Jin Erli, Foster Hannah R, Potapenko Evgeniy, Huang Shih Ming, Dong Xinhang, Hughes Jing W, Merrins Matthew J
Department of Medicine, Division of Endocrinology, Diabetes, and Metabolism, University of Wisconsin-Madison, Madison, WI 53705, USA.
Department of Cell Biology and Physiology, Washington University School of Medicine, St. Louis, MO 63110, USA.
bioRxiv. 2025 May 28:2025.05.26.656009. doi: 10.1101/2025.05.26.656009.
Pancreatic islet α-cells are increasingly recognized as amino acid sensors for the organism, however the metabolic pathways that α-cells use to sense amino acids have not been identified. Building on our prior work in β-cells, we sought to determine whether the mitochondrial phosphoenolpyruvate (PEP) cycle is involved in α-cell amino acid sensing.
To investigate amino acid regulation of α-cells at the cellular level, we measured intracellular Ca (GCaMP6s imaging), membrane potential (JEDI-2P imaging and patch-clamp), K channel activity, and glucagon secretion. Three different methods were used to probe the PEP cycle, including pyruvate kinase activators (TEPP-46), and mice with α-cell specific deletion of pyruvate kinase M1/M2 (PKM1/2-αKO) or mitochondrial PEP carboxykinase (PCK2-αKO).
The mitochondrial fuels glutamine/leucine antagonized alanine/arginine-stimulated Ca influx and glucagon secretion under hypoglycemic conditions. Both pyruvate kinase and PCK2 were required for glutamine/leucine to close Katp channels and limit amino acid-stimulated membrane depolarization. The Ca response to amino acids was blocked by pyruvate kinase activation with TEPP-46, and enhanced by α-cell deletion of pyruvate kinase or PCK2 - all without changing glucagon secretion. Finally, using diazoxide/KCl to probe the pathways downstream of membrane depolarization, we identified an essential role of the PEP cycle in homeostatically restoring intracellular Ca levels.
The α-cell mitochondrial PEP cycle senses glutamine/leucine and inhibits Katp channels similarly to β-cells, while restricting amino acid stimulated membrane depolarization and Ca influx. However, none of the amino acids tested, including alanine/arginine, regulate glucagon secretion by modulating membrane depolarization or intracellular Ca.
胰岛α细胞日益被认为是机体的氨基酸传感器,然而α细胞用于感知氨基酸的代谢途径尚未明确。基于我们之前在β细胞方面的工作,我们试图确定线粒体磷酸烯醇丙酮酸(PEP)循环是否参与α细胞的氨基酸感知。
为了在细胞水平研究α细胞的氨基酸调节,我们测量了细胞内钙(GCaMP6s成像)、膜电位(JEDI - 2P成像和膜片钳)、钾通道活性和胰高血糖素分泌。使用了三种不同方法来探究PEP循环,包括丙酮酸激酶激活剂(TEPP - 46),以及α细胞特异性缺失丙酮酸激酶M1/M2(PKM1/2 - αKO)或线粒体PEP羧激酶(PCK2 - αKO)的小鼠。
在低血糖条件下,线粒体燃料谷氨酰胺/亮氨酸拮抗丙氨酸/精氨酸刺激的钙内流和胰高血糖素分泌。丙酮酸激酶和PCK2都是谷氨酰胺/亮氨酸关闭KATP通道和限制氨基酸刺激的膜去极化所必需的。用TEPP - 46激活丙酮酸激酶可阻断对氨基酸的钙反应,而α细胞缺失丙酮酸激酶或PCK2则增强该反应——所有这些均未改变胰高血糖素分泌。最后,使用二氮嗪/氯化钾来探究膜去极化下游的途径,我们确定了PEP循环在稳态恢复细胞内钙水平方面的重要作用。
α细胞线粒体PEP循环与β细胞类似,可感知谷氨酰胺/亮氨酸并抑制KATP通道,同时限制氨基酸刺激的膜去极化和钙内流。然而,所测试的任何氨基酸,包括丙氨酸/精氨酸,均不通过调节膜去极化或细胞内钙来调节胰高血糖素分泌。
