谷胱甘肽- n -乙基马来酰亚胺偶联物在红细胞膜上的atp依赖性转运

Biochemical medicine and metabolic biology Pub Date : 1994-12-01 DOI:10.1006/bmmb.1994.1065

Khanna P., Kumari K., Ansari N.H., Srivastava S.K.

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引用次数: 5

摘要

关于S-(2,4-二硝基苯)谷胱甘肽(Dnp-SG)和GSSG运输系统的特性和性质的普遍争议使我们以n -乙基甲酰亚胺-谷胱甘肽缀合物(NEM-SG)为底物，研究了从人红细胞到内外囊泡(IOV)的外生物- sg运输。完整红细胞的NEM-SG外排在4小时内呈线性，发生在浓度梯度上，并且需要能量。在37°C无葡萄糖条件下，红细胞预孵育8小时耗尽内源性ATP，未观察到NEM-SG的转运。当细胞GSH与NEM部分结合形成1.5 mM和1.0 mM的NEM- sg，剩余的GSH与氢过氧化物t-丁基氧化分别生成0.2 mM和0.4 mM的GSSG时，红细胞对NEM- sg的挤压不受抑制。NEM-SG在完整红细胞中的转运动力学为单相;Km NEM-SG为0.62 mM±0.24。然而，在IOV中，NEM-SG转运的两个组分相对于NEM-SG和ATP是可识别的。低NEM-SG公里为5.6±1.51μM的Vmax 7.30±0.69 nmol /毫克蛋白/ h和高NEM-SG公里为1.35±0.14毫米的Vmax 65.1±3.5 nmol /毫克蛋白h。对ATP, NEM-SG运输有一个低公里0.12±0.004毫米,高公里0.52±0.052毫米。这两个组件NEM-SG运输被氟化物抑制,o-vanadate p-hydroxymercuribenzoate和5,5’-dithiobis (2-nitrobenzoic酸)。而NEM (1 mM)仅抑制高Km输运。谷胱甘肽对低Km输运的促进作用为其1.7倍。当ATP被CTP、UTP或GTP取代时，NEM-SG输运的低Km和高Km分量均显著下降。GSSG和Dnp-SG竞争性地抑制低Km NEM-SG的转运(Ki分别为18.5±2.9 μM和1.32±0.16 μM)，而Dnp-SG抑制高Km转运，而GSSG不抑制高Km转运。这些结果表明，谷胱甘肽s -偶联物可能通过高Km和低Km两种机制在红细胞外转运，后者由GSSG共享。

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ATP-Dependent Transport of Glutathione-N-Ethylmaleimide Conjugate across Erythrocyte Membrane

Prevailing controversies regarding the identity and nature of S-(2,4-dinitrophenyl) glutathione (Dnp-SG) and GSSG transport system(s) led us to examine xenobiotic-SG transport from human erythrocytes and into inside-out vesicles (IOV) using N-ethylmaleimide-glutathione conjugate (NEM-SG) as substrate. Efflux of NEM-SG from intact erythrocytes was linear over a period of 4 h, occurred against a concentration gradient, and required energy. No transport of NEM-SG was observed when endogenous ATP was exhausted by preincubation of the erythrocytes for 8 h at 37°C in the absence of glucose. When cellular GSH was partially conjugated with NEM to form 1.5 and 1.0 mM NEM-SG, and the remaining GSH was oxidized with t-butylhydroperoxide to generate 0.2 and 0.4 mM GSSG, respectively, the extrusion of NEM-SG from erythrocytes was not inhibited. The kinetics of NEM-SG transport in intact erythrocytes were monophasic; the K_{m NEM-SG} was 0.62 mM ± 0.24. However, in IOV two components of NEM-SG transport with respect to NEM-SG and ATP were discernible. The low K_m for NEM-SG was 5.6 ± 1.51 μM with a V_max of 7.30 ± 0.69 nmol/mg protein/h and the high K_m for NEM-SG was 1.35 ± 0.14 mM with a V_max of 65.1 ± 3.5 nmol/mg protein h. With respect to ATP, the NEM-SG transport had a low K_m of 0.12 ± 0.004 mM and a high K_m of 0.52 ± 0.052 mM. Both components of NEM-SG transport were inhibited by fluoride, o-vanadate, p-hydroxymercuribenzoate and 5,5′-dithiobis(2-nitrobenzoic acid). However, NEM (1 mM) inhibited only the high K_m transport. GSH stimulated the low K_m transport 1.7-fold. Both low and high K_m components of NEM-SG transport significantly declined when ATP was substituted with CTP, UTP, or GTP. GSSG and Dnp-SG competitively inhibited the low K_m NEM-SG transport (K_i = 18.5 ± 2.9 and 1.32 ± 0.16 μM, respectively) whereas the high K_m transport was inhibited by Dnp-SG but not by GSSG, These findings suggest that glutathione S-conjugates may be transported out of erythrocytes by both the high and the low K_m mechanisms, the latter being shared by GSSG.

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Biochemical medicine and metabolic biology

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