UMLS:C0027819 - FACTA Search

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Query: UMLS:C0027819 (neuroblastoma)
27,800 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Iodine ions exhibited the thyroxin-like effect on incorporation of 1-14C-leucine into proteins of isolated mitochondria and microsomes of thyroidectomized rats in vitro. Thyroxin, triiodothyronine (T3) and ICl increased the incorporation of 1-14C-leucine into proteins of isolated mitochondria of thyroidectomized rats, but did not affect the protein synthesis in microsomes in vitro. Rifampycin and olivomycin abolished completely the stimulating effect of T3 and ICl on incorporation of the label into mitochondrial proteins. The thyroid hormones and iodine ions stimulated protein synthesis in vitro in liver microsomes of thyroidectomized animals only after preincubation with mitochondria or nuclei. In these conditions preincubation with mitochondria elevated the rate of 1-14C-leucine incorporation into microsomal proteins 2--2.5-fold. In similar experiments with nuclei--4--4.8-fold stimulation was detected. Thyroid hormones and iodine ions stimulated synthesis of specific factors in mitochondria (MBS) and in nuclei (NBS) of thyroidectomized rat liver tissue, which increased the protein synthesis in isolated microsomes in vitro. Synthesis of MBS- and NBS-factor required the presence of all the four ribosetriphosphates (ATP, GTP, UTP, CTP) and was inhibited completely by olivomycin; rifampycin blocked only the MBS factor synthesis. NBS- and MBS-factors appear to be RNA (mRNA), synthesized in nuclei and mitochondria, which are transported into the incubation media and translated by ribosomes.
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PMID:[Effect of triiodothyronine and ICl on protein synthesis in cell-free systems]. 42 69

Because genetic predisposition probably plays an important role in the aetiology of most of childhood cancers, studies of second primaries occurring after these cancers may be particularly informative about possible common genetic mechanisms in both of these cancers. We have studied the incidence of thyroid tumours occurring after cancer in childhood in a cohort of 592 children treated before 1970. Among these children, six later developed a thyroid carcinoma, and 18 developed a thyroid adenoma. Radiation doses received to the thyroid by each of the irradiated children have been estimated using individual radiotherapeutic technical records. Thyroid carcinomas and thyroid adenomas were five times more frequent after irradiation for neuroblastoma than after irradiation for any other first cancer. This ratio did not depend on sex, nor on time elapsed since irradiation, nor on dose of radiation received for the thyroid gland. This result suggests that there is a common mechanism for the occurrence of neuroblastoma and of differentiated thyroid tumour.
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PMID:Epidemiological evidence for a common mechanism for neuroblastoma and differentiated thyroid tumour. 155 99

Thyroid hormones must cross the plasma membrane to interact with nuclear or other intracellular receptors. In brain cells, most of the T3 in the nucleus is derived intracellularly from T4. While a saturable transport system has been demonstrated for T3 in a number of cell types, the evidence for such a system for T4 is less well established. In a mouse neuroblastoma cell line (NB41A3) the transport of T4 was found to be stereospecific, saturable, and energy dependent. When cells were incubated with radiolabeled hormone, the nuclear accumulation of L-T4 was 3.8-fold higher than that of D-T4, whereas isolated nuclei had a similar Ka for both enantiomers. Exposure of cells to antimycin and monodansylcadaverine decreased nuclear uptake of L-T4 (Ki of 197 and 55 microM, respectively), but had little effect on D-T4 uptake. Furthermore, L-system neutral amino acids, in particular L-phenylalanine at physiological concentrations, were shown to be competitive inhibitors of both T3 and T4 transport. In the presence of 0.1 mM L-phenylalanine the Km of the saturable plasma membrane transport of L-T3 increased 2.3-fold, and that of L-T4 increased 2.1-fold. In contrast, 1.0 mM L-serine or D-phenylalanine had little effect on L-T4 transport. This interaction of L-system amino acid and thyroid hormone transport may be of physiological importance.
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PMID:The transport of thyroxine into mouse neuroblastoma cells, NB41A3: the effect of L-system amino acids. 235 Nov 15

