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RESEARCH PRODUCT

Effect of the Alkaline Cations on the Stability of the Model Polynucleotide Poly(dG-dC)·Poly(dG-dC)

Marcello GiominiMauro GiustiniGiuseppe GennaroMarta AiroldiAnna Maria Giuliani

subject

Hofmeister seriesalkaline cationsSodiumPolynucleotidesInorganic chemistryAnalytical chemistrychemistry.chemical_elementSodium Chloridemodel polynucleotidesAbsorbancePolydeoxyribonucleotidesUltraviolet visible spectroscopyalkaline cations; hofmeister effect; model polynucleotides; uv-spectroscopyStructural BiologyCationsuv-spectroscopyhofmeister effectMicroemulsionAlkaline cationMolecular BiologyAqueous solutionMetals AlkaliChemistryModel polynucleotideGeneral MedicineHydrogen-Ion ConcentrationAlkali metalPolynucleotideNucleic Acid Conformation

description

When the model polynucleotide poly(dG-dC)∙poly(dG-dC) [polyGC] is titrated with a strong acid (HCl) in unbuffered aqueous solutions containing the chlorides of the alkali metals in the concentration range 0.010 M-0.600 M, two transitions in the absorbance vs. pH plots are evidenced, characterized by the constants pK(a(₁)) and pK(a(₂)). The limiting values at infinite saline concentrations of these two constants, namely pK(∞)(a(₁)) and pK(∞)(a(₂)) obtained making use of the "one site saturation constant" equation or, in turn, of the double logarithmic plot: pK(a) vs. log([salt]⁻¹), exhibit a clear dependence on the nature of the cations. The effects of the different alkali cations on the pK(∞)(a) values follow the Hofmeister series. In fact, the pK(∞)(a(₁)) and the pK(∞)(a(₂)) values are smaller for Li+ and Na+ than for Rb+ and Cs+, with K+ at the border between the two, showing that the transitions require higher concentrations of protons to occur in the presence of high concentrations of the cosmotropic ions.

yearjournalcountryeditionlanguage
2011-01-01Journal of Biomolecular Structure and Dynamics
https://doi.org/10.1080/07391102.2011.10507407