Hypothalamic insulin and glucagon-like peptide-1 levels in an animal model of depression and their effect on corticotropin-releasing hormone promoter gene activity in a hypothalamic cell line

Background

In depression, excessive glucocorticoid action may cause maladaptive brain changes, including in the pathways controlling energy metabolism. Insulin and glucagon-like peptide-1 (GLP-1), besides regulation of glucose homeostasis, also possess neurotrophic properties. Current study was aimed at investigating the influence of prenatal stress (PS) on insulin, GLP-1 and their receptor (IR and GLP-1R) levels in the hypothalamus. GLP-1 and GLP-1R were assayed also in the hippocampus and frontal cortex – brain regions mainly affected in depression. The second objective was to determine the influence of exendin-4 and insulin on CRH promoter gene activity in in vitro conditions.

Corticotropin-releasing hormone (CRH)-immunoreactive (IR) axon varicosities target a subset of growth hormone-releasing hormone (GHRH)-IR neurons in the human hypothalamus

It is a general consensus that stress is one of the major factors that suppresses growth. Previous studies revealed that the catecholaminergic and neuropeptide Y (NPY) systems, involved in the activation of stress-related neuronal circuits, influence growth hormone (GH)-release via modulating growth hormone-releasing hormone (GHRH) secretion. Indeed, catecholaminergic and NPY-immunoreactive (IR) axon varicosities abut on the surface of the GHRH neurons forming contacts. These juxtapositions appear to be real synapses and may represent the morphological substrate of the impact of stress on growth. In addition to catecholamines and NPY, there is a vast amount of evidence that corticotropin-releasing hormone (CRH), a major stress hormone, also influences GH secretion. Whether this modulatory effect is direct, or indirect, via the hypothalamic GHRH system, has not been elucidated yet.In the present study, we examined the possibility that CRH influences GH secretion via modulating the GHRH release by direct synaptic mechanisms. Since the verification of these synapses by electron microscopy is problematic in human due to the long post mortem time, in order to reveal the putative CRH-GHRH juxtapositions, light microscopic double label immunohistochemistry was utilized. In the infundibular nucleus, a subset (6%) of the GHRH perikarya received abutting CRH fiber varicosities forming multiple contacts while passing by. No gaps appeared between the contacting elements. The morphology of these CRH-GHRH juxtapositions suggests that, among other neurotransmitters/neuromodulators, CRH influences growth by modulating the hypothalamic GHRH secretion via direct synaptic mechanisms.     

Localization of ocular albinism-1 gene product GPR143 in the rat central nervous system

l-3,4-Dihydroxyphenylalanine (DOPA) has been believed to be a precursor of dopamine, and itself being an inert amino acid. Previously, we have proposed DOPA as a neurotransmitter candidate in the central nervous system (CNS). Recent findings have suggested DOPA as an endogenous agonist of a G-protein coupled receptor, ocular albinism 1 gene product (OA1), which is highly expressed in the retinal pigmental epithelium. However, whether OA1 functions as a receptor for DOPA in vivo, and whether this receptor–ligand interaction is responsible for a wide variety of DOPA actions have not been determined yet. To gain insight into the functional implication of OA1, we perform immunohistochemical examination with anti-OA1 antibody to localize OA1 in the adult rat brain. We observed OA1 immunoreactive cells in the hippocampus, cerebral cortex, cerebellum cortex, striatum, substantia nigra, hypothalamic median eminence and supraoptic nucleus, nucleus tractus solitarii and caudal ventrolateral medulla and rostral ventrolateral medulla, medial habenular nucleus and olfactory bulb. This study reveals, for the first time, the unique distribution pattern of OA1-immunoreactive neurons and/or cells in the rat CNS.     