Thyroid hormone (T3) has a multiplicity of effects on the developing nervous system. We have investigated T3 action using a cholinergic neuroblastoma cell line (S-20Y) as a model. S-20Y contains a nuclear receptor for T3 with binding properties similar to those of other T3 target tissues. In addition, these cells can carry out 5'-deiodination, which is necessary to produce active thyroid hormone in vivo. The enzyme involved in this process appears to be a type I deiodinase, based on its reaction kinetics and its susceptibility to inhibition by propylthiouracil. S-20Y cells maintained in T3-depleted medium showed decreased choline acetyltransferase (ChAT) activity. ChAT activity was restored to the control level in a dose-dependent manner by T3 repletion. Neither cell density nor viability was influenced by the hypothyroid state. The presence of a T3 receptor and the enzyme activity for T3 production, together with an effect of T3 on ChAT activity, demonstrate that S-20Y cells are a target for T3 action and suggest that these cells represent an excellent model system for studies of T3 effects on nervous tissues.
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PMID:Thyroid hormone actions on a cholinergic neuroblastoma cell line (S-20Y). 376 Aug 76

The thyrotropin-releasing hormone (TRH) gene is regulated negatively at the transcriptional level by thyroid hormone (T3). T3 positive regulatory effects on other target genes, such as the growth hormone gene, are mediated through heterodimerization of thyroid hormone receptors (TRs) with RXR or other auxiliary nuclear protein(s). To explore whether an accessory co-suppressor protein(s) may be involved in T3 inhibitory regulation of human TRH gene transcription, transient gene expression studies have been carried out using a hTRH-luciferase (TRH-Luc) chimetric reporter construct, an hTR beta 1 expression construct, and pABgal-hTR beta 1 ligand-binding domain (LBD) fusion constructs, cotransfected into a human neuroblastoma cell line (HTB-11,ATCC). Results herein indicate that T3-dependent inhibitory regulation (48-60% of control) of the hTRH gene promoter by hTR beta 1-T3 complexes could be abrogated completely by cotransfection of a 10 x excess of hTR beta 1-LBD (TR 168-456 aa) in a pABgal94 vector. In striking contrast, cotransfection of a 10 x excess of highly truncated hTR beta 1-LBD (TR 452-456 aa) failed to reverse T3-mediated TRH promoter inhibition. This squelching effect by excessive intact TR-LBD, moreover, could not be reversed by raising T3 concentration 100-fold (from 10(-8) to 10(-6) M), thus excluding a squelching effect of T3 itself by excess LBD. These results suggest that negative regulation of the hTRH gene promoter activity by TR beta 1-T3 complexes involves interactions with an accessory co-suppressor protein, which may bridge DNA-bound TR beta 1-T3 complexes to the transcriptional initiation complex.
Thyroid 1996 Jun
PMID:Reversal of TR-T3 inhibition of the hTRH gene by excess TR ligand-binding domain: evidence for novel accessory protein. 883 32

Thyroid and adrenal tumors, excluding neuroblastoma, are infrequent in children. Because of the problems involved in applying diagnostic and prognostic criteria developed for adult tumors to pediatric tumors, proper diagnosis of thyroid and adrenal tumors in pediatric patients and proper patient management require close collaboration on the part of clinicians, surgeons, and surgical pathologists. In view of that fact, an approach to handling thyroid and adrenal tumors is presented. Special attention is paid to the following aspects of managing both types of tumors: procedure, fine-needle aspiration, intraoperative consultation (frozen sections), gross examination, histologic examination, special studies, diagnosis, and prognostic features.
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PMID:An approach to handling pediatric thyroid and adrenal tumors excluding neuroblastoma. 953 51

