CONTEXT Stress is considered to be a major factor in the regulation of growth. Psychosocial dwarfism, characterized with short stature, delayed puberty, and depression, is typically preceded by psychological harassment or stressful environment. It has been observed that stress suppresses GH secretion, possibly via the attenuation of GHRH secretion. However, the exact mechanism of the impact of stress on growth has not been elucidated yet. OBJECTIVE Our previous studies revealed intimate associations between neuropeptide Y (NPY)-immunoreactive (IR) axonal varicosities and GHRH-IR perikarya in the human hypothalamus. Because NPY is considered to be a stress molecule, NPY-GHRH juxtapositions may represent an important factor of stress-suppressed GHRH release. In addition to NPY, catecholamines are among the major markers of stress. Thus, in the present study, we examined the putative juxtapositions between the catecholaminergic tyrosine hydroxylase (TH)-/dopamine-β-hydroxylase-/phenylethanolamine N-methyltransferase-IR and GHRH-IR neural elements in the human hypothalamus. To reveal these juxtapositions, double-label immunohistochemistry was used. RESULTS Our findings revealed that the majority of the GHRH-IR perikarya formed intimate associations with TH-IR fiber varicosities. The majority of these juxtapositions were found in the infundibular nucleus/median eminence. CONCLUSIONS The lack of phenylethanolamine N-methyltransferase-GHRH associations and the small number of dopamine-β-hydroxylase-GHRH juxtapositions suggest that the vast majority of the observed TH-GHRH juxtapositions represent dopaminergic associations. The density of the abutting TH-IR fibers on the surface of the GHRH perikarya suggests that these juxtapositions may be functional synapses, and thus, in addition to NPY, catecholamines may regulate GHRH secretion via direct synaptic mechanisms.

Neuropeptide Y (NPY) is a 36 amino acid peptide, which among others, plays a pivotal role in stress response. Although previous studies confirmed that NPY release is increased by stress in several species, the exact mechanism of the stress-induced NPY release has not been elucidated yet. In the present study, we examined, with morphological means, the possibility that catecholamines directly influence NPY release in the human hypothalamus. Since the use of electron microscopic techniques is virtually impossible in immunostained human samples due to the long post mortem time, double-label immunohistochemistry was utilised in order to reveal the putative catecholaminergic-NPY associations. The present study is the first to demonstrate juxtapositions between the catecholaminergic, tyrosine hydroxylase (TH)/dopamine-beta hydroxylase (DBH)-immunoreactive (IR) and NPY-IR neural elements in the human hypothalamus. These en passant type associations are most numerous in the infundibular and periventricular areas of the human diencephalon. Here, NPY-IR neurons often form several contacts with catecholaminergic fibre varicosities, without any observable gaps between the contacting elements, suggesting that these juxtapositions may represent functional synapses. The lack of phenylethanolamine N-methyltransferase (PNMT)-NPY juxtapositions and the relatively few observed DBH-NPY associations suggest that the vast majority of the observed TH-NPY juxtapositions represent dopaminergic synapses. Since catecholamines are known to be the crucial components of the stress response, the presence of direct, catecholaminergic (primarily dopaminergic)-NPY-IR synapses may explain the increased NPY release during stress. The released NPY in turn is believed to play an active role in the responses that are directed to maintain the homeostasis during stressful conditions.

Binge drinking (blood-alcohol levels ≥ 0.08 g% in a 2-h period), is a significant public health burden in need of improved treatment. Gene therapy may offer beneficial alternatives to current psychosocial and pharmacotherapeutic interventions, but identification of the target genes is a clinical challenge. We report that a GABA(A) α2 siRNA vector (pHSVsiLA2) infused into the central nucleus of the amygdala (CeA) of alcohol-preferring (P) rats caused profound and selective reduction of binge drinking associated with inhibition of α2 expression, decreased GABA(A) receptor density, and inhibition of Toll-like receptor 4 (TLR4). CeA infusion of a TLR4 siRNA vector (pHSVsiLTLR4a) also inhibited binge drinking, but neither vector functioned when infused into the ventral pallidum. Binge drinking was inhibited by a GABA(A) α1 siRNA vector (pHSVsiLA1) infused into the ventral pallidum, unrelated to TLR4. The vectors did not alter sucrose intake and a scrambled siRNA vector was negative. The data indicate that GABA(A) α2-regulated TLR4 expression in the CeA contributes to binge drinking and may be a key early neuroadaptation in excessive drinking.