Central orchestration of peripheral nutrient partitioning and substrate utilization: Implications for the metabolic syndrome

Energy homoeostasis is maintained through a complex interplay of nutrient intake and energy expenditure. The central nervous system is an essential component of this regulation, as it integrates circulating signals of hunger and satiety to develop adaptive responses at the behavioural and metabolic levels, while the hypothalamus is regarded as a particularly crucial structure in the brain in terms of energy homoeostasis. The arcuate nucleus (ARC) of the hypothalamus contains at least two intermingled neuronal populations: the neurons that produce neuropeptide Y (NPY); and the Agouti-related protein (AgRP) produced by AgRP/NPY neurons situated below the third ventricle in close proximity to proopiomelanocortin (POMC)-producing neurons. POMC neurons exert their catabolic and anorectic actions by releasing α-melanocyte-stimulating hormone (α-MSH), while AgRP neurons oppose this action by exerting tonic GABAergic inhibition of POMC neurons and releasing the melanocortin receptor inverse agonist AgRP. The release of neurotransmitters and neuropeptides by second-order AgRP neurons appears to take place on a multiple time scale, thereby allowing neuromodulation of preganglionic neuronal activity and subsequent control of nutrient partitioning – in other words, the coordinated regulation of conversion, storage and utilization of carbohydrates vs. lipids. This suggests that the function of AgRP neurons extends beyond the strict regulation of feeding to the regulation of efferent organ activity, such that AgRP neurons may now be viewed as an important bridge between central detection of nutrient availability and peripheral nutrient partitioning, thus providing a mechanistic link between obesity and obesity-related disorders.     

Obesity and neuroinflammation: A pathway to cognitive impairment

Obesity is a growing problem worldwide and is associated with a range of comorbidities, including cognitive dysfunction. In this review we will address the evidence that obesity and high fat feeding can lead to cognitive dysfunction. We will also examine the idea that obesity-associated systemic inflammation leads to inflammation within the brain, particularly the hypothalamus, and that this is partially responsible for these negative cognitive outcomes. Thus, obesity, and high fat feeding, lead to systemic inflammation and excess circulating free fatty acids. Circulating cytokines, free fatty acids and immune cells reach the brain at the level of the hypothalamus and initiate local inflammation, including microglial proliferation. This local inflammation likely causes synaptic remodeling and neurodegeneration within the hypothalamus, altering internal hypothalamic circuitry and hypothalamic outputs to other brain regions. The result is disruption to cognitive function mediated by regions such as hippocampus, amygdala, and reward-processing centers. Central inflammation is also likely to affect these regions directly. Thus, central inflammation in obesity leads not just to disruption of hypothalamic satiety signals and perpetuation of overeating, but also to negative outcomes on cognition.     

Role of hypothalamic corticotropin-releasing factor in mediating alcohol-induced activation of the rat hypothalamic–pituitary–adrenal axis

Alcohol stimulates the hypothalamic–pituitary–adrenal (HPA) axis through brain-based mechanisms in which endogenous corticotropin-releasing factor (CRF) plays a major role. This review first discusses the evidence for this role, as well as the possible importance of intermediates such as vasopressin, nitric oxide and catecholamines. We then illustrate the long-term influence exerted by alcohol on the HPA axis, such as the ability of a first exposure to this drug during adolescence, to permanently blunt neuroendocrine responses to subsequent exposure of the drug. In view of the role played by CRF in addiction, it is likely that a better understanding of the mechanisms through which this drug stimulates the HPA axis may lead to the development of new therapies used in the treatment of alcohol abuse, including clinically relevant CRF antagonists.     

Neuroendocrine control of maternal behavior in non-human and human mammals

Mammalian parental care is essentially provided by the mother and it occupies most of the reproductive period for female. The synchronization of maternal behavior with parturition and lactation ensures that the mother responds to the needs of the young at the appropriate time. This temporal synchrony is accomplished by hormonal changes that underly both the onset of maternal behavior and of parturition and lactation. The aim of this review is to describe and compare the hormonal mechanisms that regulate the onset of maternal behavior across a variety of mammals, including humans, that represent different behavioral strategies. Are involved the steroid hormones, estradiol and progesterone synthesized by the ovaries which primed the future mother to repond maternally. In response to these steroids, oxytocin release induced by vaginocervical stimulation and prolactin release affect the maternal brain. The medial preoptic area integrates the hormonal signals to regulate maternal behavior. The hormonal cocktail that stimulates maternal behavior varies across mammalian species. Because most of the studies in humans are correlative and because human environment is complex, direct causality between hormones and maternal behavior is unclear. However, one can reasonably think that hormones create a positive bias towards the baby increasing the occurrence of maternal behavior.     

