A biosensor for theophylline based on fluorescence detection of ligand-induced hammerhead ribozyme cleavage

Recently, Breaker and coworkers engineered hammerhead ribozymes that rearrange from a catalytically inactive to an active conformation upon allosteric binding of a specific ligand. To monitor cleavage activity in real time, we have coupled a donor-acceptor fluorophore pair to the termini of the substrate RNA of such a hammerhead ribozyme, modified to cleave in trans in the presence of the bronchodilator theophylline. In the intact substrate, the fluorophores interact by fluorescence resonance energy transfer (FRET). The specific FRET signal breaks down as the effector ligand binds, the substrate is cleaved, and the products dissociate, with a rate constant dependent on the concentration of the ligand. Our biosensor cleaves substrate at 0.46 min(-1) in 1 mM theophylline and 0.04 min(-1) without effector, and discriminates against caffeine, a structural relative of theophylline. We have measured the theophylline-dependence profile of this biosensor, showing that concentrations as low as 1 microM can be distinguished from background. To probe the mechanism of allosteric regulation, a single nucleotide in the communication domain between the catalytic and ligand-binding domains was mutated to destabilize the inactive conformation of the ribozyme. As predicted, this mutant shows the same activity (0.3 min(-1)) in the presence and absence of theophylline. Additionally, time-resolved FRET measurements on the biosensor ribozyme in complex with a noncleavable substrate analog reveal no significant changes in fluorophore distance distribution upon binding of effector.     

Intracellular ribozyme-catalyzed trans-cleavage of RNA monitored by fluorescence resonance energy transfer

Small catalytic RNAs like the hairpin ribozyme are proving to be useful intracellular tools; however, most attempts to demonstrate trans-cleavage of RNA by ribozymes in cells have been frustrated by rapid cellular degradation of the cleavage products. Here, we describe a fluorescence resonance energy transfer (FRET) assay that directly monitors cleavage of target RNA in tissue-culture cells. An oligoribonucleotide substrate was modified to inhibit cellular ribonuclease degradation without interfering with ribozyme cleavage, and donor (fluorescein) and acceptor (tetramethylrhodamine) fluorophores were introduced at positions flanking the cleavage site. In simple buffers, the intact substrate produces a strong FRET signal that is lost upon cleavage, resulting in a red-to-green shift in dominant fluorescence emission. Hairpin ribozyme and fluorescent substrate were microinjected into murine fibroblasts under conditions in which substrate cleavage can occur only inside the cell. A strong FRET signal was observed by fluorescence microscopy when substrate was injected, but rapid decay of the FRET signal occurred when an active, cognate ribozyme was introduced with the substrate. No acceleration in cleavage rates was observed in control experiments utilizing a noncleavable substrate, inactive ribozyme, or an active ribozyme with altered substrate specificity. Subsequently, the fluorescent substrates were injected into clonal cell lines that expressed cognate or noncognate ribozymes. A decrease in FRET signal was observed only when substrate was microinjected into cells expressing its cognate ribozyme. These results demonstrate trans-cleavage of RNA within mammalian cells, and provide an experimental basis for quantitative analysis of ribozyme activity and specificity within the cell.     

Rapid kinetic characterization of hammerhead ribozymes by real-time monitoring of fluorescence resonance energy transfer (FRET)

In established methods for analyzing ribozyme kinetics, radiolabeled RNA substrates are primarily used. Each data point requires the cumbersome sampling, gel electrophoretic separation, and quantitation of reaction products, apart from the continuous loss of substrate by radioactive decay. We have used stable, double fluorescent end-labeled RNA substrates. Fluorescence of one fluorophore is quenched by intramolecular energy transfer (FRET). Upon substrate cleavage, both dyes become separated in two RNA products and fluorescence is restored. This can be followed in real time and ribozyme reactions can be analyzed under multiple (substrate excess) and under single (ribozyme excess) turnover conditions. A detailed comparison of unlabeled, single, and double fluorescent-labeled RNAs revealed moderate kinetic differences. Results with two systems, hammerhead ribozymes in I/II (small ribozyme, large substrate) and in I/III format (large ribozyme, small substrate), are reported.     

