Umbilical cord blood-derived stem cells improve heat tolerance and hypothalamic damage in heat stressed mice.

Heatstroke is characterized by excessive hyperthermia associated with systemic inflammatory responses, which leads to multiple organ failure, in which brain disorders predominate. This definition can be almost fulfilled by a mouse model of heatstroke used in the present study. Unanesthetized mice were exposed to whole body heating (41.2°C for 1 hour) and then returned to room temperature (26°C) for recovery. Immediately after termination of whole body heating, heated mice displayed excessive hyperthermia (body core temperature ~42.5°C). Four hours after termination of heat stress, heated mice displayed (i) systemic inflammation; (ii) ischemic, hypoxic, and oxidative damage to the hypothalamus; (iii) hypothalamo-pituitary-adrenocortical axis impairment (reflected by plasma levels of both adrenocorticotrophic-hormone and corticosterone); (iv) decreased fractional survival; and (v) thermoregulatory deficits (e.g., they became hypothermia when they were exposed to room temperature). These heatstroke reactions can be significantly attenuated by human umbilical cord blood-derived CD34(+) cells therapy. Our data suggest that human umbilical cord blood-derived stem cells therapy may improve outcomes of heatstroke in mice by reducing systemic inflammation as well as hypothalamo-pituitary-adrenocortical axis impairment.

Protective effects of hypothalamic beta-endorphin neurons against alcohol-induced liver injuries and liver cancers in rat animal models.

BACKGROUND: Recently, retrograde tracing has provided evidence for an influence of hypothalamic ß-endorphin (BEP) neurons on the liver, but functions of these neurons are not known. We evaluated the effect of BEP neuronal activation on alcohol-induced liver injury and hepatocellular cancer. METHODS: Male rats received either BEP neuron transplants or control transplants in the hypothalamus and were randomly assigned to feeding alcohol-containing liquid diet or control liquid diet for 8 weeks or to treatment of a carcinogen diethylnitrosamine (DEN). Liver tissues of these animals were analyzed histochemically and biochemically for tissue injuries or cancer. RESULTS: Alcohol feeding increased liver weight and induced several histopathological changes such as prominent microvesicular steatosis and hepatic fibrosis. Alcohol feeding also increased the levels of triglyceride, hepatic stellate cell (HSC) activation factors, and catecholamines in the liver and endotoxin levels in the plasma. However, these effects of alcohol on the liver were reduced in animals with BEP neuron transplants. BEP neuron transplants also suppressed carcinogen-induced liver histopathologies such as extensive fibrosis, large focus of inflammatory infiltration, hepatocellular carcinoma (HCC), collagen deposition, numbers of preneoplastic foci, levels of HSC activation factors and catecholamines, as well as inflammatory milieu and increased the levels of natural killer cell cytotoxic factors in the liver. CONCLUSIONS: These findings are the first evidence for a role of hypothalamic BEP neurons in influencing liver functions. Additionally, the data identify that BEP neuron transplantation prevents hepatocellular injury and HCC formation possibly via influencing the immune function.

Effect of allotransplantation of embryonic brain tissues and administration of potentiated antibodies to bombesin on hemodynamics in rats with emotional hypertension.

Transcutaneous allotransplantation of embryonic tissues from the anterior hypothalamus and amygdaloid complex and administration of potentiated antibodies to bombesin normalized blood pressure and parameters of ECG in rats with emotional hypertension.

Biotinylated dextran amine as a marker for fetal hypothalamic homografts and their efferents.

We have explored the use of biotinylated dextran amine (BDA) as a marker for labeling fetal brain grafts and their connections with the host. As a model system we used transplantation of the hamster suprachiasmatic nucleus, the site of an endogenous biological clock governing circadian rhythms. Similar transplants into arrhythmic hosts have been shown to restore behavioral function with a period specific to the donor. For locomotor rhythms, efferent connections are not necessary. For other responses, including endocrine rhythms, efferent connections may be necessary. In order to visualize homografts and their efferents, injections of BDA, an anterograde tracer, were made into the anterior hypothalamic (AH) region containing the SCN or into the dorsal cortex (CTX) of fetal hamster brains. The fetal AH or CTX was microdissected out and stereotaxically implanted into the third ventricle of intact, adult hamsters. After 2, 4, 8, or 12 weeks, hosts were sacrificed and their brains were processed for detection of BDA by either histochemistry or immunofluorescence. BDA intensely labeled graft neurons, their dendrites, and axons with minimal or no spread to the adjacent host brain. Labeled graft axons could be followed for long distances (>1 mm) into the host brain and graft-derived varicosities formed close contacts with host neurons. BDA-labeled graft neurons, located at the perimeter of the graft, also extended dendrite-like processes into the host parenchyma. We conclude that BDA is a useful marker for fetal homografts and their efferents for survival times of less than 2 months.

