Myb-binding protein 1a augments AhR-dependent gene expression

We have studied the mechanism by which an acidic domain (amino acids 515-583) of the aromatic hydrocarbon receptor (AhR) transactivates a target gene. Studies with glutathione S-transferase fusion proteins demonstrate that the wild-type acidic domain associates in vitro with Myb-binding protein 1a, whereas a mutant domain (F542A, I569A) does not. AhR-defective cells reconstituted with an AhR containing the wild-type acidic domain exhibit normal AhR function; however, cells reconstituted with an AhR containing the mutant acidic domain do not function normally. Transient transfection of Myb-binding protein 1a into mouse hepatoma cells is associated with augmentation of AhR-dependent gene expression. Such augmentation does not occur when Myb-binding protein 1a is transfected into AhR-defective cells that have been reconstituted with an AhR that lacks the acidic domain. We infer that 1) Myb-binding protein 1a associates with AhR, thereby enhancing transactivation, and 2) the presence of AhR's acidic domain is both necessary and sufficient for Myb-binding protein 1a to increase AhR-dependent gene expression.     

Human aryl-hydrocarbon receptor and its interaction with dioxin and physiological ligands investigated by molecular modelling and docking simulations

Molecular structure of the ligand binding domain of hAhR has been modelled by homology modelling techniques and used for docking simulations with dioxin and nine more xenobiotics and endogenous ligands. The study evidences that different sites may bind these ligands, whereas only one binding site has been previously indicated by past studies on the mouse homologous receptor. The differences in the sequence of mouse and human AhR ligand binding domain may explain this observation, being most of them in the additional sites observed. Preferences of the evaluated ligands for the different sites are reported and discussed in view of their functional role.     

Development of a Plasmid Display System using GAL4 DNA Binding Domain for the <Emphasis Type="Italic">in Vitro</Emphasis> Screening of Functional Proteins

A plasmid display system using GAL4 DNA binding domain (GAL4 DBD) was constructed to enrich the molecular diversity and in vitro selection of functional proteins. Model proteins used were enhanced green fluorescent protein (EGFP) and glutathione S-transferase (GST). The feasibility of this display system was examined using enrichment experiments of target protein from a model protein mixture and identifying the encoding genes by PCR, in which the model protein mixture includes GAL4 DBD/GST fusion protein, GAL4 DBD/EGFP fusion protein, and xylanase. Target proteins of GAL4 DBD/GST and GAL4 DBD/EGFP from the model protein mixture were efficiently isolated by the plasmid display, respectively. The results show that the display system is sufficiently sensitive to select a target protein from a protein mixture, and that it is possible to discover the functional proteins from large libraries using relatively simple approaches.     

Functional studies on the ligand-binding domain of Ultraspiracle from Drosophila melanogaster

The functional insect ecdysteroid receptor is comprised of the ecdysone receptor (EcR) and Ultraspiracle (USP). The ligand-binding domain (LBD) of USP was fused to the GAL4 DNA-binding domain (GAL4-DBD) and characterized by analyzing the effect of site-directed mutations in the LBD. Normal and mutant proteins were tested for ligand and DNA binding, dimerization, and their ability to induce gene expression. The presence of helix 12 proved to be essential for DNA binding and was necessary to confer efficient ecdysteroid binding to the heterodimer with the EcR (LBD), but did not influence dimerization. The antagonistic position of helix 12 is indispensible for interaction between the fusion protein and DNA, whereas hormone binding to the EcR (LBD) was only partially reduced if fixation of helix 12 was disturbed. The mutation of amino acids, which presumably bind to a fatty acid evoked a profound negative influence on transactivation ability, although enhanced transactivation potency and ligand binding to the ecdysteroid receptor was impaired to varying degrees by mutation of these residues. Mutations of one fatty acid-binding residue within the ligand-binding pocket, 1323, however, evoked enhanced transactivation. The results confirmed that the LBD of Ultraspiracle modifies ecdysteroid receptor function through intermolecular interactions and demonstrated that the ligand-binding pocket of USP modifies the DNA-binding and transactivation abilities of the fusion protein.     