RNA Catalyst as a Reporter for Screening Drugs against RNA Editing in Trypanosomes

Substantial progress has been made in determining the mechanism of mitochondrial RNA editing in trypanosomes. Similarly, considerable progress has been made in identifying the components of the editosome complex that catalyze RNA editing. However, it is still not clear how those proteins work together. Chemical compounds obtained from a high-throughput screen against the editosome may block or affect one or more steps in the editing cycle. Therefore, the identification of new chemical compounds will generate valuable molecular probes for dissecting the editosome function and assembly. In previous studies, in vitro editing assays were carried out using radio-labeled RNA. These assays are time consuming, inefficient and unsuitable for high-throughput purposes. Here, a homogenous fluorescence-based “mix and measure” hammerhead ribozyme in vitro reporter assay to monitor RNA editing, is presented. Only as a consequence of RNA editing of the hammerhead ribozyme a fluorescence resonance energy transfer (FRET) oligoribonucleotide substrate undergoes cleavage. This in turn results in separation of the fluorophore from the quencher thereby producing a signal. In contrast, when the editosome function is inhibited, the fluorescence signal will be quenched. This is a highly sensitive and simple assay that should be generally applicable to monitor in vitro RNA editing or high throughput screening of chemicals that can inhibit the editosome function.     

Enzymic hydrolysis of intramolecular complexes for monitoring theophylline in homogeneous competitive protein-binding reactions

A novel approach in the design of fluorogenic substrate-analyte conjugates that can be used in a substrate-labeled fluorescent immunoassay (SLFIA) is described. The new SLFIA uses an enzyme substrate molecule that contains a fluorophore component and a quencher component, separated by a chain containing a bond which can be hydrolyzed by an enzyme. The feasibility of using this approach, in the construction of a fluorophore-quencher-analyte conjugate for monitoring analytes in homogeneous competitive protein binding reactions was demonstrated by using flavin-N⁶-(6-aminohexyl-theophylline) adenine dinucleotide (FAD-Theophylline) as the intramolecularly quenched fluorogenic substrate. Hydrolysis of the FAD-theophylline by nucleotide pyrophosphatase yielding FMN and AMP-theophylline restores the fluorescence to the expected level of FMN. Antibody to theophylline, however, inhibits the enzymic hydrolysis, and this inhibition is relieved in competitive binding when theophylline is added.     

Characterization of deoxy- and ribo-containing oligonucleotide substrates in the hammerhead self-cleavage reaction

Deoxynucleotides were introduced into a substrate fragment of the hammerhead RNA self-cleaving domain. A substrate lacking the 2' hydroxyl adjacent to the cleavage site showed no detectable cleavage under a variety of reaction conditions. Competition experiments indicate that this fragment binds to the ribozyme with an affinity similar to the all RNA fragment, suggesting that the attacking 2' hydroxyl does not substantially contribute to the binding of substrate to ribozyme. Similar competition experiments with the all DNA substrate indicate a much lower affinity for the ribozyme perhaps due to the lack of other 2' hydroxyls. A substrate containing all deoxy residues except for a ribonucleotide at the cleavage site was also shown to be active.     

Leakage and slow allostery limit performance of single drug-sensing aptazyme molecules based on the hammerhead ribozyme

Engineered “aptazymes” fuse in vitro selected aptamers with ribozymes to create allosteric enzymes as biosensing components and artificial gene regulatory switches through ligand-induced conformational rearrangement and activation. By contrast, activating ligand is employed as an enzymatic cofactor in the only known natural aptazyme, the glmS ribozyme, which is devoid of any detectable conformational rearrangements. To better understand this difference in biosensing strategy, we monitored by single molecule fluorescence resonance energy transfer (FRET) and 2-aminopurine (AP) fluorescence the global conformational dynamics and local base (un)stacking, respectively, of a prototypical drug-sensing aptazyme, built from a theophylline aptamer and the hammerhead ribozyme. Single molecule FRET reveals that a catalytically active state with distal Stems I and III of the hammerhead ribozyme is accessed both in the theophylline-bound and, if less frequently, in the ligand-free state. The resultant residual activity (leakage) in the absence of theophylline contributes to a limited dynamic range of the aptazyme. In addition, site-specific AP labeling shows that rapid local theophylline binding to the aptamer domain leads to only slow allosteric signal transduction into the ribozyme core. Our findings allow us to rationalize the suboptimal biosensing performance of the engineered compared to the natural aptazyme and to suggest improvement strategies. Our single molecule FRET approach also monitors in real time the previously elusive equilibrium docking dynamics of the hammerhead ribozyme between several inactive conformations and the active, long-lived, Y-shaped conformer.     

