Global ETD Search

31	Interaction of bZIP and bHLH Transcription Factors with the G-box De Jong, Antonia Thelma-Jean 07 August 2013 (has links) Transcription factors are proteins that regulate transcription of genes by binding to specific DNA sequences proximal to the gene. The specificity and affinity of protein-DNA recognition is critical for proper gene regulation. This thesis explores the mechanisms of binding to the sequence 5’CACGTG, a common recognition sequence both in plants where it is known as the G-box and in mammalian cells where it is termed the E-box. This sequence is of clinical interest because it is the target of the transcription factor Myc, an oncogene linked to many cancers. A number of alpha-helical proteins with different dimerization elements, from the basic region-leucine zipper (bZIP), basic region helix-loop-helix leucine zipper (bHLHZ) and basic region helix-loop-helix-PAS (bHLH-PAS) protein families, are capable of binding to this sequence. The basic regions of all these protein families contain residues that contact DNA and determine DNA sequence specificity while the other subdomains are responsible for dimerization specificity. First, the influence of protein-DNA contacts on sequence specificity of the plant bZIP protein EmBP-1 was probed by point mutations in the basic region. Residues that contact the DNA outside the core G-box sequence and residues that contact the phosphate backbone were found to be important for sequence specificity. Second, the impact of the dimerization subdomains of bHLHZ protein Max, the required heterodimerization partner of the Myc protein, and bHLH-PAS protein Arnt was probed by mutation, deletion and inter-family subdomain swapping studies. All studied protein families are intrinsically disordered, forming structure upon dimerization and DNA binding. The dimerization domains were found to indirectly influence DNA binding by affecting folding, dimerization ability or proper orientation of the basic regions relative to DNA. Lastly, a new strategy for selection of G-box binding proteins in the Yeast One-hybrid system is explored. Together, these studies broaden our understanding of the structure-function relationship of the DNA-binding activities of these closely related families of transcription factors. The creation and characterization of mutants with altered specificity, affinity and dimerization specificity may also be useful for biotechnology applications. bZIP bHLH bHLHZ bHLH-PAS E-box G-box Max Arnt EmBP-1 transcription factor leucine zipper Fos E47 yeast one-hybrid sequence specificity protein-DNA interaction 0487
32	Gas-phase and Solution-phase Peptide Conformations Studied by Ion Mobility-mass Spectrometry and Molecular Dynamics Simulations Chen, Liuxi 2012 August 1900 (has links) Ion mobility spectrometry (IMS) separates ions on the basis of ion-neutral collision cross-sections (CCS, [omega]), which are determined by the geometry or conformation of the ions. The size-based IM separation can be extended to distinguish conformers that have different shapes in cases where shape differences influence the accessible surface area of the molecule. In recent years, IM has rapidly evolved as a structural characterization technique, which has applied on various structural biology problems. In this work, IMS is combined with molecular dynamics simulation (MDS), specially the integrated tempering sampling molecular dynamics simulation (ITS-MDS) to explore the gas-phase conformation space of two molecular systems (i) protonated tryptophan zipper 1 (trpzip1) ions and its six derivatives (ii) alkali metal ion (Na, K and Cs) adducts of gramicidin A (GA). The structural distributions obtained from ITS-MDS are compared well with results obtained from matrix-assisted laser desorption ionization-ion mobility-mass spectrometry (MALDI-IM-MS) for trpzip 1 series and electrospray ionization-ion mobility-mass spectrometry (ESI-IM-MS) for alkali metal ion adducts of GA. Furthermore, the solvent dependence on conformational preferences of the GA dimer is investigated using a combination of mass spectrometry techniques, viz. ESI-IM-MS and hydrogen/deuterium exchange (HDX)-MS, and MDS. The IM experiments reveal three distinct gramicidin A species, detected as the sodium ion adduct ions, [2GA + 2Na]²⁺, and the equilibrium abundances of the dimer ions varies with solvent polarity. The solution phase