Your search keyword '"Pyle, A M"' showing total 23 results

1. Control of branch-site choice by a group II intron.

Author

Chu VT, Adamidi C, Liu Q, Perlman PS, and Pyle AM

Subjects

Base Sequence, Hydrolysis, Kinetics, Models, Biological, Molecular Sequence Data, Mutation, Phylogeny, Plasmids metabolism, RNA, Messenger metabolism, DNA Replication, Introns, Nucleic Acid Conformation, RNA Splicing, RNA, Catalytic chemistry, Spliceosomes chemistry

Abstract

The branch site of group II introns is typically a bulged adenosine near the 3'-end of intron domain 6. The branch site is chosen with extraordinarily high fidelity, even when the adenosine is mutated to other bases or if the typically bulged adenosine is paired. Given these facts, it has been difficult to discern the mechanism by which the proper branch site is chosen. In order to dissect the determinants for branch-point recognition, new mutations were introduced in the vicinity of the branch site and surrounding domains. Single mutations did not alter the high fidelity for proper branch-site selection. However, several combinations of mutations moved the branch site systematically to new positions along the domain 6 stem. Analysis of those mutants, together with a new alignment of domain 5 and domain 6 sequences, reveals a set of structural determinants that appear to govern branch-site selection by group II introns.

Published

2001

2. Visualizing the solvent-inaccessible core of a group II intron ribozyme.

Author

Swisher J, Duarte CM, Su LJ, and Pyle AM

Subjects

Base Sequence, Catalytic Domain, Hydroxyl Radical, Models, Molecular, Molecular Sequence Data, Nucleic Acid Conformation, Solvents, Introns, RNA, Catalytic chemistry

Abstract

Group II introns are well recognized for their remarkable catalytic capabilities, but little is known about their three-dimensional structures. In order to obtain a global view of an active enzyme, hydroxyl radical cleavage was used to define the solvent accessibility along the backbone of a ribozyme derived from group II intron ai5gamma. These studies show that a highly homogeneous ribozyme population folds into a catalytically compact structure with an extensively internalized catalytic core. In parallel, a model of the intron core was built based on known tertiary contacts. Although constructed independently of the footprinting data, the model implicates the same elements for involvement in the catalytic core of the intron.

Published

2001

3. Guiding ribozyme cleavage through motif recognition: the mechanism of cleavage site selection by a group ii intron ribozyme.

Author

Su LJ, Qin PZ, Michels WJ, and Pyle AM

Subjects

Base Pair Mismatch, Base Pairing, Base Sequence, Binding Sites, Cations, Divalent metabolism, Exons genetics, Kinetics, Models, Genetic, Mutation genetics, RNA Precursors chemistry, RNA Precursors genetics, RNA, Catalytic classification, Single-Strand Specific DNA and RNA Endonucleases metabolism, Substrate Specificity, Thermodynamics, Introns genetics, RNA Precursors metabolism, RNA, Catalytic genetics, RNA, Catalytic metabolism

Abstract

The mechanism by which group II introns cleave the correct phosphodiester linkage was investigated by studying the reaction of mutant substrates with a ribozyme derived from intron ai5gamma. While fidelity was found to be quite high in most cases, a single mutation on the substrate (+1C) resulted in a dramatic loss of fidelity. When this mutation was combined with a second mutation that induces a bulge in the exon binding site 1/intron binding site 1 (EBS1/IBS1) duplex, the base-pairing register of the EBS1/IBS1 duplex was shifted and the cleavage site moved to a downstream position on the substrate. Conversely, when mismatches were incorporated at the EBS1/IBS1 terminus, the duplex was effectively truncated and cleavage occurred at an upstream site. Taken together, these data demonstrate that the cleavage site of a group II intron ribozyme can be tuned at will by manipulating the thermodynamic stability and structure of the EBS1/IBS1 pairing. The results are consistent with a model in which the cleavage site is not designated through recognition of specific nucleotides (such as the 5'-terminal residue of EBS1). Instead, the ribozyme detects a structure at the junction between single and double-stranded residues on the bound substrate. This finding explains the puzzling lack of phylogenetic conservation in ribozyme and substrate sequences near group II intron target sites., (Copyright 2001 Academic Press.)

