The cleavage of RNA can be accelerated by a number of factors. These factors include an acidic group (Lewis acid) or a basic group that aids in the deprotonation of the attacking nucleophile, in effect enhancing the nucleophilicity of the nucleophile; an acidic group that can neutralize and stabilize the leaving group; and any environment that can stabilize the pentavalent species that is either a transition state or a short-lived intermediate. The catalytic properties of ribozymes are due to factors that are derived from the complicated and specific structure of the ribozyme-substrate complex. It was postulated initially that nature had adopted a rather narrowly defined mechanism for the cleavage of RNA. However, recent findings have clearly demonstrated the diversity of the mechanisms of ribozyme-catalyzed reactions. Such mechanisms include the metal-independent cleavage that occurs in reactions catalyzed by hairpin ribozymes and the general double-metal-ion mechanism of catalysis in reactions catalyzed by the Tetrahymena group I ribozyme. Furthermore, the architecture of the complex between the substrate and the hepatitis delta virus ribozyme allows perturbation of the pK(a) of ring nitrogens of cytosine and adenine. The resultant perturbed ring nitrogens appear to be directly involved in acid/base catalysis. Moreover, while high concentrations of monovalent metal ions or polyamines can facilitate cleavage by hammerhead ribozymes, divalent metal ions are the most effective acid/base catalysts under physiological conditions.
RNA interference (RNAi) is a gene-silencing phenomenon that involves the double-stranded RNA-mediated cleavage of mRNA, and small interfering RNAs (siRNAs) can cause RNAi in mammalian cells. There have been many attempts to clarify the mechanism of RNAi, but information about the relationship between the sequence and structure, in particular, a tight structure, of the target RNA and the activities of siRNAs are limited. In the present study, we examined this relationship by introducing the TAR element, which adopts a very stable secondary structure, at different positions within target RNAs. Our results suggested that the activities of siRNAs were affected by the tight stem-loop structure of TAR. In contrast, the position of the target within the mRNA, the binding of the Tat protein to the TAR, and the location of the target within a translated or a noncoding region had only marginal effects on RNAi. When the target sequence was placed in two different orientations, only one orientation had a significant effect on the activities of siRNA, demonstrating that the presence of certain nucleotides at some specific positions was favorable for RNAi. Systematic analysis of 47 different sites within 47 plasmids under identical conditions indicated that it is the target sequence itself, rather than its location, that is the major determinant of siRNA activity.
We synthesized three types of 11mer substrate, namely the natural substrate S11O and the thio-substituted substrates S11 S pS and S11 R pS, in which the respective pro-S p and pro-R p oxygen atoms were replaced by sulfur, and subjected them to detailed kinetic analysis in the cleavage reaction catalyzed by a hammerhead ribozyme. In agreement with previous findings, in the presence of Mg(2+)or Ca(2+)ions the rate of ribozyme-catalyzed cleavage of S11 S pS was as high as that of S11O, whereas the corresponding rate for S11 R pS was nearly four orders of magnitude lower than that for either S11O or S11 S pS. However, the rate of the ribozyme-catalyzed reaction with each of the three substrates was enhanced by Cd(2+)ions. Such results have generally been taken as evidence that supports the direct interaction of the sulfur atom at the R p position of the cleavage site with the added Cd(2+)ion. However, our present analysis demonstrates that (i) the added Cd(2+)ion binds at the P9 site; (ii) the bound Cd(2+)ion at the P9 site replaces two Mg(2+)or two Ca(2+)ions, an observation that suggests a different mode of interaction with the added Cd(2+)ion; and, most importantly and in contrast to the conclusion reached by other investigators, (iii) the Cd(2+)ion does not interact with the sulfur atom at the R p position of the scissile phosphate either in the ground state or in the transition state.
The catalysis of various amines for the hydrolysis of RNA has been kinetically investigated, and the catalytic rate constants for each of the ionic states of these amines are determined. Ethylenediamine and 1,3-propanediamine are highly active under the physiological conditions, mainly because they preferentially take the catalytically active monocationic forms. The catalysis of these diamines is further promoted by the intramolecular acid-base cooperation of the neutral amine and the ammonium ion. In contrast, monoamines overwhelmingly exist at pH 7 as the inactive cations. Potential application of the catalysis by the diamines and the related oligoamines is discussed.
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