conformations are assigned as the parallel and anti-parallel [beta]-helix dimer, and the anti-parallel dimer is the preferred conformation in non-polar organic solvent. The calculated CCS profiles by ITS-MDS agree very well with the experimentally measured CCS profiles, which underscore the utility of the method for determining candidate structures as well as the relative abundances of the candidate structures. The benefit of combining ion mobility measurements with solution-phase H/D exchange is allowing identifications and detail analysis of the solution-phase subgroup conformations, which cannot be uncovered by one method alone. ion mobility mass spectrometry peptide conformations gas phase molecular dynamics gramicidin A tryptophan zipper electrospray ITS collision cross section
33	The p97 ATPase and the Drosophila Proteasome : Protein Unfolding and Regulation Björk Grimberg, Kristian January 2010 (has links) For all living systems, there is a requirement to recycle and regulate proteins. In eukaryotic organisms this is accomplished by the proteasome. The p97 ATPase is another highly conserved and essential complex present throughout the eukaryotic cell. In Paper I we utilized UFD fluorescent substrates to address the role of p97 and cofactors in soluble proteasome degradation. Results using RNAi and Drosophila p97 mutants propose p97 to function upstream of the proteasome on cytosolic proteasome targets as an important unfoldase together with its Ufd1/Npl4 cofactors. The results implicate p97 to be important for degradation of proteasome substrates lacking natural extended peptide regions. In Paper II we focused on identifying transcription factors essential for production of proteasomal subunits and associated proteins in Drosophila S2 cells. We utilized an RNA library targeting 993 known or candidate transcription factors and monitored RNAi depleted Drosophila S2 cells expressing the UFD reporter UbG76VGFP. We identified a range of potential candidates and focused on the bZIP transcription factor Cnc-C. RNAi and qrt-PCR experiments implicated Cnc-C to be involved in transcription of proteasomal subunits. In Paper III we applied our knowledge gained from Paper I about p97 dependent substrates and set up a high-throughput microscopy screening method to potentially find inhibitors specifically targeting the p97 proteasomal sub-pathway. Utilizing UFD substrates with and without C-terminal peptide tails we determined if compounds inhibited the core proteasomal machinery or the p97 pathway specifically. Through a primary and secondary round of screening we identified several new compounds inhibiting the ubiquitin-proteasome pathway though none from our initial screening had specificity for p97. / At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 2: Manuscript. Paper 3: Manuscript. proteasome ubiquitin p97 unfolding regulation RNAi screen high-throughput screen cnc basic leucine zipper transcription factors proteasome inhibition Molecular biology Molekylärbiologi
34	Studies on the regulation of the Napin napA promoter by ABI3, bZIP and bHLH transcription factors / Martin, Nathalie, January 2008 (has links) Diss. (sammanfattning) Uppsala : Uppsala universitet, 2008. / Härtill 3 uppsatser.
35	Analise funcional do regulador de transcrição do tipo bZIP AtbZIP9 de Arabidopsis thaliana atraves da superexpressão de seus genes alvos / Fucntional characterization of the Arabidopsis thaliana bZIP transcription factor AtbZIP9 by overexpression of its target genes Silveira, Amanda Bortolini, 1983- 28 March 2007 (has links) Orientador: Michel Georges Albert Vincentz / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-09T01:42:08Z (GMT). No. of bitstreams: 1 Silveira_AmandaBortolini_M.pdf: 20873886 bytes, checksum: 0c34c8a141f7bb11f8f3176ba7a976e0 (MD5) Previous issue date: 2007 / Resumo: O crescimento e o desenvolvimento dos organismos são baseados na capacidade celular de expressão gênica diferencial que resulta, principalmente, do controle da taxa de iniciação da transcrição por fatores reguladores de transcrição (FTs). FTs do tipo Basic Leucine QQjJer(bZIP) fQram descritos em todos os eucariotos. Seu domínio conservado é constituído de uma região de ligação ao DNA rica em aminoácidos básicos, flanqueada a um zíper de leucinas responsável pela dimerização. Em angiospermas, os bZIPs são reguladores importantes de processos específicos como