. GRF-i fibers in the ME of MSG-treated rats were enhanced when MBH grafts were in close contact with the ME, but not when transplants were located dorsally or rostrally in the third ventricle without making contact with the recipient's ME. Fetal cerebral cortex, which was grafted as a control tissue, did not contain GRF-i neurons. These immunohistochemical results suggest that grafted fetal GRF-i perikarya may contact the recipient's ME to increase the content of GRF previously depleted by exposure to MSG.

Are neurons of the arcuate nucleus necessary for pathfinding by GnRH fibers arising from third ventricular grafts?

The hypogonadal (hpg) mouse lacks GnRH due to a severe truncation of the gene by which it is encoded. This results in an infertile animal with an infantile reproductive system. When fetal or 1-day postnatal septal/preoptic area of a normal mouse is grafted into the third ventricle of an hpg mouse, GnRH-containing fibers grow out of the grafts and innervate the host median eminence (ME), a normal target of these fibers. GnRH axons exiting the graft course follow a very stereotyped pathway through host tissue. They are observed passing through the ependymal wall of the ventricle directly into the ME or arching through the host arcuate nucleus to terminate in the host ME. Given the fixed pattern of outgrowth, we wanted to determine if the neurons of the arcuate nucleus, which lie between the graft and its target, are exerting an influence on the growth and direction of these fibers. The excitotoxin monosodium glutamate (MSG) has been shown to destroy the vast majority of arcuate neurons when administered neonatally. Mutant host animals treated with MSG received fetal grafts of normal septal/preoptic area. Brains were examined for GnRH fiber outgrowth 30 days later to assess early outgrowth which preferentially uses the arcuate route. We report here that the pattern of outgrowth is virtually identical to that observed in saline-injected, grafted animals. There is also no difference in the success rate of grafts placed in control vs MSG-treated hosts nor in the stimulation of testicular growth. The results of this experiment imply that axonal outgrowth to the ME does not rely on arcuate neurons for guidance information or trophic substances. These functions may be subserved by glia, tanycytes/ependyma, or the target.

[Hyperinsulinemia and B-cell proliferation in rats treated postnatally with L-glutamate]

Development of hyperinsulinemia was investigated which appeared late in the obese state in rats postnatally treated with L-glutamate. Insulin concentrations were estimated in the blood plasma of the caval and portal vein, and morphometric and immunohistochemical measurements of cells in the islets of Langerhans were performed, and also glucose tolerance tests. Not earlier than at 3 months hyperinsulinemia is shown in glutamate obese rats (GOR) in the peripheral blood plasma. Also in the portal blood plasma the insulin concentration is higher (167%) in GOR relative to controls. The insulin concentrations in the portal vein rise further in both animal groups whereas insulin concentration in the peripheral blood remains at the different levels in both animal groups. Impaired glucose tolerance was observed for GOR only. Islets of Langerhans in the Pancreas show enlargement and increased proliferation of B-cells in GOR. In contrast the number of D-cells is diminished. The hyperplasia of islets differs remarkably to hypoplasia of other organs in GOR. We conclude that the peripheral hyperinsulinemia is caused by a permanent hypersecretion of insulin.

Age- and dose-dependent effects of neonatal monosodium glutamate (MSG) administration to female rats

The age- and dose-dependent effects of neonatal MSG were evaluated in pre- and postpubertal female rats. The neurotoxic action of MSG was assessed by examining monoamine content in microdissected regions of the mediobasal hypothalamus. MSG was administered at a dose of 4 mg/g on postnatal days 2 and 4 (MSG-Lo) or on postnatal days 2, 4, 6 and 8 (MSG-Hi). MSG-Hi treatment significantly reduced dopamine (DA) content in the arcuate nucleus (ANH) and lateral median eminence (LME) on postnatal day 21 when compared to NaCl-injected controls. DA content relative to controls was not altered in the ANH or LME postnatal or postnatal day 60 in MSG-Hi, however, norepinephrine (NE) was significantly (p less than 0.05) decreased on both postnatal day 21 and 60 in the LME. MSG-Lo treatment significantly (p less than 0.05) reduced ANH NE content on postnatal day 60 compared to controls. Both MSG-Hi and MSG-Lo treatment increased 5-hydroxyindoleacetic acid content in the preoptic area (POA) on postnatal day 60 relative to the controls. Developmental changes independent of MSG treatment were noted in the hypothalamus. DA and 3,4-dihydroxyphenylacetic acid (DOPAC) content in the POA were 2-3-fold higher on postnatal day 21 compared to postnatal day 60. In contrast, DA content increased with age in the ANH, LME and medial ME. NE content in the ANH increased as a function of age in controls, but not in MSG-treated rats. The effects of MSG treatment on the postnatal development and maturation of neurons in the mediobasal hypothalamus were discussed in relation to the direct neurotoxicity of MSG.