Published

2001

4. Kinetic dissection of the multistep process in L1.ltrB intron mobility.

Author

Aizawa Y, Xiang Q, and Pyle AM

Subjects

DNA genetics, DNA metabolism, Kinetics, RNA genetics, RNA metabolism, RNA Splicing, Recombination, Genetic, Ribonucleoproteins metabolism, Introns

Abstract

A kinetic characterization is presented for intron insertion into a target duplex DNA site during L1.ltrB intron mobility. This reaction is catalyzed by a ribonucleoprotein particle (RNP), consisting of a lariat form of group II intron RNA and the intron-encoded LtrA protein. In the first stage of intron mobility, the RNA component of the enzyme by itself inserts directly into the target ds DNA site, and thus, the RNP enzyme does not carry out turnover. Using single-turnover kinetics, we established an in vitro kinetic assay system and investigated mechanism of the intron RNA insertion process.

Published

2001

5. Metal ion binding sites in a group II intron core.

Author

Sigel RK, Vaidya A, and Pyle AM

Subjects

Base Sequence, Binding Sites, Catalysis, Cations metabolism, Conserved Sequence genetics, Exons genetics, Lead metabolism, Lutetium metabolism, Magnesium metabolism, Molecular Sequence Data, RNA Splice Sites genetics, RNA, Catalytic genetics, Substrate Specificity, Terbium metabolism, Introns genetics, Metals metabolism, Nucleic Acid Conformation, RNA, Catalytic chemistry, RNA, Catalytic metabolism

Abstract

Group II introns are catalytic RNA molecules that require divalent metal ions for folding, substrate binding, and chemical catalysis. Metal ion binding sites in the group II core have now been elucidated by monitoring the site-specific RNA hydrolysis patterns of bound ions such as Tb(3+) and Mg(2+). Major sites are localized near active site elements such as domain 5 and its surrounding tertiary interaction partners. Numerous sites are also observed at intron substructures that are involved in binding and potentially activating the splice sites. These results highlight the locations of specific metal ions that are likely to play a role in ribozyme catalysis.

Published

2000

6. A tertiary interaction that links active-site domains to the 5' splice site of a group II intron.

Author

Boudvillain M, de Lencastre A, and Pyle AM

Subjects

Base Pairing, Catalytic Domain, Conserved Sequence, Introns genetics, Mutation, Nucleic Acid Conformation, Plasmids, RNA, Catalytic genetics, Introns physiology, RNA, Catalytic physiology

Abstract

Group II introns are self-splicing RNAs that are commonly found in the genes of plants, fungi, yeast and bacteria. Little is known about the tertiary structure of group II introns, which are among the largest natural ribozymes. The most conserved region of the intron is domain 5 (D5), which, together with domain 1 (D1), is required for all reactions catalysed by the intron. Despite the importance of D5, its spatial relationship and tertiary contacts to other active-site constituents have remained obscure. Furthermore, D5 has never been placed directly at a site of catalysis by the intron. Here we show that a set of tertiary interactions (lambda-lambda') links catalytically essential regions of D5 and D1, creating the framework for an active-site and anchoring it at the 5' splice site. Highly conserved elements similar to components of the lambda-lambda' interaction are found in the eukaryotic spliceosome.

