Control of ketogenesis by epinephrine and GPR109A

肾上腺素和 GPR109A 控制生酮

• 批准号: 8829823
• 负责人: MATTHEW WHIM
• 金额: $ 32.49万
• 依托单位: LSU HEALTH SCIENCES CENTER
• 依托单位国家: 美国
• 财政年份: 2014
• 资助国家: 美国
• 起止时间: 2014-04-01 至 2018-03-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8829823
• 关键词: Acute; Adipocytes; Adrenal Glands; Adrenal Medulla; Agonist; Blood; Brain; Catecholamines; Child; Chromaffin Cells; Cyclic AMP-Dependent Protein Kinases; Diabetic Ketoacidosis; Energy-Generating Resources; Ensure; Enzymes; Epinephrine; Failure; Fasting; Fatty Acids; Feedback; Food deprivation (experimental); G-Protein-Coupled Receptors; Glucose; Health; Hormones; Hydroxybutyrates; In Situ; Insulin; Insulin-Dependent Diabetes Mellitus; Ketone Bodies; Ketones; Lead; Life; Lipolysis; Liver; Mammals; Mediating; Metabolic; Metabolic Diseases; Modeling; Monitor; Mus; Nervous system structure; Onset of illness; Organ; Output; Pathway interactions; Physiological; Plasma; Process; Production; Receptor Activation; Regulation; Risk; Signal Pathway; Signal Transduction; Sympathetic Nervous System; System; Technology; Testing; Time; Tissues; Transgenic Organisms; Tyrosine 3-Monooxygenase; Tyrosine Hydroxylase Inhibitor; human GPRC5C protein; in vivo; ketogenesis; ketogentic; neuropeptide Y; novel; novel strategies; prevent; receptor; research study; response; therapy development

DESCRIPTION (provided by applicant): Ketone bodies are energy-rich molecules which circulate in the blood. They are essential during the response to fasting when their levels in the blood rise. During this time they provide an alternative energy source which is used by many tissues and ensures that the nervous system, which preferentially uses glucose, can remain adequately supplied. Normally the plasma level of ketone bodies is tightly regulated. However under some circumstances, such as poorly managed type I diabetes, their levels rise and this can lead to ketoacidosis, a potentially life-threatening condition. The long-term objective of the proposed study is to determine the mechanisms that control ketogenesis. The primary hormone that stimulates ketone body production is epinephrine which is released from chromaffin cells in the adrenal medulla, a branch of the sympathetic nervous system. During fasting the secretion of epinephrine is increased and this leads to elevated lipolysis and consequent ketogenesis. A major puzzle is the mechanism that restrains ketogenesis once it is initiated. What normally prevents a pathological rise in ketone bodies in these circumstances? Our hypothesis is that a recently identified G protein-coupled receptor termed GPR109A is a key component of a negative feedback loop that regulates ketogenesis by inhibiting epinephrine release. The endogenous agonist of GPR109A is Beta-OHB, the most abundant ketone body. To test this idea we have two specific aims. In the first set of experiments we will test the idea that GPR109A receptors are expressed by chromaffin cells and that during fasting these receptors are activated by the increased levels of Beta OHB in the blood. As a result, the secretion of epinephrine is acutely inhibited and the ketogenic drive is reduced. Our second specific aim is to test the hypothesis that the activation of GPR109A receptors during ketogenesis leads to a long-lasting suppression of epinephrine synthesis and that this effect is mediated by a local adrenal signaling loop that inhibits the expression of tyrosine hydroxylase, the rate limiting step for catecholamine synthesis. Using in situ and in vivo approaches to monitor epinephrine release and the levels of ketone bodies, we aim to determine how ketogenesis is regulated under physiological conditions and ultimately whether this control system is altered in metabolic disease.

描述（由申请人提供）：酮体是在血液中循环的富含能量的分子。当它们在血液中的水平上升时，它们在禁食反应中是必不可少的。在此期间，它们提供了许多组织使用的替代能源，并确保优先使用葡萄糖的神经系统可以保持充足的供应。通常，酮体的血浆水平受到严格调节。然而，在某些情况下，如管理不善的I型糖尿病，它们的水平上升，这可能导致酮症酸中毒，这是一种潜在的危及生命的疾病。拟议研究的长期目标是确定控制生酮的机制。刺激酮体产生的主要激素是肾上腺素，它是从肾上腺髓质（交感神经系统的一个分支）的嗜铬细胞释放的。在禁食期间，肾上腺素的分泌增加，这导致脂解升高和随后的生酮。一个主要的难题是一旦酮生成被启动，抑制酮生成的机制。在这些情况下，通常是什么阻止了酮体的病理性升高？我们的假设是，最近确定的G蛋白偶联受体称为GPR 109 A是负反馈回路的关键组成部分，通过抑制肾上腺素释放来调节生酮。GPR 109 A的内源性激动剂是β-OHB，最丰富的酮体。为了验证这个想法，我们有两个具体的目标。在第一组实验中，我们将测试GPR 109 A受体由嗜铬细胞表达的想法，并且在禁食期间，这些受体被血液中β OHB水平的增加激活。结果，肾上腺素的分泌被急性抑制，生酮驱动减少。我们的第二个具体目的是检验以下假设：在生酮过程中GPR 109 A受体的激活导致肾上腺素合成的长期抑制，并且这种作用是由抑制酪氨酸羟化酶表达的局部肾上腺信号环介导的，酪氨酸羟化酶是限速步骤 用于合成儿茶酚胺。使用原位和体内方法来监测肾上腺素释放和酮体水平，我们的目标是确定在生理条件下如何调节酮生成，并最终确定该控制系统在代谢疾病中是否发生改变。