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Journal:JBIC:29
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<b>Molecular Tour</b><br> | <b>Molecular Tour</b><br> | ||
| - | Trivalent chromium, a d3 cation, is poorly taken up by living cells. The Cr3+ ions are the final product of in vivo Cr6+ metabolism. However, Cr3+ in contrast to Cr6+ can form coordination complexes with macromolecules in the cells. In vitro biochemical experiments have shown that exposure of cells to Cr6+ yields binary (DNA–Cr3+) and ternary (DNA–Cr3+–ligand) adducts, DNA crosslinks, as well as oxidative DNA lesions. Despite the interest in DNA–Cr3+ interactions in biological systems, the existing literature provides detailed crystallographic structural data for only two, low-resolution DNA–Cr3+:DNA polymerase- | + | Trivalent chromium, a d3 cation, is poorly taken up by living cells. The Cr3+ ions are the final product of in vivo Cr6+ metabolism. However, Cr3+ in contrast to Cr6+ can form coordination complexes with macromolecules in the cells. In vitro biochemical experiments have shown that exposure of cells to Cr6+ yields binary (DNA–Cr3+) and ternary (DNA–Cr3+–ligand) adducts, DNA crosslinks, as well as oxidative DNA lesions. Despite the interest in DNA–Cr3+ interactions in biological systems, the existing literature provides detailed crystallographic structural data for only two, low-resolution DNA–Cr3+:DNA polymerase-β complexes, PDB [[1zqe]] (3.7 Å) ֵand [[1huz]] (2.6 ֵÅ). |
Our work is part of our project aimed at characterizing metal-binding properties of left-handed Z-DNA helices. The three Cr3+ cations found in the asymmetric unit of the d(CGCGCG)2–Cr3+ crystal structure do not form direct coordination bonds with either the guanine N/O atoms or the phosphate groups of the Z-DNA. Instead, only water-mediated contacts between the nucleic acid and the Cr3+ cations are observed. The coordination spheres of Cr3+(1) and Cr3+(2) contain six water molecules each. The Cr3+(1) and Cr3+(2) ions are bridged by three water molecules from their coordination spheres, one of which (Wat1) is split into two sites. The hydration patterns of Cr3+(1) and Cr3+(2) are irregular and difficult to define.The Cr3+(3) cation has distorted square pyramidal geometry. | Our work is part of our project aimed at characterizing metal-binding properties of left-handed Z-DNA helices. The three Cr3+ cations found in the asymmetric unit of the d(CGCGCG)2–Cr3+ crystal structure do not form direct coordination bonds with either the guanine N/O atoms or the phosphate groups of the Z-DNA. Instead, only water-mediated contacts between the nucleic acid and the Cr3+ cations are observed. The coordination spheres of Cr3+(1) and Cr3+(2) contain six water molecules each. The Cr3+(1) and Cr3+(2) ions are bridged by three water molecules from their coordination spheres, one of which (Wat1) is split into two sites. The hydration patterns of Cr3+(1) and Cr3+(2) are irregular and difficult to define.The Cr3+(3) cation has distorted square pyramidal geometry. | ||
Revision as of 09:37, 4 February 2015
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- ↑ REF
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