New tertiary constraints between the RNA components of active yeast spliceosomes: a photo-crosslinking study

Universal and strain specific structure features of segment 8 genomic RNA of influenza A virus-application of 4-thiouridine photocrosslinking

RNA structure in the influenza A virus (IAV) has been the focus of several studies that have shown connections between conserved secondary structure motifs and their biological function in the virus replication cycle. Questions have arisen on how to best recognize and understand the pandemic properties of IAV strains from an RNA perspective, but determination of the RNA secondary structure has been challenging. Herein, we used chemical mapping to determine the secondary structure of segment 8 viral RNA (vRNA) of the pandemic A/California/04/2009 (H1N1) strain of IAV. Additionally, this long, naturally occurring RNA served as a model to evaluate RNA mapping with 4-thiouridine (4sU) crosslinking. We explored 4-thiouridine as a probe of nucleotides in close proximity, through its incorporation into newly transcribed RNA and subsequent photoactivation. RNA secondary structural features both universal to type A strains and unique to the A/California/04/2009 (H1N1) strain were recognized. 4sU mapping confirmed and facilitated RNA structure prediction, according to several rules: 4sU photocross-linking forms efficiently in the double-stranded region of RNA with some flexibility, in the ends of helices, and across bulges and loops when their structural mobility is permitted. This method highlighted three-dimensional properties of segment 8 vRNA secondary structure motifs and allowed to propose several long-range three-dimensional interactions. 4sU mapping combined with chemical mapping and bioinformatic analysis could be used to enhance the RNA structure determination as well as recognition of target regions for antisense strategies or viral RNA detection.

Prp8 retinitis pigmentosa mutants cause defects in the transition between the catalytic steps of splicing

Pre-mRNA splicing must occur with high fidelity and efficiency for proper gene expression. The spliceosome uses DExD/H box helicases to promote on-pathway interactions while simultaneously minimizing errors. Prp8 and Snu114, an EF2-like GTPase, regulate the activity of the Brr2 helicase, promoting RNA unwinding by Brr2 at appropriate points in the splicing cycle and repressing it at others. Mutations linked to retinitis pigmentosa (RP), a disease that causes blindness in humans, map to the Brr2 regulatory region of Prp8. Previous in vitro studies of homologous mutations in Saccharomyces cerevisiaes how that Prp8-RP mutants cause defects in spliceosome activation. Here we show that a subset of RP mutations in Prp8 also causes defects in the transition between the first and second catalytic steps of splicing. Though Prp8-RP mutants do not cause defects in splicing fidelity, they result in an overall decrease in splicing efficiency. Furthermore, genetic analyses link Snu114 GTP/GDP occupancy to Prp8-dependent regulation of Brr2. Our results implicate the transition between the first and second catalytic steps as a critical place in the splicing cycle where Prp8-RP mutants influence splicing efficiency. The location of the Prp8-RP mutants, at the "hinge" that links the Prp8 Jab1-MPN regulatory "tail" to the globular portion of the domain, suggests that these Prp8-RP mutants inhibit regulated movement of the Prp8 Jab1/MPN domain into the Brr2 RNA binding channel to transiently inhibit Brr2. Therefore, in Prp8-linked RP, disease likely results not only from defects in spliceosome assembly and activation, but also because of defects in splicing catalysis.

Spliceosome assembly in the absence of stable U4/U6 RNA pairing

The cycle of spliceosome assembly, intron excision, and spliceosome disassembly involves large-scale structural rearrangements of U6 snRNA that are functionally important. U6 enters the splicing pathway bound to the Prp24 protein, which chaperones annealing of U6 to U4 RNA to form a U4/U6 di-snRNP. During catalytic activation of the assembled spliceosome, U4 snRNP is released and U6 is paired to U2 snRNA. Here we show that point mutations in U4 and U6 that decrease U4/U6 base-pairing in vivo are lethal in combination. However, this synthetic phenotype is rescued by a mutation in U6 that alters a U6-Prp24 contact and stabilizes U2/U6. Remarkably, the resulting viable triple mutant strain lacks detectable U4/U6 base-pairing and U4/U6 di-snRNP. Instead, this strain accumulates free U4 snRNP, protein-free U6 RNA, and a novel complex containing U2/U6 di-snRNP. Further mutational analysis indicates that disruption of the U6-Prp24 interaction rather than stabilization of U2/U6 renders stable U4/U6 di-snRNP assembly nonessential. We propose that an essential function of U4/U6 pairing is to displace Prp24 from U6 RNA, and thus a destabilized U6-Prp24 complex renders stable U4/U6 pairing nonessential.

