Abstract

AbstractThe extent and modes of binding of the divalent metal ions Mn2+ and Co2+ to DNA and the effects of salt on the binding have been studied by measurements of the effects of these paramagnetic metal ions on the longitudinal and transverse relaxation rates of the protons of the solvent water molecules, a technique that is sensitive to overall binding. The number of water molecules coordinated to the DNA–bound Mn2+ and Co2+ is found to be between five and six, and the electron spin relaxation times and the electron‐nuclear hyperfine constants associated with Mn2+ and Co2+ are little or not affected by the binding. These observations indicate little disturbance of the hydration sphere of Mn2+ and Co2+ upon binding to DNA. An average 2–3‐fold reduction in the exchange rate of the water of hydration of the bound metal ions and an order‐of‐magnitude increase in their rotational correlation time are attributed to hydrogen‐bond formation with the DNA. The binding constants of Mn2+ to DNA, at metal concentrations approaching zero, are found to be inversely proportional to the second power of the salt concentration, in agreement with the predictions of Manning's polyelectrolyte theory. A remarkable quantitative agreement with the polyelectrolyte theory is also obtained for the anticooperativity in the binding of Mn2+ to DNA, although the experimental results can be well accounted for by another simple electrostatic model. The various modes of binding of divalent metal ions to DNA are discussed.

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