A pharmacological analysis of food intake regulation in rats treated neonatally with monosodium L-glutamate (MSG)

Studies were conducted to examine deficits in food intake regulation in MSG-treated rats that result from known or suspected damage to neurotransmitter systems involved in feeding. Male rats were injected with either MSG (4 mg/g) or sodium chloride on postnatal days 2 and 4 (MSG-Lo) or postnatal days 2, 4, 6 and 8 (MSG-Hi). As adults, MSG-treated and control rats (n = 12/group) were examined for deficits in pharmacologically elicited feeding and other measures of food intake regulation. A second group of MSG-treated (n = 9/group) and control rats (n = 12) were used to measure basal blood pressure and nociceptive reactivity in adulthood. Organ weights, body weight and neuropeptide Y (NPY) content in brain regions were determined at the end of the study. MSG-Hi rats consumed significantly less food than controls during the dark part of the light cycle. Both MSG-Hi and MSG-Lo groups ate significantly less food than controls after a 48-hour fast. MSG-Hi and MSG-Lo rats consumed significantly less food than controls in response to 1.0 mg/kg morphine. MSG-Hi rats consumed significantly less food than controls during the dark phase and significantly more food than controls during the light phase in response to naloxone (1.0 mg/kg). MSG-Lo ate significantly more than controls in response to 0.1 mg/kg guanfacine. MSG-Hi and MSG-Lo showed a significant attenuation in diazepam-stimulated feeding when compared to controls. Blood pressure was significantly lower in both MSG-Hi and MSG-Lo rats compared to controls. Tail flick latencies were not altered by MSG-treatment.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of galanin-like immunoreactivity in the rat brain: effects of neonatal glutamate treatment

Concentrations of the neuropeptide, galanin, were measured using a newly characterized radioimmunoassay in brain regions of adult male rats treated neonatally with monosodium glutamate. Galanin-like immunoreactivity (galanin-IR) was significantly reduced 57% in the median eminence, 15% in the medial basal hypothalamus, and 27% in the septal region when compared to untreated littermates. Concentrations of galanin-IR were reduced 22% in the preoptic region and unchanged in the parietal cortex. These studies suggest that glutamate-sensitive, galanin-containing neurons in the arcuate nucleus project to regions of the basal forebrain of the rat in addition to the median eminence. The galanin projection from the arcuate nucleus to the median eminence suggests that this peptide plays a role in the regulation of anterior pituitary hormone secretion.

Development of hypothalamic obesity in growing rats

Administration of monosodium glutamate to neonate rats causes hypothalamic lesions in the region of the nucleus arcuatus and the eminentia mediana, followed by massive accumulation of triglycerides, diminished secretion of growth hormone, reduced body length and organ weights and diminished number of adipocytes (hypoplastic-hypertrophic obesity). Locomotor activity of obese animals is reduced by about 50%. Food intake is increased by about 10% during growth and development of obesity but decreased beneath the level of that in control animals in the stationary phase of obesity. Hyperinsulinemia coupled with insulin resistance develops in the stationary phase of obesity, i.e. when adipocyte diameter has reached approximately 100 microns. The effects of reduced secretion of growth hormone are considered to be a main factor of fat accumulation in this type of obesity.

Neurotoxicity of monosodium-L-glutamate in pregnant and fetal rats

Monosodium-L-glutamate given subcutaneously to pregnant rats caused acute necrosis of the acetylcholinesterase-positive neurons in the area postrema. The same effect has been observed in the area postrema of fetal rats. The process of neuronal cell death and the elimination of debris by microglia cells proved to be similar in pregnant animals and in their fetuses. However, embryonal neurons were more sensitive to glutamate as judged by the rapidity of the process and the dose-response relationship. These observations raise the possibility of transplacental poisoning in human fetuses after the consumption of glutamate-rich food by the mother.

