scholarly journals Structures of the Human Spliceosomes Before and After Release of the Ligated Exon

2018 ◽  
Author(s):  
Xiaofeng Zhang ◽  
Xiechao Zhan ◽  
Chuangye Yan ◽  
Wenyu Zhang ◽  
Dongliang Liu ◽  
...  
Keyword(s):  
Electron Microscopy ◽  
Splice Site ◽  
Mrna Splicing ◽  
Small Nuclear Rna ◽  
Exon Ligation ◽  
Cryo Electron Microscopy ◽  
Branch Point Sequence ◽  
Nuclear Rna ◽  
Before And After ◽  
Functional States

Pre-mRNA splicing is executed by the spliceosome, which has eight major functional states each with distinct composition. Five of these eight human spliceosomal complexes, all preceding exon ligation, have been structurally characterized. In this study, we report the cryo-electron microscopy structures of the human post-catalytic spliceosome (P complex) and intron lariat spliceosome (ILS) at average resolutions of 3.0 and 2.9 Å, respectively. In the P complex, the ligated exon remains anchored to loop I of U5 small nuclear RNA, and the 3'-splice site is recognized by the junction between the 5'-splice site and the branch point sequence. The ATPase/helicase Prp22, along with the ligated exon and eight other proteins, are dissociated in the P-to-ILS transition. Intriguingly, the ILS complex exists in two distinct conformations, one with the ATPase/helicase Prp43 and one without. Comparison of these three late-stage human spliceosomes reveals mechanistic insights into exon release and spliceosome disassembly.

scholarly journals Structure of the activated human minor spliceosome

Science ◽  
2021 ◽  
pp. eabg0879
Author(s):  
Rui Bai ◽  
Ruixue Wan ◽  
Lin Wang ◽  
Kui Xu ◽  
Qiangfeng Zhang ◽  
...  
Keyword(s):  
Electron Microscopy ◽  
Splice Site ◽  
Zinc Finger Protein ◽  
Small Nuclear Rna ◽  
Catalytic Center ◽  
Cryo Electron Microscopy ◽  
Finger Protein ◽  
Branch Point Sequence ◽  
Nuclear Rna ◽  
U5 Snrna

The minor spliceosome mediates splicing of the rare but essential U12-type pre-mRNA. Here we report the atomic features of the activated human minor spliceosome determined by cryo-electron microscopy at 2.9-Å resolution. The 5′-splice site and branch point sequence of the U12-type intron are recognized by U6atac and U12 small nuclear RNA (snRNA), respectively. Five newly identified proteins stabilize the conformation of the catalytic center. The zinc finger protein SCNM1 functionally mimics the SF3a complex of the major spliceosome. The RBM48/ARMC7 complex binds the γ-monomethyl phosphate cap at the 5′-end of U6atac snRNA. The U-box protein PPIL2 coordinates loop I of U5 snRNA and stabilizes U5 snRNP. CRIPT stabilizes U12 snRNP. Our study provides a framework for mechanistic understanding of the function of the minor spliceosome.

scholarly journals U1 small nuclear RNAs with altered specificity can be stably expressed in mammalian cells and promote permanent changes in pre-mRNA splicing.

1993 ◽  
Vol 13 (5) ◽  
pp. 2666-2676 ◽  
Author(s):  
J B Cohen ◽  
S D Broz ◽  
A D Levinson
Keyword(s):  
Splice Site ◽  
Mammalian Cells ◽  
Mrna Processing ◽  
Mrna Splicing ◽  
Small Nuclear Rna ◽  
Splice Sites ◽  
Gene Complementation ◽  
Small Nuclear Rnas ◽  
Nuclear Rna ◽  
Mutant Genes

