Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0015672 (fatigue)
 51,768 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The recurrence every 24 h of glucocorticoid elevation led us to investigate the temporal relationship between glucocorticoid receptor occupation in brain cell nuclei and the availability of cytosol sites. Adrenalectomized rats were injected i.v. with [3H]corticosterone in doses ranging from 15 to 106 nmol/kg. Peak nuclear binding occurred 1-2 h after [3H]corticosterone injection and was preceded by a peak of cytosol receptor labeling at 15-30 min. Yet 1 h after 55 or 105 nmol/kg [3H]corticosterone, no depletion in the total in vitro binding capacity of the cytosol could be detected even though estimated depletion should have been approximately 30% had it occurred. Injection of 80 nmol/kg of corticosterone per rat plus 40 nmol/kg dexamethasone also failed to reduce total cytosol binding capacity, even though estimated depletion should have been approximately 40%. No change in binding affinity of cytosol sites was observed in the injected animals compared to uninjected controls. The in vivo nuclear binding capacity of hippocampus for [3H]corticosterone (fmol/hippocampus) is about 40% of the cytosol binding capacity measured in vitro. Moreover, no more than 40% of total cytosol sites are occupied in vivo as a result of [3H]corticosterone injections which occupy nuclear sites to 80% of estimated capacity. Yet, even with the larger in vitro cytosol binding capacity, a depletion approaching 40% of cytosol binding sites would have been seen, had it occurred as a result of nuclear translocation. The apparent lack of depletion of cytosol receptors is supported by experiments which showed that two injections of [3H]corticosterone 2 h apart fail to fatigue the nuclear uptake mechanism. The present results suggest (1) that in the hippocampus an excess of extranuclear glucocorticoid binding proteins exists, and (2) that the availability of functional cytosol receptors may be regulated to maintain a relatively constant cellular level.
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PMID:Hippocampal cytosol binding capacity of corticosterone: no depletion with nuclear loading. 736 83

A certain number of HIV-infected patients (about 17% in our series) manifest symptoms of cortisol resistance--weakness, weight loss, hypertension, chronic fatigue and intense mucocutaneous melanosis--symptoms which are also typical of Addison's disease. The diagnosis of cortisol resistance is determined through the increased plasma and urinary cortisol values and limited increases in ACTH values. Compared with patients with primary glucocorticoid resistance, AIDS patients have no symptoms of mineral-corticoid or androgen excess, only of glucocorticoid deficiency at target tissues. Mononuclear leukocytes from these patients show receptor changes which consist of an increased receptor number and decreased receptor affinity for glucocorticoids. They also show defective glucocorticoid-induced inhibition of [3H]thymidine incorporation. Glucocorticoid-resistant AIDS patients have a characteristic persistent increase in interferon-alpha production. The inverse correlation between plasma values of interferon-alpha and the receptor affinity for glucocorticoids clearly suggests that interferon production is regulated by the glucocorticoid receptor: the smaller the glucocorticoid effect on lymphocyte cells is, the greater interferon production is. Owing to the antiviral effect of interferon-alpha, it is possible that glucocorticoid-resistant AIDS patients have greater defences against viral infection than other AIDS patients. As interferon-alpha is melanogenetic, its increased production may also explain the intense skin pigmentation found in patients with the glucocorticoid-resistance syndrome.
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PMID:The syndrome of acquired glucocorticoid resistance in HIV infection. 781 Dec 21

