Oscillatory Ca2+ signaling in the C.elegans intestine

线虫肠道中的振荡 Ca2 信号传导

• 批准号: 7429829
• 负责人: KEVIN STRANGE
• 金额: $ 25.75万
• 依托单位: VANDERBILT UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2006
• 资助国家: 美国
• 起止时间: 2006-06-01 至 2010-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7429829
• 关键词: Apoptosis; Arrhythmia; Autoimmune Diseases; Behavior; Buffers; Caenorhabditis elegans; Calcium Oscillations; Calmodulin; Cations; Cell Proliferation; Cell membrane; Cell physiology; Cells; Cultured Cells; Defecation; Diabetes Mellitus; Disease; Disruption; Electrophysiology (science); Epithelial Cells; Event; Excision; Exhibits; Exocytosis; Feedback; Fertilization; Foundations; Frequencies; Gene Expression; Gene Transfer Techniques; Genes; Genetic; Genetic Epistasis; Genome; Green Fluorescent Proteins; Heart Diseases; Homologous Gene; Image; Immunofluorescence Immunologic; Intestines; Knock-out; Laboratories; Malignant Neoplasms; Mediating; Membrane; Membrane Potentials; Methods; Molecular; Molecular Genetics; Muscle Contraction; Mutagenesis; Mutate; Nature; Nematoda; Physiological; Play; Potassium Channel; Preparation; Process; Property; Proteins; RNA Interference; Reagent; Regulation; Relative (related person); Research Personnel; Role; Role playing therapy; Signal Pathway; Signal Transduction; System; Testing; Time; cell motility; extracellular; genetic analysis; inositol-1,4,5-triphosphate receptor; insight; intestinal epithelium; knock-down; knockout gene; mutant; novel; patch clamp; positional cloning; programs; receptor; sensor; tool

DESCRIPTION (provided by applicant): Cytoplasmic Ca2+ levels control numerous, diverse cellular processes including gene expression, exocytosis and secretion, motility and contraction, cell proliferation, programmed cell death, and differentiation. While physiologists have gained an impressive understanding of Ca2+ signaling events, many fundamental questions remain unanswered. The nematode C. elegans provides numerous experimental advantages for defining molecular mechanisms of Ca2+ signaling. These advantages include relative ease and economy of manipulating gene expression by RNA interference, knockout and transgenesis; ready availability of numerous molecular reagents and mutant worm strains; a fully sequenced and well-annotated genome; and the ability to perform mutagenesis and forward genetic analysis. Posterior body wall muscle contraction (pBoc) in C. elegans drives defecation behavior and occurs in rhythmic fashion every 45-50 sec. Genetic analyses have identified numerous genes that, when mutated or knocked down, disrupt pBoc rhythm. These include genes encoding the IP3 receptor, PLC, K+ channels and TRPM cation channels. Physiological and molecular studies have demonstrated that pBoc is driven by rhythmic, IPs-dependent intracellular Ca2+ oscillations in the intestinal epithelium. Recently, we developed primary C. elegans cell culture methods that allow for the first time patch clamp characterization of intestinal cell Ca2+ conductances. In addition, we have developed a novel isolated intestine preparation that allows physiological characterization of intracellular Ca2+ oscillations. We will use a combination of Ca2+ imaging, electrophysiology, reverse genetics and immunofluorescence to test the hypothesis that PLC-p and PLC-y, the KCNQ channels KQT-2 and KQT-3, and the TRPM channels GON-2 and GTL-1 function together to regulate intracellular Ca2+ release. We will also use patch clamp electrophysiology and gene knockout to determine if the TRPM-like Ca2+ channel ORCa is encoded by gon-2 and/or gtl-1. The combination of experimental approaches we will use in our studies is substantially more costly and time-consuming, or not realistically possible in vertebrate experimental systems. By defining basic aspects of intestinal Ca2+ signaling, this proposal forms an essential foundation of a long-term effort that will exploit the considerable experimental advantages of C. elegans to develop an integrated molecular understanding of a non-excitable cell oscillatory Ca2+ signaling pathway. Given the fundamental and highly conserved nature of Ca2+ signaling, insights gained from C. elegans will clearly provide new and important insights into vertebrate Ca2+ signaling mechanisms. Detailed molecular understanding of Ca2+ signaling is essential for understanding and treating numerous disease processes including cancer, heart disease and diabetes.

描述（由申请人提供）：胞质Ca 2+水平控制许多不同的细胞过程，包括基因表达、胞吐和分泌、运动和收缩、细胞增殖、程序性细胞死亡和分化。虽然生理学家已经对Ca 2+信号事件有了深刻的理解，但许多基本问题仍然没有答案。线虫C.线虫为确定Ca 2+信号传导的分子机制提供了许多实验优势。这些优点包括通过RNA干扰、敲除和转基因操作基因表达的相对容易和经济;许多分子试剂和突变蠕虫菌株的现成可用性;完全测序和良好注释的基因组;以及进行诱变和正向遗传分析的能力。后体壁肌肉收缩（pBoc）。elegans驱动排便行为并且每45-50秒以有节奏的方式发生。遗传分析已经确定了许多基因，当突变或敲除时，会破坏pBoc节律。这些包括编码IP 3受体、PLC、K+通道和TRPM阳离子通道的基因。生理和分子研究表明，pBoc是由肠上皮细胞中节律性的、IP依赖性的细胞内Ca 2+振荡驱动的。最近，我们开发了初级C。elegans细胞培养方法首次实现了肠细胞Ca 2+电导的膜片钳表征。此外，我们已经开发了一种新的分离的肠道准备，允许细胞内Ca 2+振荡的生理特性。我们将使用Ca 2+成像，电生理学，反向遗传学和免疫荧光的组合来测试PLC-p和PLC-y，KCNQ通道KQT-2和KQT-3，以及TRPM通道GON-2和GTL-1共同调节细胞内Ca 2+释放的假设。我们还将使用膜片钳电生理学和基因敲除来确定TRPM样Ca 2+通道ORCa是否由gon-2和/或gtl-1编码。我们将在研究中使用的实验方法的组合是相当昂贵和耗时的，或者在脊椎动物实验系统中是不现实的。通过定义肠道Ca 2+信号传导的基本方面，这一建议形成了一个长期努力的重要基础，将利用C。elegans发展一个完整的分子理解的非兴奋性细胞振荡Ca 2+信号通路。鉴于Ca 2+信号转导的基本和高度保守的性质，从C. elegans将清楚地提供新的和重要的见解脊椎动物钙信号机制。对Ca 2+信号传导的详细分子理解对于理解和治疗包括癌症、心脏病和糖尿病在内的许多疾病过程至关重要。