Published

2000

7. New tricks from an itinerant intron.

Author

Pyle AM

Subjects

Catalysis, Genome, Bacterial, Introns physiology, Lactococcus lactis genetics, Mutagenesis, Insertional genetics, Recombination, Genetic genetics, Retroelements physiology, Introns genetics, RNA, Catalytic genetics, RNA, Catalytic metabolism, Retroelements genetics

Published

2000

8. Antagonistic substrate binding by a group II intron ribozyme.

Author

Qin PZ and Pyle AM

Subjects

Binding Sites, Catalysis, Mutation, Nucleic Acid Conformation, RNA Splicing, RNA, Catalytic antagonists & inhibitors, RNA, Catalytic chemistry, Substrate Specificity, Thermodynamics, Introns, RNA, Catalytic metabolism

Abstract

In this study, the thermodynamic properties of substrate-ribozyme recognition were explored using a system derived from group II intron ai5gamma. Substrate recognition by group II intron ribozymes is of interest because any nucleic ac?id sequence can be targeted, the recognition sequence can be quite long (>/=13 bp), and reaction can proceed with a very high degree of sequence specificity. Group II introns target their substrates throug?h the formation of base-pairing interactions with two regions of the intron (EBS1 and EBS2), which are usually located far apart in the secondary structure. These structures pair with adjacent, corresponding sites (IBS1 and IBS2) on the substrate. In order to understand the relative energetic contribution of each base-pairing interaction (EBS1-IBS1 or EBS2-IBS2) to substrate binding energy, the free energy of each helix was measured. The individual helices were found to have base-pairing free energies similar to those calculated for regular RNA duplexes of the same sequence, suggesting that each recognition helix derives its binding energy from base-pairing interactions alone and that each helix can form independently. Most interestingly, it was found that the sum of the measured individual free energies (approximately 20 kcal/mol) was much higher than the known free energy for substrate binding (approximately 12 kcal/mol). This indicates that certain group II intron ribozymes can bind their substrates in an antagonistic fashion, paying a net energetic penalty upon binding the full-length substrate. This loss of binding energy is not due to weakening of individual helices, but appears to be linked to ribozyme conformational changes induced by substrate binding. This coupling between substrate binding and ribozyme conformational rearrangement may provide a mechanism for lowering overall substrate binding energy while retaining the full information content of 13 bp, thus resulting in a mechanism for ensuring sequence specificity., (Copyright 1999 Academic Press.)

Published

1999

9. Defining functional groups, core structural features and inter-domain tertiary contacts essential for group II intron self-splicing: a NAIM analysis.

Author

Boudvillain M and Pyle AM

Subjects

Base Sequence, Calibration, Hydrolysis, Molecular Sequence Data, Mutagenesis, Introns, Nucleic Acid Conformation, RNA chemistry, RNA Splicing

Abstract

Group II introns are self-splicing RNA molecules that are of considerable interest as ribozymes, mobile genetic elements and examples of folded RNA. Although these introns are among the most common ribozymes, little is known about the chemical and structural determinants for their reactivity. By using nucleotide analog interference mapping (NAIM), it has been possible to identify the nucleotide functional groups (Rp phosphoryls, 2'-hydroxyls, guanosine exocyclic amines, adenosine N7 and N6) that are most important for composing the catalytic core of the intron. The majority of interference effects occur in clusters located within the two catalytically essential Domains 1 and 5 (D1 and D5). Collectively, the NAIM results indicate that key tetraloop-receptor interactions display a specific chemical signature, that the epsilon-epsilon' interaction includes an elaborate array of additional features and that one of the most important core structures is an uncharacterized three-way junction in D1. By combining NAIM with site-directed mutagenesis, a new tertiary interaction, kappa-kappa', was identified between this region and the most catalytically important section of D5, adjacent to the AGC triad in stem 1. Together with the known zeta-zeta' interaction, kappa-kappa' anchors D5 firmly into the D1 scaffold, thereby presenting chemically essential D5 functionalities for participation in catalysis.