Pre-mRNA 5' splice site activity depends, at least in part, on base complementarity to U1 small nuclear RNA. In transient coexpression assays, defective 5' splice sites can regain activity in the presence of U1 carrying compensatory changes, but it is unclear whether such mutant U1 RNAs can be permanently expressed in mammalian cells. We have explored this issue to determine whether U1 small nuclear RNAs with altered specificity may be of value to rescue targeted mutant genes or alter pre-mRNA processing profiles. This effort was initiated following our observation that U1 with specificity for a splice site associated with an alternative H-ras exon substantially reduced the synthesis of the potentially oncogenic p21ras protein in transient assays. We describe the development of a mammalian complementation system that selects for removal of a splicing-defective intron placed within a drug resistance gene. Complementation was observed in proportion to the degree of complementarity between transfected mutant U1 genes and different defective splice sites, and all cells selected in this manner were found to express mutant U1 RNA. In addition, these cells showed specific activation of defective splice sites presented by an unlinked reporter gene. We discuss the prospects of this approach to permanently alter the expression of targeted genes in mammalian cells.

Exploitation of a thermosensitive splicing event to study pre-mRNA splicing in vivo

1988 ◽  
Vol 8 (4) ◽  
pp. 1558-1569
Author(s):  
P E Cizdziel ◽  
M de Mars ◽  
E C Murphy
Keyword(s):  
Splice Site ◽  
Rna Splicing ◽  
Mrna Splicing ◽  
Viral Rna ◽  
Temperature Sensitive ◽  
Exon Ligation ◽  
Branch Point Sequence ◽  
Infected Cells ◽  
Low Efficiency

The spliced form of MuSVts110 viral RNA is approximately 20-fold more abundant at growth temperatures of 33 degrees C or lower than at 37 to 41 degrees C. This difference is due to changes in the efficiency of MuSVts110 RNA splicing rather than selective thermolability of the spliced species at 37 to 41 degrees C or general thermosensitivity of RNA splicing in MuSVts110-infected cells. Moreover, RNA transcribed from MuSVts110 DNA introduced into a variety of cell lines is spliced in a temperature-sensitive fashion, suggesting that the structure of the viral RNA controls the efficiency of the event. We exploited this novel splicing event to study the cleavage and ligation events during splicing in vivo. No spliced viral mRNA or splicing intermediates were observed in MuSVts110-infected cells (6m2 cells) at 39 degrees C. However, after a short (about 30-min) lag following a shift to 33 degrees C, viral pre-mRNA cleaved at the 5' splice site began to accumulate. Ligated exons were not detected until about 60 min following the initial detection of cleavage at the 5' splice site, suggesting that these two splicing reactions did not occur concurrently. Splicing of viral RNA in the MuSVts110 revertant 54-5A4, which lacks the sequence -AG/TGT- at the usual 3' splice site, was studied. Cleavage at the 5' splice site in the revertant viral RNA proceeded in a temperature-sensitive fashion. No novel cryptic 3' splice sites were activated; however, splicing at an alternate upstream 3' splice site used at low efficiency in normal MuSVts110 RNA was increased to a level close to that of 5'-splice-site cleavage in the revertant viral RNA. Increased splicing at this site in 54-5A4 viral RNA is probably driven by the unavailability of the usual 3' splice site for exon ligation. The thermosensitivity of this alternate splice event suggests that the sequences governing the thermodependence of MuSVts110 RNA splicing do not involve any particular 3' splice site or branch point sequence, but rather lie near the 5' end of the intron.

U1 small nuclear RNAs with altered specificity can be stably expressed in mammalian cells and promote permanent changes in pre-mRNA splicing

1993 ◽  
Vol 13 (5) ◽  
pp. 2666-2676
Author(s):  
J B Cohen ◽  
S D Broz ◽  
A D Levinson
Keyword(s):  
Splice Site ◽  
Mammalian Cells ◽  
Mrna Processing ◽  
Mrna Splicing ◽  
Small Nuclear Rna ◽  
Splice Sites ◽  
Gene Complementation ◽  
Small Nuclear Rnas ◽  
Nuclear Rna ◽  
Mutant Genes

