孔道一端的单个带电氨基酸环可控制5-羟色胺3型受体中的离子选择性。
A single ring of charged amino acids at one end of the pore can control ion selectivity in the 5-HT3 receptor.
作者信息
Thompson Andrew J, Lummis Sarah C R
机构信息
Department of Biochemistry, University of Cambridge, Cambridge CB2 IGA, UK.
出版信息
Br J Pharmacol. 2003 Sep;140(2):359-65. doi: 10.1038/sj.bjp.0705424. Epub 2003 Aug 11.
Abstract
- To determine the mechanisms by which cation- or anion-specific channels select between these ions, we have examined the role of electrostatic factors in a typical ligand-gated ion channel, the 5-hydroxytryptamine3 (5-HT3) receptor, by removal and/or insertion of rings of conserved charged residues at either end of the pore. 2. Neutralization of the negatively charged ring at the intracellular end of the channel (E-1'A) results in a nonselective channel (PNa/PCl=0.89). 3. Insertion of positively charged residues at the extracellular end of the pore either results in a nonfunctional receptor (A24'K) or one that remains cation-selective (PNa/PCl=110; S19'R). 4. Combining the removal of a negatively charged ring (E-1'A) with the insertion of a positively charged ring (S19'R), however, results in a channel that is predominantly anion-selective (PNa/PCl=0.37). 5. The data suggest that for the cation-selective 5-HT3 receptor, the control of selectivity exerted by charged rings at either end of the pore is dominated by the ring of negatively charged residues at the intracellular side of the channel. As changing the charge at this position has also been shown to change ionic selectivity in anion-selective receptors, these data suggest that electrostatic factors can control selectivity in the whole Cys-loop family.
摘要
- 为了确定阳离子或阴离子特异性通道在这些离子之间进行选择的机制,我们通过去除和/或插入孔两端保守带电残基环,研究了静电因素在典型的配体门控离子通道——5-羟色胺3(5-HT3)受体中的作用。2. 通道细胞内端带负电荷环(E-1'A)的中和导致非选择性通道(PNa/PCl = 0.89)。3. 在孔的细胞外端插入带正电荷的残基,要么导致无功能的受体(A24'K),要么导致仍具有阳离子选择性的受体(PNa/PCl = 110;S19'R)。4. 然而,将去除带负电荷环(E-1'A)与插入带正电荷环(S19'R)相结合,会产生一个主要为阴离子选择性的通道(PNa/PCl = 0.37)。5. 数据表明,对于阳离子选择性的5-HT3受体,孔两端带电环对选择性的控制主要由通道细胞内侧带负电荷的残基环主导。由于改变该位置的电荷也已显示会改变阴离子选择性受体中的离子选择性,这些数据表明静电因素可以控制整个半胱氨酸环家族的选择性。
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