David Rueda

Single-molecule transition-state analysis of RNA folding

How RNA molecules fold into functional structures is a problem of great significance given the expanding list of essential cellular RNA enzymes and the increasing number of applications of RNA in biotechnology and medicine. A critical step toward solving the RNA folding problem is the characterization of the associated transition states. This is a challenging task in part because the rugged energy landscape of RNA often leads to the coexistence of multiple distinct structural transitions. Here, we exploit single-molecule fluorescence spectroscopy to follow in real time the equilibrium transitions between conformational states of a model RNA enzyme, the hairpin ribozyme. We clearly distinguish structural transitions between effectively noninterchanging sets of unfolded and folded states and characterize key factors defining the transition state of an elementary folding reaction where the hairpin ribozymes two helical domains dock to make several tertiary contacts. Our single-molecule experiments in conjunction with site-specific mutations and metal ion titrations show that the two RNA domains are in a contact or close-to-contact configuration in the transition state even though the native tertiary contacts are at most partially formed. Such a compact transition state without well formed tertiary contacts may be a general property of elementary RNA folding reactions.

A rugged free energy landscape separates multiple functional RNA folds throughout denaturation

The dynamic mechanisms by which RNAs acquire biologically functional structures are of increasing importance to the rapidly expanding fields of RNA therapeutics and biotechnology. Large energy barriers separating misfolded and functional states arising from alternate base pairing are a well-appreciated characteristic of RNA. In contrast, it is typically assumed that functionally folded RNA occupies a single native basin of attraction that is free of deeply dividing energy barriers (ergodic hypothesis). This assumption is widely used as an implicit basis to interpret experimental ensemble-averaged data. Here, we develop an experimental approach to isolate persistent sub-populations of a small RNA enzyme and show by single molecule fluorescence resonance energy transfer (smFRET), biochemical probing and high-resolution mass spectrometry that commitment to one of several catalytically active folds occurs unexpectedly high on the RNA folding energy landscape, resulting in partially irreversible folding. Our experiments reveal the retention of molecular heterogeneity following the complete loss of all native secondary and tertiary structure. Our results demonstrate a surprising longevity of molecular heterogeneity and advance our current understanding beyond that of non-functional misfolds of RNA kinetically trapped on a rugged folding-free energy landscape.

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.

Fluorescent energy transfer readout of an aptazyme-based biosensor.

Biosensors are devices that amplify signals generated from the specific interaction between a receptor and an analyte of interest. RNA structural motifs called aptamers have recently been discovered as receptor components for biosensors owing to the ease with which they can be evolved in vitro to bind a variety of ligands with high specificity and affinity. By coupling an aptamer as allosteric control element to a catalytic RNA such as the hammerhead ribozyme, ligand binding is transduced into a catalytic event. We have made use of fluorescence resonance energy transfer (FRET) to further amplify ligand induced catalysis into an easily detectable fluorescence signal. This chapter reviews in detail the methods and protocols to prepare a theophylline specific aptazyme and to label its substrate with fluorophores. We also include detailed protocols to characterize by FRET the binding affinity of the target, theophylline, as well as the external substrate to the aptazyme. The chapter should therefore facilitate the implementation of RNA-based biosensor components for other analytes of interest.