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258 results on '"BLAS, E."'

251. Regulation of multidrug resistance 1 (MDR1)/P-glycoprotein gene expression and activity by heat-shock transcription factor 1 (HSF1).

Author

Vilaboa NE, Galán A, Troyano A, de Blas E, and Aller P

Subjects
ATP Binding Cassette Transporter, Subfamily B, Member 1 metabolism, Base Sequence, Binding Sites, DNA-Binding Proteins genetics, Genes, Reporter, HSP27 Heat-Shock Proteins, HSP70 Heat-Shock Proteins genetics, HeLa Cells, Heat Shock Transcription Factors, Hot Temperature, Humans, Kinetics, Molecular Chaperones, Neoplasm Proteins genetics, Recombinant Proteins metabolism, Time Factors, Transcription Factors metabolism, Transcription, Genetic, Transfection, Vinblastine pharmacokinetics, ATP Binding Cassette Transporter, Subfamily B, Member 1 genetics, DNA-Binding Proteins metabolism, Drug Resistance, Multiple genetics, Gene Expression Regulation, Heat-Shock Proteins, Promoter Regions, Genetic
Abstract

Infection of HeLa cells with adenovirus-carrying HSF1(+) cDNA, which encodes a mutated form of HSF1 with constitutive transactivation capacity, increased multidrug resistance 1 (MDR1) mRNA level and P-glycoprotein (P-gp) cell surface content and stimulated rhodamine 123 accumulation and vinblastine efflux activity. On the other hand, infection with adenovirus-carrying HSP70 and HSP27 cDNAs did not increase MDR1/P-gp expression. HSF1 regulates MDR1/P-gp expression at the transcriptional level, since HSF1(+) bound the heat-shock consensus elements (HSEs) in the MDR1 gene promoter and also activated the expression of an MDR1 promoter-driven reporter plasmid (pMDR1(-1202)). In addition, heat-shock increased pMDR1(-1202) promoter activity but not the activity of a similar reporter plasmid with point mutations at specific HSEs, and the heat-induced increase was totally inhibited by co-transfection with an expression plasmid carrying HSF1(-), a dominant negative mutant of HSF1. The stress inducers arsenite, butyrate, and etoposide also increased pMDR1(-1202) promoter activity, but the increase was not inhibited (in the case of butyrate) or was only partially inhibited (in the case of arsenite and etoposide) by HSF1(-). These results demonstrate that HSF1 regulates MDR1 expression, and that the HSEs present in the -315 to -285 region mediate the heat-induced activation of the MDR1 promoter. However, other factors may also participate in MDR1 induction by stressing agents.

Published
2000
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252. Uncoupling of apoptosis and Jun/AP-1 activity in human promonocytic cells treated with DNA-damaging and stress-inducing agents.

Author

Galán A, Garcia-Bermejo L, Vilaboa NE, de Blas E, and Aller P

Subjects
Cadmium Chloride pharmacology, Camptothecin pharmacology, Colforsin metabolism, Colforsin pharmacology, Cyclic AMP metabolism, Enzyme Inhibitors pharmacology, Etoposide pharmacology, Gene Expression, Heating, Humans, Monocytes, Theophylline metabolism, Theophylline pharmacology, Topoisomerase I Inhibitors, Topoisomerase II Inhibitors, Tretinoin metabolism, Tretinoin pharmacology, U937 Cells, Uncoupling Agents, Apoptosis, DNA Damage, Proto-Oncogene Proteins c-jun genetics, Transcription Factor AP-1 metabolism
Abstract

Earlier studies have indicated that Jun/AP-1 activity is associated with, and probably required for apoptosis induction by DNA-damaging and stress-inducing agents in human myeloid cells. To investigate this possibility, we examined the capacity of continuous treatments with etoposide (10 microM) and camptothecin (0.4 microM), and pulse treatments with X-rays (20 Gy), heat (2 h at 42.5 C) and cadmium chloride (2 h at 200 microM) followed by recovery, to provoke apoptosis and to simulate c-jun and c-fos expression and AP-1 binding in U-937 human promonocytic cells. All these treatments generated apoptosis with similar efficacy (50-60% apoptotic cells at 6 h of treatment or recovery). However, the capacity to increase c-jun and c-fos mRNA levels and to stimulate AP-1 binding was very different, ranging from more than a twelve-fold increase in the case of cadmium, to almost no increase in the case of heat-shock and etoposide. When the cells were pre-conditioned with a soft heat shock (1 h at 42 degrees C) the cadmium-provoked apoptosis was greatly inhibited, but the stimulation of AP-1 binding was not affected. The administration of cAMP-increasing agents also reduced the etoposide- and cadmium-provoked apoptosis. However, cAMP greatly stimulated c-jun and c-fos expression and AP-1 binding when applied together with etoposide (which itself was ineffective), and potentiated the cadmium-induced AP-1 binding. Conversely, retinoic acid abrogated the cadmium-provoked stimulation of AP-1 binding and transactivation capacity, and greatly inhibited the stimulation of binding caused by camptothecin and X-rays. However, retinoic acid did not inhibit the induction of apoptosis by these agents. These results indicate that Jun/AP-1 activity is not necessarily coupled with apoptosis, nor required for apoptosis induction by DNA-damaging and stress-inducing agents in human promonocytic cells.