Galanin has diverse physiological functions, including nociception, arousal/sleep regulation, cognition, and many aspects of neuroendocrine activities that are associated with feeding, energy metabolism, thermoregulation, osmotic and water balance, and reproduction. This review will provide a brief overview of galanin action in some major neuroendocrine processes. Most of the recent data are about the role of galanin in the central regulation of food intake and energy metabolism, and to some extent, in the regulation of reproduction. It seems that galanin plays a modulatory role rather than a regulatory one in the central and peripheral branches of the neuroendocrine systems. In the hypothalamus, it functions as a neurotransmitter/ neuromodulator. In the pituitary and the peripheral endocrine glands, it acts via its receptors in a paracrine/autocrine fashion. The development of new, selective, and potent antagonists of GALRs should keep advancing our knowledge not only in the physiology of galanin but also in its pathophysiology.

Galanin and neuropeptide Y (NPY) are among the most abundant neuropeptides in the hypothalamus. The role of NPY and galanin in the regulation of the secretory activity of the anterior pituitary has been well established. In addition, the two peptides interact with a number of neurons synthesizing the releasing and inhibiting hormones and a large number of other neuropeptides. The aim of the present studies was to explore if, as in rodents, NPY innervates galanin-immunoreactive (IR) neurons in the human diencephalon. Due to the long post mortem period and subsequent lack of optimal preservation of the cell membranes in the brain, electron microscopy could not be employed to show the presence of NPY-IR synapses on galanin-IR neurons. Therefore, we used light microscopic double label immunocytochemistry and high magnification microscopy with oil immersion to identify putative juxtapositions between NPY and galanin. Our studies show that similarly to rats, numerous NPY-IR nerve terminals surrounded galanin-IR neurons in the human hypothalamus. Among the hypothalamic regions, the infundibulum (infundibular or arcuate nucleus) contained the largest number of galanin-IR neurons heavily surrounded with NPY-IR nerve terminals. These en passant-type intimate associations between NPY-IR and galanin-IR neuronal elements may be functional synapses and may provide the morphological basis for the NPY-mediated galanin release. Consequently, NPY-galanin communication may mediate effects of NPY on neuronal systems innervated by galanin, and therefore may play a pivotal role in the regulation of reproduction, growth, energy and metabolism.

Previous studies revealed that growth hormone-releasing hormone (GHRH)-immunoreactive (IR) neurons form a circumscribed cell group in the basal infundibulum/median eminence of the human hypothalamus. GHRH from these neurons is released into the hypothalamo-hypophyseal portal circulatory system in a pulsatile manner. It is a common consensus that the pulsatile release of GHRH is the main driving force behind the pulsatile release of growth hormone (GH) and may contribute to the regulation of other hypothalamic functions. The pulsatile release of GHRH requires synchronized activity of GHRH-IR neurons. However, the morphological basis of this synchronization between the GHRH-IR neural elements has not been elucidated yet. Since the utilization of electron microscopy combined with immunohistochemistry is virtually impossible in the human brain due to the long post mortem period, immunohistochemistry, evaluated with oil immersion light microscopy, was used in order to reveal the associations between the GHRH elements. Numerous GHRH-GHRH juxtapositions have been detected in the infundibular area/median eminence, where GHRH-IR axonal varicosities often formed multiple contacts with GHRH-IR perikarya. Examination of these associations with high magnification oil immersion light microscopy revealed (1) axonal swellings at the site of the contacts and (2) no gaps between the contacting elements suggesting that these juxtapositions may be functional synapses. The large number of GHRH-GHRH juxtapositions in the infundibular area/median eminence suggests that these synapse-like structures may represent the morphological substrate of the synchronized activity of GHRH neurons that in turn may result in the pulsatile release of GHRH in human.

