Group II intron folding under near-physiological conditions: collapsing to the near-native state

LncRNA SChLAP1 promotes cancer cell proliferation and invasion via its distinct structural domains and conserved regions

Long non-coding RNAs (lncRNAs) play key roles in a range of biological processes and disease progression. Despite their functional significance and therapeutic potential, lncRNAs' mechanisms of action remain understudied. One such lncRNA is the Second Chromosome Locus Associated with Prostate-1 (SChLAP1). SChLAP1 is overexpressed in malignant prostate cancer and is associated with unfavorable patient outcomes, such as metastasis and increased mortality. In this study, we demonstrated that SChLAP1 possesses distinct structural domains and conserved regions that may contribute to its function. We determined the secondary structure of SChLAP1 using chemical probing methods combined with mutational profiling (DMS-MaP and SHAPE-MaP). Our in vitro secondary structural model revealed that SChLAP1 consists of two distinct secondary-structural modules located at its 5' and 3' ends, both featuring regions with a high degree of structural organization. Our in vivo chemical probing identified potential protein-binding hotspots within the two modules. Overexpression of the modules led to a notable increase in cancer cell proliferation and invasion, proving their functional significance on the oncogenicity of SChLAP1. In conclusion, we discovered functionally important, independent modules with well-defined structures of SChLAP1. These results will serve as a guide to explore the detailed molecular mechanisms by which SChLAP1 promotes aggressive prostate cancer, ultimately contributing to the development of SChLAP1 as a novel therapeutic target.

Effects of Preferential Counterion Interactions on the Specificity of RNA Folding

The real-time search for native RNA structure is essential for the operation of regulatory RNAs. We previously reported that a fraction of the Azoarcus ribozyme achieves a compact structure in less than a millisecond. To scrutinize the forces that drive initial folding steps, we used time-resolved SAXS to compare the folding dynamics of this ribozyme in thermodynamically isostable concentrations of different counterions. The results show that the size of the fast-folding population increases with the number of available counterions and correlates with the flexibility of initial RNA structures. Within 1 ms of folding, Mg²⁺ exhibits a smaller preferential interaction coefficient per charge, ΔΓ₊/ Z, than Na⁺ or [Co(NH₃)₆]³⁺. The lower ΔΓ₊/ Z corresponds to a smaller yield of folded RNA, although Mg²⁺ stabilizes native RNA more efficiently than other ions at equilibrium. These results suggest that strong Mg²⁺-RNA interactions impede the search for globally native structure during early folding stages.

Group II Intron Self-Splicing

Group II introns are large, autocatalytic ribozymes that catalyze RNA splicing and retrotransposition. Splicing by group II introns plays a major role in the metabolism of plants, fungi, and yeast and contributes to genetic variation in many bacteria. Group II introns have played a major role in genome evolution, as they are likely progenitors of spliceosomal introns, retroelements, and other machinery that controls genetic variation and stability. The structure and catalytic mechanism of group II introns have recently been elucidated through a combination of genetics, chemical biology, solution biochemistry, and crystallography. These studies reveal a dynamic machine that cycles progressively through multiple conformations as it stimulates the various stages of splicing. A central active site, containing a reactive metal ion cluster, catalyzes both steps of self-splicing. These studies provide insights into RNA structure, folding, and catalysis, as they raise new questions about the behavior of RNA machines.

Assembly and dynamics of the U4/U6 di-snRNP by single-molecule FRET

In large ribonucleoprotein machines, such as ribosomes and spliceosomes, RNA functions as an assembly scaffold as well as a critical catalytic component. Protein binding to the RNA scaffold can induce structural changes, which in turn modulate subsequent binding of other components. The spliceosomal U4/U6 di-snRNP contains extensively base paired U4 and U6 snRNAs, Snu13, Prp31, Prp3 and Prp4, seven Sm and seven LSm proteins. We have studied successive binding of all protein components to the snRNA duplex during di-snRNP assembly by electrophoretic mobility shift assay and accompanying conformational changes in the U4/U6 RNA 3-way junction by single-molecule FRET. Stems I and II of the duplex were found to co-axially stack in free RNA and function as a rigid scaffold during the entire assembly, but the U4 snRNA 5' stem-loop adopts alternative orientations each stabilized by Prp31 and Prp3/4 binding accounting for altered Prp3/4 binding affinities in presence of Prp31.