Preparation of yeast whole cell splicing extract

Pre-mRNA splicing, the removal of introns from pre-messenger RNA, is an essential step in eukaryotic gene expression. In humans, it has been estimated that 60 % of noninfectious diseases are caused by errors in splicing, making the study of pre-mRNA splicing a high priority from a health perspective. Pre-mRNA splicing is also complicated: the molecular machine that catalyzes the reaction, the spliceosome, is composed of five small nuclear RNAs, and over 100 proteins, making splicing one of the most complex processes in the cell.An important tool for studying pre-mRNA splicing is the in vitro splicing assay. With an in vitro assay, it is possible to test the function of each splicing component by removing the endogenous version and replacing it (or reconstituting it) with a modified one. This assay relies on the ability to produce an extract-either whole cell or nuclear-that contains all of the activities required to convert pre-mRNA to mRNA. To date, splicing extracts have only been produced from human and S. cerevisiae (yeast) cells. We describe a method to produce whole cell extracts from yeast that support splicing with efficiencies up to 90 %. These extracts have been used to reconstitute snRNAs, screen small molecule libraries for splicing inhibitors, and purify a variety of splicing complexes.

Evidence for a group II intron-like catalytic triplex in the spliceosome

To catalyze pre-mRNA splicing, U6 small nuclear RNA positions two metals that interact directly with the scissile phosphates. U6 metal ligands correspond stereospecifically to metal ligands within the catalytic domain V of a group II self-splicing intron. Domain V ligands are organized by base-triple interactions, which also juxtapose the 3' splice site with the catalytic metals. However, in the spliceosome, the mechanism for organizing catalytic metals and recruiting the substrate has remained unclear. Here we show by genetics, cross-linking and biochemistry in yeast that analogous triples form in U6 and promote catalytic-metal binding and both chemical steps of splicing. Because the triples include an element that defines the 5' splice site, they also provide a mechanism for juxtaposing the pre-mRNA substrate with the catalytic metals. Our data indicate that U6 adopts a group II intron-like tertiary conformation to catalyze splicing.

Conformational heterogeneity of the protein-free human spliceosomal U2-U6 snRNA complex

The complex formed between the U2 and U6 small nuclear (sn)RNA molecules of the eukaryotic spliceosome plays a critical role in the catalysis of precursor mRNA splicing. Here, we have used enzymatic structure probing, (19)F NMR, and analytical ultracentrifugation techniques to characterize the fold of a protein-free biophysically tractable paired construct representing the human U2-U6 snRNA complex. Results from enzymatic probing and (19)F NMR for the complex in the absence of Mg(2+) are consistent with formation of a four-helix junction structure as a predominant conformation. However, (19)F NMR data also identify a lesser fraction (up to 14% at 25°C) of a three-helix conformation. Based upon this distribution, the calculated ΔG for inter-conversion to the four-helix structure from the three-helix structure is approximately -4.6 kJ/mol. In the presence of 5 mM Mg(2+), the fraction of the three-helix conformation increased to ∼17% and the Stokes radius, measured by analytical ultracentrifugation, decreased by 2%, suggesting a slight shift to an alternative conformation. NMR measurements demonstrated that addition of an intron fragment to the U2-U6 snRNA complex results in displacement of U6 snRNA from the region of Helix III immediately 5' of the ACAGAGA sequence of U6 snRNA, which may facilitate binding of the segment of the intron adjacent to the 5' splice site to the ACAGAGA sequence. Taken together, these observations indicate conformational heterogeneity in the protein-free human U2-U6 snRNA complex consistent with a model in which the RNA has sufficient conformational flexibility to facilitate inter-conversion between steps of splicing in situ.

