Christine Guthrie

Mechanical Devices of the Spliceosome: Motors, Clocks, Springs, and Things

We thank J. Thorner, J. Lorsch, and D. Herschlag for provocative discussions; J. Abelson, R. Luhrmann, T. Nilsen, and R. Reed for preprints; and G. Chanfreau, C. Collins, A. Frankel, A. Kistler, K. Lynch, S. Rader, B. Raumann, D. Ryan, C. Siebel, J. Wagner, Y. Wang, J. Wilhelm, and members of the Guthrie laboratory for critical reading of the manuscript. We are indebted to S. Korolev and G. Waksman (Washington University School of Medicine) and P. Weber (Schering-Plough Research Institute) for contributing Figure 8Figure 8. We apologize to our colleagues for work that could not be cited due to a limitation on references. Cited work from this laboratory is supported by NIH grant GM21119 to C. G. J. P. S. is supported by a California Division-American Cancer Society Fellowship #1–59–97B. C. G. is an American Cancer Society Research Professor of Molecular Genetics.

Exportin 1 (Crm1p) Is an Essential Nuclear Export Factor

Nuclear protein export is mediated by nuclear export signals (NESs), but the mechanisms governing this transport process are not well understood. Using a novel protein export assay in S. cerevisiae, we identify CRM1 as an essential mediator of nuclear protein export in yeast. Crm1p shows homology to importin beta-like transport factors and is able to specifically interact with both the NES motif and the Ran GTPase. A mutation in the shuttling protein Crm1p affects not only protein export, but also mRNA export, indicating that these pathways are tightly coupled in S. cerevisiae. The presented data are consistent with the conclusion that Crm1p is a carrier for the NES-mediated protein export pathway. We propose CRM1 be renamed exportin 1 (XPO1).

A novel base-pairing interaction between U2 and U6 snRNAs suggests a mechanism for the catalytic activation of the spliceosome

Prior to the chemical steps of mRNA splicing, the extensive base-pairing interaction between the U4 and U6 spliceosomal snRNAs is disrupted. Here, we use a mutational analysis in yeast to demonstrate a conserved base-pairing interaction between the U6 and U2 snRNAs that is mutually exclusive with the U4-U6 interaction. In this novel pairing, conserved sequences in U6 interact with a sequence in U2 that is immediately upstream of the branch point recognition region. Remarkably, the residues in U6 that can be consequently juxtaposed with the intron substrate include those that have been proposed previously to be catalytic. Both the first and second steps of splicing are inhibited when this base-paired structure is mutated. These observations, together with the high conservation of the U2-U6 structure, lead us to propose that it might be a component of the spliceosomal active site.

Recognition of the TACTAAC box during mRNA splicing in yeast involves base pairing to the U2-like snRNA

The U2 snRNP binds to the site of branch formation during splicing of mammalian pre-mRNA in vitro. In Saccharomyces cerevisiae the branch site is within the so-called TACTAAC box (UACUAAC box), an absolutely conserved intron sequence required for splicing. Based on the identification and sequence of a U2 analogue in yeast, a specific base pairing interaction between the UACUAAC box and a highly conserved region of this snRNA can be proposed. To test this hypothesis, we have taken advantage of two mutations constructed previously in the UACUAAC box of an actin-HIS4 fusion. These mutant strains were transformed with stable plasmids bearing U2-like snRNAs into which changes predicted to restore base pairing had been introduced. Allele-specific suppression of biological and biochemical phenotypes was observed in both cases. Recognition of the UACUAAC box thus relies, at least in part, on Watson-Crick base pairing with the yeast U2 analogue.

RNA unwinding in U4/U6 snRNPs requires ATP hydrolysis and the DEIH-box splicing factor Brr2

BACKGROUND The dynamic rearrangements of RNA structure which occur during pre-mRNA splicing are thought to be mediated by members of the DExD/H-box family of RNA-dependent ATPases. Although three DExD/H-box splicing factors have recently been shown to unwind synthetic RNA duplexes in purified systems, in no case has the natural biological substrate been identified. A duplex RNA target of particular interest is the extensive base-pairing interaction between U4 and U6 small nuclear RNAs. Because these helices must be disrupted to activate the spliceosome for catalysis, this rearrangement is believed to be tightly regulated in vivo. RESULTS We have immunopurified Brr2, a DEIH-box ATPase, in a native complex containing U1, U2, U5 and duplex U4/U6 small nuclear ribonucleoprotein particles (snRNPs). Addition of hydrolyzable ATP to this complex results in the disruption of U4/U6 base-pairing, and the release of free U4 and U6 snRNPs. A mutation in the helicase-like domain of Brr2 (brr2-1) prevents these RNA rearrangements. Notably, U4/U6 dissociation and release occur in the absence of exogenously added pre-mRNA. CONCLUSIONS Disruption of U4/U6 base-pairing in native snRNPs requires ATP hydrolysis and Brr2. This is the first assignment of a DExD/H-box splicing factor to a specific biological unwinding event. The unwinding function of Brr2 can be antagonized by the annealing activity of Prp24. We propose the existence of a dynamic cycle, uncoupled from splicing, that interconverts free and base-paired U4/U6 snRNPs.