How do metal ions direct ribozyme folding?

Ribozymes, which carry out phosphoryl-transfer reactions, often require Mg(2+) ions for catalytic activity. The correct folding of the active site and ribozyme tertiary structure is also regulated by metal ions in a manner that is not fully understood. Here we employ coarse-grained molecular simulations to show that individual structural elements of the group I ribozyme from the bacterium Azoarcus form spontaneously in the unfolded ribozyme even at very low Mg(2+) concentrations, and are transiently stabilized by the coordination of Mg(2+) ions to specific nucleotides. However, competition for scarce Mg(2+) and topological constraints that arise from chain connectivity prevent the complete folding of the ribozyme. A much higher Mg(2+) concentration is required for complete folding of the ribozyme and stabilization of the active site. When Mg(2+) is replaced by Ca(2+) the ribozyme folds, but the active site remains unstable. Our results suggest that group I ribozymes utilize the same interactions with specific metal ligands for both structural stability and chemical activity.

Strategy for Internal Labeling of Large RNAs with Minimal Perturbation by Using Fluorescent PNA

Fluorescence techniques for the investigation of biomolecules and their folding pathways require an efficient labeling strategy. A common method to internally label large RNAs involves the introduction of long loops for hybridization of fluorophore-carrying DNA strands. Such loops often disturb the structure, and thus the functionality, of the RNA. Here we show, in a proof of concept study with a >600 nucleotide group II intron ribozyme, that the usage of the nucleic acid analogue peptide nucleic acid (PNA) is more efficient in several aspects, minimizing the required structural modifications of the RNA. We demonstrate by various methods, including smFRET, that much smaller concentrations and shorter PNAs can be applied, compared to DNA, for rapid and specific internal RNA labeling. The folding pathway and catalytic activity of this large ribozyme is only minimally affected by the PNA, but the background signal is significantly reduced.

Native Purification and Analysis of Long RNAs

The purification and analysis of long noncoding RNAs (lncRNAs) in vitro is a challenge, particularly if one wants to preserve elements of functional structure. Here, we describe a method for purifying lncRNAs that preserves the cotranscriptionally derived structure. The protocol avoids the misfolding that can occur during denaturation-renaturation protocols, thus facilitating the folding of long RNAs to a native-like state. This method is simple and does not require addition of tags to the RNA or the use of affinity columns. LncRNAs purified using this type of native purification protocol are amenable to biochemical and biophysical analysis. Here, we describe how to study lncRNA global compaction in the presence of divalent ions at equilibrium using sedimentation velocity analytical ultracentrifugation and analytical size-exclusion chromatography as well as how to use these uniform RNA species to determine robust lncRNA secondary structure maps by chemical probing techniques like selective 2'-hydroxyl acylation analyzed by primer extension and dimethyl sulfate probing.

Probing RNA folding by hydroxyl radical footprinting

In recent years RNA molecules have emerged as central players in the regulation of gene expression. Many of these noncoding RNAs possess well-defined, complex, three-dimensional structures which are essential for their biological function. In this context, much effort has been devoted to develop computational and experimental techniques for RNA structure determination. Among available experimental tools to investigate the higher-order folding of structured RNAs, hydroxyl radical probing stands as one of the most informative and reliable ones. Hydroxyl radicals are oxidative species that cleave the nucleic acid backbone solely according to the solvent accessibility of individual phosphodiester bonds, with no sequence or secondary structure specificity. Therefore, the cleavage pattern obtained directly reflects the degree of protection/exposure to the solvent of each section of the molecule under inspection, providing valuable information about how these different sections interact together to form the final three-dimensional architecture. In this chapter we describe a robust, accurate and very sensitive hydroxyl radical probing method that can be applied to any structured RNA molecule and is suitable to investigate RNA folding and RNA conformational changes induced by binding of a ligand.

A chemogenetic approach to study the structural basis of protein-facilitated RNA folding

Large RNA molecules play important roles in all aspects of cellular metabolism ranging from mRNA splicing and protein biosynthesis to regulation of gene expression. In order to correctly perform its function in the cell, an RNA molecule must fold into a complex tertiary structure. Folding of many large RNAs is slow either due to formation of stable misfolded intermediates or due to high contact order or instability of obligate folding intermediates. Therefore many RNAs use protein cofactors to facilitate their folding in vivo. Folding of the yeast mitochondrial group II intron ai5γ to the native state under physiological conditions is facilitated by the protein cofactor Mss116. This chapter describes the use of Nucleotide Analog Interference Mapping (NAIM) to identify specific substructures within the intron molecule that are directly affected by the protein.