Published

1998

10. A map of the binding site for catalytic domain 5 in the core of a group II intron ribozyme.

Author

Konforti BB, Liu Q, and Pyle AM

Subjects

Base Sequence, Binding Sites, Catalysis, Chromosome Mapping, Evaluation Studies as Topic, Kinetics, Molecular Sequence Data, Electron Transport Complex IV genetics, Introns, Nucleic Acid Conformation, RNA, Catalytic chemistry, Saccharomyces cerevisiae enzymology

Abstract

Group II introns are ribozymes with a complex tertiary architecture that is of great interest as a model for RNA folding. Domain 5 (D5) is a highly conserved region of the intron that is considered one of the most critical structures in the catalytic core. Despite its central importance, the means by which D5 interacts with other core elements is unclear. To obtain a map of potential interaction sites, dimethyl sulfate was used to footprint regions of the intron that are involved in D5 binding. These studies were complemented by measurements of D5 binding to a series of truncated intron derivatives. In this way, the minimal region of the intron required for strong D5 association was defined and the sites most likely to represent thermodynamically significant positions of tertiary contact were identified. These studies show that ground-state D5 binding is mediated by tertiary contacts to specific regions of D1, including a tetraloop receptor and an adjacent three-way junction. In contrast, D2 and D3 are not found to stabilize D5 association. These data highlight the significance of D1-D5 interactions and will facilitate the identification of specific tertiary contacts between them.

Published

1998

11. More than one way to splice an RNA: branching without a bulge and splicing without branching in group II introns.

Author

Chu VT, Liu Q, Podar M, Perlman PS, and Pyle AM

Subjects

Adenosine genetics, Base Sequence, Endoribonucleases, Kinetics, Models, Genetic, Point Mutation, RNA genetics, Sequence Analysis, RNA, Sequence Deletion, Introns, Nucleic Acid Conformation, RNA chemistry, RNA Splicing genetics

Abstract

Domain 6 (D6) of group II introns contains a bulged adenosine that serves as the branch-site during self-splicing. In addition to this adenosine, other structural features in D6 are likely to contribute to the efficiency of branching. To understand their role in promoting self-splicing, the branch-site and surrounding nucleotides were mutagenized. Detailed kinetic analysis on the self-splicing efficiency of the mutants revealed several interesting features. First, elimination of the branch-site does not preclude efficient splicing, which takes place instead through a hydrolytic first step. Second, pairing of the branch-site does not eliminate branching, particularly if the adenosine is involved in a mispair. Third, the G-U pairs that often surround group II intron branch-points contribute to the efficiency of branching. These results suggest that there is a strong driving force for promoting self-splicing by group II introns, which employ a versatile set of different mechanisms for ensuring that splicing is successful. In addition, the behavior of these mutants indicates that a bulged adenosine per se is not the important determinant for branch-site recognition in group II introns. Rather, the data suggest that the branch-site adenosine is recognized as a flipped base, a conformation that can be promoted by a variety of different substructures in RNA and DNA.

Published

1998

12. The architectural organization and mechanistic function of group II intron structural elements.

Author

Qin PZ and Pyle AM

Subjects

Animals, Base Sequence, Conserved Sequence, Molecular Sequence Data, RNA Splicing, Introns, Nucleic Acid Conformation, RNA chemistry, RNA genetics

Abstract

Group II introns are large, self-splicing RNAs and mobile genetic elements that provide good model systems for studies of RNA folding. The structures and mechanistic functions of individual domains are being elucidated, and long-range tertiary interactions between the domains are being identified, thus helping to define the three-dimensional architecture of the intron.

Published

1998

13. Sequence specificity of a group II intron ribozyme: multiple mechanisms for promoting unusually high discrimination against mismatched targets.

Author

Xiang Q, Qin PZ, Michels WJ, Freeland K, and Pyle AM

Subjects

Base Composition genetics, Base Sequence, Binding Sites genetics, Energy Transfer genetics, Kinetics, Oligodeoxyribonucleotides metabolism, Substrate Specificity genetics, Introns genetics, Mutagenesis, Site-Directed, Nucleic Acid Conformation, RNA, Catalytic genetics