What ethologically based models have taught us about the neural systems underlying fear and anxiety

Classical Pavlovian fear conditioning to painful stimuli has provided the generally accepted view of a core system centered in the central amygdala to organize fear responses. Ethologically based models using other sources of threat likely to be expected in a natural environment, such as predators or aggressive dominant conspecifics, have challenged this concept of a unitary core circuit for fear processing. We discuss here what the ethologically based models have told us about the neural systems organizing fear responses. We explored the concept that parallel paths process different classes of threats, and that these different paths influence distinct regions in the periaqueductal gray - a critical element for the organization of all kinds of fear responses. Despite this parallel processing of different kinds of threats, we have discussed an interesting emerging view that common cortical-hippocampal-amygdalar paths seem to be engaged in fear conditioning to painful stimuli, to predators and, perhaps, to aggressive dominant conspecifics as well. Overall, the aim of this review is to bring into focus a more global and comprehensive view of the systems organizing fear responses.     

颅脑损伤合并高钠血症63例临床分析

目的：探讨颅脑损伤后合并高钠血症的临床治疗及高钠血症对预后的影响。方法回顾分析该院2007年1月-2014年12月间收治的重型颅脑损伤合并高钠血症63例患者临床资料,对比血钠高低对死亡率的影响,对比控制尿量组与非控制尿量组血钠恢复时间。结果轻度高钠组、中度高钠组、重度高钠组分别有17例、24例、22例,各组的死亡率分别为29.4%、45.8%、63.6%,轻度高钠组与重度高钠组间相比,差异有统计学意义(P<0.05)。控制尿量组28例,非控制尿量组18例,两组的血钠恢复正常所需的平均天数分别为(4.57±1.86)、(6.38±1.49),两组相比差异有统计学意义(P<0.05)。结论颅脑损伤合并高钠血症血钠值越高,死亡率越高,除常规治疗外,控制尿量可明显缩短血钠恢复的时间。     

3 Tesla serial magnetic resonance imaging of human African trypanosomiasis (Trypanosoma brucei gambiense) and review of the literature

We report serial magnetic resonance imaging (MRI) findings and follow-up in a case of human African trypanosomiasis (HAT) presenting with limited lesions followed by early and complete resolution. We searched the literature for documented cases and reviewed MRI findings before treatment. A 30-year-old Lebanese man, who had lived in Gabon for six years, presented with a two-year history of rash, anorexia, weight loss, arthralgia, paresthesia, and hypersomnia. Previously, the patient had received corticosteroid therapy for unconfirmed ANCA-associated vasculitis. Physical examination revealed a painless chancre on the left arm located at the site of an old insect bite, enlarged cervical, axillar and inguinal lymph nodes, hepatosplenomegaly and impaired concentration. Blood analysis showed an elevated protein level (90 g/L) with hypoalbuminemia (24.2 g/L) and elevated IgM (26.4 g/L). Bone marrow aspirate and biopsy failed to detect any parasite. Polymerase chain reaction tests on blood and cerebrospinal fluid were positive for Trypanosoma. Serology tests confirmed the diagnosis of HAT due to Trypanosoma brucei gambiense infection. 3T MRI showed lesions in the hypothalamus and basal ganglia, the internal capsule, and the mesencephalon bilaterally. Follow-up MRI showed interval progression of the abnormalities. Treatment with melarsoprol was followed by clinical improvement with regression of the lesions on the three-month MRI, then total resolution at the 10-month follow-up. This case highlights a pattern of mild MRI lesions in T. brucei gambiense HAT with a total and rapid resolution under treatment. The literature review (16 HAT cases with sufficient radiological data, included ours) revealed an MRI pattern of brain lesion distribution that could be helpful for diagnosis and orienting biological tests.