Combined mesencephalic and hypothalamic transplants reverse lesion-induced sexual behavior deficits in the male rat.

Studies of sexual behavior in rodent animal models have provided evidence about the relevant role played by the medial preoptic area of the anterior hypothalamus and the central tegmental field within the mesencephalon in the control of this behavior. Bilateral lesions of the anterior hypothalamus or central tegmental field as well as combined unilateral lesions of both these regions result in sexual behavior deficits. Studies using fetal hypothalamic transplants have been shown to reverse sexual behavior deficits induced either by lesions or aging. However, no previous study has evaluated the effect of combined homotopic transplants into both the anterior hypothalamus and the mesencephalon. In the present study male Wistar animals received two electrolytic lesions, one aimed at the ipsilateral medial preoptic area of the anterior hypothalamus and the other at the contralateral central tegmental field. Following these lesions, unilateral homotopic fetal hypothalamic and mesencephalic transplants were placed into the lesioned areas. Sexual behavior recovered gradually and by weeks 14-15 after transplantation, above 90% of animals with bilateral transplants showed mounts, intromissions, and ejaculations. Only animals with viable transplants located within both lesioned areas showed recovery. These results indicate that the behavioral deficits induced by combined unilateral lesions of hypothalamic and mesencephalic regions can be reversed by homotopic fetal transplants and that this recovery could be the result of the restoration of a behavioral relevant circuit between transplants and host brain nuclei separated by as much as 5 mm, which makes this an excellent model to study mechanisms underlying behavioral recovery after transplantation.

Tanycytes transplanted into the adult rat spinal cord support the regeneration of lesioned axons.

During past years a number of therapeutic strategies have been developed in order to stimulate axonal regeneration after traumatic injuries of the spinal cord. Recently, encouraging data have been obtained by grafting specific glial cells such as Schwann cells or olfactory ensheathing glial cells, known to support the regeneration of peripheral or central axons, respectively. In a recent series of studies, we have shown that tanycytes, a particular glial cell type present in the mediobasal hypothalamus, were able to support the regeneration of a variety of axons innervating this region. The aim of the present study was to determine whether tanycytes could also support the regeneration of lesioned spinal axons. Cultured hypothalamic tanycytes and cortical astrocytes were prelabeled with Fast blue (FB) and grafted into the thoracic spinal cord of adult rats. Three weeks after the transplantation, the animals were fixed and spinal cord sections treated for multiple fluorescence detection of the FB-labeled transplanted cells on the one hand and of various glial and neuronal markers on the other hand. We show here that in all the spinal cords examined, transplanted tanycytes or astrocytes formed large spherical clusters of about 0.5 mm in diameter, located in the mediolateral spinal cord layer. The immunodetection of glial markers showed that transplanted astrocytes exhibited intense immunostaining for both glial fibrillary acidic protein (GFAP) and vimentin (VIM), whereas transplanted tanycytes were intensely immunostained for VIM, but GFAP negative. The immunodetection of axonal markers showed that contrasting with astrocyte transplants, tanycyte transplants were invaded by numerous axonal fibers. These data indicate that tanycyte transplants may represent a useful therapeutic tool for the reparation of the lesioned spinal axons.

Is the primitive regulation of pituitary prolactin (tPRL177 and tPRL188) secretion and gene expression in the euryhaline tilapia (Oreochromis mossambicus) hypothalamic or environmental?

