Self-splicing of the Tetrahymena group I ribozyme without conserved base-triples

Efficient circularization of protein-encoding RNAs via a novel cis-splicing system

Circular RNAs (circRNAs) have emerged as a promising alternative to linear mRNA, owing to their unique properties and potential therapeutic applications, driving the development of novel approaches for their production. This study introduces a cis-splicing system that efficiently produces circRNAs by incorporating a ribozyme core at one end of the precursor, thereby eliminating the need for additional spacer elements between the ribozyme and the gene of interest (GOI). In this cis-splicing system, sequences resembling homologous arms at both ends of the precursor are crucial for forming the P9.0 duplex, which in turn facilitates effective self-splicing and circularization. We demonstrate that the precise recognition of the second transesterification site depends more on the structural characteristics of P9.0 adjacent to the ωG position than on the nucleotide composition of the P9.0-ωG itself. Further optimization of structural elements, like P10 and P1-ex, significantly improves circularization efficiency. The circRNAs generated through the cis-splicing system exhibit prolonged protein expression and minimal activation of the innate immune response. This study provides a comprehensive exploration of circRNA generation via a novel strategy and offers valuable insights into the structural engineering of RNA, paving the way for future advancements in circRNA-based applications.

Optimization of a novel biophysical model using large scale in vivo antisense hybridization data displays improved prediction capabilities of structurally accessible RNA regions

Current approaches to design efficient antisense RNAs (asRNAs) rely primarily on a thermodynamic understanding of RNA–RNA interactions. However, these approaches depend on structure predictions and have limited accuracy, arguably due to overlooking important cellular environment factors. In this work, we develop a biophysical model to describe asRNA–RNA hybridization that incorporates in vivo factors using large-scale experimental hybridization data for three model RNAs: a group I intron, CsrB and a tRNA. A unique element of our model is the estimation of the availability of the target region to interact with a given asRNA using a differential entropic consideration of suboptimal structures. We showcase the utility of this model by evaluating its prediction capabilities in four additional RNAs: a group II intron, Spinach II, 2-MS2 binding domain and glgC 5΄ UTR. Additionally, we demonstrate the applicability of this approach to other bacterial species by predicting sRNA–mRNA binding regions in two newly discovered, though uncharacterized, regulatory RNAs.

Generation and development of RNA ligase ribozymes with modular architecture through "design and selection"

In vitro selection with long random RNA libraries has been used as a powerful method to generate novel functional RNAs, although it often requires laborious structural analysis of isolated RNA molecules. Rational RNA design is an attractive alternative to avoid this laborious step, but rational design of catalytic modules is still a challenging task. A hybrid strategy of in vitro selection and rational design has been proposed. With this strategy termed “design and selection,” new ribozymes can be generated through installation of catalytic modules onto RNA scaffolds with defined 3D structures. This approach, the concept of which was inspired by the modular architecture of naturally occurring ribozymes, allows prediction of the overall architectures of the resulting ribozymes, and the structural modularity of the resulting ribozymes allows modification of their structures and functions. In this review, we summarize the design, generation, properties, and engineering of four classes of ligase ribozyme generated by design and selection.

The IStron CdISt1 of Clostridium difficile: molecular symbiosis of a group I intron and an insertion element

The IStron CdISt1 was first discovered as an insertion into the tcdA gene of the clinical isolate C34. It combines structural and functional properties of a group I intron at its 5'-end with those of an insertion element at its 3'-end. Up to date four different types could be found, mainly differing in their IS-element portions. Contrasting classical group I introns, CdISt1 is always integrated in ORFs encoding bacterial protein. In case CdISt1 had only the IS-element function such insertion would inactivate the protein encoded by the host gene. It is only due to the self-splicing activity of the group I intron parts that CdISt1 integration does not abolish protein function. Both elements seem to exist in molecular symbiosis and CdISt1 could thus be a prototype of a novel class of genetic elements. Moreover, integration of the CdISt1 into the genome could be advantageous for the bacterium, a motor function for evolution of bacterial proteins is discussed. In clinical practice CdISt1 might well serve as a tool for epidemiological studies of C. difficile infections.

