Bernd Knobloch scite author profile

It is well known that Mg2+ and other divalent metal ions bind to the phosphate groups of nucleic acids. Subtle differences in the coordination properties of these metal ions to RNA, especially to ribozymes, determine whether they either promote or inhibit catalytic activity. The ability of metal ions to coordinate simultaneously with two neighboring phosphate groups is important for ribozyme structure and activity. However, such an interaction has not yet been quantified. Here, we have performed potentiometric pH titrations to determine the acidity constants of the protonated dinucleotide H2(pUpU)-, as well as the binding properties of pUpU3- towards Mg2+, Mn2+, Cd2+, Zn2+, and Pb2+. Whereas Mg2+, Mn2+, and Cd2+ only bind to the more basic 5'-terminal phosphate group, Pb2+, and to a certain extent also Zn2+, show a remarkably enhanced stability of the [M(pUpU)]- complex. This can be attributed to the formation of a macrochelate by bridging the two phosphate groups within this dinucleotide by these metal ions. Such a macrochelate is also possible in an oligonucleotide, because the basic structural units are the same, despite the difference in charge. The formation degrees of the macrochelated species of [Zn(pUpU)]- and [Pb(pUpU)]- amount to around 25 and 90 %, respectively. These findings are important in the context of ribozyme and DNAzyme catalysis, and explain, for example, why the leadzyme could be selected in the first place, and why this artificial ribozyme is inhibited by other divalent metal ions, such as Mg2+.

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Comparison of the Acid–Base Properties of Ribose and 2′‐Deoxyribose Nucleotides

Mucha¹,

Knobloch²,

Jeżowska‐Bojczuk³

et al. 2008

Chemistry A European J

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The extent to which the replacement of a ribose unit by a 2'-deoxyribose unit influences the acid-base properties of nucleotides has not hitherto been determined in detail. In this study, by potentiometric pH titrations in aqueous solution, we have measured the acidity constants of the 5'-di- and 5'-triphosphates of 2'-deoxyguanosine [i.e., of H(2)(dGDP)(-) and H(2)(dGTP)(2-)] as well as of the 5'-mono-, 5'-di-, and 5'-triphosphates of 2'-deoxyadenosine [i.e., of H(2)(dAMP)(+/-), H(2)(dADP)(-), and H(2)(dATP)(2-)]. These 12 acidity constants (of the 56 that are listed) are compared with those of the corresponding ribose derivatives (published data) measured under the same experimental conditions. The results show that all protonation sites in the 2'-deoxynucleotides are more basic than those in their ribose counterparts. The influence of the 2'-OH group is dependent on the number of 5'-phosphate groups as well as on the nature of the purine nucleobase. The basicity of N7 in guanine nucleotides is most significantly enhanced (by about 0.2 pK units), while the effect on the phosphate groups and the N1H or N1H(+) sites is less pronounced but clearly present. In addition, (1)H NMR chemical shift change studies in dependence on pD in D(2)O have been carried out for the dAMP, dADP, and dATP systems, which confirmed the results from the potentiometric pH titrations and showed the nucleotides to be in their anti conformations. Overall, our results are not only of relevance for metal ion binding to nucleotides or nucleic acids, but also constitute an exact basis for the calculation, determination, and understanding of perturbed pK(a) values in DNAzymes and ribozymes, as needed for the delineation of acid-base mechanisms in catalysis.

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Acid–Base and Metal‐Ion‐Binding Properties of Xanthosine 5′‐Monophosphate (XMP) in Aqueous Solution: Complex Stabilities, Isomeric Equilibria, and Extent of Macrochelation

