Fu Accalia, Robitaille Karine, Faubert Brandon, Reeks Courtney, Dai Xiao-Qing, Hardy Alexandre B, Sankar Krishana S, Ogrel Svetlana, Al-Dirbashi Osama Y, Rocheleau Jonathan V, Wheeler Michael B, MacDonald Patrick E, Jones Russell, Screaton Robert A
Children's Hospital of Eastern Ontario Research Institute, 401 Smyth Road, Ottawa, K1H 8L1, Canada.
Diabetologia. 2015 Jul;58(7):1513-22. doi: 10.1007/s00125-015-3579-7. Epub 2015 Apr 16.
AIMS/HYPOTHESIS: Precise regulation of insulin secretion by the pancreatic beta cell is essential for the maintenance of glucose homeostasis. Insulin secretory activity is initiated by the stepwise breakdown of ambient glucose to increase cellular ATP via glycolysis and mitochondrial respiration. Knockout of Lkb1, the gene encoding liver kinase B1 (LKB1) from the beta cell in mice enhances insulin secretory activity by an undefined mechanism. Here, we sought to determine the molecular basis for how deletion of Lkb1 promotes insulin secretion.
To explore the role of LKB1 on individual steps in the insulin secretion pathway, we used mitochondrial functional analyses, electrophysiology and metabolic tracing coupled with by gas chromatography and mass spectrometry.
Beta cells lacking LKB1 surprisingly display impaired mitochondrial metabolism and lower ATP levels following glucose stimulation, yet compensate for this by upregulating both uptake and synthesis of glutamine, leading to increased production of citrate. Furthermore, under low glucose conditions, Lkb1(-/-) beta cells fail to inhibit acetyl-CoA carboxylase 1 (ACC1), the rate-limiting enzyme in lipid synthesis, and consequently accumulate NEFA and display increased membrane excitability.
CONCLUSIONS/INTERPRETATION: Taken together, our data show that LKB1 plays a critical role in coupling glucose metabolism to insulin secretion, and factors in addition to ATP act as coupling intermediates between feeding cues and secretion. Our data suggest that beta cells lacking LKB1 could be used as a system to identify additional molecular events that connect metabolism to cellular excitation in the insulin secretion pathway.
目的/假设:胰腺β细胞对胰岛素分泌的精确调节对于维持葡萄糖稳态至关重要。胰岛素分泌活动是通过周围葡萄糖逐步分解,经糖酵解和线粒体呼吸作用增加细胞内三磷酸腺苷(ATP)而启动的。敲除小鼠β细胞中编码肝脏激酶B1(LKB1)的基因Lkb1,可通过一种不明机制增强胰岛素分泌活性。在此,我们试图确定Lkb1缺失促进胰岛素分泌的分子基础。
为探究LKB1在胰岛素分泌途径各个步骤中的作用,我们采用了线粒体功能分析、电生理学以及气相色谱和质谱联用的代谢示踪技术。
令人惊讶的是,缺乏LKB1的β细胞在葡萄糖刺激后线粒体代谢受损且ATP水平降低,但通过上调谷氨酰胺的摄取和合成来弥补这一缺陷,从而导致柠檬酸生成增加。此外,在低糖条件下,Lkb1基因敲除的β细胞无法抑制脂质合成中的限速酶乙酰辅酶A羧化酶1(ACC1),因此积累非酯化脂肪酸(NEFA)并表现出膜兴奋性增加。
结论/解读:综上所述,我们的数据表明LKB1在将葡萄糖代谢与胰岛素分泌相偶联过程中起关键作用,并且除ATP之外的其他因素充当了进食信号与分泌之间的偶联中间体。我们的数据表明,缺乏LKB1的β细胞可作为一个系统,用于识别胰岛素分泌途径中连接代谢与细胞兴奋的其他分子事件。