The kinetics of ribozyme cleavage: a tool to analyze RNA folding as a function of catalysis

As catalytically active RNAs, ribozymes can be characterized by kinetic measurements similar to classical enzyme kinetics. However, in contrast to standard protein enzymes, for which reactions can usually be started by mixing the enzyme with its substrate, ribozymes are typically self-cleaving. The reaction has to be initiated by folding the RNA into its active conformation. Thus, ribozyme kinetics are influenced by both folding and catalytic components and often enable indirect observation of RNA folding. Here, I describe how to obtain quantitative ribozyme cleavage data via denaturing polyacrylamide gel electrophoresis (PAGE) of radioactively labeled in vitro transcripts and discuss general considerations for subsequent kinetic analysis.

Yeast and human mitochondrial helicases

Mitochondria are semiautonomous organelles which contain their own genome. Both maintenance and expression of mitochondrial DNA require activity of RNA and DNA helicases. In Saccharomyces cerevisiae the nuclear genome encodes four DExH/D superfamily members (MSS116, SUV3, MRH4, IRC3) that act as helicases and/or RNA chaperones. Their activity is necessary for mitochondrial RNA splicing, degradation, translation and genome maintenance. In humans the ortholog of SUV3 (hSUV3, SUPV3L1) so far is the best described mitochondrial RNA helicase. The enzyme, together with the matrix-localized pool of PNPase (PNPT1), forms an RNA-degrading complex called the mitochondrial degradosome, which localizes to distinct structures (D-foci). Global regulation of mitochondrially encoded genes can be achieved by changing mitochondrial DNA copy number. This way the proteins involved in its replication, like the Twinkle helicase (c10orf2), can indirectly regulate gene expression. Here, we describe yeast and human mitochondrial helicases that are directly involved in mitochondrial RNA metabolism, and present other helicases that participate in mitochondrial DNA replication and maintenance. This article is part of a Special Issue entitled: The Biology of RNA helicases - Modulation for life.

Mss116p: a DEAD-box protein facilitates RNA folding

RNA folding is an essential aspect underlying RNA-mediated cellular processes. Many RNAs, including large, multi-domain ribozymes, are capable of folding to the native, functional state without assistance of a protein cofactor in vitro. In the cell, trans-acting factors, such as proteins, are however known to modulate the structure and thus the fate of an RNA. DEAD-box proteins, including Mss116p, were recently found to assist folding of group I and group II introns in vitro and in vivo. The underlying mechanism(s) have been studied extensively to explore the contribution of ATP hydrolysis and duplex unwinding in helicase-stimulated intron splicing. Here we summarize the ongoing efforts to understand the novel role of DEAD-box proteins in RNA folding.

Dimerization of nucleic acid hairpins in the conditions caused by neutral cosolutes

Characterization of metal ion binding to RNA and DNA base pairs is important for understanding their energy contribution to the folding and conformational changes of nucleic acid structures. In this study, we examine the equilibrium shift from the hairpin toward the dimer formation, induced by nonspecifically bound metal ions. The hairpin dimerization is markedly enhanced in the presence of high background concentrations of poly(ethylene glycol) (PEG) and several small organic molecules. The simple volume exclusion effect and the base pair stability cannot entirely account for this increase. We find that the dielectric constant correlates well with the dimerization efficiency in the conditions caused by small alcohol molecules and amide compounds as well as PEG. The hairpin dimerization experiments reveal the potential of PEG for enhancing the binding affinity between nucleic acids and metal ions, by reducing the solution dielectric constant without decreasing the thermodynamic stability of nucleic acid structures. The results presented here contribute to the understanding of nucleic acid folding and its ability to switch between alternative conformations under the condition of limited cation availability and cellular physiology.

