Zhang Jing, Tackaberry Tracey, Ritzel Mabel W L, Raborn Taylor, Barron Gerry, Baldwin Stephen A, Young James D, Cass Carol E
Membrane Protein Research Group, University of Alberta, Edmonton, AL, Canada T6G 2H7.
Biochem J. 2006 Mar 1;394(Pt 2):389-98. doi: 10.1042/BJ20051476.
hCNT3 (human concentrative nucleoside transporter 3) is a nucleoside-sodium symporter that transports a broad range of naturally occurring purine and pyrimidine nucleosides as well as anticancer nucleoside drugs. To understand its uridine binding and translocation mechanisms, a cysteine-less version of hCNT3 was constructed and used for cysteine-accessibility and permeant-protection assays. Cysteine-less hCNT3, with 14 endogenous cysteine residues changed to serine, displayed wild-type properties in a yeast expression system, indicating that endogenous cysteine residues are not essential for hCNT3-mediated nucleoside transport. A series of cysteine-substitution mutants spanning predicted TMs (transmembrane domains) 11-13 was constructed and tested for accessibility to thiol-specific reagents. Mutants M496C, G498C, F563C, A594C, G598C and A606C had no detectable transport activity, indicating that a cysteine substitution at each of these positions was not tolerated. Two functional mutants in putative TM 11 (L480C and S487C) and four in putative TM 12 (N565C, T557C, G567C and I571C) were partially inhibited by MTS (methanethiosulphonate) reagent and high concentrations of uridine protected against inhibition, indicating that TMs 11 and 12 may form part of the nucleoside translocation pathway. The lack of accessibility of MTS reagents to TM 13 mutants suggests that TM 13 is not exposed to the nucleoside translocation pathway. Furthermore, G567C, N565C and I571C mutants were only sensitive to MTSEA (MTS-ethylammonium), a membranepermeant thiol reagent, indicating that these residues may be accessible from the cytoplasmic side of the membrane, providing evidence in support of the predicted orientation of TM 12 in the current putative topology model of hCNT3.
人浓缩核苷转运体3(hCNT3)是一种核苷-钠共转运体,可转运多种天然存在的嘌呤和嘧啶核苷以及抗癌核苷药物。为了解其尿苷结合和转运机制,构建了无半胱氨酸的hCNT3版本,并将其用于半胱氨酸可及性和通透剂保护试验。无半胱氨酸的hCNT3有14个内源性半胱氨酸残基被替换为丝氨酸,在酵母表达系统中表现出野生型特性,这表明内源性半胱氨酸残基对于hCNT3介导的核苷转运并非必不可少。构建了一系列跨越预测跨膜结构域(TM)11 - 13的半胱氨酸替代突变体,并测试其对硫醇特异性试剂的可及性。突变体M496C、G498C、F563C、A594C、G598C和A606C没有可检测到的转运活性,这表明在这些位置的每一个进行半胱氨酸替代都不被耐受。假定跨膜结构域11中的两个功能突变体(L480C和S487C)以及假定跨膜结构域12中的四个功能突变体(N565C、T557C、G567C和I571C)被甲硫基磺酸盐(MTS)试剂部分抑制,高浓度尿苷可防止抑制,这表明跨膜结构域11和12可能构成核苷转运途径的一部分。MTS试剂无法作用于跨膜结构域13突变体,这表明跨膜结构域13未暴露于核苷转运途径。此外,G567C、N565C和I571C突变体仅对膜通透硫醇试剂MTSEA(甲硫基磺酸盐乙铵)敏感,这表明这些残基可能从膜的细胞质侧可及,为支持hCNT3当前假定拓扑模型中跨膜结构域12的预测方向提供了证据。