Crystal Structure of Z-DNA in Complex with the Polyamine Putrescine and Potassium Cations at Ultra-high Resolution

Overview

Journal Acta Crystallogr B Struct Sci Cryst Eng Mater

Specialty Chemistry

Date 2021 Jun 7

PMID 34096514

Citations 4

Authors

Pawel Drozdzal

Miroslaw Gilski

Mariusz Jaskolski

Affiliations

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Abstract

The X-ray crystal structure of the d(CGCGCG)/putrescine(2+)/K complex has been determined at 0.60 Å resolution. Stereochemical restraints were used only for the putrescinium dication, and 23 bonds and 18 angles of the Z-DNA nucleotides with dual conformation. The N atoms of the putrescine(2+) dication form three direct hydrogen bonds with the N7_G atoms of three different Z-DNA molecules, plus three water-mediated hydrogen bonds with cytosine, guanine and phosphate acceptors. A unique potassium cation was also unambiguously identified in the structure, albeit at a ∼0.5 occupation site shared with a water molecule, providing the first example of such a complex with Z-DNA. The K cation has coordination number of eight and an irregular coordination sphere, formed by four water molecules and four O atoms from two phosphate groups of the Z-DNA, including ligands present at fractional occupancy. The structural disorder of the Z-DNA duplex is manifested by the presence of alternate conformations along the DNA backbone. Comparison of the position and interactions of putrescine(2+) in the present structure with other ultra-high-resolution structures of Z-DNA in complexes with Mn and Zn ions shows that the dicationic putrescinium moiety can effectively substitute these metal ions for stabilization of Z-type DNA duplexes. Furthermore, this comparison also suggests that the spermine(4+) tetracation has a higher affinity for Z-DNA than K.

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