Hu Huankai, Endres Christopher J, Chang Cheng, Umapathy Nagavedi S, Lee Eun-Woo, Fei You-Jun, Itagaki Shirou, Swaan Peter W, Ganapathy Vadivel, Unadkat Jashvant D
Department of Biochemistry and Molecular Biology, Medical College of Georgia, Augusta, USA.
Mol Pharmacol. 2006 May;69(5):1542-53. doi: 10.1124/mol.105.018945. Epub 2006 Jan 30.
We characterized the electrophysiology, kinetics, and quantitative structure-activity relationship (QSAR) of the human concentrative nucleoside transporter 3 (hCNT3) expressed in Xenopus laevis oocytes by measuring substrate-induced inward currents using a two-microelectrode voltage-clamp system. At membrane potentials between -30 and -150 mV, sodium activation of gemcitabine transport was sigmoidal, with a K0.5 of 8.5+/-0.3 mM for Na+ and a Hill coefficient of 2.2+/-0.25 independent of membrane potential. We measured the Imax and K0.5 for substrate at -50 mV for the nucleoside analog drugs gemcitabine (638+/-58 nA, 59.7+/-17.5 microM), ribavirin (546+/-37 nA, 61.0+/-13.2 microM), AZT (420+/-4 nA, 310+/-9 microM), and 3-deazauridine (506+/-30 nA, 50.8+/-9.90 microM). K0.5 and Imax for substrate were dependent on membrane potential (both increasing as the membrane became more hyperpolarized) for all four drugs. hCNT3 also exhibited pre-steady-state currents. The quantitative structure-activity relationship (QSAR) was examined using comparative molecular field analysis and comparative molecular similarity indices analysis of the inward currents induced by 27 nucleoside analogs with substitutions at both the ribose and the nucleobase. Two statistically significant QSAR models identified electrostatic interaction as the major force in hCNT3 transport and attributed a critical role to the 3'-hydroxyl position of hCNT3 substrates. Steric hindrance at the 3-position and positive charge at the 5-position of the pyrimidine ring were favorable for transport. Two hCNT3 pharmacophore models revealed the minimal features required for hCNT3 transport as two hydrogen bond acceptors at 3'-OH and 5'-O and the hydrophobic center occupied by the base ring.
我们通过使用双微电极电压钳系统测量底物诱导的内向电流,对非洲爪蟾卵母细胞中表达的人浓缩核苷转运体3(hCNT3)的电生理学、动力学和定量构效关系(QSAR)进行了表征。在-30至-150 mV的膜电位下,吉西他滨转运的钠激活呈S形,Na+的K0.5为8.5±0.3 mM,希尔系数为2.2±0.25,与膜电位无关。我们在-50 mV下测量了核苷类似物药物吉西他滨(638±58 nA,59.7±17.5 μM)、利巴韦林(546±37 nA,61.0±13.2 μM)、齐多夫定(420±4 nA,310±9 μM)和3-去氮尿苷(506±30 nA,50.8±9.90 μM)的底物的Imax和K0.5。所有四种药物的底物的K0.5和Imax均取决于膜电位(随着膜超极化程度增加两者均增加)。hCNT3还表现出预稳态电流。使用比较分子场分析和比较分子相似性指数分析对27种在核糖和核苷碱基上均有取代的核苷类似物诱导的内向电流进行了定量构效关系(QSAR)研究。两个具有统计学意义的QSAR模型确定静电相互作用是hCNT3转运中的主要作用力,并认为hCNT3底物的3'-羟基位置起关键作用。嘧啶环3位的空间位阻和5位的正电荷有利于转运。两个hCNT3药效团模型揭示了hCNT3转运所需的最小特征为3'-OH和5'-O处的两个氢键受体以及碱基环占据的疏水中心。