Generation of a catalytic module on a self-folding RNA

It is theoretically possible to obtain a catalytic site of an artificial ribozyme from a random sequence consisting of a limited numbers of nucleotides. However, this strategy has been inadequately explored. Here, we report an in vitro selection technique that exploits modular construction of a structurally constrained RNA to acquire a catalytic site for RNA ligation from a short random sequence. To practice the selection, a sequence of 30 nucleotides was located close to the putative reaction site in a derivative of a naturally occurring self-folding RNA whose crystal structure is known. RNAs whose activity depended on the starting three-dimensional structure were selected with 3'-5' ligation specificity, indicating that the strategy can be used to acquire a variety of catalytic sites and other functional RNA modules.

Artificial modules for enhancing rate constants of a Group I intron ribozyme without a P4-P6 core element

In this paper we report newly selected artificial modules that enhance the kcat values comparable with or higher than those of the wild-type ribozyme with broad substrate specificity. The elements required for the catalysis of Group I intron ribozymes are concentrated in the P3-P7 domain of their core region, which consists of two conserved helical domains, P4-P6 and P3-P7. Previously, we reported the in vitro selection of artificial modules residing at the peripheral region of a mutant Group I ribozyme lacking P4-P6. We found that derivatives of the ribozyme containing the modules performed the reversal of the first step of the self-splicing reaction efficiently by using their affinity to the substrate RNA, although their kcat values and substrate specificity were uninfluenced and limited, respectively. The results show that it is possible to add a variety of new domains at the peripheral region that play a role comparable with that of the conserved P4-P6 domain.

Modular engineering of a Group I intron ribozyme

All Group I intron ribozymes contain a conserved core region consisting of two helical domains, P4-P6 and P3-P7. Recent studies have demonstrated that the elements required for catalysis are concentrated in the P3-P7 domain. We carried out in vitro selection experiments by using three newly constructed libraries on a variant of the T4 td Group I ribozyme containing only a P3-P7 domain in its core. Selected variants with new peripheral elements at L7.1, L8 or L9 after nine cycles efficiently catalyzed the reversal reaction of the first step of self-splicing. The variants from this selection contained a short sequence complementary to the substrate RNA without exception. The most active variant, which was 3-fold more active than the parental wild-type ribozyme, was developed from the second selection by employing a clone from the first selection. The results show that the P3-P7 domain can stand as an independent catalytic module to which a variety of new domains for enhancing the activity of the ribozyme can be added.

Relationship between the self-splicing activity and the solidity of the master domain of the Tetrahymena group I ribozyme

The highly conserved P3-P7 domain of the Group I intron ribozymes is known to contain essential elements, such as the binding site for the cofactor guanosine, required for conducting the splicing reaction. We investigated the domain of the Tetrahymena intron ribozyme and its variants in order to clarify the relationship between its stability and function. We found that the destabilization of the P3-P7 domain facilitates the active structure formation at high magnesium ion concentrations where the formation is retarded for the wild type. The destabilized domain also increases K(GTP)(m) although this can be compensated by increasing the concentration of Mg(2+), indicating that the stable domain is required for establishing a tight guanosine binding site. The results suggest that the stability of the domain affects the rate-limiting step in the RNA folding pathway and also regulates the efficiency of the splicing reaction.

Conserved base-pairings between C266-A268 and U307-G309 in the P7 of the Tetrahymena ribozyme is nonessential for the in vitro self-splicing reaction

P7 is highly conserved in Group I self-splicing intron ribozymes. This region is known to coordinate metal ions and bind a cofactor guanosine required for the self-splicing. To further investigate the fundamental role of the corresponding region in the Tetrahymena ribozyme, we attempted to identify minimal requirements for the base-paired region excluding the guanosine binding site. We discovered that a variety of sequences are eligible and its derivatives possessing extra nucleotide(s) can still conduct the first step of splicing, indicating that no particular base-pairing is essential in this region for conducting the reaction in vitro. The results provide two hypotheses for the fundamental role of this region: (i) if the region contains element(s) that are strictly required in the catalysis, they are not necessarily tightly fixed in the ribozyme and (ii) if not, its fundamental role may simply be to coordinate neighboring regions that are directly involved in the catalysis.