We examined the effects of environmental salinity on circulating levels of the two prolactins (tPRL177 and tPRL188) and levels of pituitary tPRL177 and tPRL188 mRNA in the euryhaline tilapia, Oreochromis mossambicus. Fish were sham-operated or hypophysectomized and the rostral pars distalis (RPD) autotransplanted onto the optic nerve. Following post-operative recovery in (1/4) seawater, tilapia were transferred to fresh water (FW), (1/4) seawater (SW) or SW. Serum tPRL177 and tPRL188 levels in sham-operated and RPD-autotransplanted fish were highest in FW and decreased as salinity was increased. tPRL177 and tPRL188 mRNA levels in RPD implants as well as in pituitaries from the sham-operated fish were also highest in FW and decreased with increasing salinity. Serum osmolality increased with salinity, with the highest levels occurring in the seawater groups. We conclude that some plasma factor (probably plasma osmolality), in the absence of hypothalamic innervation, exerts a direct regulatory action on prolactin release and gene expression in the pituitary of O. mossambicus. This regulation is in accord with the actions of the two prolactins in the freshwater osmoregulation of the tilapia.

Restoration of circadian behavior by anterior hypothalamic grafts containing the suprachiasmatic nucleus: graft/host interconnections.

Destruction of the hypothalamic suprachiasmatic nucleus (SCN) disrupts circadian behavior. Transplanting SCN tissue from fetal donors into SCN-lesioned recipients can restore circadian behavior to the arrhythmic hosts. In the transplantation model employing fetal hamster donors and SCN-lesioned hamsters as hosts, the period of the restored circadian behavior is hamster-typical. However, when fetal rat anterior hypothalamic tissue containing the SCN is implanted into SCN-lesioned rats, the period of the restored circadian rhythm is only rarely typical of that of the intact rat. The use of an anterior hypothalamic heterograft model provides new approaches to donor specificity of restored circadian behavior and with the aid of species-specific markers, provides a means for assessing connectivity between the graft and the host. Using an antibody that stains rat and mouse neuronal tissue but not hamster neurons, it has been demonstrated that rat and mouse anterior hypothalamic heterografts containing the SCN send numerous processes into the host (hamster) neuropil surrounding the graft, consistent with graft efferents reported in other hypothalamic transplantation models in which graft and host tissue can be differentiated (i.e., Brattleboro rat and hypogonadal mouse). Moreover, SCN neurons within anterior hypothalamic grafts send an appropriately restricted set of efferent projections to the host brain which may participate in the functional recovery of circadian locomotor activity.

Regeneration of neurosecretory axons into various types of intrahypothalamic grafts is promoted by the absence of blood brain barrier: fine structural analysis.

Isogenous grafts of neural lobe and optic nerve and autologous grafts of sciatic nerve were placed into contact with the intrahypothalamically transected hypothalamo-neurohypophysial tract, and their fine structural characteristics examined at various time periods thereafter. The vascular bed of neural lobe grafts is composed primarily of fenestrated capillaries, that are permeable to blood-borne HRP throughout the entire experimental period. The microvasculature of sciatic nerve grafts consists of continuous, as well as fenestrated capillaries, which are similarly permeable to HRP. Fenestrated capillaries and HRP leakage in optic nerve grafts are observed at 10 days, but only in grafts located ventrally in the hypothalamus at 30 days. Neurosecretory axon regeneration is seen only in grafts or adjacent hypothalamus where the blood-brain barrier is breached. Regenerating axons are closely associated with the specific glial cells of the respective graft. Based on these observations, we conclude that blood-borne factors are necessary to initiate and sustain regeneration of transected neurosecretory axons, and that such regeneration occurs only in the presence of glial cells.

Transgene expression in rat fetal brain grafts is maintained for 7 months after ex vivo adenoviral vector-mediated gene transfer.

Fetal brain tissue fragments containing the suprachiasmatic nucleus were infected with an adenoviral vector containing the marker gene LacZ encoding for beta-galactosidase, and subsequently cultured or transplanted in the third ventricle of SCN-lesioned adult Wistar rats. In previous studies we optimized the infection procedure and characterized the immunological response directed against the viral vector in this model. The present study reports on beta-gal expression for at least 7 months in neuronal and glial cells. Maturation of the transplanted fetal SCN with respect to immunoreactivity for vasoactive intestinal polypeptide and C-terminal propressophysin was not hampered by the viral infection.