A Genetic Interaction Map of RNA Processing Factors Reveals Links Between Sem1/Dss1-Containing Complexes and mRNA Export and Splicing

We used a quantitative, high-density genetic interaction map, or E-MAP (Epistatic MiniArray Profile), to interrogate the relationships within and between RNA-processing pathways. Due to their complexity and the essential roles of many of the components, these pathways have been difficult to functionally dissect. Here, we report the results for 107,155 individual interactions involving 552 mutations, 166 of which are hypomorphic alleles of essential genes. Our data enabled the discovery of links between components of the mRNA export and splicing machineries and Sem1/Dss1, a component of the 19S proteasome. In particular, we demonstrate that Sem1 has a proteasome-independent role in mRNA export as a functional component of the Sac3-Thp1 complex. Sem1 also interacts with Csn12, a component of the COP9 signalosome. Finally, we show that Csn12 plays a role in pre-mRNA splicing, which is independent of other signalosome components. Thus, Sem1 is involved in three separate and functionally distinct complexes.

The Glc7p Nuclear Phosphatase Promotes mRNA Export by Facilitating Association of Mex67p with mRNA

mRNA export is mediated by Mex67p:Mtr2p/NXF1:p15, a conserved heterodimeric export receptor that is thought to bind mRNAs through the RNA binding adaptor protein Yra1p/REF. Recently, mammalian SR (serine/arginine-rich) proteins were shown to act as alternative adaptors for NXF1-dependent mRNA export. Npl3p is an SR-like protein required for mRNA export in S. cerevisiae. Like mammalian SR proteins, Npl3p is serine-phosphorylated by a cytoplasmic kinase. Here we report that this phosphorylation of Npl3p is required for efficient mRNA export. We further show that the mRNA-associated fraction of Npl3p is unphosphorylated, implying a subsequent nuclear dephosphorylation event. We present evidence that the essential, nuclear phosphatase Glc7p promotes dephosphorylation of Npl3p in vivo and that nuclear dephosphorylation of Npl3p is required for mRNA export. Specifically, recruitment of Mex67p to mRNA is Glc7p dependent. We propose a model whereby a cycle of cytoplasmic phosphorylation and nuclear dephosphorylation of shuttling SR adaptor proteins regulates Mex67p:Mtr2p/NXF1:p15-dependent mRNA export.

The question remains: Is the spliceosome a ribozyme?

The two phosphoryl transfer steps of pre-mRNA splicing are catalyzed within the large ribonuclear protein machine called the spliceosome. The highly dynamic nature of the spliceosome has presented many challenges to a structural and mechanistic understanding of its catalytic core. While much evidence supports the popular hypothesis that the catalytic steps of pre-mRNA splicing are mediated by spliceosomal RNA, a role for protein in catalysis cannot yet be ruled out. A highly conserved protein, Prp8, is a component of the catalytic core. We review data consistent with the hypothesis that Prp8 functions as a cofactor to an RNA enzyme.

A mechanism to enhance mRNA splicing fidelity: The RNA-dependent ATPase Prp16 governs usage of a discard pathway for aberrant lariat intermediates

PRP16 encodes an RNA-dependent ATPase required for the second step of mRNA splicing in S. cerevisiae. We have isolated seven alleles of PRP16 that, like the original allele prp16-1, allow splicing of introns with a mutant branch site (UACUAAC to UACUACC), by forming lariat intermediates at the mutant C nucleotide. Every suppressor mutation maps to the region of PRP16 common to RNA-dependent ATPases. We purified three of the mutant proteins and found that all exhibit reduced ATPase activity, as does Prp16-1. An in vivo analysis of the steady-state levels of the splicing intermediates and products provides evidence for a pathway, under the genetic control of PRP16, to discard incorrectly branched substrates. We propose that decreasing the rate of ATP hydrolysis by Prp16 allows aberrantly formed lariat intermediates more time to proceed through the productive rather than the discard branch of this pathway.

Mutations in conserved intron sequences affect multiple steps in the yeast splicing pathway, particularly assembly of the spliceosome.

Yeast introns contain three highly conserved sequences which are known to be required for splicing of pre‐mRNA. Using in vitro mutagenesis, we have synthesized seven point mutations at five different sites in these signals in the yeast actin intron. The mutant introns were then inserted into each of three constructs, which allowed us to assess the consequences both in vivo and in vitro. In virtually every case, we found the efficiency of splicing to be significantly depressed; mature mRNA levels in vivo ranged from 0 to 47% of wild‐type. Surprisingly, the tightest mutations were not necessarily at the sites of nucleolytic cleavage and branch formation; these nucleotides are thus highly preferred, but are not absolutely necessary. Moreover, while particular nucleotides are specifically required for the final step in splicing, i.e. 3′ cleavage and exon ligation, the predominant consequence of mutation within the conserved signals appears to be the inhibition of assembly of the splicing complex.