Familial glucocorticoid resistance (FGR) is a rare hereditary disorder characterized by hypercortisolism and the absence of stigmata of Cushing's syndrome. The inability of glucocorticoids to exert their effects on target tissues is compensated for by increases in circulating corticotropin (ACTH) and cortisol, the former causing excess secretion of both adrenal androgens and adrenal steroid-biosynthesis intermediates with salt-retaining activity. There is considerable variability in the clinical presentations of FGR ranging from asymptomatic, to isolated chronic fatigue and to hypertension with or without hypokalemic alkalosis or to hyperandrogenism, or both. In women, hyperandrogenism can result in acne, hirsutism, menstrual irregularities, oligoanovulation, and infertility; in men it may lead to infertility and in children to precocious puberty. The reported molecular defects in FGR, such as point mutations and a microdeletion of the glucocorticoid receptor (GR) gene, cause partial resistance by, respectively, compromising the function of the GR or decreasing its intracellular concentration in glucocorticoid target tissues. Complete glucocorticoid resistance is believed to be incompatible with life in humans. Hence, the glucocorticoid resistance cases reported have been partial and of variable degree. The extreme variability in the clinical manifestations of the disorder can, additionally, be explained by differing sensitivity of target tissues to mineralocorticoids or androgens or both, and perhaps by different biochemical defects of the glucocorticoid receptor, causing selective resistance of certain glucocorticoid responses in specific tissues. Isolated tissue-resistance from a somatic mutation of the GR in a corticotropinoma from a patient with Nelson's syndrome was also found, suggesting that this may be a mechanism of tumorigenesis. There is additional evidence that defects of GR function can appear surreptitiously in a variety of clinical conditions, suggesting that glucocorticoid resistance in humans may be involved in the pathogenesis and/or clinical picture of a plethora of disease states, of which FGR is the archetype.
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PMID:Glucocorticosteroid resistance in humans. Elucidation of the molecular mechanisms and implications for pathophysiology. 782 90

Familial glucocorticoid resistance results from the partial inability of glucocorticoids to exert their effects on their target tissues throughout the organism. The condition is associated with compensatory elevations of circulating ACTH and cortisol, with the former causing excess abnormal secretion of steroids with mineralocorticoid and androgen activity. The manifestations of glucocorticoid resistance vary from asymptomatic to chronic fatigue, to varying degrees of hypertension and/or hypokalaemic alkalosis and hyperandrogenism. The latter can be manifest in women as acne, hirsutism, menstrual irregularity, oligoanovulation and infertility, in men as infertility, and in children as precocious puberty. Different molecular defects of the highly conserved glucocorticoid receptor gene, altering its concentration and functional characteristics, appear to cause the syndrome of familial glucocorticoid resistance. Depending on the molecular defect, this syndrome is transmitted by an autosomal dominant or recessive trait. There are recent suggestions that non-generalized forms of glucocorticoid resistance may exist, resulting in autoimmune-inflammatory phenomena or psychiatric manifestations.
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PMID:Hormone-nuclear receptor interactions in health and disease. Glucocorticoid resistance. 798 Aug 39

Glucocorticoid resistance results from the partial, albeit apparently generalized, inability of glucocorticoids to exert their effects on target tissues. The condition is associated with compensatory increases in circulating pituitary corticotropin and cortisol, with the former causing excess secretion of both adrenal androgens and adrenal steroid biosynthesis intermediates with salt-retaining activity. The manifestations of glucocorticoid resistance vary from chronic fatigue (perhaps a result of glucocorticoid deficiency in the central nervous system) to various degrees of hypertension with or without hypokalemic alkalosis or hyperandrogenism, or both, caused by increased cortisol and other salt-retaining steroids and adrenal androgens, respectively. In women, hyperandrogenism can result in acne, hirsutism, menstrual irregularities, oligoanovulation, and infertility; in men, it may lead to infertility and in children, to precocious puberty. Different molecular defects, such as point mutations or a microdeletion of the highly conserved glucocorticoid receptor gene, alter the functional characteristics or concentrations of the intracellular receptor and appear to cause glucocorticoid resistance. The extreme variability in the clinical manifestations of glucocorticoid resistance and its mimicry of many common diseases can be explained by the overall degree of glucocorticoid resistance, differing sensitivity of target tissues to mineralocorticoids or androgens or both, and perhaps different biochemical defects of the glucocorticoid receptor, with selective resistance of certain glucocorticoid responses in specific tissues. The various different symptoms of classic glucocorticoid resistance and the theoretical potential of this condition to appear surreptitiously emphasize the importance of the glucocorticoid receptor in the pathogenesis of human disease.
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PMID:Syndromes of glucocorticoid resistance. 818 39

