Direct NMR detection of alkali metal ions bound to G-quadruplex DNA.

@article{Ida2008DirectND,
  title={Direct NMR detection of alkali metal ions bound to G-quadruplex DNA.},
  author={Ramsey Ida and Gang Wu},
  journal={Journal of the American Chemical Society},
  year={2008},
  volume={130 11},
  pages={
          3590-602
        }
}
  • R. Ida, Gang Wu
  • Published 23 February 2008
  • Chemistry, Biology
  • Journal of the American Chemical Society
We describe a general multinuclear (1H, 23Na, 87Rb) NMR approach for direct detection of alkali metal ions bound to G-quadruplex DNA. This study is motivated by our recent discovery that alkali metal ions (Na+, K+, Rb+) tightly bound to G-quadruplex DNA are actually "NMR visible" in solution (Wong, A.; Ida, R.; Wu, G. Biochem. Biophys. Res. Commun. 2005, 337, 363). Here solution and solid-state NMR methods are developed for studying ion binding to the classic G-quadruplex structures formed by… 
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Role of Alkali Metal Ions in G-Quadruplex Nucleic Acid Structure and Stability.
TLDR
This chapter focuses on the essential and specific coordination of alkali metal cations by G-quadruplex nucleic acids, and most notably on studies highlighting cation-dependent dissimilarities in their stability, structure, formation, and interconversion.
Competitive binding exchange between alkali metal ions (K+, Rb+, and Cs+) and Na+ ions bound to the dimeric quadruplex [d(G4T4G4)]2: a 23Na and 1H NMR study
TLDR
Comparing this value to those reported in the literature for the surface of the G‐quadruplex formed by 5′‐guanosinemonophosphate and for thesurface of double‐helical DNA suggests that topology factors may have an important influence on the cation affinity for the phosphate groups on DNA.
Direct observation of guanine radical cation deprotonation in G-quadruplex DNA.
TLDR
The unique deprotonation features observed here for G-quadruplexes open possibilities for their interesting applications as molecular electronic devices, while the elucidated mechanisms can provide illuminations for the rational design of G- quadruplex structures toward such applications and enrich the fundamental understandings of DNA radical chemistry.
The role of alkali metal cations in the stabilization of guanine quadruplexes: why K(+) is the best.
TLDR
It is revealed that the desolvation and size of the alkali metal cation are both almost equally responsible for the order of affinity.
Cation binding to 15-TBA quadruplex DNA is a multiple-pathway cation-dependent process
TLDR
Using extensive simulations, the first time observed full spontaneous exchange of internal cation between quadruplex molecule and bulk solvent at atomistic resolution and suggests that expulsion of the internally bound ion is correlated with initial binding of the incoming ion.
Internal sodium ions and water molecules in guanine quadruplexes: magnetic relaxation dispersion studies of [d(G3T4G3)]2 and [d(G4T4G4)]2.
TLDR
The MRD data indicate that both quadruplexes contain Na (+) ions between the T 4 loops and the terminal G-quartets and that these ions have one water ligand, in agreement with previous solid-state (23)Na NMR findings but contrary to the only crystal structure of this quadruplex.
Characterization of metal ion-nucleic acid interactions in solution.
TLDR
The physicochemical properties of metal ions found and used in combination with nucleic acids in solution are compiled and spectroscopic techniques like EPR, lanthanide(III) luminescence, IR and Raman as well as various NMR methods are summarized.
Linkage of cation binding and folding in human telomeric quadruplex DNA.
Understanding alkali metal cation affinities of multi-layer guanine quadruplex DNA
TLDR
Analysis of the stabilizing interactions between alkali cations and the DNA bases in double and triple-layer guanine quadruplex DNA reproduced the experimental affinity trend of the order Li+< Rb+ < Na+ < K+.
Highly Selective Detection of K+ Based on a Dimerized G-Quadruplex DNAzyme.
TLDR
A K+ specific biosensor is constructed on the basis of a dimerized G-quadruplex (GQ) DNA, which is promoted by K+, and the enzymatic activity of the resulting DNAzyme depends on the concentration of the K+.
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References

Solid - state nuclear magnetic resonance studies of alkali metal ions in nucleic acids and related systems
  • NMR Spectroscopy of Biological Solids