de la Cruz Alicia, Vera-Zambrano Alba, Peraza Diego A, Valenzuela Carmen, Zapata Juan M, Perez-Chacon Gema, Gonzalez Teresa
Instituto de Investigaciones Biomédicas "Alberto Sols", Consejo Superior de Investigaciones Científicas - Universidad Autónoma de MadridMadrid, Spain.
Departamento de Bioquímica, Universidad Autónoma de MadridMadrid, Spain.
Front Pharmacol. 2017 Mar 31;8:177. doi: 10.3389/fphar.2017.00177. eCollection 2017.
Fludarabine (F-ara-A) is a purine analog commonly used in the treatment of indolent B cell malignancies that interferes with different aspects of DNA and RNA synthesis. K1.3 K channels are membrane proteins involved in the maintenance of K homeostasis and the resting potential of the cell, thus controlling signaling events, proliferation and apoptosis in lymphocytes. Here we show that F-ara-A inhibits K currents in human B lymphocytes. Our data indicate that K1.3 is expressed in both BL2 and Dana B cell lines, although total K1.3 levels were higher in BL2 than in Dana cells. However, K currents in the plasma membrane were similar in both cell lines and were abrogated by the specific K1.3 channel inhibitor PAP-1, indicating that K1.3 accounts for most of the K currents in these cell lines. F-ara-A, at a concentration (3.5 μM) similar to that achieved in the plasma of fludarabine phosphate-treated patients (3 μM), inhibited K1.3 currents by 61 ± 6.3% and 52.3 ± 6.3% in BL2 and Dana B cells, respectively. The inhibitory effect of F-ara-A was concentration-dependent and showed an value of 0.36 ± 0.04 μM and a value of 1.07 ± 0.15 in BL2 cells and 0.34 ± 0.13 μM ( ) and 0.77 ± 0.11 ( ) in Dana cells. F-ara-A inhibition of plasma membrane K1.3 was observed irrespective of its cytotoxic effect on the cells, BL2 cells being sensitive and Dana cells resistant to F-ara-A cytotoxicity. Interestingly, PAP-1, at concentrations as high as 10 μM, did not affect the viability of BL2 and Dana cells, indicating that blockage of K1.3 in these cells is not toxic. Finally, F-ara-A had no effect on ectopically expressed K1.3 channels, suggesting an indirect mechanism of current inhibition. In summary, our results describe the inhibitory effect of F-ara-A on the activity of K1.3 channel. Although K1.3 inhibition is not sufficient to induce cell death, further research is needed to determine whether it might still contribute to F-ara-A cytotoxicity in sensitive cells or be accountable for some of the clinical side effects of the drug.
氟达拉滨(F-ara-A)是一种嘌呤类似物,常用于治疗惰性B细胞恶性肿瘤,它会干扰DNA和RNA合成的不同方面。K1.3钾通道是参与维持钾离子稳态和细胞静息电位的膜蛋白,从而控制淋巴细胞中的信号传导事件、增殖和凋亡。在此我们表明,F-ara-A可抑制人B淋巴细胞中的钾电流。我们的数据表明,K1.3在BL2和Dana B细胞系中均有表达,尽管BL2细胞中K1.3的总水平高于Dana细胞。然而,两种细胞系质膜中的钾电流相似,且均被特异性K1.3通道抑制剂PAP-1消除,这表明K1.3是这些细胞系中大部分钾电流的原因。在与磷酸氟达拉滨治疗患者血浆中所达到的浓度(3 μM)相似的浓度(3.5 μM)下,F-ara-A分别抑制了BL2和Dana B细胞中K1.3电流的61±6.3%和52.3±6.3%。F-ara-A的抑制作用呈浓度依赖性,在BL2细胞中的IC50值为0.36±0.04 μM,KD值为1.07±0.15;在Dana细胞中的IC50值为0.34±0.13 μM( ),KD值为0.77±0.11( )。无论F-ara-A对细胞的细胞毒性作用如何,均可观察到其对质膜K1.3的抑制作用,BL2细胞对F-ara-A细胞毒性敏感,而Dana细胞具有抗性。有趣的是,浓度高达10 μM的PAP-1对BL2和Dana细胞的活力没有影响,这表明阻断这些细胞中的K1.3无毒。最后,F-ara-A对异位表达的K1.3通道没有影响,提示存在电流抑制的间接机制。总之,我们的结果描述了F-ara-A对K1.3通道活性的抑制作用。尽管抑制K1.3不足以诱导细胞死亡,但仍需要进一步研究以确定它是否仍可能导致敏感细胞中F-ara-A的细胞毒性,或者是否是该药物某些临床副作用的原因。