Patients with familial cortisol resistance have continuously elevated serum cortisol without any clinical manifestations of Cushing's syndrome due to hyposensitivity to cortisol in all tissues including the hypothalamus and the pituitary. Clinical symptoms of the disease are hypertension with hypokalemia and hyporeninemia, virilism in women and mild general fatigue. As the cause of the disease, a defect in glucocorticoid receptor affinity or binding capacity due to mutations in the glucocorticoid receptor gene has been reported. Another cause of the disease is the presence of heat labile glucocorticoid receptor. In 4 of 5 families with cortisol resistance reported so far, mutations of the glucocorticoid receptor gene have been demonstrated.
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PMID:[Familial cortisol resistance and mutations of the glucocorticoid receptor gene]. 970 71

Abnormalities of glucocorticoid receptors were assumed to cause resistance or hypersensitivity to glucocorticoid, while only glucocorticoid resistance has been described clinically. Patients with familial cortisol resistance have continuously elevated serum cortisol without any clinical manifestations of Cushing's syndrome due to hyposensitivity to cortisol in all tissues including the hypothalamus and the pituitary. Clinical symptoms of the disease are characterized by hypertension with hypokalemia and hyporeninemia, virilism in women, isosexual precocity in a boy and mild general fatigue. As the cause of the disease, a defect in glucocorticoid receptor affinity or binding capacity due to mutations in the glucocorticoid receptor gene has been reported. Another cause of the disease is the presence of heat labile glucocorticoid receptor. In 5 of 6 families with cortisol resistance reported so far, mutations of the glucocorticoid receptor gene have been demonstrated.
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PMID:[Disorders caused by abnormalities of glucocorticoid receptors]. 1185 26

Glucocorticoid resistance is a rare, familial, or sporadic condition characterized by partial end-organ insensitivity to glucocorticoids. The clinical spectrum of the condition ranges from completely asymptomatic to severe hyperandrogenism, fatigue, and/or mineralocorticoid excess. The molecular basis of glucocorticoid resistance in several families and sporadic cases has been ascribed to mutations in the human glucocorticoid receptor-alpha (hGRalpha) gene, which impair the ability of the receptor to transduce the glucocorticoid signal. We systematically investigated the molecular mechanisms through which natural, ligand-binding domain hGRalpha mutants, including hGRalphaI559N, hGRalphaV571A, hGRalphaD641V, hGRalphaV729I, and hGRalphaI747M, produce a defective signal and determined whether their differential effects on hGRalpha function might account for the type of genetic transmission of the disorder and the variable clinical phenotype of the affected subjects. Our findings suggest that all five mutant receptors studied have ligand-binding domains with decreased intrinsic transcriptional activity. Unlike hGRalphaI559N and I747M previously shown to exert a dominant negative effect upon the transcriptional activity of hGRalpha, hGRalphaV571A, D641V, and V729I do not have such an effect. All five mutants studied demonstrate varying degrees of decreased affinity for the ligand in a standard dexamethasone binding assay, but preserve their ability to bind DNA. The nondominant negative mutants, hGRalphaV571A, D641V, and V729I, show delayed translocation into the nucleus after exposure to ligand. Finally, hGRalphaI559N, V571A, D641V, and V729I display an abnormal interaction with the glucocorticoid receptor-interacting protein-1 coactivator in vitro, as this was previously shown also for hGRalphaI747M. We conclude that each of the above hGRalpha mutations imparts different functional defects upon the glucocorticoid signal transduction pathway, which explains the autosomal recessive or dominant transmission of the disorder, but might only explain in part its variable clinical phenotype.
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PMID:Natural glucocorticoid receptor mutants causing generalized glucocorticoid resistance: molecular genotype, genetic transmission, and clinical phenotype. 1507 Sep 67