The brace for a growing scaffold: Mss116 protein promotes RNA folding by stabilizing an early assembly intermediate

The ai5γ group II intron requires a protein cofactor to facilitate native folding in the cell. Yeast protein Mss116 greatly accelerates intron folding under near-physiological conditions both in vivo and in vitro. Although the effect of Mss116 on the kinetics of ai5γ ribozyme folding and catalysis has been extensively studied, the precise structural role and interaction sites of Mss116 have been elusive. Using Nucleotide Analog Interference Mapping to study the folding of splicing precursor constructs, we have identified specific intron functional groups that participate in Mss116-facilitated folding and we have determined their role in the folding mechanism. The data indicate that Mss116 stabilizes an early, obligate folding intermediate within intron domain 1, thereby laying the foundation for productive folding to the native state. In addition, the data reveal an important role for the IBS2 exon sequence and for the terminus of domain 6, during the folding of self-splicing group IIB intron constructs.

Raa4 is a trans-splicing factor that specifically binds chloroplast tscA intron RNA

During trans-splicing of discontinuous organellar introns, independently transcribed coding sequences are joined together to generate a continuous mRNA. The chloroplast psaA gene from Chlamydomonas reinhardtii encoding the P(700) core protein of photosystem I (PSI) is split into three exons and two group IIB introns, which are both spliced in trans. Using forward genetics, we isolated a novel PSI mutant, raa4, with a defect in trans-splicing of the first intron. Complementation analysis identified the affected gene encoding the 112.4 kDa Raa4 protein, which shares no strong sequence identity with other known proteins. The chloroplast localization of the protein was confirmed by confocal fluorescence microscopy, using a GFP-tagged Raa4 fusion protein. RNA-binding studies showed that Raa4 binds specifically to domains D2 and D3, but not to other conserved domains of the tripartite group II intron. Raa4 may play a role in stabilizing folding intermediates or functionally active structures of the split intron RNA.

RNA catalysis as a probe for chaperone activity of DEAD-box helicases

DEAD-box proteins are vitally important to cellular processes and make up the largest class of helicases. Many DEAD-box proteins function as RNA chaperones by accelerating structural transitions of RNA, which can result in the resolution of misfolded conformers or conversion between functional structures. While the biological importance of chaperone proteins is clear, their mechanisms are incompletely understood. Here, we illustrate how the catalytic activity of certain RNAs can be used to measure RNA chaperone activity. By measuring the amount of substrate converted to product, the fraction of catalytically active molecules is measured over time, providing a quantitative measure of the formation or loss of native RNA. The assays are described with references to group I and group II introns and their ribozyme derivatives, and examples are included that illustrate potential complications and indicate how catalytic activity measurements can be combined with physical approaches to gain insights into the mechanisms of DEAD-box proteins as RNA chaperones.

Kinetic characterization of group II intron folding and splicing

Group II introns are large self-splicing ribozymes found in bacterial genomes, in organelles of plants and fungi, and even in some animal organisms. Many organellar group II introns interrupt important housekeeping genes; therefore, their splicing is critical for the survival of the host organism. Group II introns are versatile catalytic RNAs: they facilitate their own excision from a pre-mRNA, they promote ligation of exons to form a translation-competent mature mRNA; they can act like mobile genomic elements and insert themselves into RNA and DNA targets with remarkable precision, which makes them attractive tools for genetic engineering. The first step in characterization of any group II intron is the evaluation of its catalytic activity and its ability to properly fold into the native functionally active structure. This chapter describes kinetic assays used to characterize folding and catalytic properties of group II intron-derived ribozymes.

ATP-dependent roles of the DEAD-box protein Mss116p in group II intron splicing in vitro and in vivo

