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The cryo-electron microscopy structure of a yeast spliceosome stalled before mature RNA formation provides insight into the mechanism of exon ligation. Structure of the spliceosomal C* complex Recent years have seen substantial progress in understanding the structure of various intermediates of the splicing process. Two groups, led by Reinhard Lührmann and Kiyoshi Nagai, now describe the cryo-electron microscopy structures (from human and yeast cells, respectively) of the splicing intermediate known as the C* complex. The notable feature observed in this complex, relative to the preceding catalytic intermediate (the C complex), is a remodelling that positions the branch-site adenosine and the branched intron out of the catalytic core, opening up space for the 3′ exon to dock in preparation for exon ligation. The spliceosome excises introns from pre-mRNAs in two sequential transesterifications—branching and exon ligation 1 —catalysed at a single catalytic metal site in U6 small nuclear RNA (snRNA) 2 , 3 . Recently reported structures of the spliceosomal C complex 4 , 5 with the cleaved 5′ exon and lariat–3′-exon bound to the catalytic centre revealed that branching-specific factors such as Cwc25 lock the branch helix into position for nucleophilic attack of the branch adenosine at the 5′ splice site. Furthermore, the ATPase Prp16 is positioned to bind and translocate the intron downstream of the branch point to destabilize branching-specific factors and release the branch helix from the active site 4 . Here we present, at 3.8 Å resolution, the cryo-electron microscopy structure of a Saccharomyces cerevisiae spliceosome stalled after Prp16-mediated remodelling but before exon ligation. While the U6 snRNA catalytic core remains firmly held in the active site cavity of Prp8 by proteins common to both steps, the branch helix has rotated by 75° compared to the C complex and is stabilized in a new position by Prp17, Cef1 and the reoriented Prp8 RNase H-like domain. This rotation of the branch helix removes the branch adenosine from the catalytic core, creates a space for 3′ exon docking, and restructures the pairing of the 5′ splice site with the U6 snRNA ACAGAGA region. Slu7 and Prp18, which promote exon ligation, bind together to the Prp8 RNase H-like domain. The ATPase Prp22, bound to Prp8 in place of Prp16, could interact with the 3′ exon, suggesting a possible basis for mRNA release after exon ligation 6 , 7 . Together with the structure of the C complex 4 , our structure of the C* complex reveals the two major conformations of the spliceosome during the catalytic stages of splicing.

Spliceosome rearrangements facilitated by RNA helicase PRP16 before catalytic step two of splicing are poorly understood. Here we report a 3D cryo-electron microscopy structure of the human spliceosomal C complex stalled directly after PRP16 action (C*). The architecture of the catalytic U2–U6 ribonucleoprotein (RNP) core of the human C* spliceosome is very similar to that of the yeast pre-Prp16 C complex. However, in C* the branched intron region is separated from the catalytic centre by approximately 20 Å, and its position close to the U6 small nuclear RNA ACAGA box is stabilized by interactions with the PRP8 RNase H-like and PRP17 WD40 domains. RNA helicase PRP22 is located about 100 Å from the catalytic centre, suggesting that it destabilizes the spliced mRNA after step two from a distance. Comparison of the structure of the yeast C and human C* complexes reveals numerous RNP rearrangements that are likely to be facilitated by PRP16, including a large-scale movement of the U2 small nuclear RNP. The cryo-EM structure of the splicing intermediate known as the C* complex from human. Structure of the spliceosomal C* complex Recent years have seen substantial progress in understanding the structure of various intermediates of the splicing process. Two groups, led by Reinhard Lührmann and Kiyoshi Nagai, now describe the cryo-electron microscopy structures (from human and yeast cells, respectively) of the splicing intermediate known as the C* complex. The notable feature observed in this complex, relative to the preceding catalytic intermediate (the C complex), is a remodelling that positions the branch-site adenosine and the branched intron out of the catalytic core, opening up space for the 3′ exon to dock in preparation for exon ligation.

Catalyzed by the spliceosome, precursor mRNA splicing proceeds in two steps: branching and exon ligation. Transition from the C (catalytic post-branching spliceosome) to the C* (catalytic pre-exon ligation spliceosome) complex is driven by the adenosine triphosphatase/helicase Prp16. Zhan et al. report the cryo-electron microscopy structure of the human C complex, showing that two step I splicing factors stabilize the active site and link it to Prp16. Science , this issue p. 537 The cryo–electron microscopy structure of the human C complex spliceosome reveals mechanistic insights into ribonucleoprotein remodeling. Splicing by the spliceosome involves branching and exon ligation. The branching reaction leads to the formation of the catalytic step I spliceosome (C complex). Here we report the cryo–electron microscopy structure of the human C complex at an average resolution of 4.1 angstroms. Compared with the Saccharomyces cerevisiae C complex, the human complex contains 11 additional proteins. The step I splicing factors CCDC49 and CCDC94 (Cwc25 and Yju2 in S. cerevisiae , respectively) closely interact with the DEAH-family adenosine triphosphatase/helicase Prp16 and bridge the gap between Prp16 and the active-site RNA elements. These features, together with structural comparison of the human C and C* complexes, provide mechanistic insights into ribonucleoprotein remodeling and allow the proposition of a working mechanism for the C-to-C* transition.