Glucocorticoid resistance is a rare, familial or sporadic condition characterized by partial end-organ insensitivity to glucocorticoids. The clinical spectrum of the condition is broad, ranging from completely asymptomatic to severe hyperandrogenism and/or mineralocorticoid excess. The molecular basis of glucocorticoid resistance has been ascribed to mutations in the human glucocorticoid receptor-alpha (hGRalpha) gene, which impair one or more of the molecular mechanisms of GR action, thus altering tissue sensitivity to glucocorticoids. We identified a new case of generalized glucocorticoid resistance in a young woman who presented with a long-standing history of fatigue, anxiety, hyperandrogenism, and hypertension. The disease was caused by a novel, heterozygous mutation (T-->C) at nucleotide position 2318 (exon 9) of the hGRalpha gene, which resulted in substitution of leucine by proline at amino acid position 773 in the ligand-binding domain of the receptor. We systematically investigated the molecular mechanisms through which the natural hGRalphaL773P mutant impaired glucocorticoid signal transduction. Compared with the wild-type hGRalpha, hGRalphaL773P demonstrated a 2-fold reduction in the ability to transactivate the glucocorticoid-inducible mouse mammary tumor virus promoter, exerted a dominant negative effect on the wild-type receptor, had a 2.6-fold reduction in the affinity for ligand, showed delayed nuclear translocation (30 vs. 12 min), and, although it preserved its ability to bind to DNA, displayed an abnormal interaction with the GR-interacting protein 1 coactivator in vitro. We conclude that the carboxyl terminus of the ligand-binding domain of hGRalpha is extremely important in conferring transactivational activity by altering multiple functions of this composite transcription factor.
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PMID:A novel point mutation in the ligand-binding domain (LBD) of the human glucocorticoid receptor (hGR) causing generalized glucocorticoid resistance: the importance of the C terminus of hGR LBD in conferring transactivational activity. 1576 88

Chronic fatigue syndrome (CFS) is a significant public health problem of unknown etiology, the pathophysiology has not been elucidated, and there are no characteristic physical signs or laboratory abnormalities. Some studies have indicated an association of CFS with deregulation of immune functions and hypothalamic-pituitary-adrenal (HPA) axis activity. In this study, we examined the association of sequence variations in the glucocorticoid receptor gene (NR3C1) with CFS because NR3C1 is a major effector of the HPA axis. There were 137 study participants (40 with CFS, 55 with insufficient symptoms or fatigue, termed as ISF, and 42 non-fatigued controls) who were clinically evaluated and identified from the general population of Wichita, KS. Nine single nucleotide polymorphisms (SNPs) in NR3C1 were tested for association of polymorphisms and haplotypes with CFS. We observed an association of multiple SNPs with chronic fatigue compared to non-fatigued (NF) subjects (P < 0.05) and found similar associations with quantitative assessments of functional impairment (by the SF-36), with fatigue (by the Multidimensional Fatigue Inventory) and with symptoms (assessed by the Centers for Disease Control Symptom Inventory). Subjects homozygous for the major allele of all associated SNPs were at increased risk for CFS with odds ratios ranging from 2.61 (CI 1.05-6.45) to 3.00 (CI 1.12-8.05). Five SNPs, covering a region of approximately 80 kb, demonstrated high linkage disequilibrium (LD) in CFS, but LD gradually declined in ISF to NF subjects. Furthermore, haplotype analysis of the region in LD identified two associated haplotypes with opposite alleles: one protective and the other conferring risk of CFS. These results demonstrate NR3C1 as a potential mediator of chronic fatigue, and implicate variations in the 5' region of NR3C1 as a possible mechanism through which the alterations in HPA axis regulation and behavioural characteristics of CFS may manifest.
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PMID:Glucocorticoid receptor polymorphisms and haplotypes associated with chronic fatigue syndrome. 1674 Jan 43


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