Gating rearrangements in cyclic nucleotide-gated channels revealed by patch-clamp fluorometry

Site-specific fluorescence recordings have shown great promise in understanding conformational changes in signaling proteins. The reported applications on ion channels have been limited to extracellular sites in whole oocyte preparations. We are now able to directly monitor gating movements of the intracellular domains of cyclic nucleotide-gated channels using simultaneous site-specific fluorescence recording and patchclamp current recording from inside-out patches. Fluorescence signals were reliably observed when fluorophore was covalently attached to a site between the cyclic nucleotide-binding domain and the pore. While iodide, an anionic quencher, has a higher quenching efficiency in the channel's closed state, thallium ion, a cationic quencher, has a higher quenching efficiency in the open state. The state and charge dependence of quenching suggests movements of charged or dipolar residues near the fluorophore during CNG channel activation.     

Using molecular beacons as a sensitive fluorescence assay for enzymatic cleavage of single-stranded DNA

Traditional methods to assay enzymatic cleavage of DNA are discontinuous and time consuming. In contrast, recently developed fluorescence methods are continuous and convenient. However, no fluorescence method has been developed for single-stranded DNA digestion. Here we introduce a novel method, based on molecular beacons, to assay single-stranded DNA cleavage by single strand-specific nucleases. A molecular beacon, a hairpin-shaped DNA probe labeled with a fluorophore and a quencher, is used as the substrate and enzymatic cleavage leads to fluorescence enhancement in the molecular beacon. This method permits real time detection of DNA cleavage and makes it easy to characterize the activity of DNA nucleases and to study the steady-state cleavage reaction kinetics. The excellent sensitivity, reproducibility and convenience will enable molecular beacons to be widely useful for the study of single-stranded DNA cleaving reactions.     

Fluorophore-quencher pair for monitoring protein motion

A fluorophore/quencher pair capable of detecting conformational changes of DNA-protein complexes is described. The system employs a fluorescent nucleoside analog 1,3-diaza-2-oxophenothiazine (tC) within duplex DNA and a non-fluorescent quencher (TEMPO) attached to an engineered cysteine residue of the protein. The straightforward labeling methodology allows for the placement of the fluorophore and quencher moieties at specific positions suited to studying the conformational change of interest. To illustrate the utility of the tC-TEMPO pair, we have monitored nucleotide-induced conformational changes of the Klenow fragment (KF) polymerase bound to duplex DNA. In this system, tC was incorporated in the primer strand of the duplex, adjacent to the 3′ end, while TEMPO was positioned at the end of the O-helix within the fingers domain of KF. Using steady-state fluorescence spectroscopy, we measured the quenching efficiency in a binary complex of tC-modified DNA and TEMPO-labeled KF and in ternary complexes containing cognate or non-cognate dNTP substrates. The quenching efficiency is significantly enhanced in the presence of a cognate dNTP, indicating that the O-helix has moved closer towards the DNA. In contrast, no significant tC quenching is observed in the presence of a non-cognate dNTP, indicating that the O-helix remains in a position that is beyond the distance reporting range of the tC-TEMPO pair. These results demonstrate that a cognate dNTP substrate induces a large conformational change of the O-helix, which can be sensitively detected using the tC-TEMPO pair. This fluorophore/quencher pair may be useful to study conformational changes associated with other DNA-enzyme complexes.     

