Selective 2′-hydroxyl acylation analyzed by primer extension (SHAPE) is a widely used technique for studying the structure and function of RNA molecules. It characterizes the flexibility of single nucleotides in the context of the local RNA structure. Here we describe the application of SHAPE-MaP (mutational profiling) to study different conformational states of the group II intron during the self-splicing reaction.Kink-turns are important RNA structural modules that facilitate long-range tertiary interactions and form binding sites for members of the L7Ae family of proteins. Present in a wide variety of functional RNAs, kink-turns play key organizational roles in many RNA-based cellular processes, including translation, modification, and tRNA biogenesis. It is important to determine the contribution of kink-turns to the overall architecture of resident RNAs, as these modules dictate ribonucleoprotein (RNP) assembly and function. This chapter describes a site-directed, hydroxyl radical-mediated footprinting strategy that utilizes L7Ae-tethered chemical nucleases to experimentally validate computationally identified kink-turns in any RNA and under a wide variety of conditions. The work plan described here uses the catalytic RNase P RNA as an example to provide a blueprint for using this footprinting method to map RNA-protein interactions in other RNP complexes.Ribozymes are RNAs that catalyze reactions. They occur in nature, and can also be evolved in vitro to catalyze novel reactions. This chapter provides detailed protocols for using inverse folding software to design a ribozyme sequence that will fold to a known ribozyme secondary structure and for testing the catalytic activity of the sequence experimentally. This protocol is able to design sequences that include pseudoknots, which is important as all naturally occurring full-length ribozymes have pseudoknots. The starting point is the known pseudoknot-containing secondary structure of the ribozyme and knowledge of any nucleotides whose identity is required for function. The output of the protocol is a set of sequences that have been tested for function. Using this protocol, we were previously successful at designing highly active double-pseudoknotted HDV ribozymes.Pseudoknots are important motifs for stabilizing the structure of functional RNAs. As an example, pseudoknotted hammerhead ribozymes are highly active compared to minimal ribozymes. The design of new RNA sequences that retain the function of a model RNA structure includes taking in account pseudoknots presence in the structure, which is usually a challenge for bioinformatics tools. Our method includes using “Enzymer,” a software for designing RNA sequences with desired secondary structures that may include pseudoknots. Enzymer implements an efficient stochastic search and optimization algorithm to sample RNA sequences from low ensemble defect mutational landscape of an initial design template to generate an RNA sequence that is predicted to fold into the desired target structure.Deoxyribozymes capable of catalyzing sequence-specific RNA cleavage have broad applications in biotechnology. find protocol In vitro selected RNA-cleaving deoxyribozymes normally contain two substrate-binding arms and a central catalytic core region. Here, we describe the systematic characterization and optimization of an RNA-cleaving deoxyribozyme with an unusually short left binding arm, and its special sequence requirement for its optimal catalytic activity.In vitro selection is an established approach to create artificial ribozymes with defined activities or to modify the properties of naturally occurring ribozymes. For the Varkud satellite ribozyme of Neurospora, an in vitro selection protocol based on its phosphodiester bond cleavage activity has not been previously reported. Here, we describe a simple protocol for cleavage-based in vitro selection that we recently used to identify variants of the Varkud satellite ribozyme able to target and cleave a non-natural stem-loop substrate derived from the HIV-1 TAR RNA. It allows quick selection of active ribozyme variants from the transcription reaction based on the size of the self-cleavage product without the need for RNA labeling. This results in a streamlined procedure that is easily adaptable to engineer ribozymes with new activities.The epsilon domain of Hepatitis B virus plays a crucial role in encapsidation of viral pregenomic RNA and its partial NMR structure has been determined. However, we recently described a potassium-dependent ribonucleolytic activity associated with this region, so that a 53 nt long RNA containing the epsilon domain could release itself and cleaved other RNAs. We describe here the experimental methodologies for setting up the reactions and outline a general strategy for initial demonstration of this self-cleaving ribozyme activity.Retrozymes are a novel family of non-autonomous retrotransposable elements that contain hammerhead ribozyme motifs. These retroelements are found widespread in eukaryotic genomes, with active copies present in many species, which rely on other autonomous transposons for mobilization. Contrary to other retrotransposons, transcription of retrozymes in vivo leads to the formation and accumulation of circular RNAs, which can be readily detected by RNA blotting. In this chapter, we describe the procedures needed to carry out the cloning of genomic retrozymes, and to detect by northern blot their circular RNA retrotransposition intermediates.Self-cleaving ribozymes are RNA molecules that catalyze a site-specific self-scission reaction. Analysis of self-cleavage is a crucial aspect of the biochemical study and understanding of these molecules. Here we describe a co-transcriptional assay that allows the analysis of self-cleaving ribozymes in different reaction conditions and in the presence of desired ligands and/or cofactors. Utilizing a standard T7 RNA polymerase in vitro transcription system under limiting Mg2+ concentration, followed by a 25-fold dilution of the reaction in desired conditions of self-cleavage (buffer, ions, ligands, pH, temperature, etc.) to halt the synthesis of new RNA molecules, allows the study of self-scission of these molecules without the need for purification or additional preparation steps, such as refolding procedures. Furthermore, because the transcripts are not denatured, this assay likely yields RNAs in conformations relevant to co-transcriptionally folded species in vivo.