UNIPROT:P01189 - FACTA Search

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Query: UNIPROT:P01189 (beta-endorphin)
21,003 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

High circulating levels of glucocorticoid hormones adversely affect cognition. Previous studies exploring the hypothalamic-pituitary-adrenal (HPA) axis and basal cortisol levels in the elderly reported that subjects with mid-range cortisol levels outperformed subjects with high cortisol levels on assessments of memory and attention. This study examines the efficacy of mifepristone, a glucocorticoid-antagonist, in decelerating the rate of cortisol-related cognitive decline in subjects with mile-to-moderate Alzheimer's disease (AD). Rate of cognitve decline is compared in AD subjects randomized to receive 200 mg of mifepristone daily for 6 mo or placebo. The Alzheimer's Disease Assessment Scale (ADAS) and the Folstein Mini Mental Status Exam (MMSE) will be the primary measures used to assess change in cognitve function over the 6 mo period, supplemented by a neuropsychological battery testing memory and language and reasoning skills. During each visit, subjects will have samples collected for determination of plasma adrenocorticotropin (ACTH), serum cortisol and salivary cortisol levels to assess HPA axis activity. The placebo arm of this study also investigate whether subjects with high baseline cortisol levels experience greater declines in cognitive impairment over time relative to subjects with Ad who have low baseline cortisol levels. Additionally, this study test the hypothesis that AD subjects with elevated cortisol at baseline will perform more poorly on neuropsychological exams that do subjects with low cortisol.
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PMID:Slowing the progression of cognitive decline in Alzheimer's disease using mifepristone. 1221 81

Treating dementia of the Alzheimer's type is a terrible challenge that will require an innovative pharmacological strategy simultaneously addressing symptoms and causes of the complex neurodegenerative process involved in Alzheimer's disease. The present review will outline the most recent data, albeit restricted to preliminary preclinical studies, suggesting that the sigma(1) receptor agonist may present some efficacy. The sigma(1) receptor is a unique intraneuronal protein that modulates intracellular Ca(2+) mobilization and extracellular Ca(2+) influx, leading to a wide spectrum of neuromodulatory activity. At the behavioral level, sigma(1)-receptor agonists are antiamnesic and anti-depressant drugs. The sigma(1) receptor is also one of the receptors at which neurosteroids act to exert their rapid nongenomic effects in the brain. In particular, dehydroepiandrosterone (DHEA) is an endogenous sigma(1) agonist and progesterone, a potent antagonist of the sigma(1) receptor. The beta-amyloid protein-related toxicity induces important disturbances of neurosteroid syntheses and releases mechanisms, particularly by affecting the corticotropin-releasing hormone systems. In turn, sigma(1)-receptor agonists showed an enhanced efficacy in animal models of Alzheimer's disease-related learning impairments or depressive responses. In addition, selective sigma(1) agonists, as well as DHEA, showed marked neuroprotective activity in vitro against oxidative stress-related damages. Acting chronically through the sigma(1) receptor may indeed offer a new way to alleviate the cognitive disturbances observed in Alzheimer's disease and promote long-term improvements. (c) 2002 Prous Science. All rights reserved.
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PMID:Improving Alzheimer's Disease-Related Cognitive Deficits with sigma1 Receptor Agonists. 1267 46

Galanin, a 29-30 amino-acid neuropeptide is distributed in the central and peripheral nervous systems, the pituitary gland, the gastrointestinal tract and also in the pancreas. The endogenous and exogenous effects of galanin are mediated by three receptor subtypes, which are termed: GALR1, GALR2, and GALR3. Galanin has a significant role in physiological and pathological processes in adults as well as in children. It has an ability to contract smooth muscles in GI (facilitation and inhibition), stimulates reflexes in the CNS, decreases pancreatic amylase secretion, changes transport of electrolytes Na+ and CL-. It takes part in etiopathogenesis of depression, Alzheimer's disease and diarrhoea, exerts tonic inhibition of nociceptive input to the central nervous system and regulates a function of hypothalamic-pituitary system. Galanin decreases insulin and somatostatin secretion, increases glucagon secretion, takes part in prolactin release, stimulates growth hormone-releasing hormone, hypothalamic gonadotropin releasing hormone and corticotropin releasing hormone. It causes increase of somatotropin secretion, luteinizing hormone and foliculotropin release and adrenocorticotropin secretion. The hypothalamic galanin takes part in etiopathogenesis of obesity not only in human reproductive period, but also in adolescence, increasing the appetite and changing fat metabolism. This variety of actions emphasizes the potential importance of this peptide in the regulation of cells function and the need to understand the mechanism by which they act.
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PMID:[The role of galanin in the endocrine system]. 1281 74