The localization of neuronal perikarya which have axon terminals on capillaries of the external zone of the median eminence (hypophysiotropic neurons) has been determined in the rat after injection of wheat germ agglutinin (WGA) directly into external zone of the median eminence or after peripheral injection of Fluoro-Gold. The retrogradely transported WGA and endogenous peptides (luteinizing hormone-releasing hormone, somatostatin, galanin, or neurotensin) have been detected by double-labeling immunocytochemical techniques (PAP or ABS) using contrasting chromogens. Retrograde labeling with Fluro-Gold has been combined with fluoroscence immunocuytochemistry, using Texas red as the second chromogen. A few examples of triple labeling (Fluoro-Gold and two endogenous peptides) are also demonstrated. Detailed descriptions of double-labeling techniques, including preparation and administration of the tracers and simultaneous detection of the retrograde tracers and endogenous peptides, are presented.

Galantamine, a drug used to treat Alzheimer's disease, has recently emerged as a potential medical countermeasure against the toxicity of organophosphorus (OP) compounds, including the nerve agent soman. Here, magnetic resonance imaging (MRI) was used to characterize the neurotoxic effects of soman and the ability of galantamine to prevent these effects in guinea pigs, the best non-primate model to predict the effectiveness of antidotes against OP toxicity in humans. The brains of treated and untreated guinea pigs were imaged using a clinical 3.0 Tesla MRI scanner at 48h before and 6-7h, 48h and 7 days after their challenge with 1.0xLD50 soman (26.3mug/kg, sc). Significant brain atrophy was observed among all untreated animals at 7 days after their challenge with soman. In mildly intoxicated animals, significant shortening of spin-spin relaxation times (T2) was observed in the thalamus and amygdala at 7h after the challenge. In severely intoxicated animals, T2 values and T2-weighted signal intensities increased significantly in the piriform cortex, hippocampus, thalamus and amygdala; in most regions, changes were long-lasting. Voxel-based morphometric analysis of the images revealed that other brain regions were also damaged in these animals. Neuronal loss was confirmed histopathologically. In animals that were treated with galantamine (8mg/kg, im) 30min prior to the exposure to soman, T2, T2-weighted signal intensities, and CSF volumes were largely unaffected. It is, therefore, concluded that galantamine can effectively prevent the structural brain damage induced by an acute exposure to soman.

There have been continued efforts to develop effective antidotal therapies against poisoning with organophosphorus (OP) compounds, including nerve agents and pesticides. We reported recently that galantamine, a drug used to treat Alzheimer's disease, administered before (up to 3 h) or soon after (up to 5 min) an exposure of guinea pigs to 1.5-2 x LD50 soman or sarin effectively counteracted the acute toxicity and lethality of the nerve agents provided that the animals were also post-treated with atropine. Here, we demonstrate that administered to guinea pigs at 30 min before or up to 15 min after an acute challenge with 1 x LD50 soman, galantamine (8 mg/kg, intramuscular) alone is sufficient to counteract the lethality and acute toxicity of the nerve agent. Evidence is also provided that 100% survival can be attained when the association of appropriate doses of galantamine and atropine is administered 30-45 min after the challenge of the guinea pigs with 1 x LD50 soman. Galantamine counteracts the neurodegeneration and the changes in the nicotinic cholinergic system that result from an acute exposure of guinea pigs to 1 x LD50 soman. The results presented herein corroborate that galantamine is an effective antidote against OP poisoning.

Previous studies revealed that oxytocin release is increased by various forms of stress. Hypertonic saline injection, immobilization, and several other stressors elevated the blood level of oxytocin in rats. However, the mechanism of the stress-induced oxytocin release in human is not elucidated yet. Although numerous studies indicate that catecholamines play a pivotal role in modulating the release of oxytocin, there is a lack of data regarding the morphological substrate of this phenomenon. In order to reveal putative juxtapositions between tyrosine hydroxylase-immunoreactive (TH-IR) catecholaminergic and the oxytocinergic systems in the human hypothalamus, we utilized double-label immunohistochemistry in the present study. Numerous TH-IR axon varicosities abutted on oxytocin-IR neurons in the supraoptic and paraventricular nuclei, forming synapse-like associations. Close examination of these juxtapositions with high magnification failed to reveal any gaps between the contacting elements. In summary, the intimate associations between the TH-IR and oxytocin-IR elements may be functional synapses and may represent the morphological substrate of stress-influenced oxytocin release. The finding that several oxytocin-IR perikarya did not receive apparent TH innervation suggests that additional mechanisms may play significant roles in the oxytocin modulation by stressors.