EXTRA VIEW Nucleus 6:6, 455--461; November/December 2015; © 2015 Taylor & Francis Group, LLC

Intron or no intron: a matter for nuclear pore complexes Amandine Bonnet and Benoit Palancade* Institut Jacques Monod; CNRS; UMR 7592; Univ Paris Diderot; Sorbonne Paris Cite; Paris, France

N

Keywords: nuclear pore complexes, mRNA transcription, mRNA quality control, mRNA export, sumoylation, SUMO-protease Ulp1, THO/TREX complex Abbreviations: MPA, mycophenolic acid; mRNP, messenger ribonucleoparticle; NPC, nuclear pore complex; SUMO, small ubiquitin-like modifier; THO, suppressor of the transcriptional defect of hpr1 by overexpression; TREX, transcription and export complex *Correspondence to: Benoit Palancade; Email: [email protected] Submitted: 10/14/2015 Revised: 10/29/2015 Accepted: 11/01/2015 http://dx.doi.org/10.1080/19491034.2015.1116660 Extra View to: Bonnet A, Bretes H, Palancade B. Nuclear pore components affect distinct stages of intron-containing gene expression. Nucleic Acids Res. 2015 Apr 30; 43(8):4249–61; http://dx. doi.org/10.1093/nar/gkv280

www.tandfonline.com

uclear pore complexes (NPCs) have been shown to regulate distinct steps of the gene expression process, from transcription to mRNA export. In particular, mRNAs expressed from intron-containing genes are surveyed by a specific NPC-dependent quality control pathway ensuring that unspliced mRNAs are retained within the nucleus. In this Extra View, we summarize the different approaches that have been developed to evaluate the contribution of various NPC components to the expression of introncontaining genes. We further present the mechanistic models that could account for pre-mRNA retention at the nuclear side of NPCs. Finally, we discuss the possibility that other stages of intron-containing gene expression could be regulated by nuclear pores, in particular through the regulation of mRNA biogenesis factors by the NPC-associated SUMO protease Ulp1.

Introduction Nuclear pore complexes (NPCs) are large macromolecular assemblies inserted within the nuclear envelope and composed of multiple copies of proteins called nucleoporins (Nups). Subcomplexes of Nups form a structural scaffold which surrounds a central channel harboring phenylalanine-glycine (FG) repeats involved in dynamic interactions with the cargoes, e.g. proteins and ribonucleoparticles. While several decades of research have provided detailed information about the function of NPCs as gateways for the nucleo-cytoplasmic trafficking of macromolecules, an increasing number of reports have revealed that NPCs have also important roles in gene expression, Nucleus

genome maintenance and cell cycle progression.1 Establishment of gene expression programs requires the integration of the multiple nuclear and cytoplasmic steps of mRNA metabolism, including transcription, processing, nuclear export, translation and degradation. Besides the critical function of FG-containing nucleoporins in the translocation of mRNAs into the cytoplasm, other NPC components have also been shown to contribute directly, or indirectly, to different stages of the gene expression process.2,3 One of the central players in the connection between NPC and gene expression is the nuclear basket, a peripheral extension of the nuclear pore which protrudes toward the nucleus and forms a platform which interacts with genes, mRNAs and other regulators, such as the SUMO-deconjugating enzyme Ulp1/SENP2, both in yeast and metazoans.4 Notably, proteins of the nuclear basket have been involved in a quality control mechanism preventing the export of misassembled or unprocessed messenger ribonucleoparticles (mRNPs), in particular pre-mRNAs harboring an unspliced intron.5 Cytoplasmic pre-mRNA leakage has been observed in a number of mutant conditions5, notably in yeast cells inactivated for nuclear basket components (Nup60, Mlp1)6 or their interacting partners (Pml39, Ulp1).7,8 However, the molecular mechanisms underlying the relative contribution of these different players to the nuclear retention of introncontaining pre-mRNAs have remained elusive. In spite of the additional costs associated with intron-containing mRNA metabolism, eukaryotic genomes benefit from the presence of introns in various 455

situations: intron retention modulates transcript stability and thereby gene expression levels9; alternative splicing increases the diversity of the proteome10; and introns can stimulate mRNA export.11 In view of the important flow of intron-containing mRNAs produced in eukaryotic cells, regulated splicing events must be precisely coordinated with mRNA export in order to prevent premRNA translation into aberrant proteins. In this Extra View, we will focus on the role of nuclear pore components in the control of intron-containing gene expression, from transcription to pre-mRNA retention, mainly based on studies performed in S. cerevisiae. For further details about the connection between gene expression and NPCs in other model organisms, the reader is invited to refer to review articles where this topic has been extensively discussed.2,3,5

Unraveling the Multiple Roles of Nuclear Pore Components in the Expression of Intron-Containing Genes Several complementary approaches have been used in the past to decipher the multiple contributions of nucleoporins to gene expression in budding yeast.2 Chromatin immunoprecipitation12,13,14 and microscopy observation of tagged loci15,16,17,18 have revealed the interaction of NPCs with a subset of genes. In addition, molecular analyses and reporter systems have uncovered gene expression defects in nucleoporin mutants.19,20,21,22 Finally, in situ hybridization and dedicated assays have been used to monitor mRNA export and pre-mRNA retention, as previously reviewed.5 We have recently investigated the molecular basis for NPC-associated premRNA quality control and further clarified the role of distinct nuclear pore components in unspliced mRNA retention.23 For this purpose, we took advantage of a set of LacZ-based reporter constructs24 to evaluate mRNA expression, mRNA splicing and cytoplasmic pre-mRNA leakage. These analyses have been performed in a battery of yeast mutants affecting the nuclear pore scaffold (Nup133, Nup120,