The yeast DEAD-box protein Mss116p functions as a general RNA chaperone in splicing mitochondrial group I and group II introns. For most of its functions, Mss116p is thought to use ATP-dependent RNA unwinding to facilitate RNA structural transitions, but it has been suggested to assist in the folding of one group II intron (aI5γ) primarily by stabilizing a folding intermediate. Here we compare three aI5γ constructs: one with long exons, one with short exons, and a ribozyme construct lacking exons. The long exons result in slower splicing, suggesting that they misfold and/or stabilize nonnative intronic structures. Nevertheless, Mss116p acceleration of all three constructs depends on ATP and is inhibited by mutations that compromise RNA unwinding, suggesting similar mechanisms. Results of splicing assays and a new two-stage assay that separates ribozyme folding and catalysis indicate that maximal folding of all three constructs by Mss116p requires ATP-dependent RNA unwinding. ATP-independent activation is appreciable for only a subpopulation of the minimal ribozyme construct and not for constructs containing exons. As expected for a general RNA chaperone, Mss116p can also disrupt the native ribozyme, which can refold after Mss116p removal. Finally, using yeast strains with mitochondrial DNA containing only the single intron aI5γ, we show that Mss116p mutants promote splicing in vivo to degrees that correlate with their residual ATP-dependent RNA-unwinding activities. Together, our results indicate that, although DEAD-box proteins play multiple roles in RNA folding, the physiological function of Mss116p in aI5γ splicing includes a requirement for ATP-dependent local unfolding, allowing the conversion of nonfunctional RNA structure into functional RNA structure.

DEAD-box protein facilitated RNA folding in vivo

In yeast mitochondria the DEAD-box helicase Mss116p is essential for respiratory growth by acting as group I and group II intron splicing factor. Here we provide the first structure-based insights into how Mss116p assists RNA folding in vivo. Employing an in vivo chemical probing technique, we mapped the structure of the ai5γ group II intron in different genetic backgrounds to characterize its intracellular fold. While the intron adopts the native conformation in the wt yeast strain, we found that the intron is able to form most of its secondary structure, but lacks its tertiary fold in the absence of Mss116p. This suggests that ai5γ is largely unfolded in the mss116-knockout strain and requires the protein at an early step of folding. Notably, in this unfolded state misfolded substructures have not been observed. As most of the protein-induced conformational changes are located within domain D1, Mss116p appears to facilitate the formation of this largest domain, which is the scaffold for docking of other intron domains. These findings suggest that Mss116p assists the ordered assembly of the ai5γ intron in vivo.

Single-molecule analysis of Mss116-mediated group II intron folding

DEAD-box helicases are conserved enzymes involved in nearly all aspects of RNA metabolism, but their mechanisms of action remain unclear. Here, we investigated the mechanism of the DEAD-box protein Mss116 on its natural substrate, the group II intron ai5γ. Group II introns are structurally complex catalytic RNAs considered evolutionarily related to the eukaryotic spliceosome, and an interesting paradigm for large RNA folding. We used single-molecule fluorescence to monitor the effect of Mss116 on folding dynamics of a minimal active construct, ai5γ–D135. The data show that Mss116 stimulates dynamic sampling between states along the folding pathway, an effect previously observed only with high Mg²⁺ concentrations. Furthermore, the data indicate that Mss116 promotes folding through discrete ATP-independent and ATP-dependent steps. We propose that Mss116 stimulates group II intron folding through a multi-step process that involves electrostatic stabilization of early intermediates and ATP hydrolysis during the final stages of native state assembly.

The tertiary structure of group II introns: implications for biological function and evolution

Group II introns are some of the largest ribozymes in nature, and they are a major source of information about RNA assembly and tertiary structural organization. These introns are of biological significance because they are self-splicing mobile elements that have migrated into diverse genomes and played a major role in the genomic organization and metabolism of most life forms. The tertiary structure of group II introns has been the subject of many phylogenetic, genetic, biochemical and biophysical investigations, all of which are consistent with the recent crystal structure of an intact group IIC intron from the alkaliphilic eubacterium Oceanobacillus iheyensis. The crystal structure reveals that catalytic intron domain V is enfolded within the other intronic domains through an elaborate network of diverse tertiary interactions. Within the folded core, DV adopts an activated conformation that readily binds catalytic metal ions and positions them in a manner appropriate for reaction with nucleic acid targets. The tertiary structure of the group II intron reveals new information on motifs for RNA architectural organization, mechanisms of group II intron catalysis, and the evolutionary relationships among RNA processing systems. Guided by the structure and the wealth of previous genetic and biochemical work, it is now possible to deduce the probable location of DVI and the site of additional domains that contribute to the function of the highly derived group IIB and IIA introns.

Compact intermediates in RNA folding

Large noncoding RNAs fold into their biologically functional structures via compact yet disordered intermediates, which couple the stable secondary structure of the RNA with the emerging tertiary fold. The specificity of the collapse transition, which coincides with the assembly of helical domains, depends on RNA sequence and counterions. It determines the specificity of the folding pathways and the magnitude of the free energy barriers to the ensuing search for the native conformation. By coupling helix assembly with nascent tertiary interactions, compact folding intermediates in RNA also play a crucial role in ligand binding and RNA-protein recognition.

