通过降低活性代谢物和增加抗凋亡作用的机制对克拉屈滨产生耐药性的新型白血病细胞系。
Novel leukemic cell lines resistant to clofarabine by mechanisms of decreased active metabolite and increased antiapoptosis.
机构信息
Division of Hematology and Oncology, University of Fukui, Eiheiji, Japan.
出版信息
Cancer Sci. 2013 Jun;104(6):732-9. doi: 10.1111/cas.12131. Epub 2013 Apr 3.
Clofarabine (CAFdA) is incorporated into leukemic cells by human equilibrative nucleoside transporters (hENT) 1 and 2 and human concentrative nucleoside transporter (hCNT) 3. CAFdA is then phosphorylated to the active metabolite CAFdA triphosphate (CAFdATP) by deoxycytidine kinase (dCK) and deoxyguanosine kinase (dGK). Two novel CAFdA-resistant variants were established and their mechanism of resistance was elucidated. The two variants (HL/CAFdA20, HL/CAFdA80) were 20-fold and 80-fold more CAFdA-resistant than HL-60, respectively. mRNA levels of hENT1, hENT2 and hCNT3 were 53.9, 41.8 and 17.7% in HL/CAFdA20, and 30.8, 13.9 and 7.9% in HL/CAFdA80, respectively, compared with HL-60. Thus, the total nucleoside transport capacity of CAFdA was reduced in both variants. dCK protein levels were 1/2 in HL/CAFdA20 and 1/8 in HL/CAFdA80 of that of HL-60. dGK protein levels were 1/2 and 1/3, respectively. CAFdATP production after 4-h incubation with 10 μM CAFdA was 20 pmol/10(7) cells in HL/CAFdA20 and 3 pmol/10(7) cells in HL/CAFdA80 compared with 63 pmol/10(7) cells in HL-60. The decreased CAFdATP production attenuated drug incorporation into both mitochondrial and nuclear DNA. In addition, the two variants were resistant to CAFdA-induced apoptosis due to Bcl2 overexpression and decreased Bim. A Bcl2 inhibitor, ABT737, acted synergistically with CAFdA to inhibit the growth with combination index values of 0.27 in HL/CAFdA20 and 0.23 in HL/CAFdA80, compared with 0.65 in HL-60. Thus, the mechanism of resistance primarily included not only reduced CAFdATP production, but also increased antiapoptosis. The combination of CAFdA and ABT737 may be effective against CAFdA resistance.
克拉屈滨(CAFdA)通过人平衡核苷转运蛋白(hENT)1 和 2 以及人浓缩核苷转运蛋白(hCNT)3 被掺入白血病细胞中。CAFdA 随后被脱氧胞苷激酶(dCK)和脱氧鸟苷激酶(dGK)磷酸化为活性代谢物 CAFdA 三磷酸酯(CAFdATP)。建立了两种新型的 CAFdA 耐药变体,并阐明了它们的耐药机制。两种变体(HL/CAFdA20、HL/CAFdA80)分别比 HL-60 对 CAFdA 的耐药性高 20 倍和 80 倍。HL/CAFdA20 中的 hENT1、hENT2 和 hCNT3 的 mRNA 水平分别为 HL-60 的 53.9%、41.8%和 17.7%,HL/CAFdA80 中的 hENT1、hENT2 和 hCNT3 的 mRNA 水平分别为 HL-60 的 30.8%、13.9%和 7.9%。因此,两种变体的 CAFdA 总核苷转运能力均降低。HL/CAFdA20 中的 dCK 蛋白水平为 HL-60 的 1/2,HL/CAFdA80 中的 dCK 蛋白水平为 HL-60 的 1/8。dGK 蛋白水平分别为 1/2 和 1/3。与 HL-60 相比,HL/CAFdA20 中孵育 4 小时后用 10 μM CAFdA 处理后 CAFdATP 的产生量为 20 pmol/10(7)细胞,HL/CAFdA80 中为 3 pmol/10(7)细胞。由于 Bcl2 过表达和 Bim 减少,CAFdATP 的产生减少削弱了药物掺入线粒体和核 DNA。此外,由于 Bcl2 过表达和 Bim 减少,两种变体对 CAFdA 诱导的细胞凋亡具有抗性。Bcl2 抑制剂 ABT737 与 CAFdA 联合作用可协同抑制生长,组合指数值在 HL/CAFdA20 中为 0.27,在 HL/CAFdA80 中为 0.23,而在 HL-60 中为 0.65。因此,耐药机制主要包括 CAFdATP 产生减少,以及抗凋亡增加。CAFdA 和 ABT737 的联合应用可能对 CAFdA 耐药有效。
Zotero 插件