Investigation of an unusual metal-RNA cluster in the P5abc subdomain of the group I intron

Burns, Shannon Naomi

12 April 2006

This dissertation focuses on the spectroscopic and thermodynamic characterization of the unusual metal-RNA cluster found in the P5abc subdomain of the Tetrahymena group I intron. The P5abc subdomain is a part of the P4-P6 domain found in the Tetrahymena thermophila group I intron selfsplicing RNA. From both X-ray crystal structures of the P4-P6 domain, a remarkable cluster of Mg2+ or Mn2+ ions was found in the P5abc subdomain (Cate et al. 1996; Juneau et al. 2001). It is believed that the metal ion core in the P5abc subdomain stabilizes the active conformation of the RNA (Cate et al. 1996). An understanding of the role of these metal ions in facilitating the correct structure of the P5abc subdomain provides insight into how metal ions help overcome the folding barriers of complex RNA structures. Under solution conditions, the properties of this uncommon metal ion core and its influence on the truncated P5abc subdomain structure have been investigated. Both EPR spectroscopy and thermal denaturation experiments have been employed to search for a spectroscopic signature of metal ion core formation and also determine the thermodynamic contribution of the metal ion core on the stability of the folded P5abc structure. A spectroscopic signature of metal ion core formation was assigned for the P5abc subdomain by EPR microwave power saturation studies. Power saturation studies of the P5abc subdomain, P4-P6 domain and corresponding mutants reveal that the addition of 5 equivalents of Mn2+ are required for the wild type P5abc subdomain to form the metal ion core under solution conditions in 0.1 M NaCl. Results from both domain and subdomain microwave power saturation studies suggest that this technique can be applied for detecting clustering of Mn2+ ions in other RNA structures. The thermodynamic consequence of this metal ion core was probed by thermal denaturation techniques including UV-Vis spectroscopy and differential scanning calorimetry (DSC). DSC experiments were utilized to directly determine the thermodynamic contribution of the metal ion core. This value was determined to be an average of ∆∆G of -5.3 kcal/mol and is consistent with ∆∆G values obtained for other RNA tertiary structures.

P5abc subdomain

Group I Intron

ribozymes

metal ions

spectroscopy

EPR

thermal denaturation

DSC

Characterization of folding and misfolding of the Tetrahymena thermophila group I ribozyme

Mitchell, David III

07 November 2013

The functions of many cellular RNAs require that they fold into specific three-dimensional native structures, which typically involves arranging secondary structure elements and stabilizing the folded structure with tertiary contacts. However, RNA folding is inherently complex, as most RNAs fold along pathways containing multiple intermediates, including some misfolded intermediates that can accumulate and persist. Our understanding of the origins and structures of misfolded forms and the resolution of misfolding remains limited. Here, we investigate folding of the Tetrahymena intron, an extensively studied RNA folding model system since its initial discovery decades ago. The ribozyme variant predominantly misfolds, and slow refolding to the native state requires extensive structural disruption. Paradoxically, the misfolded conformation contains extensive native structure and lacks incorrect secondary and tertiary contacts despite requiring displacement of a native helix, termed P3, with incorrect secondary structure to misfold. We propose a model for a new origin of RNA misfolding to resolve this paradox, wherein misfolded ribozyme contains within its core incorrect arrangement of two single-stranded segments, i.e. altered topology. This model predicts a requirement for P3 disruption to exchange the misfolded and native topologies. We mutated P3 to modulate its stability and used the ribozyme's catalytic activity to show that P3 is disrupted during the refolding transition. Furthermore, we demonstrate that unfolding of the peripheral tertiary contacts precedes disruption of P3 to allow the necessary structural transitions. We then explored the influence of topology on the pathways leading to the misfolded and native states. Our results suggest that P3 exists in an earlier pathway intermediate that resembles the misfolded conformation, and that P3 unfolds to allow a small yet significant fraction of ribozyme to avoid misfolding. Despite being on a path to misfolding, the decision to misfold depends upon the probability of disrupting P3 and exchanging topology at this intermediate. Additionally, we show that having a stable P3 in the unfolded ribozyme allows almost complete avoidance of misfolding. Together, these studies lead to a physical model for folding and misfolding of a large RNA that is unprecedented in its scope and detail. / text