Hypothalamic neuronal histamine: implications of its homeostatic control of energy metabolism.

In a series of studies on histaminergic functions in the hypothalamus, probes to manipulate activities of histaminergic neuron systems were applied to assess its physiologic and pathophysiologic implications using non-obese normal and Zucker obese rats, an animal model of genetic obesity. Food intake is suppressed by either activation of H1-receptor or inhibition of the H3-receptor in the ventromedial hypothalamus (VMH) or the paraventricular nucleus, each of which is involved in satiety regulation. Histamine neurons in the mesencephalic trigeminal sensory nucleus modulate masticatory functions, particularly eating speed through the mesencephalic trigeminal motor nucleus, and activation of the histamine neurons in the VMH suppress intake volume of feeding at meals. Energy deficiency in the brain, i.e., intraneuronal glucoprivation, activates neuronal histamine in the hypothalamus. Such low energy intake in turn accelerates glycogenolysis in the astrocytes to prevent the brain from energy deficit. Thus, both mastication and low energy intake act as afferent signals for activation of histaminergic nerve systems in the hypothalamus and result in enhancement of satiation. There is a rationale for efficacy of a very-low-calorie conventional Japanese diet as a therapeutic tool for weight reduction. Feeding circadian rhythm is modulated by manipulation of hypothalamic histamine neurons. Hypothalamic histamine neurons are activated by an increase in ambient temperature. Hypothalamic neuronal histamine controls adaptive behavior including a decrease in food intake and ambulation, and an increase in water intake to maintain body temperature to be normally constant. In addition, interleukin-1 beta, an endogenous pyrogen, enhanced turnover of neuronal histamine through prostaglandin E2 in the brain. Taken together, the histamine neuron system in the hypothalamus is essential for maintenance of thermoregulation through the direct and indirect control of adaptive behavior. Behavioral and metabolic abnormalities of obese Zucker rats including hyperphagia, disruption of feeding circadian rhythm, hyperlipidemia, hyperinsulinemia, and disturbance of thermoregulation are essentially derived from a defect in hypothalamic neuronal histamine. Abnormalities produced by depletion of neuronal histamine from the hypothalamus in normal rats mimic those of obese Zuckers. Grafting the lean Zucker fetal hypothalamus into the obese Zucker pups attenuates those abnormalities. These findings indicate that histamine nerve systems in the brain play a crucial role in maintaining homeostatic energy balance.

Hypothalamic grafts induce the recovery of lordosis in female hamsters with lesions of the ventromedial hypothalamus.

Previous studies have documented the ability of neural grafts to stimulate the recovery of lordosis from neurochemical deficits. However, it was unclear if grafts also could reverse deficits in lordosis caused by lesions at critical points in the neural circuit controlling this response. To address this question, female hamsters were subjected to unilateral lesions of the ventromedial hypothalamus (VMN), a structure well known for its mediation of hormonal effects on lordosis. The effects of these lesions were described by noting the ability of manual stimulation of one flank to reinstate a deteriorating lordosis response. Consistent with past results, unilateral VMN lesions decreased responsiveness to stimulation of just the contralateral flank. Females showing such lateralized decrements then received control treatments or implants into the lesioned area of basal hypothalamic tissue from a neonatal male or female hamster. Approximately 1 month later, tests of lordosis reinstatement by ipsi- or contralateral manual stimuli were repeated. Whereas lateralized decrements in responsiveness persisted in control subjects, implants of tissue from male or female neonates led to reliable improvements in lordosis, reversing the lesion-induced decrease in contralateral responsiveness. The mechanism responsible for this change is unclear, but could involve an elevation in a lordosis-facilitating neuromodulator. Alternatively, it could depend on the reinforcement or replacement of neural circuits for lordosis, possibly including those that connect the two VMNs with each other or with the periaqueductal gray of the midbrain.

The development of a species difference in the local distribution of brain estrogen receptive cells.