Sigel¹,

Massoud²,

Song³

et al. 2006

Chemistry A European J

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The four acidity constants of threefold protonated xanthosine 5'-monophosphate, H3(XMP)+, reveal that at the physiological pH of 7.5 (XMP-H)(3-) strongly dominates (and not XMP(2-) as given in textbooks); this is in contrast to the related inosine (IMP(2-)) and guanosine 5'-monophosphate (GMP(2-)) and it means that XMP should better be named as xanthosinate 5'-monophosphate. In addition, evidence is provided for a tautomeric (XMP-HN1)(3-)/(XMP-HN3)(3-) equilibrium. The stability constants of the M(H;XMP)+ species were estimated and those of the M(XMP) and M(XMP-H)- complexes (M2+=Mg2+, Ca2+, Sr2+, Ba2+, Mn2+, Co2+, Ni2+, Cu2+, Zn2+, Cd2+) measured potentiometrically in aqueous solution. The primary M2+ binding site in M(XMP) is (mostly) N7 of the monodeprotonated xanthine residue, the proton being at the phosphate group. The corresponding macrochelates involving P(O)2(OH)- (most likely outer-sphere) are formed to approximately 65% for nearly all M2+. In M(XMP-H)- the primary M2+ binding site is (mostly) the phosphate group; here the formation degree of the N7 macrochelates varies widely from close to zero for the alkaline earth ions, to approximately 50% for Mn2+, and approximately 90% or more for Co2+, Ni2+, Cu2+, Zn2+, and Cd2+. Because for (XMP-H)(3-) the micro stability constants quantifying the M2+ affinity of the xanthosinate and PO3(2-) residues are known, one may apply a recently developed quantification method for the chelate effect to the corresponding macrochelates; this chelate effect is close to zero for the alkaline earth ions and it amounts to about one log unit for Co2+, Ni2+, Cu2+. This method also allows calculation of the formation degrees of the monodentatally coordinated isomers; this information is of relevance for biological systems because it demonstrates how metal ions can switch from one site to another through macrochelate formation. These insights are meaningful for metal-ion-dependent reactions of XMP in metabolic pathways; previous mechanistic proposals based on XMP(2-) need revision.

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Metal ion-binding properties of (N3)-deprotonated uridine, thymidine, and related pyrimidine nucleosides in aqueous solution

Knobloch

Linert

Sigel

2005

Proc. Natl. Acad. Sci. U.S.A.

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The acidity constants for (N3)H of the uridine-type ligands (U) 5-fluorouridine, 5-chloro-2-deoxyuridine, uridine, and thymidine (2-deoxy-5-methyluridine) and the stability constants of the M(U-H) ؉ complexes for M 2؉ chelate formation ͉ equilibrium constants ͉ metal ion complexes ͉ nucleic acids ͉ nucleobase properties T he importance of metal ion-nucleic acid interactions in the metabolic machinery is well recognized and applied, e.g., in medicinal chemistry (1). Crystal-structure analyses of nucleic acids (2), especially RNAs (3), show that metal ions coordinate to the phosphate-diester bridges as well as to nucleobase residues, and they are important for folding and catalysis of ribozymes (3-5).The N7 sites of purine residues are exposed in the major groove of DNA (2) and accessible for metal ion binding (6). Maybe this is one reason why their metal ion-coordinating properties are relatively well studied (6-11) in contrast to those of pyrimidine-nucleobase residues (8-10). In fact, the stabilities and solution structures of cytidine (Cyd) complexes of biologically relevant metal ions were quantified only recently (12). Knowledge on uridine complexes is scarce: The carbonyl oxygens (C2)O and (C4)O of uracil residues in low (2, 13) and high (2, 3, 14, 15) molecular weight derivatives may interact in the solid state with metal ions, but in aqueous (aq) solution monodentate carbonyl-oxygen ligands bind only if correctly positioned by primary sites (16).In a recent study (17) with Mg 2ϩ

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Bernd Knobloch

Acid–Base and Metal‐Ion Binding Properties of the RNA Dinucleotide Uridylyl‐(5′→3′)‐[5′]uridylate (pUpU³⁻)

Comparison of the Acid–Base Properties of Ribose and 2′‐Deoxyribose Nucleotides

Acid–Base and Metal‐Ion‐Binding Properties of Xanthosine 5′‐Monophosphate (XMP) in Aqueous Solution: Complex Stabilities, Isomeric Equilibria, and Extent of Macrochelation

Metal ion-binding properties of (N3)-deprotonated uridine, thymidine, and related pyrimidine nucleosides in aqueous solution

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Bernd Knobloch

Acid–Base and Metal‐Ion Binding Properties of the RNA Dinucleotide Uridylyl‐(5′→3′)‐[5′]uridylate (pUpU3−)

Comparison of the Acid–Base Properties of Ribose and 2′‐Deoxyribose Nucleotides

Acid–Base and Metal‐Ion‐Binding Properties of Xanthosine 5′‐Monophosphate (XMP) in Aqueous Solution: Complex Stabilities, Isomeric Equilibria, and Extent of Macrochelation

Metal ion-binding properties of (N3)-deprotonated uridine, thymidine, and related pyrimidine nucleosides in aqueous solution

Contact Info

Product

Resources

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Acid–Base and Metal‐Ion Binding Properties of the RNA Dinucleotide Uridylyl‐(5′→3′)‐[5′]uridylate (pUpU³⁻)