Precursor-mRNA splicing is catalyzed by an extraordinarily large and highly dynamic macromolecular assemblage termed the spliceosome. Detailed biochemical and structural study of the spliceosome presents a formidable challenge, but there has recently been significant progress made on this front highlighted by the crystal structure of a 10-subunit human U1 snRNP. This review provides an overview of our current understanding of the architecture of the spliceosome and the RNA-protein complexes integral to its function, the U snRNPs.
In yeast, the U2 small nuclear ribonucleic acid (snRNA) component of the spliceosome is targeted for additional post-transcriptional modifications in response to cellular stress. Uridines 56 and 93 are both modified to pseudouridines (Ψ) during nutrient deprivation, while U56 is also pseudouridylated during heat shock. Both positions are located within stem II, which must toggle between two mutually exclusive structures during splicing. Stem IIa forms during spliceosome assembly, and stem IIc forms during the catalytic steps. We have studied how uridine 56 and 93 pseudouridylation impacts conformational switching of stem II. Using single-molecule Förster resonance energy transfer, we show that Ψ56 dampens conformational dynamics of stem II and stabilizes stem IIc. In contrast, Ψ93 increases dynamics of non-stem IIc conformations. Pseudouridylation impacts conformational switching of stem II by Mg or the U2 protein Cus2; however, when Mg and Cus2 are used in combination, the impacts of pseudouridylation can be suppressed. These results show that stress-induced post-transcriptional modification of U56 and U93 alters snRNA conformational dynamics by distinct mechanisms and that protein and metal cofactors of the spliceosome alter how snRNAs respond to these modifications.
The DEAD-box family of proteins are ATP-dependent, RNA-binding proteins implicated in many aspects of RNA metabolism. Pre-mRNA splicing in eukaryotes requires three DEAD-box ATPases (Prp5, Prp28 and Sub2), the molecular mechanisms of which are poorly understood. Here, we use single molecule FRET (smFRET) to study the conformational dynamics of yeast Prp5. Prp5 is essential for stable association of the U2 snRNP with the intron branch site (BS) sequence during spliceosome assembly. Our data show that the Prp5 RecA-like domains undergo a large conformational rearrangement only in response to binding of both ATP and RNA. Mutations in Prp5 impact the fidelity of BS recognition and change the conformational dynamics of the RecA-like domains. We propose that BS recognition during spliceosome assembly involves a set of coordinated conformational switches among U2 snRNP components. Spontaneous toggling of Prp5 into a stable, open conformation may be important for its release from U2 and to prevent competition between Prp5 re-binding and subsequent steps in spliceosome assembly.
Highlights d Network models were built from spliceosome structures captured at different steps d Spliceosome structural dynamics result in step-specific network fluctuations d Network connectivity is centered around the spliceosome active site d Betweenness parameters correlate with genetic lethality for splicing factors
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