Abstract

Group II intron ai5 gamma was reconstructed into a multiple-turnover ribozyme that efficiently cleaves small oligonucleotide substrates in-trans. This construct makes it possible to investigate sequence specificity, since second-order rate constants (kcat/K(m), or the specificity constant) can be obtained and compared with values for mutant substrates and with other ribozymes. The ribozyme used in this study consists of intron domains 1 and 3 connected in-cis, together with domain 5 as a separate catalytic cofactor. This ribozyme has mechanistic features similar to the first step of reverse-splicing, in which a lariat intron attacks exogenous RNA and DNA substrates, and it therefore serves as a model for the sequence specificity of group II intron mobility. To quantitatively evaluate the sequence specificity of this ribozyme, the WT kcat/Km value was compared to individual kcat/Km values for a series of mutant substrates and ribozymes containing single base changes, which were designed to create mismatches at varying positions along the two ribozyme-substrate recognition helices. These mismatches had remarkably large effects on the discrimination index (1/relative kcat/K(m)), resulting in values > 10,000 in several cases. The delta delta G++ for mismatches ranged from 2 to 6 kcal/mol depending on the mismatch and its position. The high specificity of the ribozyme is attributable to effects on duplex stabilization (1-3 kcal/mol) and unexpectedly large effects on the chemical step of reaction (0.5-2.5 kcal/mol). In addition, substrate association is accompanied by an energetic penalty that lowers the overall binding energy between ribozyme and substrate, thereby causing the off-rate to be faster than the rate of catalysis and resulting in high specificity for the cleavage of long target sequences (> or = 13 nucleotides).

Published

1998

14. Group II intron splicing in vivo by first-step hydrolysis.

Author

Podar M, Chu VT, Pyle AM, and Perlman PS

Subjects

Esterification, Genes, Fungal, Hydrolysis, Mitochondria metabolism, Mutagenesis, Site-Directed, RNA, Fungal metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Introns, RNA Splicing

Abstract

Group I, group II and spliceosomal introns splice by two sequential transesterification reactions. For both spliceosomal and group II introns, the first-step reaction occurs by nucleophilic attack on the 5' splice junction by the 2' hydroxyl of an internal adenosine, forming a 2'-5' phosphodiester branch in the intron. The second reaction joins the two exons with a 3'-5' phosphodiester bond and releases intron lariat. In vitro, group II introns can self-splice by an efficient alternative pathway in which the first-step reaction occurs by hydrolysis. The resulting linear splicing intermediate participates in normal second-step reactions, forming spliced exon and linear intron RNAs. Here we show that the group II intron first-step hydrolysis reaction occurs in vivo in place of transesterification in the mitochondria of yeast strains containing branch-site mutations. As expected, the mutations block branching, but surprisingly still allow accurate splicing. This hydrolysis pathway may have been a step in the evolution of splicing mechanisms.

Published

1998

15. Ribozyme catalysis from the major groove of group II intron domain 5.

Author

Konforti BB, Abramovitz DL, Duarte CM, Karpeisky A, Beigelman L, and Pyle AM

Subjects

Binding Sites physiology, Kinetics, Nucleotides chemistry, Protein Structure, Tertiary, RNA, Catalytic genetics, Introns physiology, Nucleic Acid Conformation, RNA Splicing genetics, RNA, Catalytic chemistry, RNA, Catalytic metabolism

Abstract

The most highly conserved nucleotides in D5, an essential active site component of group II introns, consist of an AGC triad, of which the G is invariant. To understand how this G participates in catalysis, the mechanistic contribution of its functional groups was examined. We observed that the exocyclic amine of G participates in ground state interactions that stabilize D5 binding from the minor groove. In contrast, each major groove heteroatom of the critical G (specifically N7 or O6) is essential for chemistry. Thus, major groove atoms in an RNA helix can participate in catalysis, despite their presumed inaccessibility. N7 or O6 of the critical G could engage in critical tertiary interactions with the rest of the intron or they could, together with phosphate oxygens, serve as a binding site for catalytic metal ions.

Published

1998

16. Stopped-flow fluorescence spectroscopy of a group II intron ribozyme reveals that domain 1 is an independent folding unit with a requirement for specific Mg2+ ions in the tertiary structure.

