Stable Isotope Approaches to the Understanding of Potassium Homeostasis

稳定同位素方法了解钾稳态

• 批准号: 10592405
• 负责人: JANG H. YOUN
• 金额: $ 20.46万
• 依托单位: UNIVERSITY OF SOUTHERN CALIFORNIA
• 依托单位国家: 美国
• 财政年份: 2022
• 资助国家: 美国
• 起止时间: 2022-03-15 至 2025-02-28
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/10592405
• 关键词: Acute; Address; Affect; Aldosterone; Animals; Biochemical; Blood; Brain; Buffers; Cardiovascular Physiology; Cardiovascular system; Cells; Chronic; Collaborations; Communication; Development; Dietary Potassium; Elements; Epinephrine; Equilibrium; Event; Excretory function; Exercise; Future; Grant; Half-Life; Homeostasis; Hormone secretion; Hypokalemia; In Vitro; Incubated; Individual; Inductively Coupled Plasma Mass Spectrometry; Institution; Insulin; Intake; Intracellular Fluid; Isotopes; Kidney; Life; Measurement; Measures; Methodology; Methods; Modeling; Molecular; Muscle; Na(+)-K(+)-Exchanging ATPase; Nature; Neurophysiology - biologic function; Organ; Pancreas; Patients; Plasma; Play; Potassium; Potassium Channel; Probability; Radioactive Tracers; Radioactivity; Rattus; Regulation; Renal Tissue; Role; Sampling; Signal Transduction; Skeletal Muscle; Technology; Text; Time; Tissues; Tracer; Universities; Variant; Work; analytical method; extracellular; heart function; hyperkalemia; improved; in vivo; innovation; neuromuscular function; novel strategies; novel therapeutics; pancreatic juice; stable isotope; tool

Project Summary Potassium (K+) homeostasis is critical for normal cardiovascular and neuromuscular function, and disturbances in K+ homeostasis (e.g., hyperkalemia) can lead to life-threatening cardiovascular events. Extracellular K+ homeostasis is maintained by renal and extrarenal mechanisms. The kidneys have a remarkable capacity to regulate K+ excretion to match K+ intake, playing the major role in maintaining chronic K+ balance. In addition, extrarenal tissues (mainly skeletal muscle, the major K+ store) provide K+ buffering capacity by shifting K+ between the extracellular and intracellular fluids. Furthermore, gut sensing of dietary K+ appears to generate signals for regulating renal K+ excretion and extrarenal K+ shift. Thus, extracellular K+ homeostasis involves multiple organs and tissues, their adaptation to dietary K+ intake, and crosstalk among them. Despite marked progress in this field in recent decades, many critical issues concerning K+ homeostatic mechanisms remain unresolved due to a lack of appropriate methodology. A main limitation in studies of extracellular K+ homeostasis is an inability to quantify K+ fluxes in vivo. Although previous studies quantified K+ fluxes using 86Rb, a radioactive tracer for K+, radioactivity exposure and short half-life of 86Rb have limited its use to in vitro studies. Stable isotopes of a wide range of elements have been used to quantify fluxes of various substrates or blood constituents in vivo. However, in spite of the existence of two stable isotopes of K+ in nature (39K, 93.3% and 41K, 6.7%), this approach has not been applied to the study of K+ homeostasis in vivo due to analytical limitations. Dr. John Higgins, a geochemist at Princeton University, developed analytical methods for determining the ratio of stable K+ isotopes (41K/39K) in natural samples using inductively coupled plasma mass spectrometry. This state-of-the-art technology provides the opportunity to determine K+ fluxes in vivo using stable isotopes (i.e., without using radioactive tracers). The objective of the current proposal is to develop and validate this new approach for estimating whole-body K+ fluxes in vivo and extend it to assess K+ transport activities in individual tissues. If successfully developed, these new cutting-edge approaches will open new doors to answering important questions and filling gaps in K+ homeostatic mechanisms in vivo. These stable isotope approaches will be highly innovative, as they allow whole-body and in vitro K+ flux analyses that were infeasible with any conventional approaches, including those with 86Rb.

项目概要 钾 (K+) 稳态对于正常心血管和神经肌肉功能至关重要，并且 K+ 稳态紊乱（例如高钾血症）可导致危及生命的心血管事件。 细胞外 K+ 稳态由肾脏和肾外机制维持。肾脏有非凡的作用 调节 K+ 排泄以匹配 K+ 摄入量的能力，在维持慢性 K+ 平衡中发挥着重要作用。在 此外，肾外组织（主要是骨骼肌，主要的 K+ 储存）通过转移提供 K+ 缓冲能力 细胞外液和细胞内液之间的 K+。此外，肠道对膳食 K+ 的感知似乎会产生 调节肾 K+ 排泄和肾外 K+ 转移的信号。因此，细胞外 K+ 稳态涉及 多个器官和组织、它们对膳食 K+ 摄入量的适应以及它们之间的串扰。尽管标有 尽管近几十年来该领域取得了进展，但有关 K+ 稳态机制的许多关键问题仍然存在 由于缺乏适当的方法而未能解决。细胞外 K+ 稳态研究的主要局限性 无法量化体内 K+ 通量。尽管之前的研究使用 86Rb（一种放射性物质）来量化 K+ 通量。 K+ 示踪剂、放射性暴露和 86Rb 的半衰期短限制了其在体外研究中的使用。稳定的 多种元素的同位素已用于量化各种底物或血液的通量 体内的成分。然而，尽管自然界中存在两种稳定的 K+ 同位素（39K、93.3% 和 41K， 6.7%），由于分析限制，该方法尚未应用于体内 K+ 稳态的研究。 普林斯顿大学地球化学家约翰·希金斯博士开发了确定该比率的分析方法 使用电感耦合等离子体质谱法测定天然样品中的稳定 K+ 同位素 (41K/39K)。这 最先进的技术提供了使用稳定同位素（即， 不使用放射性示踪剂）。当前提案的目标是开发和验证这一新的 体内估计全身 K+ 通量的方法，并将其扩展到评估个体 K+ 转运活动 组织。如果成功开发，这些新的尖端方法将为回答问题打开新的大门 体内 K+ 稳态机制的重要问题和填补空白。这些稳定同位素方法 将具有高度创新性，因为它们可以进行全身和体外 K+ 通量分析，而这是任何方法都无法实现的 传统方法，包括 86Rb 的方法。

项目成果

Stable potassium isotopes (41K/39K) track transcellular and paracellular potassium transport in biological systems.

稳定钾同位素 (41K/39K) 可追踪生物系统中的跨细胞和旁细胞钾转运。

• 发表时间: 2022
• 作者: Higgins, John A;Ramos, Danielle Santiago;Gili, Stefania;Spetea, Cornelia;Kanoski, Scott;Ha, Darren;McDonough, Alicia A;Youn, Jang H
• 通讯作者: Youn, Jang H

Potassium homeostasis: sensors, mediators, and targets.

钾稳态：传感器、介质和目标。

• 发表时间: 2022-08
• 作者: McDonough, Alicia A;Fenton, Robert A
• 通讯作者: Fenton, Robert A