The expression of estrogen receptor (ER)alpha and -beta in the infundibular nucleus of the hypothalamus was studied immunocytochemically in 28 control subjects and 14 patients with Alzheimer's disease (AD). A shift was found from more nuclear staining of ERalpha in young female controls to more cytoplasmic staining in elderly female controls, whereas no such change was observed in elderly male controls. The shift of ERalpha from nucleus to cytoplasm in elderly female controls was accompanied by a relative absence of AD neuropathology, i.e. hyperphosphorylated tau stained by hyperphosphorylated tau protein (AT8). In contrast, male and female AD patients showed more nuclear ERalpha and a much stronger AD neuropathology. It is proposed that the shift of ERalpha from nucleus to the cytoplasm may reflect activation of neurons and that hyperactivity decreases the risk that neurons in the course of aging develop AD neuropathology. In contrast, the presence of nuclear ERalpha seems to predispose to reduced activity and increases the risk of some neurons to develop AD neuropathology. ERbeta in basket-like terminals was preferentially observed in elderly male controls and AD patients, a novel phenomenon. This suggests that the presence of basket-like ERbeta may reflect reduced activity, which is-associated with an increase in hyperphosphorylated tau staining. However, the neurons inside the basket-like ERbeta showed signs of hyperactivity and did not stain for AT8. All AT8-positive neurons in the infundibular nucleus contained alphaMSH as a marker for proopiomelanocortin neurons. These neurons produce beta-endorphin that inhibits GnRH release. Because they diminish in activity in postmenopausal women, this may contribute to the hyperactivity of GnRH neurons. The regulation of the gonadal axis may thus be affected by AD neuropathology independent of AD neuropathology in cognition-related brain structures.
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PMID:Changes in estrogen receptor-alpha and -beta in the infundibular nucleus of the human hypothalamus are related to the occurrence of Alzheimer's disease neuropathology. 1507 Sep 64

Brain asymmetry is understood as an anatomical, functional or neurochemical difference between the two hemispheres. It is not a static but rather a dynamic phenomenon in which both environmental and endogenous factors act as modulators. Aging modifies brain asymmetry, and an imbalance in specific asymmetries characterizes some brain disorders such as schizophrenia, depression, infantile autism or Alzheimer's disease. However, it is not clear whether these changes are a cause or a consequence of these disorders. Although this phenomenon has been extensively studied, its functional significance is not yet clear, and the neurochemical basis underlying anatomical or functional asymmetries in the brain is still poorly understood. In recent decades intensive research on the behaviour of neuropeptides has revealed asymmetries in their distribution in the brain, and there is evidence that the lateralized patterns of distribution are involved in the regulatory control of some neuropeptidase activities. Therefore, if these enzymatic activities are distributed asymmetrically, their endogenous substrates would presumably be affected in an asymmetrical way, as would the functions they are involved in. Here we review the most significant literature regarding human and animal brain asymmetry involving neuropeptides such as corticotropin-releasing hormone, cholecystokinin, luteinizing hormone-releasing hormone, thyrotropin-releasing hormone and angiotensin II, as well as their neuropeptidases.
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PMID:Neuropeptides, neuropeptidases and brain asymmetry. 1558 19

G protein-coupled receptors (GPCRs) play pivotal roles in regulating the function and plasticity of neuronal circuits in the nervous system. Among the myriad of GPCRs expressed in neural cells, class II GPCRs which couples predominantly to the Gs-adenylate cyclase-cAMP signaling pathway, have recently received considerable attention for their involvement in regulating neuronal survival. Neuropeptides that activate class II GPCRs include secretin, glucagon-like peptides (GLP-1 and GLP-2), growth hormone-releasing hormone (GHRH), pituitary adenylate cyclase activating peptide (PACAP), corticotropin-releasing hormone (CRH), vasoactive intestinal peptide (VIP), parathyroid hormone (PTH), and calcitonin-related peptides. Studies of patients and animal and cell culture models, have revealed possible roles for class II GPCRs signaling in the pathogenesis of several prominent neurodegenerative conditions including stroke, Alzheimer's, Parkinson's, and Huntington's diseases. Many of the peptides that activate class II GPCRs promote neuron survival by increasing the resistance of the cells to oxidative, metabolic, and excitotoxic injury. A better understanding of the cellular and molecular mechanisms by which class II GPCRs signaling modulates neuronal survival and plasticity will likely lead to novel therapeutic interventions for neurodegenerative disorders.
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PMID:Class II G protein-coupled receptors and their ligands in neuronal function and protection. 1605 36