Nuclearly encoded splicing factors implicated in RNA splicing in higher plant organelles

Plant organelles arose from two independent endosymbiosis events. Throughout evolutionary history, tight control of chloroplasts and mitochondria has been gained by the nucleus, which regulates most steps of organelle genome expression and metabolism. In particular, RNA maturation, including RNA splicing, is highly dependent on nuclearly encoded splicing factors. Most introns in organelles are group II introns, whose catalytic mechanism closely resembles that of the nuclear spliceosome. Plant group II introns have lost the ability to self-splice in vivo and require nuclearly encoded proteins as cofactors. Since the first splicing factor was identified in chloroplasts more than 10 years ago, many other proteins have been shown to be involved in splicing of one or more introns in chloroplasts or mitochondria. These new proteins belong to a variety of different families of RNA binding proteins and provide new insights into ribonucleo-protein complexes and RNA splicing machineries in organelles. In this review, we describe how splicing factors, encoded by the nucleus and targeted to the organelles, take part in post-transcriptional steps in higher plant organelle gene expression. We go on to discuss the potential for these factors to regulate organelle gene expression.

Dual roles for the Mss116 cofactor during splicing of the ai5γ group II intron

The autocatalytic group II intron ai5γ from Saccharomyces cerevisiae self-splices under high-salt conditions in vitro, but requires the assistance of the DEAD-box protein Mss116 in vivo and under near-physiological conditions in vitro. Here, we show that Mss116 influences the folding mechanism in several ways. By comparing intron precursor RNAs with long (∼300 nt) and short (∼20 nt) exons, we observe that long exon sequences are a major obstacle for self-splicing in vitro. Kinetic analysis indicates that Mss116 not only mitigates the inhibitory effects of long exons, but also assists folding of the intron core. Moreover, a mutation in conserved Motif III that impairs unwinding activity (SAT → AAA) only affects the construct with long exons, suggesting helicase unwinding during exon unfolding, but not in intron folding. Strong parallels between Mss116 and the related protein Cyt-19 from Neurospora crassa suggest that these proteins form a subclass of DEAD-box proteins that possess a versatile repertoire of diverse activities for resolving the folding problems of large RNAs.

Protein-facilitated folding of group II intron ribozymes

Multiple studies hypothesize that DEAD-box proteins facilitate folding of the ai5gamma group II intron. However, these conclusions are generally inferred from splicing kinetics, and not from direct monitoring of DEAD-box protein-facilitated folding of the intron. Using native gel electrophoresis and dimethyl sulfate structural probing, we monitored Mss-116-facilitated folding of ai5gamma intron ribozymes and a catalytically active self-splicing RNA containing full-length intron and short exons. We found that the protein directly stimulates folding of these RNAs by accelerating formation of the compact near-native state. This process occurs in an ATP-independent manner, although ATP is required for the protein turnover. As Mss 116 binds RNA nonspecifically, most binding events do not result in the formation of the compact state, and ATP is required for the protein to dissociate from such nonproductive complexes and rebind the unfolded RNA. Results obtained from experiments at different concentrations of magnesium ions suggest that Mss 116 stimulates folding of ai5gamma ribozymes by promoting the formation of unstable folding intermediates, which is then followed by a cascade of folding events resulting in the formation of the compact near-native state. Dimethyl sulfate probing results suggest that the compact state formed in the presence of the protein is identical to the near-native state formed more slowly in its absence. Our results also indicate that Mss 116 does not stabilize the native state of the ribozyme, but that such stabilization results from binding of attached exons.

Metal ion-N7 coordination in a ribozyme branch domain by NMR

The N7 of purine nucleotides presents one of the most dominant metal ion binding sites in nucleic acids. However, the interactions between kinetically labile metal ions like Mg(2+) and these nitrogen atoms are inherently difficult to observe in large RNAs. Rather than using the insensitive direct (15)N detection, here we have used (2)J-[(1)H,(15)N]-HSQC (Heteronuclear Single Quantum Coherence) NMR experiments as a fast and efficient method to specifically observe and characterize such interactions within larger RNA constructs. Using the 27 nucleotides long branch domain of the yeast-mitochondrial group II intron ribozyme Sc.ai5gamma as an example, we show that direct N7 coordination of a Mg(2+) ion takes place in a tetraloop nucleotide. A second Mg(2+) ion, located in the major groove at the catalytic branch site, coordinates mainly in an outer-sphere fashion to the highly conserved flanking GU wobble pairs but not to N7 of the sandwiched branch adenosine.