Structure of the yeast U2/U6 snRNA complex

The U2/U6 snRNA complex is a conserved and essential component of the active spliceosome that interacts with the pre-mRNA substrate and essential protein splicing factors to promote splicing catalysis. Here we have elucidated the solution structure of a 111-nucleotide U2/U6 complex using an approach that integrates SAXS, NMR, and molecular modeling. The U2/U6 structure contains a three-helix junction that forms an extended "Y" shape. The U6 internal stem-loop (ISL) forms a continuous stack with U2/U6 Helices Ib, Ia, and III. The coaxial stacking of Helix Ib on the U6 ISL is a configuration that is similar to the Domain V structure in group II introns. Interestingly, essential features of the complex--including the U80 metal binding site, AGC triad, and pre-mRNA recognition sites--localize to one face of the molecule. This observation suggests that the U2/U6 structure is well-suited for orienting substrate and cofactors during splicing catalysis.

The conserved 3' end domain of U6atac snRNA can direct U6 snRNA to the minor spliceosome

U6 and U6atac snRNAs play analogous critical roles in the major U2-dependent and minor U12-dependent spliceosomes, respectively. Previous results have shown that most of the functional cores of these two snRNAs are either highly similar in sequence or functionally interchangeable. Thus, a mechanism must exist to restrict each snRNA to its own spliceosome. Here we show that a chimeric U6 snRNA containing the unique and highly conserved 3' end domain of U6atac snRNA is able to function in vivo in U12-dependent spliceosomal splicing. Function of this chimera required the coexpression of a modified U4atac snRNA; U4 snRNA could not substitute. Partial deletions of this element in vivo, as well as in vitro antisense experiments, showed that the 3' end domain of U6atac snRNA is necessary to direct the U4atac/U6atac.U5 tri-snRNP to the forming U12-dependent spliceosome. In vitro experiments also uncovered a role for U4atac snRNA in this targeting.

RNA crosslinking methods

RNA-RNA crosslinking provides a rapid means of obtaining evidence for the proximity of functional groups in structurally complex RNAs and ribonucleoproteins. Such evidence can be used to provide a physical context for interpreting structural information from other biochemical and biophysical methods and for the design of further experiments. The identification of crosslinks that accurately reflect the native conformation of the RNA of interest is strongly dependent on the position of the crosslinking agent, the conditions of the crosslinking reaction, and the method for mapping the crosslink position. Here, we provide an overview of protocols and experimental considerations for RNA-RNA crosslinking with the most commonly used long- and short-range photoaffinity reagents. Specifically, we describe the merits and strategies for random and site-specific incorporation of these reagents into RNA, the crosslinking reaction and isolation of crosslinked products, the mapping crosslinked sites, and assessment of the crosslinking data.

"Nought may endure but mutability": spliceosome dynamics and the regulation of splicing

The spliceosome is both compositionally and conformationally dynamic. Each transition along the splicing pathway presents an opportunity for progression, pausing, or discard, allowing splice site choice to be regulated throughout both the assembly and catalytic phases of the reaction.

Three essential and conserved regions of the group II intron are proximal to the 5'-splice site

Despite the central role of group II introns in eukaryotic gene expression and their importance as biophysical and evolutionary model systems, group II intron tertiary structure is not well understood. In order to characterize the architectural organization of intron ai5gamma, we incorporated the photoreactive nucleotides s(4)U and s(6)dG at specific locations within the intron core and monitored the formation of cross-links in folded complexes. The resulting data reveal the locations for many of the most conserved, catalytically important regions of the intron (i.e., the J2/3 linker region, the IC1(i-ii) bulge in domain 1, the bulge of D5, and the 5'-splice site), showing that all of these elements are closely colocalized. In addition, we show by nucleotide analog interference mapping (NAIM) that a specific functional group in J2/3 plays a role in first-step catalysis, which is consistent with its apparent proximity to other first-step components. These results extend our understanding of active-site architecture during the first step of group II intron self-splicing and they provide a structural basis for spliceosomal comparison.

Proximity of conserved U6 and U2 snRNA elements to the 5' splice site region in activated spliceosomes

Major structural changes occur in the spliceosome during its catalytic activation, which immediately precedes the splicing of pre-mRNA. Whereas changes in snRNA conformation are well documented at the level of secondary RNA-RNA interactions, little is known about the tertiary structure of this RNA-RNA network, which comprises the spliceosome's catalytic core. Here, we have used the hydroxyl-radical probe Fe-BABE, tethered to the tenth nucleotide (U(+10)) of the 5' end of a pre-mRNA intron, to map RNA-RNA proximities in spliceosomes. These studies revealed that several conserved snRNA regions are close to U(+10) in activated spliceosomes, namely (i) the U6 snRNA ACAGAG-box region, (ii) portions of the U6 intramolecular stem-loop (U6-ISL) including a nucleotide implicated in the first catalytic step (U74), and (iii) the region of U2 that interacts with the branch point. These data constrain the relative orientation of these structural elements with respect to U(+10) in the activated spliceosome. Upon conversion of the activated spliceosome to complex C, the accessibility of U6-ISL to hydroxyl-radical cleavage is altered, suggesting rearrangements after the first catalytic step.