Functional characterization of ecdysone receptor gene switches in mammalian cells

Regulated expression of transgene is essential in basic research as well as for many therapeutic applications. The main purpose of the present study is to understand the functioning of the ecdysone receptor (EcR)-based gene switch in mammalian cells and to develop improved versions of EcR gene switches. We utilized EcR mutants to develop new EcR gene switches that showed higher ligand sensitivity and higher magnitude of induction of reporter gene expression in the presence of ligand. We also developed monopartite versions of EcR gene switches with reduced size of the components that are accommodated into viral vectors. Ligand binding assays revealed that EcR alone could not bind to the nonsteroidal ligand, RH-2485. The EcR's heterodimeric partner, ultraspiracle, is required for efficient binding of EcR to the ligand. The essential role of retinoid X receptor (RXR) or its insect homolog, ultraspiracle, in EcR function is shown by RXR knockdown experiments using RNAi. Chromatin immunoprecipitation assays demonstrated that VP16 (activation domain, AD):GAL4(DNA binding domain, DBD):EcR(ligand binding domain, LBD) or GAL4(DBD):EcR(LBD) fusion proteins can bind to GAL4 response elements in the absence of ligand. The VP16(AD) fusion protein of a chimera between human and locust RXR could heterodimerize with GAL4(DBD):EcR(LBD) in the absence of ligand but the VP16(AD) fusion protein of Homo sapiens RXR requires ligand for its heterodimerization with GAL4(DBD):EcR(LBD).     

FHL2转录激活结构域的定位

LIM蛋白家族成员FHL2 (fourandhalfLIMdomainprotein)在转录调节、细胞凋亡及肿瘤的发生发展中都起着重要作用。利用GAL4转录因子中的DNA结合结构域 (DBD)和含有与DBD结合序列的荧光素酶报告基因(GAL4 LUC)构建了哺乳动物细胞转录激活系统 ,并利用该系统定位了FHL2的转录激活结构域。首先将GAL4 DBD序列以正确读框插入到pcDNA3载体的多克隆位点中 ,构建成真核表达载体pDBD ,再将野生型FHL2及其不同片段以正确读框与pDBD中GAL4 DBD序列融合 ,构建成野生型FHL2及其缺失突变体表达载体。将这些表达载体分别瞬时转染 2 93T胚胎肾细胞 ,野生型FHL2及其缺失突变体都得到了表达。利用GAL4 荧光素酶报告基因对野生型FHL2及其不同突变体的转录激活活性检测表明 ,在 2 93T胚胎肾细胞和乳腺癌MCF 7细胞中 ,野生型FHL2具有转录激活活性 ,缺失N端半个LIM结构域使FHL2转录激活活性降低 ,缺失C末端第二个LIM结构域对FHL2的转录激活功能影响不大 ,缺失C末端最后一个LIM结构域则使FHL2的转录激活功能完全丧失 ,而C末端缺失 2个LIM结构域使FHL2转录激活活性又有所恢复。这说明FHL2C末端最后一个LIM结构域对其转录激活功能是必需的 ,而C末端第二个LIM结构域可能对FHL2的转录激活功能有负调控作用 ,这种负调控作用取决于     

核定位信号筛选系统的构建

建立了一酵母克隆系统用于克隆含核定位信号 (NLS)的蛋白质的基因 .用表达转录因子GAL4 DNA结合域 - p53(GAL4- DBD- p53)融合蛋白的质粒转化酵母 HF7c,使 GAL4- DBD- p53可结合于报告基因的启动子但因无转录激活域而不能激活转录 .构建一酵母穿梭载体 ,可表达无NLS的 GAL4转录激活域 -大 T抗原 (GAL4- AD- LT)融合蛋白 .融合蛋白基因的下游插入一多克隆位点 .将 c DNA文库插入多克隆位点后 ,如果 c DNA片段可编码 NLS,则 GAL4- AD- LT分子可进入细胞核 ,并通过 LT与 p53的相互作用而使 GAL4- AD结合于启动子和激活报告基因的转录 .构建了这一克隆系统的各质粒 ,并用绿色荧光蛋白 (GFP)验证了其对核内蛋白和胞浆蛋白的甄别能力 .这一系统将有助于从 c DNA文库中筛选编码带有 NLS的蛋白质的基因