ABSTRACT
Under standard reaction conditions, a hammerhead ribozyme with a phosphorodithioate linkage at the cleavage site cleaved to the expected products with a rate about 500-fold slower than the corresponding phosphodiester linkage. When the greater stability of the dithioate linkage to nonenzymatic nucleophilic attack is taken into account, the hammerhead is remarkably effective at cleaving the dithioate linkage considering that the R(P)-phosphoromonothioate linkage is virtually inactive. On the basis of experiments determining the Mg(2+) concentration dependence of the cleavage rate and the stimulation of cleavage by thiophilic Cd(2+) ion, the lesser catalytic rate enhancement of the dithioate linkage is primarily due to the loss of a single Mg(2+) ion bound near the cleavage site. These results are qualitatively similar to, but quantitatively different from, similar experiments examining the hammerhead cleavage properties of the R(P)-phosphoromonothioate linkage. The dithioate linkage thus promises to be a valuable alternative phosphate analogue to the monothioate linkage in studying the mechanisms of RNA catalysis.
Subject(s)
Phosphates/chemistry , Phosphates/metabolism , RNA, Catalytic/metabolism , Base Sequence , Cadmium/metabolism , Cadmium/pharmacology , Catalysis/drug effects , Chromatography, High Pressure Liquid , Dose-Response Relationship, Drug , Kinetics , Magnesium/metabolism , Magnesium/pharmacology , Metals/metabolism , Metals/pharmacology , Nucleic Acid Conformation , Oxygen/metabolism , RNA, Catalytic/chemistry , RNA, Catalytic/genetics , Static Electricity , Substrate Specificity , Sulfur/metabolism , ThermodynamicsABSTRACT
Most mutations in the sequence of the RNA hairpin that specifically binds MS2 coat protein either reduce the binding affinity or have no effect. However, one RNA mutation, a uracil to cytosine change in the loop, has the unusual property of increasing the binding affinity to the protein by nearly 100-fold. Guided by the structure of the protein-RNA complex, we used a series of protein mutations and RNA modifications to evaluate the thermodynamic basis for the improved affinity: The tight binding of the cytosine mutation is due to (i) the amino group of the cytosine residue making an intra-RNA hydrogen bond that increases the propensity of the free RNA to adopt the structure seen in the complex and (ii) the increased affinity of hydrogen bonds between the protein and a phosphate two bases away from the cytosine residue. The data are in good agreement with a recent comparison of the cocrystal structures of the two complexes, where small differences in the two structures are seen at the thermodynamically important sites.