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- Title
Acid–base and metal ion binding properties of 2-thiocytidine in aqueous solution.
- Authors
Brasuń, Justyna; Matera, Agnieszka; Sochacka, Elżbieta; Swiatek-Kozlowska, Jolanta; Kozlowski, Henryk; Operschall, Bert P.; Sigel, Helmut
- Abstract
The thionucleoside 2-thiocytidine (C2S) occurs in nature in transfer RNAs; it receives attention in diverse fields like drug research and nanotechnology. By potentiometric pH titrations we measured the acidity constants of H(C2S)+ and the stability constants of the M(C2S)2+ and M(C2S−H)+ complexes (M2+ = Zn2+, Cd2+), and we compared these results with those obtained previously for its parent nucleoside, cytidine (Cyd). Replacement of the (C2)=O unit by (C2)=S facilitates the release of the proton from (N3)H+ in H(C2S)+ (p K a = 3.44) somewhat, compared with H(Cyd)+ (p K a = 4.24). This moderate effect of about 0.8 p K units contrasts with the strong acidification of about 4 p K units of the (C4)NH2 group in C2S (p K a = 12.65) compared with Cyd (p K a ≈ 16.7); the reason for this result is that the amino–thione tautomer, which dominates for the neutral C2S molecule, is transformed upon deprotonation into the imino–thioate form with the negative charge largely located on the sulfur. In the M(C2S)2+ complexes the (C2)S group is the primary binding site rather than N3 as is the case in the M(Cyd)2+ complexes, though owing to chelate formation N3 is to some extent still involved in metal ion binding. Similarly, in the Zn(C2S−H)+ and Cd(C2S−H)+ complexes the main metal ion binding site is the (C2)S− unit (formation degree above 99.99% compared with that of N3). However, again a large degree of chelate formation with N3 must be surmised for the M(C2S−H)+ species in accord with previous solid-state studies of related ligands. Upon metal ion binding, the deprotonation of the (C4)NH2 group (p K a = 12.65) is dramatically acidified (p K a ≈ 3), confirming the very high stability of the M(C2S−H)+ complexes. To conclude, the hydrogen-bonding and metal ion complex forming capabilities of C2S differ strongly from those of its parent Cyd; this must have consequences for the properties of those RNAs which contain this thionucleoside.
- Subjects
METAL ions; RIBONUCLEASES; RNA; ACIDITY function; IONS
- Publication
Journal of Biological Inorganic Chemistry (JBIC), 2008, Vol 13, Issue 5, p663
- ISSN
0949-8257
- Publication type
Article
- DOI
10.1007/s00775-008-0351-1