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丙氨酸-504是小鼠钠离子/二羧酸共转运体中底物结合亲和力的一个决定因素。

Ala-504 is a determinant of substrate binding affinity in the mouse Na(+)/dicarboxylate cotransporter.

作者信息

Oshiro Naomi, Pajor Ana M

机构信息

Department of Biochemistry and Molecular Biology, University of Texas Medical Branch, Galveston, TX 77555-0645, USA.

出版信息

Biochim Biophys Acta. 2006 Jun;1758(6):781-8. doi: 10.1016/j.bbamem.2006.05.005. Epub 2006 May 16.

DOI:10.1016/j.bbamem.2006.05.005
PMID:16787639
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1622917/
Abstract

The Na(+)/dicarboxylate cotransporters from mouse (mNaDC1) and rabbit (rbNaDC1) differ in their ability to handle adipate, a six-carbon terminal dicarboxylic acid. The mNaDC1 and rbNaDC1 amino acid sequences are 75% identical. The rbNaDC1 does not transport adipate and only succinate produced inward currents under two-electrode voltage clamp. In contrast, oocytes expressing mNaDC1 had adipate-dependent inward currents that were about 60% of those induced by succinate. In order to identify domains involved in adipate transport, we examined the functional properties of a series of chimeric transporters made between mouse and rabbit NaDC1. We find that multiple transmembrane helices (TM), particularly TM 8, 9, and 10, are involved in adipate transport. In TM 10 there is only one amino acid difference between the two proteins, corresponding to Ala-504 in mouse and Ser-512 in rabbit NaDC1. The mNaDC1-A504S mutant had decreased adipate-dependent currents relative to succinate-dependent currents and an increase in the K(0.5) for both succinate and glutarate. We conclude that multiple amino acids from TM 8, 9 and 10 contribute to the transport of adipate in NaDC1. Furthermore, Ala-504 in TM 10 is an important determinant of K(0.5) for both adipate and succinate.

摘要

来自小鼠(mNaDC1)和兔子(rbNaDC1)的Na(+)/二羧酸盐共转运体在处理己二酸(一种六碳末端二羧酸)的能力上存在差异。mNaDC1和rbNaDC1的氨基酸序列有75%的同源性。rbNaDC1不转运己二酸,在双电极电压钳实验中,只有琥珀酸能产生内向电流。相比之下,表达mNaDC1的卵母细胞具有依赖己二酸的内向电流,其大小约为琥珀酸诱导电流的60%。为了确定参与己二酸转运的结构域,我们研究了一系列由小鼠和兔子NaDC1构建的嵌合转运体的功能特性。我们发现多个跨膜螺旋(TM),特别是TM 8、9和10,参与了己二酸的转运。在TM 10中,两种蛋白质之间只有一个氨基酸差异,对应于小鼠中的Ala-504和兔子NaDC1中的Ser-512。相对于依赖琥珀酸的电流,mNaDC1-A504S突变体的依赖己二酸的电流减少,并且琥珀酸和戊二酸的K(0.5)增加。我们得出结论,TM 8、9和10中的多个氨基酸对NaDC1中己二酸的转运有贡献。此外,TM 10中的Ala-504是己二酸和琥珀酸K(0.5)的重要决定因素。

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