Characterization of Group I Introns in the Ribosomal RNA Internal Transcribed Spacers of Eight Orders of Sharks

Patil, Veena P.

17 November 2011

No description available.

Molecular Biology

Group I introns

Ribosomal RNA

Internal transcribed spacers

Probing stability, specificity, and modular structure in group I intron RNAs

Wan, Yaqi

03 February 2011

Many functional RNAs are required to fold into specific three-dimensional structures. A fundamental property of RNA is that its secondary structure and even some tertiary contacts are highly stable, which gives rise to independent modular RNA motifs and makes RNAs prone to adopting misfolded intermediates. Consequently, in addition to stabilizing the native structure relative to the unfolded species (defined here as stability), RNAs are faced with the challenge of stabilizing the native structure relative to alternative structures (defined as structural specificity). How RNAs have evolved to overcome these challenges is incompletely understood. Self-splicing group I introns have been used to study RNA structure and folding for decades. Among them, the Tetrahymena intron was the first discovered and has been studied extensively. In this work, we found that a version of the intron that was generated by in vitro selection for enhanced stability also displayed enhanced specificity against a stable misfolded structure that is globally similar to the native state, despite the absence of selective pressure to increase the energy gap between these structures. Further dissection suggests that the increased specificity against misfolding arises from two point mutations, which strengthen a local tertiary contact network that apparently cannot form in the misfolded conformation. Our results suggest that the structural rigidity and intricate networks of contacts inherent to structured RNAs can allow them to evolve exquisite structural specificity without explicit negative selection, even against closely-related alternative structures. To explore further how RNAs gain stability from intricate architectures, we examined a novel group I intron from red algae (Bangia). Biochemical methods and computational modeling suggest that this intron possesses general motifs of group IC1 introns but also forms an atypical tertiary contact, which has been reported previously in other subgroups and helps position the reactive helix at the active site. In the Bangia intron, the partners have been swapped relative to known group I RNAs that include this contact. This result underscores the modular nature of RNA motifs and provides insight into how structured RNAs can arrange helices and contacts in multiple ways to achieve and stabilize functional structures. / text

Group I ribozyme

RNA structure

Structural specificity

RNA folding

Bangia

RNA

Tetrahymena

Introns

Group I introns

The roles of CYT-18 in folding, misfolding and structural specificity of the Tetrahymena group I ribozyme

Chadee, Amanda Barbara

22 March 2011

Group I introns are structured RNAs that have been used extensively as model systems for RNA folding because they are experimentally tractable, yet complex enough to have folding challenges associated with larger RNAs. The Tetrahymena group I intron consists of a set of conserved core helices and a set of peripheral elements. Peripheral elements surround the core helices and form long range tertiary contacts between each other and to the core. Interestingly, a long-lived misfolded state is populated that has the same long range tertiary contacts as the native state but differs locally within the core. Our lab showed that the intact periphery is necessary to specify the correct core structure, as mutating tertiary contacts or removing the P5abc peripheral element dramatically destabilized the native ribozyme relative to the misfolded form. However, we also showed that the thermodynamic benefit peripheral structure provided is accompanied by kinetic liability in folding, apparently because native tertiary contacts formed by peripheral elements around the misfolded core must come apart to allow refolding of the misfolded RNA to the native state. In addition to peripheral elements, proteins also play a role in stabilizing the native structures of many group I introns. The CYT-18 protein, which occupies the same binding site as P5abc, stabilizes the functional structures of certain group I introns by using a set of insertions that are absent in other related bacterial and mitochondrial aminoacyl tRNA synthetases. Using the P5abc deletion variant of the Tetrahymena ribozyme, I sought to further define CYT-18 roles in RNA folding by probing its thermodynamic and kinetic effects on the native state formation relative to the misfolded state. I demonstrated that CYT-18, like P5abc, provided thermodynamic stability to the native state. However, unlike P5abc, CYT-18 had no apparent effect on the refolding kinetics, suggesting that a protein co-factor can stabilize the functional structure without acquiring the associated costs in RNA folding kinetics. Furthermore, I found that the mechanism of CYT-18 action appears to be distinct from P5abc. Disruption of the long-range contact P14, which is formed between P5c and L2 and is part of the network of peripheral contacts, dramatically weakened P5abc binding to the native ribozyme core by ~10⁸ fold. Interestingly, CYT-18 maintained specific and tight binding to these mutants, which suggests that CYT-18 does not rely on a circular network of contacts to specifically stabilize the native state. Instead, the specificity may arise from a more direct and intimate contact of CYT-18 with the ribozyme core. This study gives insight into an evolutionary advantage of protein co-factors in RNA folding; proteins may offer thermodynamic assistance without inhibiting folding kinetics. / text