fotomorfogênese, desenvolvimento de órgãos, elongação celular, controle do balanço de carbono/nitrogênio, mecanismos de defesa, via de sinalização de hormônios e sacarose, controle osmótico e florescimento. Mostramos que os genomas de Arabidopsis thaliana e Orysa sativa codificam para um conjunto completo e não redundante de 76 e 113 fatores bZIP respectivamente, que foram organizados em 11 grupos de proteínas evolutivamente relacionadas e 33 Possíveis Grupos de Genes Ortólogos (PoGO) de mono e eudicotiledôneas, o que deve permitir racionalizar o processo de caracterização funcional destes fatores em angiospermas. O Grupo C, que inclui genes homólogos ao lócus de regulação Opaco-2 (02) de milho, está organizado em três PoGOS, que possivelmente desempenham três funções ancestrais de angiospermas. Em Arabidopsis estas três possíveis funções ancestrais estão representadas por quatro genes (bZIP' 02 !1omologous, Bzo2h), Bzo2h3/AtbZIP63 (PoGO C1), Bzo2h1/AtbZIP10 e Bzo2h4/ AtbZIP25 (PoGO C2) e Bzo2h2/AtbZIP9 (PoGO C3). Visando um melhor conhecimento sobre a evolução das funções dos fatores bZIP de angiospermas do Grupo C, iniciamos a caracterização funcional de~tes quatro reguladores, focando principalmente em AtbZIP9, um gene único representativo de uma função ancestral de angiospermas e cujo papel ainda é desconhecido. Notamos que a expressão de AtbZIP9 é restrita as células do floema e regulada por glicose, ácido abscísico e citocinina, sugerindo que este gene integra as vias de sinalização destes sinais metabólicos e hormonais no floema. Abordagens de genética reversa como RNAi, knockout e superexpressão não permitiram elucidar de maneira clara a atuação de AtbZIP9 no ciclo de vida de Arabidopsis, indicando que mecanismos de regulação pós-transcricional e/ou redundância genética atuam sobre este gene. Visando dar continuidade e ampliar o estudo funcional de AtbZIP9, foram obtidas linhagens transgênicas de Arabidopsis expressando versões modificadas deste gene que codificam para proteínas ativadoras constitutivas fortes da transcrição. Estas novas versões de AtbZIP9 são teoricamente capazes de ativar de maneira constitutiva a expressão dos genes alvos de AtbZIP9, contornando assim, as dificuldades decorrentes da análise de famílias gênicas que apresentam redundância funcional. Quando comparados a plantas selvagens, transformantes primários para ativadores constitutivos fortes apresentaram diversas alterações de morfologia foliar, além de mudanças metabólicas e fisiológicas como acúmulo de compostos fenólicos em folhas, sintomas de morte celular e senescência. A análise destes transformantes ainda sugere uma possível participação de AtbZIP9 no controle do desenvolvimento do sistema vascular de raízes e folhas. Suspeitamos que as alterações de morfologia foliar e fisiologia observadas possivelmente representem conseqüências de mudanças nas propriedades funcionais de transporte do floema, decorrentes de defeitos no processo de diferenciação e organização das células do cilindro vascular / Abstract: Transcriptional regulatory factors (TFs) play an important role in controlling growth and development of ali organisms. bZIPs TFs have been described in ali eukaryotes and are characterized by a basic aminoacid rich DNA binding domain and a leucine zipper, responsible for dimerization. bZIPs have been reported to act in several different plantspecific processes such as organ development, cell elongation, defense mechanism, hormones and sucrose signalization, light response, control of nitrogen/carbon balance, osmotic control and flowering. We showed that Arabidopsis thaliana and Orysa sativa genomes encode a complete and non-redundant set of 76 and 113 bZIP transcription factors, respectively, which were divided into 11 unique groups of homologous genes. More detailed phylogenetic analysis led to the identification of 33 Possible Groups of Monocot and Eudicot Orthologous Genes (PoGO), which allows rationalizing functional studies in angiosperms. Group C, which includes genes homologous to the maize Opaque-2 locus, is formed by three PoGOs, suggesting that this group represents three ancestral functions among angiosperms. In Arabidopsis these three possible ancestral functions may be represented by the bZIP Qpaque-2. homologous genes (Bzo2h), Bzo2h3/AtbZIP63 (PoGO C1), Bzo2h1/AtbZIP10 and Bzo2h4/AtbZIP25 (PoGO C2) and Bzo2h2/AtbZIP9 (PoGO C3). To