Author

Qin PZ and Pyle AM

Subjects

Base Sequence, Kinetics, Molecular Sequence Data, Nucleic Acid Conformation, Spectrometry, Fluorescence, Structure-Activity Relationship, Introns, Magnesium chemistry, RNA, Catalytic chemistry

Abstract

A stopped-flow fluorescence spectroscopic assay for RNA folding was used to monitor the association of a multicomponent ribozyme derived from group II intron ai5gamma. In the presence of Mg2+, association of a short fluorescein-labeled oligonucleotide substrate with intron domain 1 (D1) resulted in a unique fluorescein emission enhancement, which reflected ribozyme folding and substrate binding. It was found that substrate binding follows a simple bimolecular encounter model, with k(on) approaching the rate of simple duplex formation. The Kd between substrate and D1 was determined to be 11 nM, which is in close agreement with the Kd obtained through oligonucleotide cleavage assays requiring catalytic domain 5 (D5). Ribozyme variants D13 and D135, which contain D3 and/or D5 attached to D1 in-cis, bound substrate with very similar Kd values, suggesting that D1 can fold independently and contains all residues important for ground-state binding to substrate. Both stopped-flow fluorescence assays and chemical modification footprinting data showed that, in all three ribozymes, Mg2+ was required and sufficient for folding. The rates of substrate association and the fraction of active ribozyme showed similar [Mg2+] dependencies, indicating that folding and substrate binding in these three ribozymes are the result of similar processes involving specific, weakly bound Mg2+ ions. The apparent binding constants for the Mg2+ ions were found to be approximately 70 mM in each case. Together, these data show that D1 is an independent folding unit with respect to substrate binding and that specific Mg2+ ions are required for the formation of a distinct tertiary structure in group II introns.

Published

1997

17. Branch-site selection in a group II intron mediated by active recognition of the adenine amino group and steric exclusion of non-adenine functionalities.

Author

Liu Q, Green JB, Khodadadi A, Haeberli P, Beigelman L, and Pyle AM

Subjects

Binding Sites, Mutagenesis, Site-Directed, RNA Processing, Post-Transcriptional, RNA Splicing, RNA, Catalytic metabolism, Spliceosomes metabolism, Adenine chemistry, Introns, RNA, Catalytic chemistry

Abstract

The 2'-hydroxyl on a specific bulged adenosine is the nucleophile during the first step of splicing by group II introns. To understand the means by which the ribozyme core recognizes this adenosine, it was mutagenized and effects on catalytic activity were quantified. The results indicate that a low level of mutational variability is tolerated at the branch-site of group II introns, with no apparent loss of fidelity. Analyses of mutant and modified nucleotides at the branch-site reveal that adenine is recognized primarily through the N6 amino group and by steric exclusion of functionalities found on other bases. The mutational and single atom effects reported here contrast with those observed during spliceosomal processing, suggesting that there are important differences in adenosine recognition by the two systems.

Published

1997

18. Mobile genetic elements. Inside an intron invasion.

Author

Pyle AM

Subjects

Catalysis, RNA-Directed DNA Polymerase metabolism, Ribonucleoproteins metabolism, Transcription, Genetic, DNA genetics, DNA Transposable Elements, Introns, RNA genetics, Saccharomyces cerevisiae Proteins

Published

1996

19. Catalytic role of 2'-hydroxyl groups within a group II intron active site.

Author

Abramovitz DL, Friedman RA, and Pyle AM

Subjects

Base Composition, Base Sequence, Binding Sites, Catalysis, Exons, Hydrogen Bonding, Hydroxyl Radical chemistry, Kinetics, Models, Molecular, Molecular Sequence Data, Nucleic Acid Conformation, Oligoribonucleotides chemistry, Oligoribonucleotides metabolism, RNA metabolism, RNA, Catalytic chemistry, Introns, RNA, Catalytic metabolism

Abstract

Domain 5 is an essential active-site component of group II intron ribozymes. The role of backbone substituents in D5 function was explored through synthesis of a series of derivatives containing deoxynucleotides at each position along the D5 strand. Kinetic screens revealed that eight 2'-hydroxyl groups were likely to be critical for activity of D5. Through two separate methods, including competitive inhibition and direct kinetic analysis, effects on binding and chemistry were distinguished. Depending on their function, important 2'-hydroxyl groups lie on opposite faces of the molecule, defining distinct loci for molecular recognition and catalysis by D5.