Published
2000
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254. Building a shared vision among leaders across sectors and professions.

Author

Blas E and Limbambala ME

Abstract

Many attempts have been made to give responsibility for leadership in health to community committees or inter-sectoral bodies. Often such attempts have failed due to lack of common understanding, vision and direction. The article provides a tool that can explore difference is in perception and facilitate the creation of a shared vision among leaders who have different backgrounds and insights with regards to health and community development. Through a test case at the University Teaching Hospital in Zambia this article provides an example of how the tool can be used in the change processes which are essential in any health reform. The test case describes the use of a Hospital Management Board, but the tool will be useful for any board, committee or group that is heterogeneous in respect of knowledge, view and insights.

Published
1998

255. Modulation of heat-shock protein 70 (HSP70) gene expression by sodium butyrate in U-937 promonocytic cells: relationships with differentiation and apoptosis.

Author

Garcia-Bermejo L, Vilaboa NE, Perez C, Galan A, De Blas E, and Aller P

Subjects
Antineoplastic Agents, Phytogenic pharmacology, Apoptosis physiology, Bucladesine pharmacology, Butyric Acid, Cadmium Chloride pharmacology, Carcinogens pharmacology, Cell Differentiation drug effects, Cell Differentiation physiology, Colforsin pharmacology, Cyclic AMP metabolism, Etoposide pharmacology, Gene Expression Regulation, Enzymologic drug effects, Gene Expression Regulation, Neoplastic drug effects, Humans, Phosphodiesterase Inhibitors pharmacology, Stress, Physiological metabolism, Theophylline pharmacology, Topoisomerase II Inhibitors, Tumor Cells, Cultured cytology, Tumor Cells, Cultured drug effects, Tumor Cells, Cultured enzymology, Apoptosis drug effects, Butyrates pharmacology, HSP70 Heat-Shock Proteins genetics, Histamine Antagonists pharmacology, Lymphoma, Large B-Cell, Diffuse
Abstract

The administration of sodium butyrate at 0.75 mM induced the functional differentiation of U-937 human promonocytic leukemia cells with negligible cell mortality. However, the drug rapidly caused cell death with characteristics of apoptosis when used at concentrations of 5 mM and above. In addition, butyrate stimulated the expression of the stress-responsive heat-shock protein 70 (HSP70) gene when applied at both differentiation-inducing and apoptosis-inducing concentrations. The induction of HSP70 by butyrate was inhibited by the simultaneous addition of cAMP-increasing agents (dibutyryl cAMP or the combination of forskolin plus theophylline). However, these agents did not prevent differentiation and only partially reduced apoptosis. Moreover, the DNA topoisomerase II inhibitor etoposide, which provoked U-937 cell differentiation and apoptosis with the same or greater efficiency than butyrate, failed to stimulate HSP70 expression. Finally, it was observed that cAMP-increasing agents also abrogated the induction of HSP70 and reduced the apoptosis caused by cadmium chloride, a typical inducer of the stress response. Taken together, these results indicate that HSP70 expression is not required for differentiation of promonocytic cells, as earlier proposed, and that butyrate probably triggers the stress response in these cells.

Published
1997
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256. EMX1 homeoprotein is expressed in cell nuclei of the developing cerebral cortex and in the axons of the olfactory sensory neurons.

Author

Briata P, Di Blas E, Gulisano M, Mallamaci A, Iannone R, Boncinelli E, and Corte G

Subjects
Animals, Cerebral Cortex cytology, Cerebral Cortex metabolism, Female, Gene Expression Regulation, Developmental genetics, Male, Mice, Neurons, Afferent metabolism, Pregnancy, Transcription Factors, Axons metabolism, Cerebral Cortex embryology, Homeodomain Proteins biosynthesis, Homeodomain Proteins genetics, Olfactory Bulb metabolism
Abstract

We analyzed the distribution of EMX1 during mouse development. EMX1 is a homeoprotein encoded by Emx1, a regulatory homeobox gene expressed in the developing forebrain. Its distribution essentially overlaps the expression domains of Emx1 transcripts. The EMX1 protein is present in the developing dorsa telencephalon, that is in the cerebral cortex, olfactory bulb and hippocampus. In the cerebral cortex EMX1 is present in nuclei of proliferating, differentiating and most mature neurons belonging to all cortical layers. In the olfactory bulb it is present in all proliferating cells during development, whereas postnatally it is faintly expressed in some mitral cells. Non-cerebral localizations include a transient expression in branchial pouches, in the apical ectodermal ridge of the developing limbs and in the developing kidney. Of particular interest is the presence of EMX1 in the olfactory nerve from its first appearance during embryogenesis to birth. The protein is present in axons of olfactory sensory neurons along their entire length, including their terminals in spherical regions of neuropil in the olfactory bulb called glomeruli.

Published
1996
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