Nucleotides alkali metal ions

Murray KK. DNA sequencing by mass spectrometry. J Mass Spectrom. 1996 31 1203-15. Xiang Y, Abliz Z, Takayama M. Cleavage reactions of the complex ions derived from self-complementary deoxydinucleotides and alkali-metal ions using positive ion electrospray ionization with tandem mass spectrometry. J Am Soc Mass Spectrom. 2004 15 689-96. Boschenok J, Sheil MM. Electrospray tandem mass spectrometry of nucleotides. Rapid CommunMass Spectrom. 1996 10 144-9. 

Abstract This review summarizes computational studies devoted to interactions of metal cations with nucleobases, nucleotides, and short oligonucleotides considered as DNA/RNA models. Since this topic is complex, basically only the results obtained using ab initio and DFT methods are discussed. Part 1 focuses mainly on the interactions of the isolated bases with metal cations in bare, hydrated, and ligated forms. First, interactions of bare cations with nucleobases in gas phase approach are mentioned. Later, solvation effects using polarizable continuum models are analyzed and a comparison with explicitly hydrated ions is presented. In Part II, adducts of alkali metal, metal of alkaline earth, and zinc group metal cations with canonical base pairs are discussed. A separate section is devoted to platinum complexes related to anticancer treatment. Stacked bases and larger systems are discussed in last section. Here, semiempirical methods and molecular modeling are also discussed due to extensive size of studied complexes. 

The separation of nucleotides and deoxynucleotides, previously a formidable task involving the fractional crystallization of heavy metal and alkaloid salts 102) has been made much easier by developments in analytical techniques. Ion-exchange methods may be used for the purification, isolation, and identification of both classes of nucleotides from hydrolysis mixtures 103), Countercurrent distribution 104) and starch 106) and cellulose-column 106) as well as paper-strip chromatography 107) have also proved to be useful in separating nucleotides from natural sources. Spectro-photometric procedures based on the characteristic ultraviolet absorption spectra of the purines and pyrimidines have been the most convenient method to locate, estimate, and identify the fractions obtained in the previous separations. Since the nucleotides are acid in nature, they are often named as acids, e.g., adenylic acid, cytidylic acid. The general constitution of the purine nucleotides (and by analogy the pyrimidine nucleotides) is demonstrated by their hydrolysis by acids to a purine and ribose (or 2-deoxyribose) monophosphate and by alkalies to the nucleosides and phosphoric acid. The order of the constituents in a purine nucleotide must, therefore, be ... 

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