Published

1996

20. Two competing pathways for self-splicing by group II introns: a quantitative analysis of in vitro reaction rates and products.

Author

Daniels DL, Michels WJ Jr, and Pyle AM

Subjects

Ammonium Chloride, Ammonium Sulfate, Hydrolysis, Kinetics, Magnesium Chloride, Models, Biological, Nucleic Acid Conformation, Osmolar Concentration, Potassium Chloride, RNA, Fungal chemistry, RNA, Fungal genetics, RNA, Fungal metabolism, Ribonucleases, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae metabolism, Introns, RNA Splicing

Abstract

Self-splicing group II introns are found in bacteria and in the organellar genes in plants, fungi, and yeast. The mechanism for the first step of splicing is generally believed to involve attack of a specific intronic 2'-hydroxyl group on a phosphodiester linkage at the 5'-splice site, resulting in the formation of a lariat intron species. In this paper, we present kinetic and enzymatic evidence that in vitro there are two distinct pathways for group II intron self-splicing: one involves 2'-OH attack and another involves attack of water or hydroxide. These two pathways occur in parallel under all reaction conditions, although either can dominate in the presence of particular salts or protein cofactors. Both pathways are followed by a successful second step of splicing, and either pathway can be highly efficient. We find that the hydrolytic pathway prevails under physiological ionic conditions, while branching predominates at molar concentrations of ammonium ion. The intron is observed to adopt two major active conformations. In order to quantify their individual reaction rates, we applied a mechanistic model describing biphasic parallel kinetic behavior. Kinetic analysis throughout the investigation reveals that there is no coupling between the unproductive "spliced-exon-reopening" reaction (SER) and hydrolysis during the first step of splicing. Conditions that stimulate branching can promote the SER reaction just as efficiently as conditions that stimulate the hydrolytic pathway. Although there is little evidence that it exists in vivo, a hydrolytic splicing pathway for group II introns has important implications for the translation of intron-encoded proteins and the inhibition of intron migration into new genomic positions.

Published

1996

21. Group II intron ribozymes that cleave DNA and RNA linkages with similar efficiency, and lack contacts with substrate 2'-hydroxyl groups.

Author

Griffin EA Jr, Qin Z, Michels WJ Jr, and Pyle AM

Subjects

Animals, DNA chemistry, Hydroxylation, Kinetics, Nucleotide Mapping, Plasmids genetics, RNA chemistry, RNA Splicing, RNA, Bacterial metabolism, RNA, Catalytic chemistry, RNA, Messenger chemistry, RNA, Messenger metabolism, Tetrahymena metabolism, DNA metabolism, Introns genetics, RNA metabolism, RNA, Catalytic metabolism

Abstract

Background: Group II introns are self-splicing RNAs that have mechanistic similarity to the spliceosome complex involved in messenger RNA splicing in eukaryotes. These autocatalytic molecules can be reconfigured into highly specific, multiple-turnover ribozymes that cleave oligonucleotides in trans. We set out to use a simplified system of this kind to study the mechanism of cleavage., Results: Unlike other catalytic RNA molecules, the group II ribozymes cleave DNA linkages almost as readily as RNA linkages. One ribozyme variant cleaves DNA linkages with an efficiency comparable to that of restriction endonuclease EcoRI. Single deoxynucleotide substitutions in the substrate showed that the ribozymes bind substrate without engaging 2'-hydroxyl groups., Conclusions: The ribose 2'-hydroxyl group at the cleavage site has little role in transition-state stabilization by group II ribozymes. Substrate 2'-hydroxyl groups are not involved in substrate binding, suggesting that only base-pairing is required for substrate recognition.