GRF neurons in the rat hypothalamus

The growth hormone-releasing factor (GRF)-containing neuronal system was immunohistochemically studied in the rat hypothalamus. The immunolabeled cell bodies were determined by intraventricular administration of colchicine 24 h before killing. In intact animals, the neurons appeared in the ventral portion of the arcuate nucleus (group 1) and in the area surrounding the ventromedial nucleus (group 2). Most of the cell bodies also indicated immunoreactivity for tyrosine hydroxylase (TH). The immunoreactive fibers accumulated showing a palisade arrangement in the external layer of the median eminence. The rats treated neonatally with monosodium glutamate revealed group 2 neurons and a few immunoreactive fibers in the median eminence. Half-anterolateral deafferentation of the medial basal hypothalamus, which was performed to isolate group 1 neurons or both group 1 and 2 neurons from the other brain parts, did not remarkably affect the appearance of the fibers in the median eminence. However, the perikarya were hypertrophic and strongly immunolabeled for GRF and TH. It is concluded that the fibers containing GRF in the median eminence derive mostly from group 1 neurons, and that the neurons may be regulated by an inhibitory mechanism by other neurons on the outside of the deafferented hypothalamic islands. GRF synthesized in group 2 neurons may act on other neurons as a neurotransmitter-like substance.

The hypothalamo-infundibular growth hormone-releasing hormone (GH-RH) system of the rat

Two to 10 days after complete unilateral surgical isolation of the medial basal hypothalamus (MBH) or 3 months following neonatal monosodium glutamate (MSG) treatment, the presence of growth hormone-releasing hormone (GH-RH) immunoreactive neuronal structures was studied in rats using vibratome sections and GH-RH immunocytochemistry. Neonatal MSG treatment resulted in a dramatic decrease of GH-RH immunoreactivity in the median eminence (ME), but not complete disappearance as reported earlier. Unilateral complete deafferentation of the MBH caused only a slight decrease in GH-RH immunostaining in the posterior regions of the ipsilateral median eminence (ME). At this level GH-RH accumulation was observed in scattered transected fibers lateral to the cut, outside of the MBH. Our findings indicate that the arcuate nucleus is the major source of GH-RH immunoreactive structures in the ME. Although, however, in very small numbers, the existence of other sources of GH-RH terminals cannot be excluded.

Ontogenesis of immunoreactive tyrosine hydroxylase-containing neurons in rat hypothalamus

By employing anti-tyrosine hydroxylase (TH) serum, the ontogenesis of hypothalamic dopamine (DA) neurons was immunohistochemically examined with special attention to the medial basal hypothalamic area. DA neurons first appeared in the lateral hypothalamic walls on day 13.5 of gestation and in the anterior periventricular region and arcuate nucleus on day 15.5-16.5. In the arcuate nucleus, the appearance of the neurons was confined to the ventrolateral (VL) region, but extended to the periventricular region thereafter. About day 10 postnatally, the population of the arcuate DA neurons conjoins anterodorsally with the cell population in the anterior periventricular region. Concomitant with this, DA neurons in the VL region of the nucleus diminished in number and in stainability, becoming barely visible. Interestingly enough, the latter neurons reappeared after an anterolateral deafferentation of the medial basal hypothalamus. This did not occur in pregnant and lactating rats. Although most of the arcuate DA neurons were retarded by neonatal administration of monosodium glutamate, the immunoreactive fibers remained almost intact in the medial portion of the median eminence. It is concluded that in the periventricular-arcuate complex, DA neurons seem to play different roles relating with their ontogenetic heterogeneity.