Pre-mRNA 5' splice site activity depends, at least in part, on base complementarity to U1 small nuclear RNA. In transient coexpression assays, defective 5' splice sites can regain activity in the presence of U1 carrying compensatory changes, but it is unclear whether such mutant U1 RNAs can be permanently expressed in mammalian cells. We have explored this issue to determine whether U1 small nuclear RNAs with altered specificity may be of value to rescue targeted mutant genes or alter pre-mRNA processing profiles. This effort was initiated following our observation that U1 with specificity for a splice site associated with an alternative H-ras exon substantially reduced the synthesis of the potentially oncogenic p21ras protein in transient assays. We describe the development of a mammalian complementation system that selects for removal of a splicing-defective intron placed within a drug resistance gene. Complementation was observed in proportion to the degree of complementarity between transfected mutant U1 genes and different defective splice sites, and all cells selected in this manner were found to express mutant U1 RNA. In addition, these cells showed specific activation of defective splice sites presented by an unlinked reporter gene. We discuss the prospects of this approach to permanently alter the expression of targeted genes in mammalian cells.

scholarly journals psiCLIP reveals dynamic RNA binding by DEAH-box helicases before and after exon ligation

2021 ◽  
Vol 12 (1) ◽  
Author(s):  
Lisa M. Strittmatter ◽  
Charlotte Capitanchik ◽  
Andrew J. Newman ◽  
Martina Hallegger ◽  
Christine M. Norman ◽  
...  
Keyword(s):  
Mechanism Of Action ◽  
Splice Site ◽  
Rna Binding ◽  
Mrna Splicing ◽  
Structural Studies ◽  
Rna Helicases ◽  
Exon Ligation ◽  
Before And After ◽  
The Stability

AbstractRNA helicases remodel the spliceosome to enable pre-mRNA splicing, but their binding and mechanism of action remain poorly understood. To define helicase-RNA contacts in specific spliceosomal states, we develop purified spliceosome iCLIP (psiCLIP), which reveals dynamic helicase-RNA contacts during splicing catalysis. The helicase Prp16 binds along the entire available single-stranded RNA region between the branchpoint and 3′-splice site, while Prp22 binds diffusely downstream of the branchpoint before exon ligation, but then switches to more narrow binding in the downstream exon after exon ligation, arguing against a mechanism of processive translocation. Depletion of the exon-ligation factor Prp18 destabilizes Prp22 binding to the pre-mRNA, suggesting that proofreading by Prp22 may sense the stability of the spliceosome during exon ligation. Thus, psiCLIP complements structural studies by providing key insights into the binding and proofreading activity of spliceosomal RNA helicases.

scholarly journals A human postcatalytic spliceosome structure reveals essential roles of metazoan factors for exon ligation

Science ◽  
2019 ◽  
Vol 363 (6428) ◽  
pp. 710-714 ◽  
Author(s):  
Sebastian M. Fica ◽  
Chris Oubridge ◽  
Max E. Wilkinson ◽  
Andrew J. Newman ◽  
Kiyoshi Nagai
Keyword(s):  
Electron Microscopy ◽  
Saccharomyces Cerevisiae ◽  
Alternative Splicing ◽  
Splice Site ◽  
Active Site ◽  
Messenger Rna ◽  
Functional Assays ◽  
Exon Ligation ◽  
Cryo Electron Microscopy ◽  
Fine Tune

During exon ligation, the Saccharomyces cerevisiae spliceosome recognizes the 3′-splice site (3′SS) of precursor messenger RNA (pre-mRNA) through non–Watson-Crick pairing with the 5′SS and the branch adenosine, in a conformation stabilized by Prp18 and Prp8. Here we present the 3.3-angstrom cryo–electron microscopy structure of a human postcatalytic spliceosome just after exon ligation. The 3′SS docks at the active site through conserved RNA interactions in the absence of Prp18. Unexpectedly, the metazoan-specific FAM32A directly bridges the 5′-exon and intron 3′SS of pre-mRNA and promotes exon ligation, as shown by functional assays. CACTIN, SDE2, and NKAP—factors implicated in alternative splicing—further stabilize the catalytic conformation of the spliceosome during exon ligation. Together these four proteins act as exon ligation factors. Our study reveals how the human spliceosome has co-opted additional proteins to modulate a conserved RNA-based mechanism for 3′SS selection and to potentially fine-tune alternative splicing at the exon ligation stage.