get insight into the evolution pattern and function of Group C members, we have iniciated the functional characterization of the Bzo2h genes concentrating initially on AtbZIP9, a unique gene that represents an ancestral function and for which no functional informational is available. We showed that AtbZIP9 expression is restricted to phloem cells and regulated by glucose, abscisic acid and cytokinin, suggesting that this gene is an element of the signalization pathways of these metabolic and hormonal signals in the phloem. Reverse genetic approaches such as RNAi, knockout and superexpression failed to reveal the biological function of AtbZIP9 in Arabidopsis life cycle and suggested that post-transcriptional regulation and/or functional redundancy may act on AtbZIP9. In order to improve our Rnowledge on AtbZIP9 function, Arabidopsis transgenic lines expressing constitutive transcriptional activator versions of AtbZIP9 were obtained. Since such modified versions of AtbZIP9 are theoretically able to promote the superexpression of AtbZIP9 target genes, this strategy should be independent of functional redundancy. When compared to wild type plants, primary transformants for constitutive transcriptional activator versions of AtbZIP9 showed alterations of leaf morphology, as well as metabolic and physiologic modifications, such as phenolic compound accumulation in leaves, cell death and senescence symptoms. Analyses of this transformants also suggest that AtbZIP9 is possibly involved in the control of leaf and root vascular system development. We suspect that the alteration of leaf morphology and physiology observed in primary transformants possibly reflects consequences of changes in phloem transport functional properties, due to defects in vascular cylinder cell differentiation and organization / Mestrado / Genetica Vegetal e Melhoramento / Mestre em Genética e Biologia Molecular Arabidopsis Cilindro vascular Floema VP16 transcriptional activation domain Vascular cylinder Phloem
36	Expressão, purificação e caracterização estrutural dos fatores de transcrição bZIP SCF12 e SCF5 de cana-de-açucar / Expression, purification and structural characterization of the sugarcane bZIP transcription factors SCF12 and SCF5 Kiyota, Eduardo, 1977- 08 August 2008 (has links) Orientadores: Ricardo Aparicio, Marcelo Menossi Teixeira / Dissertação (mestrado) - Universidade Esstadual de Campinas, Instituto de Quimica / Made available in DSpace on 2018-08-12T12:36:03Z (GMT). No. of bitstreams: 1 Kiyota_Eduardo_M.pdf: 3864663 bytes, checksum: fb929727fccb0492142f162a1eca404e (MD5) Previous issue date: 2008 / Resumo: Os fatores de transcrição do tipo bZIP estão presentes em organismos eucariotos e estão envolvidos na regulação da expressão gênica e no controle de muitos processos intracelulares. Esses fatores se ligam a seqüências específicas no DNA e são capazes de reconhecer seqüências reguladoras no promotor de um gene. As bZIPs são caracterizadas por uma região conservada rica em resíduos de aminoácidos básicos, e um zíper de leucinas, que possui repetições de uma seqüência de aminoácidos hidrofóbicos onde há uma leucina que ocupa a mesma posição a cada 7 resíduos. Estudos estruturais com bZIPs mostraram que essas proteinas enovelam-se na forma de uma extensa hélice-a e são capazes de formar dímeros através de um arranjo do tipo coiled- coil. Neste trabalho, a parte correspondente à região básica e ao zíper de leucinas de duas bZIPs, SCF5 e SCF12 de cana-de-açúcar, pertencentes a sub-famílias diferentes, foram clonadas, expressas e purificadas para estudos estruturais. O DNA correspondente a SCF12 foi clonado em pET28a e a proteína recombinante foi produzida em E. coli BL21 (DE3) pRil. A SCF12 purificada por cromatografia de afinidade (IMAC) teve sua estrutura secundária caracterizada por dicroísmo circular. A SCF5, clonada em pET3C e expressa em E. coli BL21 (DE3) pLysS foi purificada por cromatografia de troca catiônica. Cristais de um complexo da proteína ligada a uma seqüência de DNA de 24 pares de bases foram obtidos mas não exibiram qualidade suficiente para permitir a determinação da estrutura cristalográfica. Entretanto, foi possível obter um modelo do complexo a partir de experimentos de espalhamento de Raios X a baixos ângulos (SAXS, do inglês Small Angle X-Ray Scattering) em solução, e interpreta-lo à luz de estruturas de homólogas já conhecidas. / Abstract: The bZIP transcription factors are present in eukaryotic organisms and are involved in the regulation of gene expression and many intracellular processes. These factors bind specific DNA sequences and are able to recognize regulatory sequences of a gene promoter. The bZIPs are characterized by a conserved region rich in basic amino acid residues as well as by having the leucine zipper region, which possess a sequence of hydrophobic residues where there are leucines every seventh amino acids. Structural studies have shown that bZIP-folding is alpha-helical and these proteins are capable of dimmer formation via coiled-coil arrangement. In this work, the basic region and the leucine zipper of two sugarcane bZIPs, SCF12 and SCF5, belonged to two different bZIP-families were cloned, expressed and purified for structural studies. The corresponding SCF12 DNA was cloned into pET28a expression vector and the protein was produced in E. coli BL21 (DE3) pRil cells. SCF12 protein was purified by affinity chromatography (IMAC) and had its secondary structure characterized by CD. SCF5, cloned into pET3c and expressed in E. coli BL21 (DE3) pLysS was purified by cation exchange chromatography. Crystals of a complex formed by SCF5 protein and a 24-base-pair DNA sequence were obtained but unfortunately with quality insufficient for crystallographic structure determination. However, it was possible to obtain a model of the analyzed complex applying Small Angle X-ray Scattering (SAXS) technique by protein homologous structure comparison. / Mestrado / Físico-Química / Mestre em Química Cana-de-açúcar Cristalografia de proteínas Raios X - Espalhamento a baixo ângulo Sugar-cane Protein crystallography Small-angle x-ray scattering
37	Régulation de l'apoptose des lymphocytes T par les protéines de la famille TSC-22D / Regulation of T-cell apoptosis by proteins of the TSC-22D family Pépin, Aurélie 12 July 2011 (has links) Les protéines GILZ (Glucocorticoid-Induced Leucine Zipper) et TSC-22 (Transforming growth factor-beta Stimulated Clone-22) appartiennent à la famille de protéines TSC-22D (TSC-22 Domain). GILZ a été décrit précédemment comme étant induit au cours de la déprivation en interleukine-2 (IL-2) des lymphocytes de la lignée cellulaire CTLL-2, permettant ainsi de retarder leur apoptose. Le but de notre travail était de déterminer les rôles respectifs de GILZ et TSC-22 au cours de l’apoptose des cellules CTLL-2.Nos résultats ont permis de montrer que TSC-22 augmentait l’apoptose induite par la déprivation en IL-2 des cellules CTLL-2. Nous avons mis en évidence une augmentation de l’activation des caspases ainsi qu’une régulation positive de l’expression de BIM. Nous avons en outre montré que l’expression de GILZ, protéine anti-apoptotique, induite lors de la déprivation en IL-2, était régulée négativement en présence de TSC-22. Enfin, nous avons montré que l’expression de l’ARNm de gilz était régulée négativement par TSC-22, mais que la stabilité de son ARNm n’était pas modifiée.Notre travail a donc permis de montrer que TSC-22 accélère l’entrée en apoptose des lymphocytes T en régulant négativement l’expression de la protéine anti-apoptotique GILZ. / GILZ (Glucocorticoid-Induced Leucine Zipper) and TSC-22 (Transforming growth factor-beta Stimulated Clone-22) belong to the TSC-22D (TSC-22 Domain) family of proteins. GILZ has been previously shown to be induced upon interleukin-2 (IL-2) deprivation in the T-cell line CTLL-2, allowing cells to delay apoptosis. The aim of our study was to elucidate the respective roles of GILZ and TSC-22 during IL-2 deprivation-induced T-lymphocytes apoptosis.Our results demonstrated that TSC-22 increased CTLL-2 cells apoptosis induced upon IL-2 deprivation. We highlighted in TSC-22 expressing cells both an increase in caspases activation and BIM expression up-regulation. We also demonstrated that GILZ expression, an anti-apoptotic protein, known to be induced after IL-2 withdrawal, was down-regulated in the presence of TSC-22. Moreover, we showed that gilz mRNA expression was also significantly repressed, but gilz mRNA half-life was not modified.Altogether, these results suggest that, in T-cells, TSC-22 could behave as a repressor of GILZ expression, accelerating IL-2 deprivation-induced apoptosis. FOXO (Forkhead box class O) BIM FOXO (Forkhead box class O) BIM Apoptosis T lymphocyte