Structured RNA

Group I intron

Catalytic RNA

RNA folding

RNA misfolding

RNA topology

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

INSIGHTS INTO ENZYMATIC MANIPULATIONS OF NUCLEIC ACIDS

Alexander, Rashada Corine

01 January 2005

This dissertation details three studies dealing with the manipulation of nucleicacids. In the first investigation, each of the four natural nucleobases were analyzed for theability to serve as a universal template at the ligation junction of a T4 DNA ligasereaction. This resulted in the first instance of sequence-independent ligation catalyzed byany DNA ligase. Although all of the nucleobases display universal templatingcapabilities, thymidine and guanosine provided the most effective results. In addition,lowered MgCl2 and ATP concentrations, as well as the inclusion of DMSO, also aided inthe sequence-independent ligation reported here. In the course of these studies, currentmethods of removing urea from denaturing-gel purified nucleic acids provedcumbersome. Therefore, in the second study simple butanol extraction was examined as ameans to eliminate urea from nucleic acid solutions. Stepwise butanol extraction was themost effective approach to solving this problem and provided a much needed techniquefor nucleic acid purification. This type of extraction also does not result in significantlosses of nucleic acid sample. The third study exploits the molecular recognition andcatalytic properties inherent in an autocatalytic group I intron to develop a ribozyme thatcan replace the 5' end of an RNA substrate with a different RNA. This 5' replacementsplicing reaction can potentially repair mutations on the 5' ends of RNA transcripts thatlead to a variety of genetic mutations. The model system was a common mutation in asmall model mimic of the k-ras gene in vitro, which predisposes individuals to lungcancer. This 5' replacement splicing reaction occurred in vitro using this small modelsystem; the reaction was also enhanced by the alteration of the molecular interactionsinvolved. The results and implications of each of these studies are detailed in thisdissertation.

MOLECULAR RECOGNITION PROPERTIES AND KINETIC CHARACTERIZATION OF TRANS EXCISION-SPLICING REACTION CATALYZED BY A GROUP I INTRON-DERIVED RIBOZYME

Sinha, Joy

01 January 2006

Group I introns belong to a class of large RNAs that catalyze their own excision from precursor RNA through a two-step process called self-splicing reaction. These self-splicing introns have often been converted into ribozymes with the ability site specifically cleave RNA molecules. One such ribozyme, derived from a self-splicing Pneumocystis carinii group I intron, has subsequently been shown to sequence specifically excise a segment from an exogenous RNA transcript through trans excision-splicing reaction.The trans excision-splicing reaction requires that the substrate be cleaved at two positions called the 5' and 3' splice sites. The sequence requirements at these splice sites were studied. All sixteen possible base pair combinations at the 5' splice site and the four possible nucleotides at the 3' splice site were tested for reactivity. It was found that all base pair combinations at the 5' splice site allow the first reaction step and seven out of sixteen combinations allow the second step to occur. Moreover, it was also found that non-Watson-Crick base pairs are important for 5' splice site recognition and suppress cryptic splicing. In contrast to the 5' splice site, 3' splice site absolutely requires a guanosine.The pathway of the trans excision-splicing reaction is poorly understood. Therefore, as an initial approach, a kinetic framework for the first step (5' cleavage) was established. The framework revealed that substrate binds at a rate expected for RNA-RNA helix formation. The substrate dissociates with a rate constant (0.9 min-1), similar to that for substrate cleavage (3.9 min-1). Following cleavage, the product dissociation is slower than the cleavage, making this step rate limiting for multiple-turnover reactions. Furthermore, evidence suggests that P10 helix forms after the 5' cleavage step and a conformational change exists between the two reaction steps of trans excision-splicing reaction. Combining the data presented herein and the prior knowledge of RNA catalysis, provide a much more detailed view of the second step of the trans excision-splicing reaction.These studies further characterize trans excision-splicing reaction in vitro and provide an insight into its reaction pathway. In addition, the results describe the limits ofthe trans excision-splicing reaction and suggest how key steps can be targeted for improvement using rational ribozyme design approach.