scholarly journals Exploitation of a thermosensitive splicing event to study pre-mRNA splicing in vivo.

1988 ◽  
Vol 8 (4) ◽  
pp. 1558-1569 ◽  
Author(s):  
P E Cizdziel ◽  
M de Mars ◽  
E C Murphy
Keyword(s):  
Splice Site ◽  
Rna Splicing ◽  
Mrna Splicing ◽  
Viral Rna ◽  
Temperature Sensitive ◽  
Exon Ligation ◽  
Branch Point Sequence ◽  
Infected Cells ◽  
Low Efficiency

The spliced form of MuSVts110 viral RNA is approximately 20-fold more abundant at growth temperatures of 33 degrees C or lower than at 37 to 41 degrees C. This difference is due to changes in the efficiency of MuSVts110 RNA splicing rather than selective thermolability of the spliced species at 37 to 41 degrees C or general thermosensitivity of RNA splicing in MuSVts110-infected cells. Moreover, RNA transcribed from MuSVts110 DNA introduced into a variety of cell lines is spliced in a temperature-sensitive fashion, suggesting that the structure of the viral RNA controls the efficiency of the event. We exploited this novel splicing event to study the cleavage and ligation events during splicing in vivo. No spliced viral mRNA or splicing intermediates were observed in MuSVts110-infected cells (6m2 cells) at 39 degrees C. However, after a short (about 30-min) lag following a shift to 33 degrees C, viral pre-mRNA cleaved at the 5' splice site began to accumulate. Ligated exons were not detected until about 60 min following the initial detection of cleavage at the 5' splice site, suggesting that these two splicing reactions did not occur concurrently. Splicing of viral RNA in the MuSVts110 revertant 54-5A4, which lacks the sequence -AG/TGT- at the usual 3' splice site, was studied. Cleavage at the 5' splice site in the revertant viral RNA proceeded in a temperature-sensitive fashion. No novel cryptic 3' splice sites were activated; however, splicing at an alternate upstream 3' splice site used at low efficiency in normal MuSVts110 RNA was increased to a level close to that of 5'-splice-site cleavage in the revertant viral RNA. Increased splicing at this site in 54-5A4 viral RNA is probably driven by the unavailability of the usual 3' splice site for exon ligation. The thermosensitivity of this alternate splice event suggests that the sequences governing the thermodependence of MuSVts110 RNA splicing do not involve any particular 3' splice site or branch point sequence, but rather lie near the 5' end of the intron.

The phylogenetically invariant ACAGAGA and AGC sequences of U6 small nuclear RNA are more tolerant of mutation in human cells than in Saccharomyces cerevisiae

1993 ◽  
Vol 13 (9) ◽  
pp. 5377-5382
Author(s):  
B Datta ◽  
A M Weiner
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Transient Expression ◽  
Human Cells ◽  
Mrna Splicing ◽  
Small Nuclear Rna ◽  
Transient Expression Assay ◽  
U6 Snrna ◽  
Nuclear Rna