Mechanisms of triiodothyronine (T3) negative regulation of the human thyrotropin-releasing hormone (TRH) gene were investigated with a chimeric construct of the 5' flanking region fused to a luciferase reporter gene, transfected into human neuroblastoma cells (HTB-11). Maximum negative regulation was achieved with constructs containing bases -242 to +54. Four sequences in this region exhibited homology with half sites of thyroid hormone response elements (TRE) (AGGTCA). The most important site was a sequence with an overlapping TRE/CRE, involving bases -53 to -60 (TGACCTCA). Potential combinatorial interactions of thyroid hormone receptors and CREB at this site were explored. Modest promoter stimulation was achieved with dibutyryl cyclic adenosine monophosphate (cAMP) (10(-3) M) plus IBMX (0.5 mM). Stimulation was greatly enhanced (+820%) by cotransfection of a constitutively activated protein kinase A (pPKA) construct. Cotransfection with pCREB increased stimulation further to 1350% above control. Stimulation of pPKA and pCREB interfered with stimulation by unliganded TRbeta1, and co-transfected pPKA and pCREB blocked T3 negative inhibition by TRbeta1-T3 complexes. When this site was mutated by polymerase chain reaction (PCR) mutagenesis, the mutant construct failed to respond to unliganded TRbeta1, and stimulation by pPKA and/or pCREB was inhibited markedly, from 12.5- to 2.1-fold, p < 0.001. Moreover, TRbeta1-T3 complexes failed to show any inhibition of the mutated promoter. These results suggest that negative regulation is achieved by inhibition of CREB stimulation of the TRH promoter at this overlapping TRE/CRE site. The two cosuppressors, NCoR and SMRT, were able to augment stimulation of the TRH promoter by unliganded TRbeta1 and enhance the magnitude of T3 inhibition. The potential role of the TRH gene and the pathophysiology of thyroid hormone resistance was investigated with three mutant TRbeta1 constructs. Thyroid hormone resistance was found to be expressed at the level of TRH gene regulation, due to lowered inhibition by mutant TRbeta1-T3 complexes and by their dominant negative effects on wild-type TRbeta1-T3 inhibition. TRH gene expression has been identified in the heart. Cardiac TRH mRNA was not regulated by T3, in contrast to HTB-11 cells, but cardiac TRH mRNA density could be augmented by glucocorticoids and by testosterone. TRH receptors were identified using Scatchard blots that showed a kilodalton of 1.4 nM and a bmax of 10 pmol/mg protein. TRH-R mRNA was identified also by reverse transcription polymerase chain reaction (RT-PCR). Enhanced ventricular contractility by TRH was demonstrated in both an open-chested dog preparation and in ex vivo ventricular myocytes, using video edge cinematography. Under controlled conditions, myocyte shortening was 13.3%, and TRH (10(-6) M) caused muscle shortening to increase 140%, (p < 0.005). TRH gene expression was demonstrated exclusively in Leydig cells of the testis. High affinity binding sites were identified in testicular membranes with a kilodalton of 1.6 x 10(-6) M. TRH was able to inhibit LH and HCG-activated testosterone secretion significantly. Thus, one paracrine role of TRH in the testis may be to serve as inhibitory modulator of gonadotropin-stimulated testosterone secretion.
Thyroid 1998 Oct
PMID:The thyrotropin-releasing hormone gene 1998: cloning, characterization, and transcriptional regulation in the central nervous system, heart, and testis. 982 56