GROUP I INTRON-DERIVED RIBOZYME REACTIONS

Johnson, Ashley Kirtley

01 January 2005

Group I introns are catalytic RNAs capable of self-splicing out of RNA transcripts. Ribozymes derived from these group I introns are used to explore the molecular recognition properties involved in intron catalysis. New ribozyme reactions are designed based on the inherent ability of these ribozymes to perform site-specific nucleophilic attacks. This study explores the molecular recognition properties of group I intron-derived ribozyme reactions and describe a new ribozyme reaction involving molecular recognition properties previously not seen.We report the development, analysis, and use of a new combinatorial approach to analyze the substrate sequence dependence of suicide inhibition, cyclization, and reverse cyclization reactions catalyzed by a group I intron from the opportunistic pathogen Pneumocystis carinii. We demonstrate that the sequence specificity of these Internal Guide Sequence (IGS) mediated reactions is not high, suggesting that RNA targeting strategies which exploit tertiary interactions could have low specificity due to the tolerance of mismatched base pairs.A group I intron-derived ribozyme from P. carinii has been previously shown to bind an exogenous RNA substrate, splice-out an internal segment, and then ligate the two ends back together (the trans excision-splicing reaction). We now report that a group I intron derived ribozyme from the ciliate Tetrahymena thermophila can also perform the trans excision-splicing reaction, although not nearly as well as the P. carinii ribozyme.In addition, we discovered a new ribozyme reaction called trans insertion-splicing where the P. carinii ribozyme binds two exogenous RNA substrates and inserts one directly into the other. Although this reaction gives the reverse products of the trans excision-splicing reaction, the trans insertion-splicing reaction is not simply the reverse reaction. The ribozyme recognizes two exogenous substrates through more complex molecular recognition interactions than what has been previously seen in group I intron-derived ribozyme reactions. We give evidence for this new reaction mechanism composed of three steps, with intermediates attached to the ribozyme.

Molecular evidence for the antiquity of group I introns inter-rupting transfer RNA genes in cyanobacteria / Molecular Bestätigung des hohes Alters von introns in Cyanobakterien

Fewer, David

31 January 2002

No description available.

32 Biologie

WU

WV

Mathematics and Natural Science

group I intron

tRNA Gene

evolutionär alt

Chloroplasten

Cyanobakterie

Bakterien

Chroococcidiopsis

Schwester-Gruppen.

group I intron

tRNA genes

ancient

chloroplast

cyanobacteria

bacteria

Chroococcidiopsis

sister taxa

42.21

42.13

42.30

42.50

Evolution intraspécifique du génome et modes de reproduction générateurs de diversité génétique chez Agaricus bisporus / Intraspecific evolution of the genome and modes of reproduction generating genetic diversity in Agaricus bisporus

Jalalzadeh Moghaddam Shahri, Banafsheh

12 December 2014

Agaricus bisporus, le champignon de Paris, est un basidiomycète saprophytenaturellement présent dans la litière de cyprès (Cupressus macrocarpa). Il possède différentsmodes de reproduction. Pour étudier leur rôle dans la dynamique spatio-temporelle et l’évolutionde la diversité génétique au cours du temps, des dispositifs expérimentaux ont été mis en place.Dix souches sauvages d’Agaricus bisporus var. bisporus ont été sélectionnées, à partir de deuxpopulations françaises, sur leurs traits phénotypiques et génotypiques. L’étude de l’évolutionmoléculaire de leurs génomes a montré que, pour le génome mitochondrial, la mobilité desintrons de groupe I apparait comme la principale source de polymorphisme. Des taux desubstitution nucléotidique (nt) faibles ont été observés chez tous les types de séquencesmitochondriales (éléments mobiles, séquences géniques et inter géniques). Cette forteconservation, comparée avec les taux élevés de substitution nt des séquences nucléairessimilaires, contraste avec ce qui est généralement décrit dans l’évolution des séquencesfongiques. Des expériences de croisements entre sporocarpes et mycelia de souches sauvages ontété menées sur du compost, dans une chambre de culture, pour simuler l’implantation d’unepopulation naturelle. Pour les sporocarpes récoltés, les données montrent l’existence d’unphénomène parasexuel de Buller conduisant à des souches hybrides d’A. bisporus dans lachambre de culture et potentiellement dans la nature. Parallèlement, les mycelia de souchessauvages ont été introduits dans deux parcelles expérimentales de cyprès. L’analyse génotypiquedes sporocarpes récoltés la première année d’introduction n’a pas permis de mettre en évidencede souche hybride et les conditions climatiques de la seconde année n’ont pas permis d’obtenir defructification. Les dispositifs et outils mis au point doivent permettre un suivi génétique spatiotemporelde la population sur le long terme. / Agaricus bisporus, the button mushroom, is a saprophytic basidiomycete naturallyfound in cypress litter (Cupressus macrocarpa). It possesses different modes of reproduction. Tostudy their role in the spatio-temporal dynamics and in the evolution of the genetic diversity,experimental systems have been set up. Ten wild strains of Agaricus bisporus var. bisporus havebeen selected, from two french populations, on both phenotypic and genotypic traits. Themolecular evolution of their genomes has shown that, for the mitochondrial genome, group Iintron mobility was the main source of gene polymorphism. Low nucleotide (nt) substitutionrates were found in all types of mitochondrial sequences (mobile elements, genic and intergenicones). This stringent conservation of mitochondrial sequences, when compared with the high ntsubstitution rates of their nuclear counterparts, contrasts to what is widely accepted in fungalsequence evolution. Mating experiments between sporocarps and mycelia of wild strains wereconducted on compost in a room culture, to simulate the implantation of a natural population.Among the collected sporocarps, results indicate the occurrence of a parasexual Bullerphenomenon leading to hybrid strains of A. bisporus in room culture and putatively in the wild.In parallel, mycelia of the wild strains have been introduced in two experimental plots of cypress.Genotypic analysis of the sporocarps collected from these plots in the first year of introduction,failed to evidence a hybrid strain. The climatic conditions of the second year did not allowobtaining fruiting-bodies. The developed experimental systems and tools must allow a followingat the genetic level of the spatio-temporal evolution of the population.