The spliceosome undergoes dramatic changes in a splicing cycle. Structures of B, Bact, C, C*, and intron lariat spliceosome complexes revealed mechanisms of 5′–splice site (ss) recognition, branching, and intron release, but lacked information on 3′-ss recognition, exon ligation, and exon release. Here we report a cryo–electron microscopy structure of the postcatalytic P complex at 3.3-angstrom resolution, revealing that the 3′ ss is mainly recognized through non–Watson-Crick base pairing with the 5′ ss and branch point. Furthermore, one or more unidentified proteins become stably associated with the P complex, securing the 3′ exon and potentially regulating activity of the helicase Prp22. Prp22 binds nucleotides 15 to 21 in the 3′ exon, enabling it to pull the intron-exon or ligated exons in a 3′ to 5′ direction to achieve 3′-ss proofreading or exon release, respectively.

Each cycle of precursor messenger RNA (pre-mRNA) splicing comprises two sequential reactions, first freeing the 5′ exon and generating an intron lariat–3′ exon and then ligating the two exons and releasing the intron lariat. The second reaction is executed by the step II catalytically activated spliceosome (known as the C* complex). Here, we present the cryo–electron microscopy structure of a C* complex from Saccharomyces cerevisiae at an average resolution of 4.0 angstroms. Compared with the preceding spliceosomal complex (C complex), the lariat junction has been translocated by 15 to 20 angstroms to vacate space for the incoming 3′-exon sequences. The step I splicing factors Cwc25 and Yju2 have been dissociated from the active site. Two catalytic motifs from Prp8 (the 1585 loop and the β finger of the ribonuclease H–like domain), along with the step II splicing factors Prp17 and Prp18 and other surrounding proteins, are poised to assist the second transesterification. These structural features, together with those reported for other spliceosomal complexes, yield a near-complete mechanistic picture on the splicing cycle.

Intron removal requires assembly of the spliceosome on precursor mRNA (pre-mRNA) and extensive remodelling to form the spliceosome’s catalytic centre. Here we report the cryo-electron microscopy structure of the yeast Saccharomyces cerevisiae pre-catalytic B complex spliceosome at near-atomic resolution. The mobile U2 small nuclear ribonucleoprotein particle (snRNP) associates with U4/U6.U5 tri-snRNP through the U2/U6 helix II and an interface between U4/U6 di-snRNP and the U2 snRNP SF3b-containing domain, which also transiently contacts the helicase Brr2. The 3′ region of the U2 snRNP is flexibly attached to the SF3b-containing domain and protrudes over the concave surface of tri-snRNP, where the U1 snRNP may reside before its release from the pre-mRNA 5′ splice site. The U6 ACAGAGA sequence forms a hairpin that weakly tethers the 5′ splice site. The B complex proteins Prp38, Snu23 and Spp381 bind the Prp8 N-terminal domain and stabilize U6 ACAGAGA stem–pre-mRNA and Brr2–U4 small nuclear RNA interactions. These results provide important insights into the events leading to active site formation. The cryo-electron microscopy structure of the yeast spliceosome in a pre-catalytic state provides insights into the molecular events leading to formation of the spliceosome active site. Visualization of a poised spliceosome Protein-coding regions of DNA can be interrupted by non-coding regions, or introns. A large multisubunit complex, the spliceosome, is used to excise introns from the messenger RNA before it is translated into protein. Formation of an active spliceosome complex on an intron requires stepwise assembly of subcomplexes, followed by their rearrangement and the loss of some factors. Kiyoshi Nagai and colleagues have solved the structure of the B complex spliceosome, poised in a pre-catalytic state. The detection of several factors that were not visualized in previous spliceosome structures provides new insights regarding the process by which the complex is activated.