A rate-limiting conformational step in the catalytic pathway of the glmS ribozyme

The glmS ribozyme is a conserved riboswitch in numerous Gram-positive bacteria and is located upstream of the glucosamine-6-phosphate (GlcN6P) synthetase reading frame. Binding of GlcN6P activates site-specific self-cleavage of the glmS mRNA, resulting in the downregulation of glmS gene expression. Unlike other riboswitches, the glmS ribozyme does not undergo structural rearrangement upon metabolite binding, indicating that the metabolite binding pocket is preformed in the absence of ligand. This observation led us to test if individual steps in the reaction pathway could be dissected by initiating the cleavage reaction before or after Mg(2+)-dependent folding. Here we show that self-cleavage reactions initiated with simultaneous addition of Mg(2+) and GlcN6P are slow (3 min(-1)) compared to reactions initiated by addition of GlcN6P to glmS RNA that has been prefolded in Mg(2+)-containing buffer (72 min(-1)). These data indicate that some level of Mg(2+)-dependent folding is rate-limiting for catalysis. Reactions initiated by addition of GlcN6P to the prefolded ribozyme also resulted in a 30-fold increase in the apparent ligand K(d) compared to those of reactions initiated by a global folding step. Time-resolved hydroxyl-radical footprinting was employed to determine if global tertiary structure formation is the rate-limiting step. The results of these experiments provided evidence for fast and largely concerted folding of the global tertiary structure (>13 min(-1)). This indicates that the rate-limiting step that we have identified either is a slow folding step between the fast initial folding and ligand binding events or represents the rate of escape from a nativelike folding trap.

Single-molecule studies of group II intron ribozymes

Group II intron ribozymes fold into their native structure by a unique stepwise process that involves an initial slow compaction followed by fast formation of the native state in a Mg(2+)-dependent manner. Single-molecule fluorescence reveals three distinct on-pathway conformations in dynamic equilibrium connected by relatively small activation barriers. From a most stable near-native state, the unobserved catalytically active conformer is reached. This most compact conformer occurs only transiently above 20 mM Mg(2+) and is stabilized by substrate binding, which together explain the slow cleavage of the ribozyme. Structural dynamics increase with increasing Mg(2+) concentrations, enabling the enzyme to reach its active state.

Divalent metal ions promote the formation of the 5'-splice site recognition complex in a self-splicing group II intron

Group II introns are ribozymes occurring in genes of plants, fungi, lower eukaryotes, and bacteria. These large RNA molecular machines, ranging in length from 400 to 2500 nucleotides, are able to catalyze their own excision from pre-mRNA, as well as to reinsert themselves into RNA or sometimes even DNA. The intronic domain 1 contains two sequences (exon binding sites 1 and 2, EBS1 and EBS2) that pair with their complementary regions at the 3'-end of the 5'-exon (intron binding sites 1 and 2, IBS1 and IBS2) such defining the 5'-splice site. The correct recognition of the 5'-splice site stands at the beginning of the two steps of splicing and is thus crucial for catalysis. It is known that metal ions play an important role in folding and catalysis of ribozymes in general. Here, we characterize the specific metal ion requirements for the formation of the 5'-splice site recognition complex from the mitochondrial yeast group II intron Sc.ai5gamma. Circular dichroism studies reveal that the formation of the EBS1.IBS1 duplex does not necessarily require divalent metal ions, as large amounts of monovalent metal ions also promote the duplex, albeit at a 5000 times higher concentration. Nevertheless, micromolar amounts of divalent metal ions, e.g. Mg2+ or Cd2+, strongly promote the formation of the 5'-splice site. These observations illustrate that a high charge density independent of the nature of the ion is needed for binding EBS1 to IBS1, but divalent metal ions are presumably the better players.