Basidiomycota

Intron de groupe I

SNP

Population sauvage

Phénomène de Buller

Basidiomycota

Group I intron

SNP

Wild population

Buller phenomenon

A survey of blue-stain fungi in Northwestern Ontario and characterization of mobile introns in ribosomal DNA

Rudski, Shelly Marie

02 September 2011

This work presents a survey of blue-stain fungi found in Northwestern Ontario, characterization of a homing endonuclease gene within Grosmannia piceiperda and finally an examination of the introns and homing endonuclease genes found in the large ribosomal subunit gene in species of Ceratocystis; using molecular techniques and phylogenetic analysis, we studied the molecular evolution of these mobile genetic elements. The blue-stain fungi of Northwestern Ontario were identified based on phylogenic analysis of rDNA internal transcribed spacer region sequences. This data was supplemented with morphological characteristics of the fungal cultures. The second project was an examination of a LAGLIDADG homing endonuclease and its IC2 group I intron. This intron is uniquely positioned within the group I intron-encoded rps3 gene of the large subunit ribosomal RNA gene. The final chapter is an investigation of the large subunit ribosomal RNA gene in species of Ceratocystis. The 3’ segment of this gene contains several novel introns and homing endonuclease genes. There is also much diversity between strains despite their close relation on the rDNA internal transcribed spacer region phylogenetic tree. Further, our data also suggest that the single motif LAGLIDADG homing endonuclease of the rDNA mL1923 intron is likely to be an ancestor to other homing endonucleases in the area. The results of these studies demonstrate the role that these elements play in the genetic diversity observed in the blue-stain fungi.

group I intron

group II intron

homing endonuclease gene

LAGLIDADG

GIY-YIG

ophiostomatoid fungi

blue-stain fungi

A survey of blue-stain fungi in Northwestern Ontario and characterization of mobile introns in ribosomal DNA

Rudski, Shelly Marie

02 September 2011

This work presents a survey of blue-stain fungi found in Northwestern Ontario, characterization of a homing endonuclease gene within Grosmannia piceiperda and finally an examination of the introns and homing endonuclease genes found in the large ribosomal subunit gene in species of Ceratocystis; using molecular techniques and phylogenetic analysis, we studied the molecular evolution of these mobile genetic elements. The blue-stain fungi of Northwestern Ontario were identified based on phylogenic analysis of rDNA internal transcribed spacer region sequences. This data was supplemented with morphological characteristics of the fungal cultures. The second project was an examination of a LAGLIDADG homing endonuclease and its IC2 group I intron. This intron is uniquely positioned within the group I intron-encoded rps3 gene of the large subunit ribosomal RNA gene. The final chapter is an investigation of the large subunit ribosomal RNA gene in species of Ceratocystis. The 3’ segment of this gene contains several novel introns and homing endonuclease genes. There is also much diversity between strains despite their close relation on the rDNA internal transcribed spacer region phylogenetic tree. Further, our data also suggest that the single motif LAGLIDADG homing endonuclease of the rDNA mL1923 intron is likely to be an ancestor to other homing endonucleases in the area. The results of these studies demonstrate the role that these elements play in the genetic diversity observed in the blue-stain fungi.

group I intron

group II intron

homing endonuclease gene

LAGLIDADG

GIY-YIG

ophiostomatoid fungi

blue-stain fungi