Estrogen receptors (ER) are crucial for estrogen-dependent brain differentiation and for estrogen-dependent neural functions of vertebrates. ER are expressed in a area-specific pattern in the vertebrate brain. The mechanisms that lead to the area-specific expression of ER are unknown. Here we use a species difference in the ER distribution between quail and chick and isochronic and isotopic quail to chick transplants to investigate mechanisms underlying the development of area-specific expression of ER. The entire neural tube rostral to the 6th somite (n = 2) or rostral to the otic capsules (n = 4) were transplanted at the second day of incubation (E2). In immunocytochemical stainings with the ER antibody H222Sp gamma, there is a defined cluster of intensely immunostained cells in the ventrolateral preoptic area of adult quails (the QERN). At the time of grafting, the entire brain primordium lacks ER. The QERN expresses ER as early as E13. The homologous area of the chicken brain does not differentiate cells that contain ER at any stage after ER are first detectable in the chicken brain at E11. In contrast, quail-chick chimeras develop the QERN phenotype in the ventrolateral preoptic area similar to quails. This implies that some signal which commits cells to the QERN phenotype (ER expression) is present in the quail brain primordium rostral to the otic capsules by embryonic day 2, and that this signal is unaffected by subsequent exposure to the global chick environment.

Vasoactive intestinal peptide efferent projections of the suprachiasmatic nucleus in anterior hypothalamic transplants: correlation with functional restoration of circadian behavior.

Circadian rhythmicity can be restored by transplantation of fetal anterior hypothalamic (AH) tissue containing the suprachiasmatic nucleus (SCN) into hosts rendered arrhythmic by SCN ablation. However, the nature of the SCN effector pathways mediating functional recovery has remained elusive. To examine implant-derived SCN innervation of the host, AH homografts (hamster-to-hamster) and heterografts (mouse- or rat-to-hamster) were employed and the distribution of vasoactive intestinal peptide (VIP) within the SCN terminal fields was evaluated. A comparison was made between cases where circadian locomotor activity was restored and cases where circadian rhythmicity remained disrupted following AH transplantation. A dense aggregation of VIP neurons and processes was identified in each transplant that restored behavioral rhythmicity in the host. In these cases, SCN-derived VIP fibers were integrated with the host brain and could be identified in host terminal fields typically innervated by SCN-VIP fibers. A correlation was noted between VIP innervation of the host paraventricular thalamic nucleus (PVT) and restoration of circadian rhythmicity. Neither qualitative nor quantitative differences in transplant VIP projections were noted between AH homografts and heterografts. These results demonstrate that SCN VIP neurons in AH transplants send an appropriately restricted set of efferent projections to the host brain and suggest that SCN efferent projections to the PVT may participate in mediating the functional recovery of circadian locomotor activity.

Characterization of histaminergic H3 receptors in intraocular tuberomammillary transplants containing histaminergic neurons.

This study was performed to investigate the physicological properties of histaminergic neurons in intraocular hypothalamic transplants. Pieces of posterolateral hypothalamus containing the tuberomammillary nucleus were dissected from Embryonic Day 17 rat fetuses and transplanted into the anterior chamber of the eye of adult rat hosts. The hypothalamic transplants were left to mature for 2-5 months, after which in vivo electrophysiological recordings were performed. Extracellular recordings revealed spontaneously active neurons in the grafts, with a mean (+/- SEM) firing rate of 2.8 +/- 2.0 Hz and a mean action potential duration of 1.2 +/- 0.5 ms. When the surface of the grafts was superfused with histamine, the neuronal activity was depressed at concentrations above 30 microM. Superfusion with the H3 agonist (R)-alpha-methylhistamine also elicited depression of baseline firing rate, with an EC50 of 0.435 microM. This depression could be antagonized by superfusion with the H3-receptor antagonist thioperamide. In studies of histamine levels using a sensitive radioenzymatic assay, the mean (+/- SEM) level of histamine in the grafts was 73 +/- 28 ng/g tissue, i.e., about half the concentration of histamine in the adult rat hypothalamus in situ. Intracellular recordings in combination with biocytin labeling and histidine decarboxylase immunohistochemistry suggested that the grafted neurons from which recordings were made were histaminergic. Taken together, these data indicate that tuberomammillary neurons continue their development in intraocular transplants and develop physiological characteristics found in these neurons in situ.

