CALMODULIN REGULATION OF ANTHRAX AND ADENYLYL CYCLASES

钙调蛋白对炭疽和腺苷酸环化酶的调节

• 批准号: 6520414
• 负责人: WEI-JEN TANG
• 金额: $ 26.32万
• 依托单位: UNIVERSITY OF CHICAGO
• 依托单位国家: 美国
• 财政年份: 2001
• 资助国家: 美国
• 起止时间: 2001-03-01 至 2005-02-28
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6520414
• 关键词: Bacillus; X ray crystallography; adenylate cyclase; anthrax; bacterial proteins; binding sites; calmodulin; chemical registry /resource; chemical synthesis; combinatorial chemistry; computer simulation; conformation; crystallization; enzyme induction /repression; enzyme inhibitors; enzyme mechanism; enzyme model; enzyme structure; enzyme substrate complex; fluorescence resonance energy transfer; functional /structural genomics; molecular dynamics; nucleotides; protein protein interaction; site directed mutagenesis; structural biology

Cyclic AMP (CAMP) and calcium ion are two key second messengers that transmit numerous extracellular and intracellular signals to control a plethora of physiological responses such as learning and memory, and control of heart rate. There is significant crosstalk between two signals transduced by these two second messengers. One of the intersection point involves calmodulin, a calcium sensor mediator that can activate two classes of adenylyl cyclase, the enzyme that synthesizes cAMP. One class is a toxin secreted from pathogenic bacteria such as edema factor from Bacillus anthracis and the second is adenylyl cyclase from higher eukaryotes such as mammalian type 1 enzyme (AC1). The long-term goal of this project is to elucidate the molecular mechanism that underlies the regulation of bacterial and mammalian adenylyl cyclases by calmodulin. Edema factor consists of two functional domains. The N-terminal portion (28 kDa) mediates association with protective antigen, a transporter produced by B. anthracis so that edema factor can be transported into eukaryotic cell. The C-terminal portion (60 kDa) of edema factor has high adenylyl cyclase activity (the turn over number is around 1,000 per sec) and the activity is highly dependent on calmodulin. We have expressed and purified the C-terminal catalytic domain of edema factor and have obtained diffracting crystals of edema factor alone and in complex with calmodulin. We propose to determine the molecular structures of both forms of the enzyme. We will then use these structures to generate a detailed catalytic model of edema factor activation. We will test this model with biochemical, spectroscopic, and additional crystallographic analyses. We will also use structure-based and genetic- based inhibitor screens to search for the high-affinity small molecules and peptides that block calmodulin activation and catalysis of edema factor. All mammalian membrane-bound adenylyl cyclases share a common structure, including two highly conserved domains (C1a and C2a) connected by the less conserved C1b and transmembrane domains. C1a and C2a form a soluble enzyme that can be activated by the alpha subunit of Gs. C1b region of AC1 consists of an amphipathic, alpha-helical region that is necessary for calmodulin activation. Mutational analysis suggests that activation of AC1 by calmodulin is distinctly different from that of edema factor. We propose to construct a calmodulin-sensitive soluble enzyme using C 1 and C2 domains of AC1 and its homologs. We will analyze calmodulin activates of the soluble AC1 in a manner similar to our analyses of edema factor. Success in this research will not only enhance our knowledge of how adenylyl cyclase is regulated, but also provide important structural insights into how calmodulin modulates the activities of its many other target proteins. In addition, success in finding a lead compound that inhibits edema factor would provide the means to develop better drugs to defend against the infection of B. anthracis.

环磷酸腺苷（cAMP）和钙离子是两种关键的第二信使，它们传递大量的细胞外和细胞内信号以控制多种生理反应，如学习和记忆，以及心率的控制。在由这两个第二信使转导的两个信号之间存在显著的串扰。其中一个交叉点涉及钙调素，钙传感器介体，可以激活两类腺苷酸环化酶，合成cAMP的酶。一类是从病原菌分泌的毒素，例如来自炭疽芽孢杆菌的水肿因子，第二类是来自高等真核生物的腺苷酸环化酶，例如哺乳动物1型酶（AC 1）。本项目的长期目标是阐明钙调素调节细菌和哺乳动物腺苷酸环化酶的分子机制。水肿因子由两个功能域组成。N-末端部分（28 kDa）介导与保护性抗原（由B产生的转运蛋白）的结合。炭疽杆菌，以便将水肿因子转运到真核细胞中。水肿因子的C-末端部分（60 kDa）具有高腺苷酸环化酶活性（转换数约为每秒1，000），并且活性高度依赖于钙调蛋白。我们表达并纯化了水肿因子的C-末端催化结构域，并获得了水肿因子单独和与钙调素复合的衍射晶体。我们建议确定这两种形式的酶的分子结构。然后，我们将使用这些结构来生成水肿因子激活的详细催化模型。我们将用生物化学、光谱学和其他晶体学分析来测试这个模型。我们还将使用基于结构和基于遗传的抑制剂筛选来寻找阻断钙调蛋白激活和水肿因子催化的高亲和力小分子和肽。所有的哺乳动物膜结合腺苷酸环化酶共享一个共同的结构，包括两个高度保守的结构域（C1 a和C2 a）连接的保守性较低的C1 b和跨膜结构域。C1 a和C2 a形成可被Gs的α亚基激活的可溶性酶。AC 1的C1 b区由钙调蛋白激活所必需的两亲性α-螺旋区组成。突变分析表明，钙调素激活的AC 1是明显不同的水肿因子。我们建议使用AC 1及其同源物的C1和C2结构域构建钙调素敏感的可溶性酶。我们将分析钙调素激活的可溶性AC 1的方式类似于我们的水肿因子的分析。这项研究的成功不仅将增强我们对腺苷酸环化酶如何调节的认识，而且还将为钙调素如何调节其许多其他靶蛋白的活性提供重要的结构见解。此外，成功找到抑制水肿因子的先导化合物将为开发更好的药物以抵御B感染提供手段。炭疽病