Precursor mRNA (pre-mRNA) splicing proceeds by two consecutive transesterification reactions via a lariat–intron intermediate. Here we present the 3.8 Å cryo-electron microscopy structure of the spliceosome immediately after lariat formation. The 5′-splice site is cleaved but remains close to the catalytic Mg 2+ site in the U2/U6 small nuclear RNA (snRNA) triplex, and the 5′-phosphate of the intron nucleotide G(+1) is linked to the branch adenosine 2′OH. The 5′-exon is held between the Prp8 amino-terminal and linker domains, and base-pairs with U5 snRNA loop 1. Non-Watson–Crick interactions between the branch helix and 5′-splice site dock the branch adenosine into the active site, while intron nucleotides +3 to +6 base-pair with the U6 snRNA ACAG AGA sequence. Isy1 and the step-one factors Yju2 and Cwc25 stabilize docking of the branch helix. The intron downstream of the branch site emerges between the Prp8 reverse transcriptase and linker domains and extends towards the Prp16 helicase, suggesting a plausible mechanism of remodelling before exon ligation. Cryo-EM reveals the configuration of substrate pre-mRNA within the active spliceosome and suggests how remodelling occurs prior to exon ligation. Structure of the branched splicing complex The excision of introns from RNA is not a concerted process, but is rather an ordered one involving two transesterification reactions by the spliceosome. In the first step, the 5′-splice site is cleaved and the intron end is joined to make a lariat structure. Kiyoshi Nagai and colleagues have captured the Saccharomyces cerevisiae spliceosome stalled immediately after this first transesterification (branching) reaction by cryo-electron microscopy single-particle reconstruction at an overall resolution of 3.8 Å. The configuration of the RNA within the complex suggests that remodelling occurs before the second step, exon ligation.

The spliceosome catalyses the excision of introns from pre-mRNA in two steps, branching and exon ligation, and is assembled from five small nuclear ribonucleoprotein particles (snRNPs; U1, U2, U4, U5, U6) and numerous non-snRNP factors 1 . For branching, the intron 5′ splice site and the branch point sequence are selected and brought by the U1 and U2 snRNPs into the prespliceosome 1 , which is a focal point for regulation by alternative splicing factors 2 . The U4/U6.U5 tri-snRNP subsequently joins the prespliceosome to form the complete pre-catalytic spliceosome. Recent studies have revealed the structural basis of the branching and exon-ligation reactions 3 , however, the structural basis of the early events in spliceosome assembly remains poorly understood 4 . Here we report the cryo-electron microscopy structure of the yeast Saccharomyces cerevisiae prespliceosome at near-atomic resolution. The structure reveals an induced stabilization of the 5′ splice site in the U1 snRNP, and provides structural insights into the functions of the human alternative splicing factors LUC7-like (yeast Luc7) and TIA-1 (yeast Nam8), both of which have been linked to human disease 5 , 6 . In the prespliceosome, the U1 snRNP associates with the U2 snRNP through a stable contact with the U2 3′ domain and a transient yeast-specific contact with the U2 SF3b-containing 5′ region, leaving its tri-snRNP-binding interface fully exposed. The results suggest mechanisms for 5′ splice site transfer to the U6 ACAGAGA region within the assembled spliceosome and for its subsequent conversion to the activation-competent B-complex spliceosome 7 , 8 . Taken together, the data provide a working model to investigate the early steps of spliceosome assembly. The cryo-electron microscopy structure of the Saccharomyces cerevisiae prespliceosome provides insights into splice-site selection and early spliceosome assembly events.

The human prototypical SR protein SRSF1 is an oncoprotein that contains two RRMs and plays a pivotal role in RNA metabolism. We determined the structure of the RRM1 bound to RNA and found that the domain binds preferentially to a CN motif (N is for any nucleotide). Based on this solution structure, we engineered a protein containing a single glutamate to asparagine mutation (E87N), which gains the ability to bind to uridines and thereby activates SMN exon7 inclusion, a strategy that is used to cure spinal muscular atrophy. Finally, we revealed that the flexible inter-RRM linker of SRSF1 allows RRM1 to bind RNA on both sides of RRM2 binding site. Besides revealing an unexpected bimodal mode of interaction of SRSF1 with RNA, which will be of interest to design new therapeutic strategies, this study brings a new perspective on the mode of action of SRSF1 in cells. SRSF1 is an oncoprotein that plays important roles in RNA metabolism. We reveal the structure of the human SRSF1 RRM1 bound to RNA, and propose a bimodal mode of interaction of the protein with RNA. A single mutation in RRM1 changed SRSF1 specificity for RNA and made it active on SMN2 exon7 splicing.

Each cycle of pre–messenger RNA splicing, carried out by the spliceosome, comprises two sequential transesterification reactions, which result in the removal of an intron and the joining of two exons. Here we report an atomic structure of a catalytic step I spliceosome (known as the complex) from Saccharomyces cerevisiae, as determined by cryo–electron microscopy at an average resolution of 3.4 angstroms. In the structure, the 2'-OH of the invariant adenine nucleotide in the branch point sequence (BPS) is covalently joined to the phosphate at the 5' end of the 5' splice site (5'SS), forming an intron lariat. The freed 5' exon remains anchored to loop I of U5 small nuclear RNA (snRNA), and the 5'SS and BPS of the intron form duplexes with conserved U6 and U2 snRNA sequences, respectively. Specific placement of these RNA elements at the catalytic cavity of Prp8 is stabilized by 15 protein components, including Snu114 and the splicing factors Cwc21, Cwc22, Cwc25, and Yju2. These features, representing the conformation of the spliceosome after the first-step reaction, predict structural changes that are needed for the execution of the second-step transesterification reaction.