Detection of an abasic site in RNA with stem-loop DNA beacons: application to an activity assay for Ricin Toxin A-Chain

The catalytic ability of Ricin Toxin A-Chain (RTA) to create an abasic site in a 14-mer stem-tetraloop RNA is exploited for its detection. RTA catalyzes the hydrolysis of the N-glycosidic bond of a specific adenosine in the GAGA tetraloop of stem-loop RNA. Thus, a 14-mer stem-loop RNA substrate containing an intact “GAGA” sequence can be discriminated from the product containing an abasic “GabGA” sequence by hybridization with a 14-mer DNA stem-loop probe sequence and following the fluorescent response of the heteroduplexes. Three DNA beacon probe designs are described. Beacon 1 probe is a stem-loop structure and has a fluorophore and a quencher covalently linked to the 5′- and 3′-ends. In this format the probe–substrate heteroduplex gives a fluorescent signal while the probe–product one remains quenched. Beacon 2 is a modified version of 1 and incorporates a pyrene deoxynucleoside for recognition of the abasic site. In this format both the substrate and product heteroduplexes give a fluorescent response. Beacon 3 utilizes a design where the fluorophore is on the substrate RNA sequence at its 5′-end while the quencher is on the probe DNA sequence at its 3′-end. In this format the fluorescence of the substrate–probe heteroduplex is quenched while that of the product–probe one is enhanced. The lower limit of detection with beacons is 14 ng/mL of RTA.     

A novel fluorogenic substrate for ribonucleases. Synthesis and enzymatic characterization.

The synthesis and enzymatic characterization of DUPAAA, a novel fluorogenic substrate for RNases of the pancreatic type is described. It consists of the dinucleotide uridylyl-3',5'-deoxyadenosine to which a fluorophore, o-aminobenzoic acid, and a quencher, 2,4-dinitroaniline, have been attached by means of phosphodiester linkages. Due to intramolecular quenching the intact substrate displayed very little fluorescence. Cleavage of the phosphodiester bond at the 3'-side of the uridylyl residue by RNase caused a 60-fold increase in fluorescence. This allowed the continuous and highly sensitive monitoring of enzyme activity. The substrate was turned over efficiently by RNases of the pancreatic type, but no cleavage was observed with the microbial RNase T1. Compared to the dinucleotide substrate UpA, the specificity constant with RNase A, RNase PL3 and RNase U(s) increased 6-, 18-, and 29-fold, respectively. These differences in increased catalytic efficiency most likely reflect differences in the importance of subsites on the enzyme in the binding of elongated substrates. Studies on the interactions of RNase inhibitor with RNase A using DUPAAA as a reporter substrate showed that it was well suited for monitoring this very tight protein-protein interaction using pre-steady-state kinetic methods.     

Sequence-specific endoribonuclease activity of the Tetrahymena ribozyme: enhanced cleavage of certain oligonucleotide substrates that form mismatched ribozyme-substrate complexes

A shortened form of the self-splicing intervening sequence RNA of Tetrahymena acts as a sequence-specific endoribonuclease. Specificity of cleavage is determined by Watson-Crick base pairing between the active site of the RNA enzyme (ribozyme) and its RNA substrate [Zaug, A. J., Been, M. D., & Cech, T. R. (1986) Nature (London) 324, 429-433]. Surprisingly, single-base changes in the substrate RNA 3 nucleotides preceding the cleavage site, giving a mismatched substrate-ribozyme complex, enhance the rate of cleavage. Mismatched substrates show up to a 100-fold increase in kcat and, in some cases, in kcat/Km. A mismatch introduced by changing a nucleotide in the active site of the ribozyme has a similar effect. Addition of 2.5 M urea or 3.8 M formamide or decreasing the divalent metal ion concentration from 10 to 2 mM reverses the substrate specificity, allowing the ribozyme to discriminate against the mismatched substrate. The effect of urea is to decrease kcat and kcat/Km for cleavage of the mismatched substrate; Km is not significantly affected at 0-2.5 M urea. Thus, progressive destabilization of ribozyme-substrate pairing by mismatches or by addition of a denaturant such as urea first increases the rate of cleavage to an optimum value and then decreases the rate.     

Cleavage of oligoribonucleotides by a ribozyme derived from the hepatitis delta virus RNA sequence.

