Monitoring post-translational modification of proteins with allosteric ribozymes.

An allosteric hammerhead ribozyme activated specifically by the unphosphorylated form of the protein kinase ERK2 was created through a rational design strategy that relies on molecular recognition of ERK2 to decrease the formation of an alternate, inactive ribozyme conformer. Neither closely related mitogen-activated protein kinases (MAPKs) nor the phosphorylated form of ERK2 induced ribozyme activity. The ribozyme quantitatively detected ERK2 added to mammalian cell lysates and also functioned quantitatively in a multiplexed solution-phase assay. This same strategy was used to construct a second ribozyme selectively activated by the phosphorylated (active) form of ERK2. This approach is generally applicable to the development of ribozymes capable of monitoring post-translational modification of specific proteins.

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.

A novel, modification-dependent ATP-binding aptamer selected from an RNA library incorporating a cationic functionality.

An analogue of uridine triphosphate containing a cationic functional group was incorporated into a degenerate RNA library by enzymatic polymerization. In vitro selection experiments using this library yielded a novel receptor that binds ATP under physiological pH and salt conditions in a manner completely dependent on the presence of the cationic functionality. The consensus sequence and a secondary structure model for the ATP binding site were obtained by the analysis of functional sequences selected from a partially randomized pool based on the minimal parental sequence. Mutational studies of this receptor indicated that several of the modified uridines are critical for ATP binding. Analysis of the binding of ATP analogues revealed that the modified RNA receptor makes numerous contacts with ATP, including interactions with the triphosphate group. In contrast, the aptamer repeatedly isolated from natural RNA libraries does not interact with the triphosphate group of ATP. The incorporation of a cationic amine into nucleic acids clearly allows novel interactions to occur during the molecular recognition of ligands, which carries interesting implications for the RNA world hypothesis. In addition, new materials generated from such functionalized nucleic acids could be useful tools in research and diagnostics.

Monitoring protein modification with allosteric ribozymes.

An allosteric ribozyme is an RNA-based enzyme (ribozyme) whose catalytic activity is modulated by molecular recognition of a protein. The direct coupling of a detectable catalytic event to molecular recognition by an allosteric ribozyme enables simple assays for quantitative protein detection. Most significantly, the mode of development and molecular recognition characteristics of allosteric ribozymes are fundamentally different from antibodies, providing them with functional characteristics that complement those of antibodies. Allosteric ribozymes can be developed using native proteins and, therefore, are often sensitive to protein conformation. In contrast, antibodies tend to recognize a series of adjacent amino acids as a consequence of antigen presentation and typically are not sensitive to protein conformation. Unlike antibody development, the development of allosteric ribozymes is a completely in vitro process that allows the specificity of an allosteric ribozyme to be tightly controlled. These significant differences from antibodies allow the pre-programmed development of conformation-state-specific protein detection reagents that can be used to investigate the activation-state of signal transduction components.

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.