Neurotensin-like immunoreactivity and neurotensin receptors in the rat hypothalamus and in the neurointermediate lobe of the pituitary gland

In the rat hypothalamus, cell bodies containing neurotensin-like immunoreactivity were mainly found in the medial preoptic area, the periventricular nucleus, the paraventricular nucleus, the supraoptic nucleus and the arcuate nucleus. [3H]neurotensin binding sites were observed throughout the hypothalamus with a dense accumulation of silver grains over the paraventricular nucleus, the arcuate nucleus and the median eminence region. By radioimmunoassay neurotensin-like immunoreactivity was also found in the neurointermediate lobe of the pituitary gland of various mammalian species and in human postmortem posterior pituitary glands. In the rat studies involving pituitary stalk transections and the neurotoxin monosodium glutamate indicated the presence of a neurotensinergic pathway from the arcuate nucleus to the neurointermediate lobe of the pituitary gland. [3H]neurotensin binding sites were found to be concentrated over the intermediate lobe of the pituitary gland and their presence was not affected by pituitary stalk transection, indicating their localization on endocrine cells of the intermediate lobe of the pituitary gland.

Monosodium glutamate lesions in rat hypothalamus studied by immunohistochemistry for gonadotropin releasing hormone, neurotensin, tyrosine hydroxylase, and glutamic acid decarboxylase and by autoradiography for [3H] estradiol

Adult male and female rats treated neonatally with monosodium glutamate (MSG) exhibit lesions in the arcuate nucleus of the hypothalamus. Immunohistochemical analysis of the distribution of tyrosine hydroxylase (TH), glutamic acid decarboxylase (GAD), neurotensin (NT) and gonadotropin-releasing hormone (GnRH) reveals substantial destructions of tuberoinfundibular dopamine and NT systems accompanied by a marked reduction of immunoreactivity in the median eminence. GAD immunoreactivity in the arcuate nucleus and median eminence is greatly reduced, while GnRH containing structures in the mediobasal hypothalamus are not noticeably affected. Evaluation of autoradiograms after intravenously administered [3H] estradiol in the ventral hypothalamus indicate an almost complete loss of target neurons in the arcuate nucleus but not in the nearby ventromedial nucleus. The results suggest that: (a) NT- and dopamine-containing neurons of the arcuate nucleus project to the median eminence via tuberoinfundibular NT and dopaminergic pathways; (b) GABA in the median eminence originates to a major extent from neurons of the arcuate nucleus through a tuberoinfundibular GABAergic system; (c) GnRH is produced in the rat outside the arcuate nucleus; (d) the MSG-induced lesion in the basal tuberal region abolishes or strongly diminishes estradiol target neurons in the arcuate nucleus.

Steroid-monoamine feedback interactions in discrete brain regions using as a model the monosodium glutamate (MSG)-lesioned rat

The present studies examine the effects of neonatal treatment with monosodium glutamate (MSG) on dopamine (DA), 5-hydroxytryptamine (5-HT) and norepinephrine (NE) metabolism in discrete brain regions and correlate them with steroid receptor kinetics in the anterior pituitary (PIT), preoptic hypothalamus (POA) and caudal hypothalamus (HYP), and with steroid negative and positive feedback effects on luteinizing hormone (LH) secretion. Substantial decreases in the neuronal activity of all three amines in the arcuate nucleus, decreased DA and 5-HT metabolism in the suprachiasmatic nucleus and, surprisingly, increased metabolism of 5-HT and NE in the median eminence was observed in adult ovariectomized (OVX), MSG-treated versus OVX, vehicle-treated litter mate controls. Measurement of estradiol receptors in the nuclear and cytosolic fractions of the POA, HYP and PIT from MSG- and vehicle-treated rats killed during diestrus or 2 weeks after OVX revealed no differences. Similarly, no differences in cytosolic progestin receptors between control and MSG unprimed or estradiol-primed, OVX rats or on progestin receptor translocation induced by progesterone in Eb-primed rats were observed. Negative and positive feedback effects of estradiol or the positive feedback of progesterone on LH secretion were not significantly impaired in MSG rats, and indeed, MSG animals actually were hyper-responsive to the administration of the steroids or of luteinizing hormone-releasing hormone. These results indicate that the MSG-induced damage to DA, 5-HT and NE elements observed within several preoptic and hypothalamic nuclei does not impair estrogen and progestin receptor kinetics, nor does it prevent adequate negative or positive steroid feedback responses, if appropriate steroid regimens are employed, and that the impaired gonadal function reported in these animals does not result primarily from inadequate steroid feedback mechanisms.