High-throughput ribozyme-based assays for detection of viral nucleic acids.

Many reports have suggested that target-activated ribozymes hold potential value as detection reagents. We show that a "half"-ribozyme ligase is activated similarly by three unstructured oligoribonucleotides representing the major sequence variants of a hepatitis C virus 5'-untranslated region (5'-UTR) target and by a structured RNA corresponding to the entire 5'-UTR. Half-ribozyme ligation product was detected both in an ELISA-like assay and in an optical immunoassay through the use of hapten-carrying substrate RNAs. Both assay formats afford a limit of detection of approximately 1 x 10(6) HCV molecules (1.6 attomol, 330 fM), a sensitivity which compares favorably to that provided by standard immunoassays. These data suggest that target-activated ribozyme systems are a viable approach for the sensitive detection of viral nucleic acids using high-throughput platforms.

Zeptomole detection of a viral nucleic acid using a target-activated ribozyme.

We describe a strategy for the ultra-sensitive detection of nucleic acids using "half" ribozymes that are devoid of catalytic activity unless completed by a trans-acting target nucleic acid. The half-ribozyme concept was initially demonstrated using a construct derived from a multiple turnover Class I ligase. Iterative RNA selection was carried out to evolve this half-ribozyme into one activated by a conserved sequence present in the hepatitis C virus (HCV) genome. Following sequence optimization of substrate RNAs, this HCV-activated half-ribozyme displayed a maximal turnover rate of 69 min(-1) (pH 8.3) and was induced in rate by approximately 2.6 x 10(9)-fold by the HCV target. It detected the HCV target oligonucleotide in the zeptomole range (6700 molecules), a sensitivity of detection roughly 2.6 x 10(6)-fold greater than that previously demonstrated by oligonucleotide-activated ribozymes, and one that is sufficient for molecular diagnostic applications.

Coenzymes as coribozymes.

Coenzymes are small organic molecules that supply a varied set of reactive groups to protein enzymes, thereby diversifying catalysis beyond the chemistries of amino acid sidechains. As RNA structures begin with a more limited chemical diversity than proteins, it seems likely that RNA enzymes would also use functional groups from other molecules to support a complex RNA world metabolism. In fact, ribonucleotide moieties in many coenzymes have long been thought to be surviving vestiges of covalently bound coenzymes in an RNA world. The idea of coenzyme utilization by ribozymes can be explored by selection-amplification of coenzyme-binding RNAs and coenzyme-assisted ribozymes. Here, we review coenzyme-RNAs, and discuss their possible significance for RNA-mediated metabolism. In summary, a plausible route from prebiotic chemistry to ribozyme biochemistry exists for CoA, and via similar activities, likely exists for all the nucleotidyl coenzymes.

Acyl-CoAs from coenzyme ribozymes.

We describe in vitro selection of two novel ribozymes that mediate coenzyme reactions. The first is a trans-capping ribozyme that attaches coenzyme A (CoA) at the 5' end of any RNA with the proper short terminal sequence, including RNAs with randomized internal sequences. From such a trans-capped CoA-RNA pool, we derive ribozymes that attack biotinyl-AMP using the SH group of CoA. These ribozymes, selected to acylate CoA with the valeryl side chain of biotin, also produce the crucial metabolic intermediates acetyl-CoA and butyryl-CoA with substantial velocities. Thus, we argue that RNAs might have used the chemical functionality offered by coenzymes to support an RNA world metabolism. In particular, we can combine our results with those of other labs to argue that simple chemistry and RNA catalysis suffice to proceed from simple chemicals to catalysis with acyl-CoAs. The trans-capping method can be generalized for production of varied coenzyme ribozymes using a single catalytic RNA subunit. Finally, the long-suggested RNA origin for CoA itself appears to be chemically feasible.