Group I introns

Structured RNAs

RNA folding

Tetrahymena

Core helices

Peripheral elements

Tertiary contacts

Ribozyme

Evolutionary investigation of group I introns in nuclear ribosomal internal transcribed spacers in Neoselachii

Cooper, Lizette

29 November 2018

No description available.

Biology

Bioinformatics

Evolution and Development

Genetics

Wildlife Conservation

Sharks

Biology

Biochemistry

Genetics

Phylogenetics

DNA Alignments

RNA Structures

Group I introns

Internal transcribed spacers

Biochemical characterization of homing endonucleases encoded by fungal mitochondrial genomes

Guha, Tuhin

23 May 2014

The small ribosomal subunit gene of the Chaetomium thermophilum DSM 1495 is invaded by a nested intron at position mS1247, which is composed of a group I intron encoding a LAGLIDADG open reading frame interrupted by an internal group II intron. The first objective was to examine if splicing of the internal intron could reconstitute the coding regions and facilitate the expression of an active homing endonuclease. Using in vitro transcription assays, the group II intron was shown to self-splice only under high salt concentration. Both in vitro endonuclease and cleavage mapping assays suggested that the nested intron encodes an active homing endonuclease which cleaves near the intron insertion site. This composite arrangement hinted that the group II intron could be regulatory with regards to the expression of the homing endonuclease. Constructs were generated where the codon-optimized open reading frame was interrupted with group IIA1 or IIB introns. The concentration of the magnesium in the media sufficient for splicing was determined by the Reverse Transcriptase-Polymerase Chain Reaction analyses from the bacterial cells grown under various magnesium concentrations. Further, the in vivo endonuclease assay showed that magnesium chloride stimulated the expression of a functional protein but the addition of cobalt chloride to the growth media antagonized the expression. This study showed that the homing endonuclease expression in Escherichia coli can be regulated by manipulating the splicing efficiency of the group II introns which may have implications in genome engineering as potential ‘on/off switch’ for temporal regulation of homing endonuclease expression . Another objective was to characterize native homing endonucleases, cytb.i3ORF and I-OmiI encoded within fungal mitochondrial DNAs, which were difficult to express and purify. For these, an alternative approach was used where two compatible plasmids, HEase.pET28b (+)-kanamycin and substrate.pUC57-chloramphenicol, based on the antibiotic markers were maintained in Escherichia coli BL21 (DE3). The in vivo endonuclease assays demonstrated that these homing endonucleases were able to cleave the substrate plasmids when expressed, leading to the loss of the antibiotic markers and thereby providing an indirect approach to screen for potential active homing endonucleases before one invests effort into optimizing protein overexpression and purification strategies. / October 2016

Homing endonucleases

Small ribosomal subunit gene

Nested intron

Twintron

Ribozyme based molecular switch

Group I introns

Group II introns

Bioprospecting

Native homing endonuclease

Temporal regulation

Fungal mitochondrial DNA

Magnesium induction

Cobalt antagonization

DNA cutting enzymes

LAGLIDADG homing endonuclease

Splicing

Genome engineering