Published

1995

22. Branch-point attack in group II introns is a highly reversible transesterification, providing a potential proofreading mechanism for 5'-splice site selection.

Author

Chin K and Pyle AM

Subjects

Base Sequence, Electron Transport Complex IV genetics, Esterification, Exons, Hydrolysis, Kinetics, Mitochondria genetics, Models, Genetic, Molecular Sequence Data, Nucleic Acid Conformation, Introns, RNA Splicing, RNA, Catalytic metabolism, Saccharomyces cerevisiae genetics

Abstract

By examining the first step of group II intron splicing in the absence of the second step, we have found that there is an interplay of three distinct reactions at the 5'-splice site: branching, reverse branching, and hydrolytic cleavage. This approach has yielded the first kinetic parameters describing eukaryotic branching and establishes that group II intron catalysis can proceed on a rapid timescale. The efficient reversibility of the first step is due to increased conformational organization in the branched intermediate and it has several important mechanistic implications. Reversibility in the first step requires that the second step of splicing serve as a kinetic trap, thus driving splicing to completion and coordinating the first and second step of splicing. Facile reverse branching also provides the intron with a proofreading mechanism to control the fidelity of 5'-splice site selection and it provides a kinetic basis for the apparent mobility of group II introns.

Published

1995

23. Conversion of a group II intron into a new multiple-turnover ribozyme that selectively cleaves oligonucleotides: elucidation of reaction mechanism and structure/function relationships.

Author

Michels WJ Jr and Pyle AM

Subjects

Base Sequence, Binding Sites, Kinetics, Molecular Sequence Data, Molecular Structure, Mutation, Oligonucleotides chemistry, Oligonucleotides genetics, Phosphates metabolism, Plasmids chemistry, Plasmids genetics, Plasmids metabolism, RNA Splicing genetics, RNA, Catalytic chemistry, Structure-Activity Relationship, Substrate Specificity, Introns, Oligonucleotides metabolism, RNA, Catalytic genetics, RNA, Catalytic metabolism

Abstract

The self-splicing ai5g group II intron was transformed into a three-part ribozyme that site-specifically cleaves small oligonucleotide substrates with multiple turnover. The ribozyme is composed of intron domain 1 (D1, 425 nucleotides), with catalytically essential domain 5 (D5, 58 nucleotides) provided separately as a reaction cofactor. Together, the D1/D5 complex cleaves small substrates analogous in sequence to the 5'-splice site of the intron. Activity of the ribozyme was studied using a combination of single- and multiple-turnover experiments in which the concentrations of the RNA components were varied in order to probe their individual role in the overall mechanism. Values for kcat, Km, and kcat/Km were the same within experimental error for the two enzymological approaches. These kinetic analyses reveal that the ribozyme utilizes a classic Michaelis-Menten reaction mechanism in which the chemical step of catalysis (kcat = kchem = approximately 0.03 min-1 at full saturation) is rate limiting for the overall reaction. The D1/D5 complex binds tightly to the substrate (Km = 6.3 nM) and specifically recognizes sequences both 5' and 3' to the ribozyme cleavage site. These studies represent the first quantitative analysis of group II recognition and affinity for the 5'-splice site. As observed in previous studies on the role of D5 RNA, D5 binds tightly to the ternary complex (Km = 870 nM). The second-order rate constant for RNA cleavage (kcat/Km = 3.3 x 10(6)) is an order of magnitude slower than that observed for other ribozymes in this mechanistic class, all of which are rate-limited by steps other than chemistry. That kcat equals kchem in this ribozyme is supported by the overall kinetic analysis and by the observation that an Rp phosphorothioate is cleaved approximately 3-fold more slowly than a phosphate at the cleavage site. These studies represent a preliminary examination of stereochemical preference by a group II intron active site in the transition state. The substrate specificity, reaction conditions, and mutational sensitivity of this ribozyme are consistent with a reaction analogous to the first step of group II intron self-splicing, although its stereochemical preference is analogous to a second-step reversal.

Published

1995