U6 small nuclear RNA (snRNA) is the most highly conserved of the five spliceosomal snRNAs that participate in nuclear mRNA splicing. The proposal that U6 snRNA plays a key catalytic role in splicing [D. Brow and C. Guthrie, Nature (London) 337:14-15, 1989] is supported by the phylogenetic conservation of U6, the sensitivity of U6 to mutation, cross-linking of U6 to the vicinity of the 5' splice site, and genetic evidence for extensive base pairing between U2 and U6 snRNAs. We chose to mutate the phylogenetically invariant 41-ACAGAGA-47 and 53-AGC-55 sequences of human U6 because certain point mutations within the homologous regions of Saccharomyces cerevisiae U6 selectively block the first or second step of mRNA splicing. We found that both sequences are more tolerant to mutation in human cells (assayed by transient expression in vivo) than in S. cerevisiae (assayed by effects on growth or in vitro splicing). These differences may reflect different rate-limiting steps in the particular assays used or differential reliance on redundant RNA-RNA or RNA-protein interactions. The ability of mutations in U6 nucleotides A-45 and A-53 to selectively block step 2 of splicing in S. cerevisiae had previously been construed as evidence that these residues might participate directly in the second chemical step of splicing; an indirect, structural role seems more likely because the equivalent mutations have no obvious phenotype in the human transient expression assay.

An mRNA-type intron is present in the Rhodotorula hasegawae U2 small nuclear RNA gene

1993 ◽  
Vol 13 (9) ◽  
pp. 5613-5619
Author(s):  
Y Takahashi ◽  
S Urushiyama ◽  
T Tani ◽  
Y Ohshima
Keyword(s):  
Mrna Splicing ◽  
Small Nuclear Rna ◽  
U2 Snrna ◽  
U6 Snrna ◽  
Branch Site ◽  
Snrna Gene ◽  
Nuclear Rna ◽  
Catalytic Role ◽  
Mrna Precursor ◽  
Site Recognition

Splicing an mRNA precursor requires multiple factors involving five small nuclear RNA (snRNA) species called U1, U2, U4, U5, and U6. The presence of mRNA-type introns in the U6 snRNA genes of some yeasts led to the hypothesis that U6 snRNA may play a catalytic role in pre-mRNA splicing and that the U6 introns occurred through reverse splicing of an intron from an mRNA precursor into a catalytic site of U6 snRNA. We characterized the U2 snRNA gene of the yeast Rhodotorula hasegawae, which has four mRNA-type introns in the U6 snRNA gene, and found an mRNA-type intron of 60 bp. The intron of the U2 snRNA gene is present in the highly conserved region immediately downstream of the branch site recognition domain. Interestingly, we found that this region can form a novel base pairing with U6 snRNA. We discuss the possible implications of these findings for the mechanisms of intron acquisition and for the role of U2 snRNA in pre-mRNA splicing.

scholarly journals U4 small nuclear RNA dissociates from a yeast spliceosome and does not participate in the subsequent splicing reaction.

1991 ◽  
Vol 11 (11) ◽  
pp. 5571-5577 ◽  
Author(s):  
S L Yean ◽  
R J Lin
Keyword(s):  
Mrna Splicing ◽  
Yeast Cells ◽  
Temperature Sensitive ◽  
Small Nuclear Rna ◽  
Small Nuclear Rnas ◽  
Nuclear Rna ◽  
Sensitive Allele ◽  
U4 Rna ◽  
Small Nuclear Ribonucleoproteins

U4 and U6 small nuclear RNAs reside in a single ribonucleoprotein particle, and both are required for pre-mRNA splicing. The U4/U6 and U5 small nuclear ribonucleoproteins join U1 and U2 on the pre-mRNA during spliceosome assembly. Binding of U4 is then destabilized prior to or concomitant with the 5' cleavage-ligation. In order to test the role of U4 RNA, we isolated a functional spliceosome by using extracts prepared from yeast cells carrying a temperature-sensitive allele of prp2 (rna2). The isolated prp2 delta spliceosome contains U2, U5, U6, and possibly also U1 and can be activated to splice the bound pre-mRNA. U4 RNA does not associate with the isolated spliceosomes and is shown not to be involved in the subsequent cleavage-ligation reactions. These results are consistent with the hypothesis that the role of U4 in pre-mRNA splicing is to deliver U6 to the spliceosome.

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