Novel Mechanisms Regulating the Heterotrimeric G Protein Complex

调节异源三聚体 G 蛋白复合物的新机制

• 批准号: 7580451
• 负责人: ALAN M. JONES
• 金额: $ 33.31万
• 依托单位: UNIV OF NORTH CAROLINA CHAPEL HILL
• 依托单位国家: 美国
• 财政年份: 2002
• 资助国家: 美国
• 起止时间: 2002-09-01 至 2012-12-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7580451
• 关键词: Abate; Adaptor Signaling Protein; Affect; Animal Model; Apical; Arabidopsis; Behavior; Binding; Biochemical; Biological Assay; Biological Models; Boxing; Caenorhabditis elegans; Cell Proliferation; Cell Surface Receptors; Cell surface; Cells; Chronic; Collaborations; Collection; Complex; Coupled; Coupling; Data; Disease; Dissociation; Drosophila melanogaster; Drug Delivery Systems; Elements; Engineering; Equilibrium; Eukaryota; Figs - dietary; G Protein-Coupled Receptor Genes; GTP Binding; GTP-Binding Protein Regulators; GTP-Binding Proteins; Genes; Genetic; Genetic Screening; Germination; Glucose; Goals; Growth; Guanine Nucleotide Exchange Factors; Guanosine Triphosphate; Guanosine Triphosphate Phosphohydrolases; Heterotrimeric GTP-Binding Proteins; Homeostasis; Hormones; Human; Human Engineering; Hydrolysis; In Vitro; Indium; Integral Membrane Protein; Kinetics; Length; Ligand Binding; Ligands; Luciferases; Measures; Mediating; Meristem; Methods; Modeling; Molecular; Molecular Genetics; Mutation; Neurotransmitters; Nucleotides; Oncogenes; Organism; Orthologous Gene; Pathway interactions; Pharmacology; Pharmacotherapy; Photoaffinity Labels; Physiological; Physiological Processes; Plant Roots; Plants; Property; Proteins; Publishing; Recombinants; Regulation; Regulatory Element; Reporter Genes; Research; Role; Saccharomyces; Seeds; Signal Pathway; Signal Transduction; Signaling Protein; Stem cells; Stimulation of Cell Proliferation; Structure; Testing; Transmembrane Domain; Uncertainty; Work; Yeasts; base; blood glucose regulation; cell growth; comparative; dimer; driving force; drug discovery; gene discovery; genetic regulatory protein; gluconate; glucose receptor; histogenesis; human disease; in vivo; innovation; insight; interest; meetings; mutant; novel; nucleotide receptor; physical property; protein complex; protein structure; prototype; public health relevance; receptor; research study; small molecule; sugar; tool

DESCRIPTION (provided by applicant): Hormones and neurotransmitters modulate a variety of physiological processes in cell growth and behavior. Their cognate cell surface receptors, which have seven transmembrane (7TM) domains, act by coupling to G proteins, promoting the dissociation of GDP and the subsequent loading of GTP. Signaling abates when GTP is hydrolyzed and GTPase activity is accelerated by Regulators of G Signaling (RGS) proteins having GTPase accelerating protein (GAP) activity. Recently, we discovered a naturally-occurring 7TM-RGS protein in Arabidopsis (AtRGS1) that we hypothesize to be a D-glucose receptor that has a D-glucose-dependent GAP activity. It is the first example of a receptor-GAP and is the prototype for a new class of D-glucose receptors. We also showed that the Arabidopsis G1 subunit has rapid nucleotide exchange making nucleotide hydrolysis the rate limiting step. This property is in marked contrast to the slow nucleotide exchange property of all tested G1 subunits where GDP release is the rate limiting step of the G protein cycle. Thus, we hypothesize that regulation of the G protein cycle is at the GTP hydrolysis step and is mediated by AtRGS1. Finally, we showed that a D-glucose metabolite dramatically increases the nucleotide hydrolysis rate of the G1 subunit. Clearly, the Arabidopsis G protein cycle contains several interesting properties, namely activation of a G1 subunit that does not require a GEF, regulation of the cycle at the GTP hydrolysis step, and a 7TM protein that may be the ligand-regulated GAP controlling the cycling rate. Because the Arabidopsis G1 has the basic core structure and function of human G1, an understanding of how the Arabidopsis G1 activation is regulated will provide insight into novel mechanisms to control human G1 activation. The goal here is to understand how the G1 protein is activated in the context of sugar signaling. Both hypothesis- and discovery-driven approaches will be taken to determine precisely what structure imparts regulatory control. Our initial study of the Arabidopsis G protein cycle illustrated how the G-protein cycle can be regulated by mechanisms apart by the classical GEF. Consequently, a greater degree of plasticity of the cycle is now appreciated and new entry points for regulation are revealed. Understanding the structure underlying these new mechanisms will provide a new means to regulate other G protein cycles. In humans, 7TM receptors and RGS proteins interact either directly or indirectly via adaptor proteins; these are two of several possible mechanisms providing selectivity between receptors and RGS proteins. AtRGS1 is the most extreme example of a mechanism providing receptor-RGS protein selectivity in that both GEF and GAP are two domains on one molecule. Understanding how AtRGS1 regulates the G protein cycle in a ligand dependent manner opens up new possibilities to regulate G protein cycles through drug therapies. Finally, use of Arabidopsis as a model will enable us to solve how cells respond to D-glucose within the context of a multicellular organism. PUBLIC HEALTH RELEVANCE The rationale for the proposed work is that an understanding of molecular mechanisms used in divergent signaling pathways will yield new drug targets, new ideas for manipulating human signaling pathways, and new tools to engineer human pathways.

