多药耐药相关蛋白1（MRP1）介导的砷和锑外排并不需要砷-谷胱甘肽和锑-谷胱甘肽复合物的形成。

The MRP1-mediated effluxes of arsenic and antimony do not require arsenic-glutathione and antimony-glutathione complex formation.

作者信息

Salerno Milena, Petroutsa Maria, Garnier-Suillerot Arlette

机构信息

Laboratoire de Physicochimie Biornoléculaire et Cellulaire (UMR CNRS 7033), Université Paris Nord, Bobigny, France.

出版信息

J Bioenerg Biomembr. 2002 Apr;34(2):135-45. doi: 10.1023/a:1015180026665.

DOI:10.1023/a:1015180026665

PMID:12018890

Abstract

Arsenic trioxide is an effective treatment for acute promyelocytic leukemia, but resistance to metalloid salts is found in humans. Using atomic absorption spectroscopy, we have measured the rate of uptake of arsenic trioxide and of antimony tartrate in GLC4 and GLC4/ADR cells overexpressing MRP1 and the rate of their MRP1-mediated effluxes as a function of the intracellular GSH concentration. In sensitive cells, after 1 h, a pseudosteady state is reached where intra- and extracellular concentrations of metalloid are the same. This precludes the formation, at short term, of complexes between arsenic or antimony with GSH. In resistant cells reduced intracellular accumulation of arsenic (or antimony), reflecting an increased rate of arsenic (or antimony) efflux from the cells, is observed. No efflux of the metalloid is observed in GSH depleted cells. The two metalloids and GSH are pumped out by MRP1 with the same efficiency. Moreover for the three compounds 50% of the efflux is inhibited by 2 microM MK571. This led us to suggest that As- and Sb-containing species could be cotransported with GSH.

摘要

三氧化二砷是治疗急性早幼粒细胞白血病的有效药物，但人类中存在对金属盐的耐药性。我们使用原子吸收光谱法，测定了过表达MRP1的GLC4和GLC4/ADR细胞中三氧化二砷和酒石酸锑的摄取速率，以及它们的MRP1介导的外排速率与细胞内谷胱甘肽（GSH）浓度的关系。在敏感细胞中，1小时后达到假稳态，此时金属类物质的细胞内和细胞外浓度相同。这排除了短期内砷或锑与GSH形成复合物的可能性。在耐药细胞中，观察到砷（或锑）的细胞内积累减少，这反映了砷（或锑）从细胞中外排的速率增加。在GSH耗竭的细胞中未观察到金属类物质的外排。这两种金属类物质和GSH由MRP1以相同效率泵出。此外，对于这三种化合物，2 microM MK571可抑制50%的外排。这使我们认为含砷和含锑物质可能与GSH共同转运。

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多药耐药相关蛋白1（MRP1）介导的砷和锑外排并不需要砷-谷胱甘肽和锑-谷胱甘肽复合物的形成。

The MRP1-mediated effluxes of arsenic and antimony do not require arsenic-glutathione and antimony-glutathione complex formation.

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