A self-cleaving RNA sequence from hepatitis delta virus was modified to produce a ribozyme capable of catalyzing the cleavage of RNA in an intermolecular (trans) reaction. The delta-derived ribozyme cleaved substrate RNA at a specific site, and the sequence specificity could be altered with mutations in the region of the ribozyme proposed to base pair with the substrate. A substrate target size of approximately 8 nucleotides in length was identified. Octanucleotides containing a single ribonucleotide immediately 5' to the cleavage site were substrates for cleavage, and cleavage activity was significantly reduced only with a guanine base at that position. A deoxyribose 5' to the cleavage site blocked the reaction. These data are consistent with a proposed secondary structure for the self-cleaving form of the hepatitis delta virus ribozyme in which a duplex forms with sequences 3' to the cleavage site, and they support a proposed mechanism in which cleavage involves attack on the phosphorus at the cleavage site by the adjacent 2'-hydroxyl group.     

Fluorescence polarization for monitoring ribozyme reactions in real time

Fluorescence polarization has been used recently to monitor diverse macromolecular interactions. In this report, the application of fluorescence polarization has been extended to monitor ribozyme reactions in real time. With fluorescently labeled substrate RNAs, group I ribozyme ligation and hammerhead ribozyme cleavage reactions were studied by fluorescence polarization in substrate excess (multiple turnover) conditions. These results also show that fluorescently labeled RNAs remain active substrates for ribozymes. Furthermore, a direct comparison of fluorescence polarization with fluorescence resonance energy transfer showed that both techniques were comparable for monitoring ribozyme reactions.     

NMR analysis of tertiary interactions in HDV ribozymes.

Three variants of minimized hepatitis delta virus (HDV) RNA ribozyme systems designed on the basis of the "pseudoknot" model were synthesized and their tertiary interactions were analyzed by NMR spectroscopy. Rz-1 is a cis-acting ribozyme system (the cleaved form, 56-mer) in which stem IV is deleted from the active domain of genomic HDV RNA. Rz-1 was uniformly labeled with stable isotopes, 13C and 15N. Rz-2 is a trans-acting ribozyme system (substrate: 8-mer, the cytidine residue at the cleavage site is replaced by 2'-O-methylcytidine; enzyme: 16-mer plus 35-mer). Rz-2 was partially labeled with stable isotopes in guanosine residues of enzyme 35mer. Rz-4 is a trans-acting ribozyme system (substrate: 8mer, the cytidine residue at the cleavage site is replaced by 2'-O-methylcytidine; enzyme 53mer) which was designed by Perrotta and Been. Rz-4 has the same sequence and an extra loop closing stem IV. From 2D-NOESY and 2D-HSQC (except for Rz-4) spectra, it was suggested each ribozyme forms "pseudoknot" type structure in solution. Additionally, it was found that G38 of Rz-1, G28 and G29 of Rz-2 and Rz-4 form base-pairs. These novel base-pairs are observed in the crystal structure of a modified genomic HDV RNA. From temperature change experiment of Rz-2, the imino proton signal of G28 disappeared at 50 degrees C earlier than the other corresponding signals. Upon MgCl2 titration of Rz-2, this signal showed the largest shift.     

Extensive phosphorothioate substitution yields highly active and nuclease-resistant hairpin ribozymes.

The catalytic function of the hairpin ribozyme has been investigated by modification-interference analysis of both ribozyme and substrate, using ribonucleoside phosphorothioates. Thiophosphate substitutions in two ribozyme domains were examined by using a novel and highly efficient two-piece ribozyme assembled from two independently synthesized oligoribonucleotides. The catalytic proficiency of the two-piece construct (KM = 48 nM, kcat = 2.3 min-1) is nearly identical to that of the one-piece ribozyme. The two-piece ribozyme is essentially unaffected by substitution with thiophosphates 5' to all guanosines, cytidines, and uridines. In contrast, incorporation of multiple adenosine phosphorothioates in the 5' domain of the ribozyme decreases ribozyme activity by a factor of 25. Modification-interference experiments using ribozymes partially substituted with adenosine phosphorothioate suggest that thiophosphates 5' to A7, A9 and A10 interfere with cleavage to a greater extent than substitutions at other sites within the molecule, but the effect is modest. Within the substrate, phosphorothioate substitution does not directly interfere with cleavage, rather, increasing thiophosphate content decreases the stability of the ribozyme-substrate complex. We describe the construction of a hairpin ribozyme containing dinucleotide extensions at its 5' and 3' ends. Full substitution of this molecule with G and C phosphorothioates results in a ribozyme with greatly enhanced stability against cellular ribonucleases without significant loss of catalytic efficiency.     

