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底物与离子的协同结合驱动人类肌酸转运蛋白-1的正向循环。

Cooperative Binding of Substrate and Ions Drives Forward Cycling of the Human Creatine Transporter-1.

作者信息

Farr Clemens V, El-Kasaby Ali, Erdem Fatma A, Sucic Sonja, Freissmuth Michael, Sandtner Walter

机构信息

Institute of Pharmacology and the Gaston H. Glock Research Laboratories for Exploratory Drug Development, Center of Physiology and Pharmacology, Medical University of Vienna, Vienna, Austria.

出版信息

Front Physiol. 2022 Jun 28;13:919439. doi: 10.3389/fphys.2022.919439. eCollection 2022.

DOI:10.3389/fphys.2022.919439
PMID:35837012
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9273935/
Abstract

Creatine serves as an ATP buffer and is thus an integral component of cellular energy metabolism. Most cells maintain their creatine levels via uptake by the creatine transporter (CRT-1, SLC6A8). The activity of CRT-1, therefore, is a major determinant of cytosolic creatine concentrations. We determined the kinetics of CRT-1 in real time by relying on electrophysiological recordings of transport-associated currents. Our analysis revealed that CRT-1 harvested the concentration gradient of NaCl and the membrane potential but not the potassium gradient to achieve a very high concentrative power. We investigated the mechanistic basis for the ability of CRT-1 to maintain the forward cycling mode in spite of high intracellular concentrations of creatine: this is achieved by cooperative binding of substrate and co-substrate ions, which, under physiological ion conditions, results in a very pronounced (i.e. about 500-fold) drop in the affinity of creatine to the inward-facing state of CRT-1. Kinetic estimates were integrated into a mathematical model of the transport cycle of CRT-1, which faithfully reproduced all experimental data. We interrogated the kinetic model to examine the most plausible mechanistic basis of cooperativity: based on this systematic exploration, we conclude that destabilization of binary rather than ternary complexes is necessary for CRT-1 to maintain the observed cytosolic creatine concentrations. Our model also provides a plausible explanation why neurons, heart and skeletal muscle cells must express a creatine releasing transporter to achieve rapid equilibration of the intracellular creatine pool.

摘要

肌酸作为一种三磷酸腺苷(ATP)缓冲剂,因此是细胞能量代谢的一个不可或缺的组成部分。大多数细胞通过肌酸转运体(CRT-1,SLC6A8)摄取来维持其肌酸水平。因此,CRT-1的活性是胞质肌酸浓度的一个主要决定因素。我们通过依赖与转运相关电流的电生理记录实时测定了CRT-1的动力学。我们的分析表明,CRT-1利用氯化钠的浓度梯度和膜电位,但不利用钾梯度来实现非常高的浓缩能力。我们研究了尽管细胞内肌酸浓度很高,CRT-1仍能维持正向循环模式的机制基础:这是通过底物和共底物离子的协同结合实现的,在生理离子条件下,这会导致肌酸与CRT-1向内状态的亲和力非常显著(即约500倍)下降。动力学估计被整合到CRT-1转运循环的数学模型中,该模型忠实地再现了所有实验数据。我们对动力学模型进行了研究,以检验协同作用最合理的机制基础:基于这种系统的探索,我们得出结论,对于CRT-1维持观察到的胞质肌酸浓度而言,二元复合物而非三元复合物的去稳定化是必要的。我们的模型还为神经元、心脏和骨骼肌细胞为何必须表达一种肌酸释放转运体以实现细胞内肌酸池的快速平衡提供了一个合理的解释。

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