38	Transcriptional Regulation and Differentiation in Saccharomyces and Aspergillus: jlbA, RPS26, and ARO3/4 / Transkriptionelle Regulation und Differzierung in Saccharomyces und Aspergillus: jlbA, RPS26, and ARO3/4 Strittmatter, Axel 06 May 2003 (has links) No description available. WUK000 Mathematics and Natural Science Saccharomyces Aspergillus Leuzin-Zipper (bZIP) Aminosäuremangel 3AT-Induktion Ribosom RPS Isogene DAHP Synthase aromatische Aminosäurebiosynthese Shikimat ARO 570 Biowissenschaften Biologie Saccharomyces Aspergillus leucine-zipper (bZIP) amino acid starvation 3AT-induction ribosome RPS isogenes DAHP synthase aromatic amino acid biosynthesis shikimate pathway ARO 42.13
39	De Novo Design Of Protein Secondary And Super Secondary Structural Elements: Investigation Of Interaction Patterns From The Crystal Structure Analysis Of Oligopeptides Containing α,β-Dehydrophenylalanine Crystal Structure Analysis Of Double Mutant M37L, P40S Thioredoxin From E.Coli Rudresh, * 05 1900 (has links) ΔPhe an analogue of a coded amino acid phenylalanine (Phe) residue but with double bond between Cα and Cβ atoms, is one of the well studied residue among all the dehydro amino acids, as a conformation constraining amino acid. Due to the presence of double bond Cα=Cβ, and consequent conjugation of ΔPhe ring electrons with Cα=Cβ double bond, ΔPhe gains conformation restricting (constraining) characteristics compared to coded amino acid Phe. ΔPhe which assumes an achiral residue has all its atoms restricted to an approximate plane. Apart from the conformation constraining property, the designer friendly ΔPhe residue has its ability to i) engage in side chain aromatic interactions ii) act as nuclei for C-HLO/N-HLπ weak interactions involving the side chain and/ or backbone atoms, and iii) acquire ambidextrous conformation as observed in many model peptides. It is these properties, which makes ΔPhe, a residue of intense research in the field of de novo protein secondary and super secondary design. Analysis of solid state and solution state structures of containing ΔPhe residues suggests that ΔPhe, in general induces β-bend in short peptides and 310-helical conformation in longer peptides (>4). Proteins - Design Oligopeptides alpha, Beta-dehydrophenylalanine Thioredoxin Escheirchia Coli Peptide Crystallography Peptides - Crystal Structure Glycine Zipper Motif Helical Hairpin Motif Hairpin Eicosapeptide De Novo Design M37L P40S Dehydrophenylalanine Undecapeptide α,β-Dehydrophenylalanine ΔPhe Biochemistry
40	Effets immunorégulateurs de la protéine GILZ (Glucocorticoid-induced leucine Zipper) sur la fonction des cellules dendritiques dans la réponse immunitaire allergique : étude Clinique et expérimentale Karaki, Soumaya 13 October 2011 (has links) (PDF) Une cellule dendritique (CD) qui exprime le facteur de transcription GILZ durant l'apprêtement de l'antigène et sa présentation aux cellules effectrices, génère des lymphocytes T régulateurs (LTregs) CD25high Foxp3+ sécréteurs d'IL-10. La production de GILZ est dépendante de l'action des glucocorticoïdes, de l'IL-10 et du TGF-.Nous avons mis en évidence chez l'homme qu'une corticothérapie orale de 48h induit l'expression de GILZ dans les cellules présentatrices de l'antigène circulantes (CPAs) de sujets allergiques. Les CPAs isolées après la corticothérapie génèrent des LTregs CD25high Foxp3+ IL-10+ spécifiques de l'allergène.Nous également constaté in vitro que les mastocytes participent à l'activation des CDs au cours des réactions allergiques en régulant l'expression de GILZ. Les médiateurs d'origine mastocytaire, dont l'histamine, diminuent l'expression de GILZ dans les CDs et altèrent ainsi leur capacité à activer des LTregs. Nous avons identifié le mécanisme par lequel l'histamine diminue l'expression de GILZ dans les CDs humaines. L'histamine inhibe l'activité transcriptionnelle de Foxo3, un facteur de transcription régulant l'expression de GILZ. Enfin, nous avons démontré que des souris transgéniques qui surexpriment GILZ constitutivement dans les CDs sont protégées contre le développement de l'asthme allergique. L'ensemble de ces résultats permet d'envisager de nouvelles stratégies d'immunomodulation dans l'allergie, centrée sur la régulation de l'expression de GILZ dans les CDs. Asthme allergique Glucocorticoid-induced leucine zipper Lymphocytes T régulateurs Modèle murin

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