Carnitine (3-hydroxy-4N-trimethylammoniumbutanoate) is a naturally occurring quaternary amine that is ubiquitous in mammalian tissues (concentrations in the order of mM). Based on limited studies of approximately 40 years ago, carnitine was considered to be a peripheral antagonist of thyroid hormone (TH) action. These interesting observations have not been explored. To study the biologic basis of this effect, we tested the following possibilities in three TH-responsive cell lines: (1) inhibition of TH entry into cells; (2) inhibition of TH entry into the nucleus; (3) inhibition of TH interaction with the isolated nuclei; and (4) facilitated efflux of TH from cells. On a preliminary basis we had verified that these cell lines (human skin fibroblasts, human hepatoma cells HepG2, and mouse neuroblastoma cells NB 41A3) take up 14Ccarnitine; however, there was no 14Ccarnitine uptake into the nuclei. Concentrations of unlabeled carnitine as high as 100 mM did not affect (125I)T3 binding to isolated nuclei or exit of TH from cells, thus excluding possibilities numbered 3 and 4. At 10 mM camitine, (125I)T3 and (125I)T4 whole-cell uptake was inhibited by approximately 20% in fibroblasts and in HepG2, but by approximately 5% in NB 41A3 cells. Inhibition of T3 nuclear uptake was evaluated in HepG2 and NB 41A3 cells. At 10 mM carnitine, inhibition of T3 nuclear uptake was disproportionately higher, namely approximately 25% in neurons and 35% in hepatocytes. At 50 mM carnitine, there was a minimal additional decrease in whole-cell uptake of either hormone but a marked decrease in T3 nuclear uptake. The latter inhibition was approximately 60% in neurons and 70% in hepatocytes. We are aware of no inhibitor of TH uptake that has such a markedly different effect on the nuclear versus whole-cell uptake. Our data are consistent with carnitine being a peripheral antagonist of TH action, and they indicate a site of inhibition at or before the nuclear envelope.
Thyroid 2000 Dec
PMID:Carnitine is a naturally occurring inhibitor of thyroid hormone nuclear uptake. 2758 Sep 51

Although it was originally believed that thyroid hormones enter target cells by passive diffusion, it is now clear that cellular uptake is effected by carrier-mediated processes. Two stereospecific binding sites for each T4 and T3 have been detected in cell membranes and on intact cells from humans and other species. The apparent Michaelis-Menten values of the high-affinity, low-capacity binding sites for T4 and T3 are in the nanomolar range, whereas the apparent Michaelis- Menten values of the low-affinity, high-capacity binding sites are usually in the lower micromolar range. Cellular uptake of T4 and T3 by the high-affinity sites is energy, temperature, and often Na+ dependent and represents the translocation of thyroid hormone over the plasma membrane. Uptake by the low-affinity sites is not dependent on energy, temperature, and Na+ and represents binding of thyroid hormone to proteins associated with the plasma membrane. In rat erythrocytes and hepatocytes, T3 plasma membrane carriers have been tentatively identified as proteins with apparent molecular masses of 52 and 55 kDa. In different cells, such as rat erythrocytes, pituitary cells, astrocytes, and mouse neuroblastoma cells, uptake of T4 and T3 appears to be mediated largely by system L or T amino acid transporters. Efflux of T3 from different cell types is saturable, but saturable efflux of T4 has not yet been demonstrated. Saturable uptake of T4 and T3 in the brain occurs both via the blood-brain barrier and the choroid plexus-cerebrospinal fluid barrier. Thyroid hormone uptake in the intact rat and human liver is ATP dependent and rate limiting for subsequent iodothyronine metabolism. In starvation and nonthyroidal illness in man, T4 uptake in the liver is decreased, resulting in lowered plasma T3 production. Inhibition of liver T4 uptake in these conditions is explained by liver ATP depletion and increased concentrations of circulating inhibitors, such as 3-carboxy-4-methyl-5-propyl-2-furanpropanoic acid, indoxyl sulfate, nonesterified fatty acids, and bilirubin. Recently, several organic anion transporters and L type amino acid transporters have been shown to facilitate plasma membrane transport of thyroid hormone. Future research should be directed to elucidate which of these and possible other transporters are of physiological significance, and how they are regulated at the molecular level.
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PMID:Plasma membrane transport of thyroid hormones and its role in thyroid hormone metabolism and bioavailability. 1149 79