Free energy landscapes of RNA/RNA complexes: with applications to snRNA complexes in spliceosomes

We develop a statistical mechanical model for RNA/RNA complexes with both intramolecular and intermolecular interactions. As an application of the model, we compute the free energy landscapes, which give the full distribution for all the possible conformations, for U4/U6 and U2/U6 in major spliceosome and U4atac/U6atac and U12/U6atac in minor spliceosome. Different snRNA experiments found contrasting structures, our free energy landscape theory shows why these structures emerge and how they compete with each other. For yeast U2/U6, the model predicts that the two distinct experimental structures, the four-helix junction structure and the helix Ib-containing structure, can actually coexist and specifically compete with each other. In addition, the energy landscapes suggest possible mechanisms for the conformational switches in splicing. For instance, our calculation shows that coaxial stacking is essential for stabilizing the four-helix junction in yeast U2/U6. Therefore, inhibition of the coaxial stacking possibly by protein-binding may activate the conformational switch from the four-helix junction to the helix Ib-containing structure. Moreover, the change of the energy landscape shape gives information about the conformational changes. We find multiple (native-like and misfolded) intermediates formed through base-pairing rearrangements in snRNA complexes. For example, the unfolding of the U2/U6 undergoes a transition to a misfolded state which is functional, while in the unfolding of U12/U6atac, the functional helix Ib is found to be the last one to unfold and is thus the most stable structural component. Furthermore, the energy landscape gives the stabilities of all the possible (functional) intermediates and such information is directly related to splicing efficiency.

Repositioning of the Reaction Intermediate within the Catalytic Center of the Spliceosome

Conformational change within the spliceosome is required between the first catalytic step of pre-mRNA splicing, when the branch site attacks the 5' splice site (SS), and the second step, when the 5' exon attacks the 3'SS. Little is known, however, about repositioning of the reaction substrates during this transition. Whereas the 5'SS is positioned for the first step by pairing with the invariant U6 snRNA-ACAGAG site, we demonstrate that this pairing interaction must be disrupted to allow transition to the second step. We propose that removal of the branch structure from the catalytic center is in competition with binding of the 3'SS substrate for the second step. Changes in the relative occupancy of first and second step substrates at the catalytic center alter efficiency of the two steps of splicing, allowing use of suboptimal intron sequences and thereby altering substrate selectivity.

Towards understanding the catalytic core structure of the spliceosome

The spliceosome catalyses the splicing of nuclear pre-mRNA (precursor mRNA) in eukaryotes. Pre-mRNA splicing is essential to remove internal non-coding regions of pre-mRNA (introns) and to join the remaining segments (exons) into mRNA before translation. The spliceosome is a complex assembly of five RNAs (U1, U2, U4, U5 and U6) and many dozens of associated proteins. Although a high-resolution structure of the spliceosome is not yet available, inroads have been made towards understanding its structure and function. There is growing evidence suggesting that U2 and U6 RNAs, of the five, may contribute to the catalysis of pre-mRNA splicing. In this review, recent progress towards understanding the structure and function of U2 and U6 RNAs is summarized.

Current awareness on yeast

In order to keep subscribers up‐to‐date with the latest developments in their field, this current awareness service is provided by John Wiley & Sons and contains newly‐published material on yeasts. Each bibliography is divided into 10 sections. 1 Books, Reviews & Symposia; 2 General; 3 Biochemistry; 4 Biotechnology; 5 Cell Biology; 6 Gene Expression; 7 Genetics; 8 Physiology; 9 Medical Mycology; 10 Recombinant DNA Technology. Within each section, articles are listed in alphabetical order with respect to author. If, in the preceding period, no publications are located relevant to any one of these headings, that section will be omitted. (4 weeks journals ‐ search completed 10th. Nov. 2004)