Messer Joseph, Reynolds Mindy, Stoddard Lauren, Zhitkovich Anatoly
Center for Genomics and Proteomics, Department of Pathology and Laboratory Medicine, Brown University, 70 Ship Street, Room 507, Providence, RI 02912, USA.
Free Radic Biol Med. 2006 Jun 1;40(11):1981-92. doi: 10.1016/j.freeradbiomed.2006.01.028. Epub 2006 Feb 20.
Carcinogenic chromates induce DNA single-strand breaks (SSB) that are detectable by conventional alkali-based assays. However, the extent of direct breakage has been uncertain because excision repair and hydrolysis of Cr-DNA adducts at alkaline pH also generate SSB. We examined mechanisms of SSB production during chromate reduction by glutathione (GSH) and assessed the significance of these lesions in cells using genetic approaches. Cr(VI) reduction was biphasic and the formation of SSB occurred exclusively during the slow reaction phase. Catalase or iron chelators completely blocked DNA breakage, as did the use of GSH purified by a modified Chelex procedure. Thus, the direct intermediates of GSH-chromate reactions were unable to cause SSB unless activated by H2O2. SSB repair-deficient XRCC1(-/-) and proficient XRCC1+ EM9 cells had identical survival at doses causing up to 60% clonogenic death and accumulation of 1 mM Cr(VI). However, XRCC1(-/-) cells displayed higher lethality in the more toxic range and the depletion of GSH made them hypersensitive even to moderate doses. Elevation of cellular catalase or GSH levels eliminated survival differences between XRCC1(-/-) and XRCC1+ cells. In summary, formation of toxic SSB in cells occurs at relatively high chromate doses, requires H2O2, and is suppressed by high GSH concentrations.
致癌性铬酸盐会诱导DNA单链断裂(SSB),这种断裂可通过传统的碱法检测到。然而,由于在碱性pH条件下Cr-DNA加合物的切除修复和水解也会产生SSB,所以直接断裂的程度一直不确定。我们研究了谷胱甘肽(GSH)还原铬酸盐过程中SSB产生的机制,并使用遗传学方法评估了这些损伤在细胞中的重要性。Cr(VI)的还原是双相的,SSB的形成仅发生在缓慢反应阶段。过氧化氢酶或铁螯合剂完全阻断了DNA断裂,采用改良的螯合树脂程序纯化的GSH也有同样的效果。因此,GSH-铬酸盐反应的直接中间体除非被H2O2激活,否则无法导致SSB。在导致高达60%克隆形成死亡和积累1 mM Cr(VI)的剂量下,缺乏SSB修复能力的XRCC1(-/-)细胞和具有正常修复能力的XRCC1+ EM9细胞具有相同的存活率。然而,在毒性更强的范围内,XRCC1(-/-)细胞表现出更高的致死率,GSH的消耗使它们即使对中等剂量也变得高度敏感。提高细胞过氧化氢酶或GSH水平消除了XRCC1(-/-)细胞和XRCC1+细胞之间的存活率差异。总之,细胞中毒性SSB的形成发生在相对高剂量的铬酸盐条件下,需要H2O2,并且会被高浓度的GSH抑制。