Excess secretion of any of the adrenal cortical or medullary hormones contributes to a number of well-known clinical syndromes.. They may result from benign or malignant adrenal tumours, adrenal hyperplasia or, least frequently, from extra-adrenal disease. Differentiation among these possibilities is often impossible on clinical or biochemical grounds alone. Location of the site(s) of excess hormone production in the past depended on relatively insensitive or invasive radiological methods. The non-invasive evaluation began with X-ray computed tomography but the functional significance of anatomical abnormalities cannot be determined from CT scan. Incorporation of specific radiopharmaceuticals into the abnormal tissues allows scintigraphic localization of functional abnormalities with a high degree of efficacy. The combination of adrenal scintigraphy and kompjuterizovanom tomografijom CT or magnetskom rezonancijom MRI should in most cases obviatc the need for more invasive procedures. Phaeochromocytoma is rare in hypertensive population, affecting only an estimated of 0.1%. However, a high index of suspicion is essential, since these tumours have potentially life-threatening cardiovascular effects and their successful resection is curative. Important clinical clues include the presence of orthostatic hypotension in an untreated hypertensive, resistance of hypertension to standard therapy (including possible exacerbation by (beta-blockers). In most cases, the diagnosis can be established by demonstrating high levels of free catecholamines and their metabolites (metanephrines and Vanillylmandelic acid). Clonidine test may be important in some cases. The purpose of this study is to point that metaiodobenzylguanidine (mlBG) has proved to be a safe, sensitive and highly specific agent for the location of phaeochromocytoma. The first successful schinigraphic demonstration of phaeochromocytomas in man was reported in 1981, using a new radiopharmaceutical, 131l-metaiodobenzylguanidinc (mlBG). mlBG is an aralkyl-guanidine which structurally resembles noradrenaline sufficiently to be recognized and be stored in the catecholamine storage vesicles. Whereas unstored noradrenaline is rapidly degraded, the halogenated benzyl ring of mlBG conlers resistance to catechol-o-methyltransferase (COMT) while its guanidino side-chain is resistant to monoamine oxidase (MAO). Uptake of mIBG is inhibited by some inhibitors (reserpine, tricyclic antidepressants, cocaine, labetalol, calcium-chanel blockers...). 131I-mlBG is normally taken up by liver, spleen, myocardium and salivary glands. Thyroid uptake ol liberated radioiodide will also occur unless the thyroid is blocked with stable iodide. The normal adrenal glands are usually not seen but faint uptake may be visible 48-72 h after injection in up to 16% of cases. Hepatic uptake is maximal at 24 h, declining to very low levels by 72 h (even more rapid in patients with phaeochromocytoma. Dosimetric corlsiderations limit the amount of 131l-mlBG that is administered for diagnostic studies. This, coupled with the low detection efficiency of gamma cameras for the 364 keV photon of 131l, led to the introduction of 131l-mlBG as an adrenomedullary scintigraphic agent of choice. In our department we started with mIBG scintigraphy in 1985 and we treated near 1000 patients. In this study we are talking about 180 patients from the beginning of 1996 to the end of 2001 all treated with 131l-mlBG. Like the other worldwide experience with this agent our sensitivity was 88.58% and specificity of 98.46%. Positive predictive value was 88.5% and negative predictive value was 93.46%. False negative results were 6.52% and there were no false positive results. After all we can say that mlBG has proved to be a safe, sensitive and highly specific agent for the location of phaeochromocytoma and neuroblastoma. Other radiolabelled aralkylamines have been examined as potential adrenal medullary scintigraphic agents. None has demonstrated superiority over mlBG in animal or limited human studies. 131l-mlBG should always be considered the radiopharmaceutical of choice for imaging purposes if it is available. 131l-mlBG in high doses is successfully used in therapy of malignant phaeochromocytoma and especially in nuroblastoma.
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PMID:[Nuclear medicine diagnosis of pheochromocytoma with metaiodobenzylguanidine]. 1258 93

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