Ribozymes of the hepatitis delta virus: recent findings on their structure, mechanism of catalysis and possible applications.

Although the delta ribozymes have been studied for more than ten years the most important information concerning their structure and mechanism of catalysis were only obtained very recently. The crystal structure of the genomic delta ribozyme turns out to be an excellent example of the extraordinary properties of RNA molecules to fold into uniquely compact structures. Details of the X-ray structure have greatly stimulated further studies on the folding of the ribozymes into functionally active molecules as well as on the mechanism of RNA catalysis. The ability of the delta ribozymes to carry out general acid-base catalysis by nucleotide side chains has been assumed in two proposed mechanisms of self-cleavage. Recently, considerable progress has been also made in characterizing the catalytic properties of trans-acting ribozyme variants that are potentially attractive tools in the strategy of directed RNA degradation.

Catalytic cleavage of cis- and trans-acting antigenomic delta ribozymes in the presence of various divalent metal ions.

Catalytic activity of four structural variants of the antigenomic delta ribozyme, two cis- and two trans-acting, has been compared in the presence of selected divalent metal ions that effectively support catalysis. The ribozymes differ in regions that are not directly involved in formation of the ribozyme active site: the region immediately preceding the catalytic cleavage site, the P4 stem and a stretch of the viral RNA sequence extending the minimal ribozyme sequence at its 3'-terminus. The variants show high cleavage activity in the presence of Mg(2+), Ca(2+) and Mn(2+), lower with Co(2+) and Sr(2+) and some variants are also active with Cd(2+) and Zn(2+) ions. In the presence of a particular metal ion the ribozymes cleave, however with different initial rates, according to pseudo-first or higher order kinetics and to different final cleavage extents. On the other hand, relatively small differences are observed in the reactions induced by various metal ions. The cleavage of trans-acting ribozymes induced by Mg(2+) is partially inhibited in the presence of Na(+), spermidine and some other divalent metal ions. The inert Co(NH(3))(6)(3+) complex is unable to support catalysis, as reported earlier for the genomic ribozyme. The results are discussed in terms of the influence of structural elements peripheral to the ribozyme active site on its cleavage rate and efficiency as well as the role of metal ions in the cleavage mechanism. Some implications concerning further studies and possible applications of delta ribozymes are also considered.

Mapping of accessible sites for oligonucleotide hybridization on hepatitis delta virus ribozymes.

Semi-random libraries of DNA 6mers and RNase H digestion were applied to search for sites accessible to hybridization on the genomic and antigenomic HDV ribozymes and their 3' truncated derivatives. An approach was proposed to correlate the cleavage sites and most likely sequences of oligomers, members of the oligonucleotide libraries, which were engaged in the formation of RNA-DNA hybrids. The predicted positions of oligomers hybridizing to the genomic ribozyme were compared with the fold of polynucleotide chain in the ribozyme crystal structure. The data exemplified the crucial role of target RNA structural features in the binding of antisense oligonucleotides. It turned out that cleavages were induced if the bound oligomer could adapt an ordered helical conformation even when it required partial penetration of an adjacent double-stranded region. The major features of RNA structure disfavoring hybridization and/or RNase H hydrolysis were sharp turns of the polynucleotide chain and breaks in stacking interactions of bases. Based on the predicted positions of oligomers hybridizing to the antigenomic ribozyme we chose and synthesized four antisense DNA 6mers which were shown to direct hydrolysis in the desired, earlier predicted regions of the molecule.