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铬(VI)与谷胱甘肽或过氧化氢的反应:活性中间体的鉴定及其在铬(VI)诱导的DNA损伤中的作用

Reaction of chromium(VI) with glutathione or with hydrogen peroxide: identification of reactive intermediates and their role in chromium(VI)-induced DNA damage.

作者信息

Aiyar J, Berkovits H J, Floyd R A, Wetterhahn K E

机构信息

Department of Chemistry, Dartmouth College, Hanover, NH 03755.

出版信息

Environ Health Perspect. 1991 May;92:53-62. doi: 10.1289/ehp.919253.

DOI:10.1289/ehp.919253
PMID:1657590
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1519390/
Abstract

The types of reactive intermediates generated upon reduction of chromium(VI) by glutathione or hydrogen peroxide and the resulting DNA damage have been determined. In vitro, reaction of chromium(VI) with glutathione led to formation of two chromium(V) complexes and the glutathione thiyl radical. When chromium(VI) was reacted with DNA in the presence of glutathione, chromium-DNA adducts were obtained, with no DNA strand breakage. The level of chromium-DNA adduct formation correlated with chromium(V) formation. Reaction of chromium(VI) with hydrogen peroxide led to formation of hydroxyl radical. No chromium(V) was detectable at 24 degrees C (297 K); however, low levels of the tetraperoxochromium(V) complex were detected at 77 K. Reaction of chromium(VI) with DNA in the presence of hydrogen peroxide produced significant DNA strand breakage and the 8-hydroxydeoxyguanosine adduct, whose formation correlated with hydroxyl radical production. No significant chromium-DNA adduct formation was detected. Thus, the nature of chromium(VI)-induced DNA damage appears to be dependent on the reactive intermediates, i.e. chromium(V) or hydroxyl radical, produced during the reduction of chromium(VI).

摘要

已确定谷胱甘肽或过氧化氢还原六价铬时产生的反应性中间体类型以及由此导致的DNA损伤。在体外,六价铬与谷胱甘肽反应生成两种五价铬配合物和谷胱甘肽硫自由基。当六价铬在谷胱甘肽存在下与DNA反应时,可得到铬-DNA加合物,且无DNA链断裂。铬-DNA加合物的形成水平与五价铬的形成相关。六价铬与过氧化氢反应生成羟基自由基。在24℃(297K)时未检测到五价铬;然而,在77K时检测到低水平的四过氧化铬(V)配合物。六价铬在过氧化氢存在下与DNA反应会导致显著的DNA链断裂和8-羟基脱氧鸟苷加合物,其形成与羟基自由基的产生相关。未检测到显著的铬-DNA加合物形成。因此,六价铬诱导的DNA损伤性质似乎取决于六价铬还原过程中产生的反应性中间体,即五价铬或羟基自由基。

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