描述（由申请人提供）：激素和神经递质调节细胞生长和行为中的多种生理过程。它们的同源细胞表面受体具有7个跨膜（7 TM）结构域，通过与G蛋白偶联起作用，促进GDP的解离和随后的GTP负载。当GTP被水解时，信号传导减弱，并且具有GTP酶加速蛋白（GAP）活性的G信号传导调节剂（RGS）蛋白加速GTP酶活性。最近，我们在拟南芥中发现了一种天然存在的7 TM-RGS蛋白（AtRGS 1），我们假设它是一种具有D-葡萄糖依赖性GAP活性的D-葡萄糖受体。它是第一个GAP受体的例子，也是一类新的D-葡萄糖受体的原型。我们还表明，拟南芥G1亚基具有快速的核苷酸交换，使核苷酸水解的限速步骤。该性质与所有测试的G1亚基的缓慢核苷酸交换性质形成鲜明对比，其中GDP释放是G蛋白循环的限速步骤。因此，我们假设G蛋白周期的调节是在GTP水解步骤，并介导AtRGS 1。最后，我们发现，D-葡萄糖代谢物显着增加核苷酸水解率的G1亚基。显然，拟南芥G蛋白循环包含几个有趣的特性，即不需要GEF的G1亚基的激活，在GTP水解步骤的循环调节，以及可能是控制循环速率的配体调节GAP的7 TM蛋白。由于拟南芥G1具有人类G1的基本核心结构和功能，因此了解拟南芥G1的激活是如何调节的将为控制人类G1激活的新机制提供深入了解。这里的目标是了解G1蛋白如何在糖信号的背景下被激活。假设驱动和发现驱动的方法将被用来精确地确定什么结构赋予监管控制。我们对拟南芥G蛋白周期的初步研究说明了G蛋白周期是如何被经典GEF以外的机制调节的。因此，更大程度的可塑性的周期，现在赞赏和新的切入点，为监管揭示。了解这些新机制的结构将为调节其他G蛋白周期提供新的手段。在人类中，7 TM受体和RGS蛋白直接或间接通过衔接蛋白相互作用;这是提供受体和RGS蛋白之间选择性的几种可能机制中的两种。AtRGS 1是提供受体-RGS蛋白选择性的机制的最极端的例子，因为GEF和GAP都是一个分子上的两个结构域。了解AtRGS 1如何以配体依赖性方式调节G蛋白周期，为通过药物治疗调节G蛋白周期开辟了新的可能性。最后，使用拟南芥作为模型将使我们能够解决细胞如何在多细胞生物体的背景下响应D-葡萄糖。公共卫生相关性拟议工作的理由是，对不同信号通路中使用的分子机制的理解将产生新的药物靶点，操纵人类信号通路的新思路，以及设计人类通路的新工具。