Induction of proenkephalin in tuberoinfundibular dopaminergic neurons by hyperprolactinemia: the role of sex steroids.

The observation that tuberoinfundibular dopaminergic (TIDA) neurons of pregnant, pseudopregnant, lactating, and aged rats express enkephalins suggested that chronically elevated PRL levels, which are characteristic for these animals, are essential for the induction of proenkephalin gene expression in TIDA neurons. The present studies investigated further the role of PRL in this phenomenon. Elevated PRL levels were achieved either experimentally by implanting anterior pituitaries under the kidney capsule of intact or hypophysectomized female rats or by using lactating rats. For controls, the elevated PRL levels were reduced with bromocryptine, a dopamine receptor agonist. The role of sex steroids in PRL-induced enkephalin gene expression was also studied in cycling, sex hormone-treated, hypophysectomized or ovariectomized rats, pituitary-implanted/sex hormone-treated rats, and ovariectomized mothers. Enkephalin immunoreactivity was detected by immunocytochemistry and enkephalin messenger RNA with in situ hybridization histochemistry using 35S- or digoxigenin-labeled riboprobes. Enkephalin or its messenger RNA was present in TIDA neurons in all experimental animals with elevated PRL levels. Although estradiol had no or only a minor effect on PRL-induced enkephalin gene expression, progesterone supported the effect of PRL. The present observations suggest that the expression of enkephalin in TIDA neurons is PRL dependent and supported by sex steroids, primarily progesterone.

Role of neuropeptide Y projection on the development of serotonergic innervation in the suprachiasmatic nucleus of the rat, shown by triple intraocular grafts.

In our previous paper, the intraocular double grafts of fetal mesencephalic raphe and suprachiasmatic nucleus (SCN) demonstrated that the serotonergic fibers from raphe tissue did not show a dense innervation of SCN [28]. To examine the influence of NPY innervation from lateral geniculate nucleus (LGN) on the development of serotonergic fibers in the SCN, fetal mesencephalic raphe, SCN and LGN tissues were transplanted together into the eye chamber of adult rat. 6 weeks after transplantation, triple grafts were immunohistochemically examined. The SCN cell cluster was recognized by vasoactive intestinal polypeptide (VIP)- and arginine vasopressin (AVP)-immunoreactive neurons and The SCN cell cluster also contained a large number of serotonin-immunoreactive fibers from raphe tissue and a moderate number of neuropeptide Y (NPY)-immunoreactive fibers from LGN tissue. The present results provide information on possible NPY-serotonin interactions in the developing SCN.

Intracranial transplantation and survival of tuberomammillary histaminergic neurons.

Investigations were undertaken to determine whether fetal histaminergic neurons in the tuberomammillary nucleus of the posterior hypothalamus survive intracranial transplantation to adult hosts. Two methods of transplantation were utilized. Grafts were placed either into the delayed cavity of a fimbria-fornix lesion or directly into the hippocampus using stereotaxic techniques. The tissue was taken from rat fetuses at embryonic days 16-17 and grafted into adult rats of either the Sprague-Dawley or the Fischer 344 strain. Routine histology and immunohistochemistry were used to evaluate the grafts. All transplants to Sprague-Dawley rats showed signs of rejection, while no signs of rejection were seen in any of the Fischer 344 rats. Transplants placed directly into the delayed fimbria-fornix cavity did not grow as well or contain as many surviving neurons as the intraparenchymal grafts. The largest number of surviving histamine-positive neurons was obtained with grafts of posterolateral blocks of hypothalamus from fetal day 17 placed directly into the CA1 region of the rostral hippocampal formation of Fischer 344 hosts. Histamine-immunoreactive cell bodies with neuritic outgrowth were found in all Fischer 344 rats that received hypothalamic grafts. Cell bodies exhibited histamine immunoreactivity evenly throughout the cytoplasm and had morphological characteristics resembling histaminergic neurons in situ. Axonal outgrowth extended throughout the grafted hypothalamic tissue, and was sometimes seen in the host hippocampal tissue as well. It is concluded that fetal histaminergic neurons survive transplantation to the adult hippocampal formation, and that this allograft procedure can supplement current strategies to investigate the function of histaminergic tuberomamillary neurons in the central nervous system.