A conserved element that stabilizes the group II intron active site

The internal loop at the base of domain 3 (D3) is one of the most conserved and catalytically important elements of a group II intron. However, the location and molecular nature of its tertiary interaction partners has remained unknown. By employing a combination of site-directed photo-cross-linking and nucleotide analog interference suppression (NAIS), we show that the domain 3 internal loop (D3IL) interacts with the epsilon-epsilon' duplex, which is an active-site element located near the 5'-splice site in D1. Our data also suggest that the D3IL may interact with the bulge of D5, which is a critical active site component. The results of this and other recent studies indicate that the D3IL participates in a complex network of tertiary interactions involving epsilon-epsilon', the bulge of D5 and J23, and that it helps to optimize active site architecture by supporting interactions among these catalytic motifs. Our results are consistent with the role of D3 as a catalytic effector that enhances intron reactivity through active site stabilization.

Do DEAD-box proteins promote group II intron splicing without unwinding RNA?

The DEAD-box protein Mss116p promotes group II intron splicing in vivo and in vitro. Here we explore two hypotheses for how Mss116p promotes group II intron splicing: by using its RNA unwinding activity to act as an RNA chaperone or by stabilizing RNA folding intermediates. We show that an Mss116p mutant in helicase motif III (SAT/AAA), which was reported to stimulate splicing without unwinding RNA, retains ATP-dependent unwinding activity and promotes unfolding of a structured RNA. Its unwinding activity increases sharply with decreasing duplex length and correlates with group II intron splicing activity in quantitative assays. Additionally, we show that Mss116p can promote ATP-independent RNA unwinding, presumably via single-strand capture, also potentially contributing to DEAD-box protein RNA chaperone activity. Our findings favor the hypothesis that DEAD-box proteins function in group II intron splicing as in other processes by using their unwinding activity to act as RNA chaperones.

A kinetic intermediate that regulates proper folding of a group II intron RNA

The D135 group II intron ribozyme follows a unique folding pathway that is direct and appears to be devoid of kinetic traps. During the earliest stages of folding, D135 collapses slowly to a compact intermediate, and all subsequent assembly events are rapid. Collapse of intron domain 1 (D1) has been shown to limit the rate constant for D135 folding, although the specific substructure of the D1 kinetic intermediate has not yet been identified. Employing time-resolved nucleotide analog interference mapping, we have identified a cluster of atoms within the D1 main stem that control the rate constant for D135 collapse. Functional groups within the kappa-zeta element are particularly important for this earliest stage of folding, which is intriguing given that this same motif also serves later as the docking site for catalytic domain 5. More important, the kappa-zeta element is shown to be a divalent ion binding pocket, indicating that this region is a Mg(2+)-dependent switch that initiates the cascade of D135 folding events. By measuring the Mg(2+) dependence of the compaction rate constant, we conclude that the actual rate-limiting step in D1 compaction involves the formation of an unstable folding intermediate that is captured by the binding of Mg(2+). This carefully orchestrated folding pathway, in which formation of an active-site docking region is early and rate limiting, ensures proper folding of the intron core and faithful splicing. It may represent an important paradigm for the folding of large, multidomain RNA molecules.

Folding of group II introns: a model system for large, multidomain RNAs?

Group II introns are among the largest ribozymes in nature. They have a highly complex tertiary architecture that enables them to catalyze numerous processes, including self-splicing and transposition reactions that have probably contributed to the evolution of eukaryotic genomes. Biophysical analyses show that, despite their large size, these RNAs can fold to their native state through direct pathways that are populated by structurally defined intermediates. In addition, proteins have specific and important roles in this folding process. As a consequence, the study of the group II introns provides a valuable system for both exploring the driving forces behind the folding of multidomain RNA molecules and investigating ribonucleoprotein assembly.

Group II introns: structure, folding and splicing mechanism

Group II introns are large autocatalytic RNAs found in organellar genomes of plants and lower eukaryotes, as well as in some bacterial genomes. Interestingly, these ribozymes share characteristic traits with both spliceosomal introns and non-LTR retrotransposons and may have a common evolutionary ancestor. Furthermore, group II intron features such as structure, folding and catalytic mechanism differ considerably from those of other large ribozymes, making group II introns an attractive model system to gain novel insights into RNA biology and biochemistry. This review explores recent advances in the structural and mechanistic characterization of group II intron architecture and self-splicing.