Senile plaques in the Alzheimer's disease (AD) are formed by aggregation of beta-amyloid (Abeta) peptide. Abeta peptide has been shown to activate microglia and stimulate their production of inflammatory factors, such as cytokines. In the AD brain, the continued presence of amyloid plaques may keep microglia persistently activated, leading to chronic inflammation in the CNS. It is well established that alpha-melanocyte-stimulating hormone (alpha-MSH) gives rise to anti-inflammatory and anti-pyretic effects. The biological activities of alpha-MSH are mediated by one or more of the melanocortin receptor (MCR) subtypes, i.e. MCR1 - MCR5. The aim of the present study was to determine the effect of alpha-MSH alone and on Abeta-activated microglial cells with regard to the secretion of inflammatory cytokines, such as interleukin-6 (IL-6), and to determine which receptor subtype mediates the effects of alpha-MSH. The human microglial cell line, CHME3, was incubated for 24 h with freshly dissolved Abeta(1-40), interferon-gamma (IFN-gamma) and/or alpha-MSH. Freshly dissolved Abeta(1-40) (5-60 microM) resulted in a dose-dependent decrease in cell viability, along with a dose-dependent increase in IL-6 release. Neither IFN-gamma nor alpha-MSH affected the Abeta-induced secretion of IL-6, but resulted in a dose-dependent increase in basal IL-6 release. Agouti, the endogenous antagonist of MCR1 and 4, further increased the alpha-MSH-induced secretion of IL-6. RT-PCR showed the expression of MCR1, MCR3, MCR4 and MCR5 mRNA. The combined data suggest that the effect of alpha-MSH in increasing IL-6 release from the human microglial cell line is mediated by MCR3 or MCR5.
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PMID:Cytokine production by a human microglial cell line: effects of beta-amyloid and alpha-melanocyte-stimulating hormone. 1637 21

The stress response is mediated by the hypothalamo-pituitary-adrenal (HPA) system. Activity of the corticotropin-releasing hormone (CRH) neurons in the hypothalamic paraventricular nucleus (PVN) forms the basis of the activity of the HPA-axis. The CRH neurons induce adrenocorticotropin (ACTH) release from the pituitary, which subsequently causes cortisol release from the adrenal cortex. The CRH neurons co-express vasopressin (AVP) which potentiates the CRH effects. CRH neurons project not only to the median eminence but also into brain areas where they, e.g., regulate the adrenal innervation of the autonomic system and affect mood. The hypothalamo-neurohypophysial system is also involved in stress response. It releases AVP from the PVN and the supraoptic nucleus (SON) and oxytocin (OXT) from the PVN via the neurohypophysis into the bloodstream. The suprachiasmatic nucleus (SCN), the hypothalamic clock, is responsible for the rhythmic changes of the stress system. Both centrally released CRH and increased levels of cortisol contribute to the signs and symptoms of depression. Symptoms of depression can be induced in experimental animals by intracerebroventricular injection of CRH. Depression is also a frequent side effect of glucocorticoid treatment and of the symptoms of Cushing's syndrome. The AVP neurons in the hypothalamic PVN and SON are also activated in depression, which contributes to the increased release of ACTH from the pituitary. Increased levels of circulating AVP are also associated with the risk for suicide. The prevalence, incidence and morbidity risk for depression are higher in females than in males and fluctuations in sex hormone levels are considered to be involved in the etiology. About 40% of the activated CRH neurons in mood disorders co-express nuclear estrogen receptor (ER)-alpha in the PVN, while estrogen-responsive elements have been found in the CRH gene promoter region, and estrogens stimulate CRH production. An androgen-responsive element in the CRH gene promoter region initiates a suppressing effect on CRH expression. The decreased activity of the SCN is the basis for the disturbances of circadian and circannual fluctuations in mood, sleep and hormonal rhythms found in depression. Neuronal loss was also reported in the hippocampus of stressed or corticosteroid-treated rodents and primates. Because of the inhibitory control of the hippocampus on the HPA-axis, damage to this structure was expected to disinhibit the HPA-axis, and to cause a positive feedforward cascade of increasing glucocorticoid levels over time. This 'glucocorticoid cascade hypothesis' of stress and hippocampal damage was proposed to be causally involved in age-related accumulation of hippocampal damage in disorders like Alzheimer's disease and depression. However, in postmortem studies we could not find the presumed hippocampal damage of steroid overexposure in either depressed patients or in patients treated with synthetic steroids.
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PMID:The stress system in depression and neurodegeneration: focus on the human hypothalamus. 1752 88