Photocrosslinking detects a compact, active structure of the hammerhead ribozyme

The hammerhead ribozyme has been intensively studied for approximately 15 years, but its cleavage mechanism is not yet understood. Crystal structures reveal a Y-shaped molecule in which the cleavage site is not ideally aligned for an S(N)2 reaction and no RNA functional groups are positioned appropriately to perform the roles of acid and base or other functions in the catalysis. If the ribozyme folds to a more compact structure in the transition state, it probably does so only transiently. We have used photocrosslinking as a tool to trap hammerhead ribozyme-substrate complexes in various stages of folding. Results suggest that the two substrate residues flanking the cleavage site approach and stack upon two guanosines (G8 and G12) in domain 2, moving 10-15 A closer to domain 2 than they appear in the crystal structure. Most crosslinks obtained with the nucleotide analogues positioned in the ribozyme core are catalytically inactive; however, one cobalt(III) hexaammine-dependent crosslink of an unmodified ribozyme retains catalytic activity and confirms the close stacking of cleavage site residue C17 with nucleotide G8 in domain 2. These findings suggest that residues involved in the chemistry of hammerhead catalysis are likely located in that region containing G8 and G12.     

Ribozymes correctly cleave a model substrate and endogenous RNA in vivo

The alpha-sarcin domain of 28 S RNA in Xenopus oocytes is attacked by several catalytic toxins (e.g. alpha-sarcin and ricin) that abolish protein synthesis. We synthesized 6 ribozymes targeted to the alpha-sarcin domain and to an oligoribonucleotide (34-mer) that mimics this domain. Sarcin ribozyme 5 (SR5) efficiently cleaved after the CUC site in the synthetic 34-mer in vitro at 50 degrees C. SR5 also cut the same site when both substrate and ribozyme were coinjected or injected separately into oocytes at 18 degrees C. Correct cleavage in vivo was shown by isolating and sequencing the large cleavage fragment. The cleavage reaction appeared to function equally well in the oocyte nucleus and cytoplasm. SR5 also correctly cleaved endogenous 28 S RNA in oocytes, although cutting was much less efficient than with alpha-sarcin. We therefore demonstrated that a ribozyme specifically cuts both a model substrate and a cellular RNA in vivo. Earlier work showed that certain injected deoxyoligonucleotides complementary to the alpha-sarcin region abolish protein synthesis. Oocyte protein synthesis was also abolished by an SR5 containing a single G----U substitution that inactivates RNA catalysis, indicating that SR5's translational suppression was perhaps due to antisense function rather than ribozyme cleavage.     

Structure, folding and activity of the VS ribozyme: importance of the 2-3-6 helical junction

The VS nucleolytic ribozyme has a core comprising five helices organized by two three-way junctions. The ribozyme can act in trans on a hairpin-loop substrate, with which it interacts via tertiary contacts. We have determined that one of the junctions (2-3-6) undergoes two-stage ion-dependent folding into a stable conformation, and have determined the global structure of the folded junction using long-range distance restraints derived from fluorescence resonance energy transfer. A number of sequence variants in the junction are severely impaired in ribozyme cleavage, and there is good correlation between changes in activity and alteration in the folding of junction 2-3-6. These studies point to a special importance of G and A nucleotides immediately adjacent to helix II, and comparison with a similar junction of known structure indicates that this could adopt a guanine-wedge structure. We propose that the 2-3-6 junction organizes important aspects of the structure of the ribozyme to facilitate productive association with the substrate, and suggest that this results in an interaction between the substrate and the A730 loop to create the active complex.