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The hairpin ribozyme is a small Mg2+-dependent catalytic RNA molecule able to catalyze the trans-cleavage of an RNA substrate via a reversible trans-esterification mechanism. In this study, the cleavage activities of several fragmented hairpin ribozyme systems were examined. Due to the complex catalytic structure of the hairpin ribozyme, a new boronic acid ester was used as a covalent linkage to hold the folding of the functional system. It has been demonstrated the possibility of replacing the phosphodiester linkage, at specific positions, with a boronic acid ester to restore or improve the catalytic activity of fragmented hairpin ribozyme.
Boronate esters formed by reaction of an oligonucleotide carrying a 5′-boronic acid moiety with the 3′-terminal cis-diol of another have been shown previously to assist assembly of fragmented DNAzymes. Here we demonstrate that boronate esters replacing the natural phosphodiester linkage at selected sites of two functional RNAs, the hairpin ribozyme and the Mango aptamer, allow assembly of functional structures. The hairpin ribozyme, a small naturally occurring RNA that supports the reversible cleavage of appropriate RNA substrates, is very sensitive to fragmentation. Splitting the ribozyme at four different sites led to a significant decrease or even loss of cleavage and ligation activity. Ribozymes assembled from fragments capable of boronate ester formation showed restoration of cleavage activity in some but not all cases, dependent on the split site. Ligation proved to be more challenging, no supportive effect of the boronate ester was observed. Split variants of the Mango aptamer also showed a dramatic loss of functionality, which however, was restored when 5′-boronic acid modified fragments were used for assembly. These studies show for the first time that boronate esters as internucleoside linkages can act as surrogates of natural phosphodiesters in functional RNA molecules.
Abstract
The 10–23 DNAzyme is an artificially developed Mg2+‐dependent catalytic oligonucleotide that can cleave an RNA substrate in a sequence‐specific fashion. In this study, new split 10–23 DNAzymes made of two nonfunctional fragments, one of which carries a boronic acid group at its 5′ end, while the other has a ribonucleotide at its 3′ end, were designed. Herein it is demonstrated that the addition of Mg2+ ions leads to assembly of the fragments, which in turn induces the formation of a new boronate internucleoside linkage that restores the DNAzyme activity. A systematic evaluation identified the best‐performing system. The results highlight key features for efficient control of DNAzyme activity through the formation of boronate linkages.