The stress response alters behavior, autonomic function, and secretion of multiple hormones, including corticotropin-releasing factor, adrenocorticotropin hormone, and cortisol, through the hypothalamic-pituitary-adrenal axis. Constitutive stress responses lead to a number of psychiatric disorders, including depression, posttraumatic stress disorder, Alzheimer's disease (AD), and other anxiety disorders through increased stress hormones and other unknown factors. Here, we performed a proteomic analysis of rat brain exposed to restraint stress compared with a nonstress group by using 2D-DIGE and MALDI-TOF analysis. Several proteins were identified by peptide mass fingerprint (PMF), including down-regulated hippocampal cholinergic neurostimulating peptide precursor protein (HCNP-pp). The current study demonstrates that HCNP-pp mRNA and protein expression are decreased in rat hippocampus after stress exposure. The level of HCNP-pp in H19-7, a rat hippocampal cell line, significantly decreases with dexamethasone treatment, a synthetic glucocorticoid. Thus, this finding suggests that HCNP-pp expression may decrease in response to stress exposure. Decreased HCNP-pp from stress exposure may result in lower levels of HCNP that might contribute to a loss of acetylcholine production.
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PMID:Decreased hippocampal cholinergic neurostimulating peptide precursor protein associated with stress exposure in rat brain by proteomic analysis. 1762 2

Corticotropin-Releasing Hormone (CRH) or Corticotropin-Releasing Factor (CRF) and its family of related naturally occurring endogenous peptides and receptors are becoming recognized for their actions within central (CNS) and peripheral (PNS) nervous systems. It should be recognized that the term 'CRH' has been displaced by 'CRF' [Guillemin, R., 2005. Hypothalamic hormones a.k.a. hypothalamic releasing factors. J. Endocrinol. 184, 11-28]. However, to maintain uniformity among contributions to this special issue we have used the original term, CRH. The term 'CRF' has been associated recently with CRH receptors and designated with subscripts by the IUPHAR nomenclature committee [Hauger, R.L., Grigoriadis, D.E., Dallman, M.F., Plotsky, P.M., Vale, W.W., Dautzenberg, F.M., 2003. International Union of Pharmacology. XXXVI. Corticotrophin-releasing factor and their ligands. Pharmacol. Rev. 55, 21-26] to denote the type and subtype of receptors activated or antagonized by CRH ligands. CRH, as a hormone, has long been identified as the regulator of basal and stress-induced ACTH release within the hypothalamo-pituitary-adrenal axis (HPA axis). But the concept, that CRH and its related endogenous peptides and receptor ligands have non-HPA axis actions to regulate CNS synaptic transmission outside the HPA axis, is just beginning to be recognized and identified [Orozco-Cabal, L., Pollandt, S., Liu, J., Shinnick-Gallagher, P., Gallagher, J.P., 2006a. Regulation of Synaptic Transmission by CRF Receptors. Rev. Neurosci. 17, 279-307; Orozco-Cabal, L., Pollandt, S., Liu, J., Vergara, L., Shinnick-Gallagher, P., Gallagher, J.P., 2006b. A novel rat medial prefrontal cortical slice preparation to investigate synaptic transmission from amygdala to layer V prelimbic pyramidal neurons. J. Neurosci. Methods 151, 148-158] is especially noteworthy since this synapse has become a prime focus for a variety of mental diseases, e.g. schizophrenia [Fischbach, G.D., 2007. NRG1 and synaptic function in the CNS. Neuron 54, 497-497], and neurological disorders, e.g., Alzheimer's disease [Bell, K.F., Cuello, C.A., 2006. Altered synaptic function in Alzheimer's disease. Eur. J. Pharmacol. 545, 11-21]. We suggest that "The Stressed Synapse" has been overlooked [c.f., Kim, J.J., Diamond, D.M. 2002. The stressed hippocampus, synaptic plasticity and lost memories. Nat. Rev., Neurosci. 3, 453-462; Radley, J.J., Morrison, J.H., 2005. Repeated stress and structural plasticity in the brain. Ageing Res. Rev. 4, 271-287] as a major contributor to many CNS disorders. We present data demonstrating CRH neuroregulatory and neuromodulatory actions at three limbic synapses, the basolateral amygdala to central amygdala synapse; the basolateral amygdala to medial prefrontal cortex synapse, and the lateral septum mediolateral nucleus synapse. A novel stress circuit is presented involving these three synapses. We suggest that CRH ligands and their receptors are significant etiological factors that need to be considered in the pharmacotherapy of mental diseases associated with CNS synaptic transmission.
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PMID:Synaptic physiology of central CRH system. 1834 52

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