456

Nup188), the nuclear basket (Mlp1, Pml39, Ulp1) or representative components of the mRNA biogenesis/export pathway, such as mRNA export adaptors (Yra1, Nab2, Npl3), the mRNA export receptor (Mex67) and other mRNP-associated factors previously shown to couple transcription with export (THO/TREX, TREX-2). Since previous characterization of these mutants had revealed profound defects in gene transcription that could possibly hinder pre-mRNA leakage phenotypes,20,25,26 we have used an ultra-sensitive b-galactosidase assay with improved properties (e.g., fast and amenable to medium-throughput screening) in order to distinguish mutants affecting premRNA retention from those affected at another stage of the gene expression process. Through this study, we have been able to define 2 classes of mutants: (i) mutants of the nuclear basket (mlp1D, pml39D), which trigger bona fide pre-mRNA leakage, and (ii) mutants of the Nup84 NPC subcomplex (nup120D, nup133D), which exhibit decreased levels of the SUMOprotease Ulp1 at NPCs27 and primarily affect expression of the reporter constructs. Epistasis analysis further revealed that Ulp1 acts on gene expression by targeting the previously reported sumoylation of the Hpr1 subunit of the THO complex,28 a process independent from the pre-mRNA retention mediated by Mlp1/Pml39.23 In addition, this study uncovered an unexpected feature of mutants affecting the Nup84 complex, the SUMO-protease Ulp1 or the THO complex, e.g. that they have less pronounced effects on the transcription of intron-containing genes as compared to intronless genes.23 An alternative system, in which the unspliced and the spliced versions of an unique reporter gene encode distinct fluorescent proteins, has been recently used to evaluate pre-mRNA splicing and premRNA export by multicolor flow cytometry analysis of yeast cell populations.29 The use of this reporter system notably allowed to define typical expression signatures in mRNA transcription or export mutants. In particular, it suggested an increased pre-mRNA splicing in mutants primarily affecting mRNA export, a result

Nucleus

consistent with the phenotypes that we scored using LacZ-based reporters in some mRNA export mutants (e.g., yra1 and nab2).23 These findings likely reflect the fact that an extended nuclear retention in export mutants favors the splicing of the poorly spliced introns present in both reporters.24,29 Another advantage of this fluorescent reporter is that it could also measure cell-to-cell variations in gene expression processes. However, the design of this assay did not take into account the expression of the corresponding intronless gene and, thereby, was not expected to identify the differential requirement of Nup84/Ulp1/THO for intron-containing and intronless gene expression as displayed in our study. The combined use of both enzymatic and cytometry reporter-based assays is therefore appropriate to further refine our understanding of the multiple stages of intron-containing gene expression, from transcription, splicing to premRNA retention and mRNA export.

Different Models Accounting for Intron-Containing mRNA Retention at Nuclear Pores Our study,23 along with previous reports, has revealed that bona fide premRNA leakage is a defining feature of a subset of nuclear pore mutants, e.g. those affecting the structural component of the nuclear basket Mlp1 and its interacting partner Pml39. Biochemical analyses further demonstrated that these factors are not required for the proper formation of export-competent mRNPs,23 in agreement with a later function at the export stage. However, it remains unclear whether Mlp1/Pml39 rather select fully processed/assembled mRNPs and favor their commitment into the mRNA export pathway, or retain at NPCs unprocessed/ misassembled mRNPs – including introncontaining mRNPs, and further prevent their translocation.30 In the “selection” model (Fig. 1A), nuclear basket-associated proteins would bind completely processed mRNPs and further favor their export. Proteomic analyses of mRNP composition have indeed revealed that Mlp1 and its paralogue Mlp2 interact with a number of mRNP

Volume 6 Issue 6

Figure 1. Models accounting for nuclear poreassociated quality control prior to mRNA export (A). In the “selection” model, the nuclear basket only docks export-competent mRNPs by interacting with dedicated mRNP components, while faulty mRNPs, unable to interact with the NPC, are retained in the nucleus. Proteins possibly marking exportcompetent particles are depicted. (B) In the “retention” model, the nuclear basket would interact with proteins specifically present on unprocessed mRNPs, preventing their export through the pore. Putative signals of incomplete processing are represented. (C) Both models can be reconciled if physical interactions of different strengths are engaged between the nuclear basket and distinct kinds of mRNPs. Dynamic interactions with exportcompetent mRNPs would favor their export while stronger interactions with faulty mRNPs would durably tether them at NPCs, either favoring the completion of processing/packaging events or triggering degradation by the NPC-associated endonuclease Swt1.

components.28,31 Proteins that could specify the complete processing and/or

www.tandfonline.com

packaging status of the mRNAs include: (i) the SR-proteins Gbp2 and Hrb1,

Nucleus

which have been reported to bind spliced transcripts and to favor their interaction with the export receptor Mex67, and whose inactivation triggers pre-mRNA leakage32 ; (ii) the poly(A)-binding protein and mRNA export adaptor Nab2, whose interaction with Mlp1 is required for optimal mRNA export.33 It should however be pointed that inactivation of MLP1 or PML39 is not sufficient per se to trigger bulk mRNA accumulation in the nucleus,6,7 suggesting that mRNA selection at NPCs is not a mandatory step in the mRNA export process. Alternatively, in the “retention” model (Fig. 1B), proteins specifically associated with faulty mRNPs would be recognized by the nuclear basket and these interactions would then trigger their retention in the nucleus. In this scenario, incomplete mRNA splicing could be signaled by yetto-be-identified intron-associated proteins. Supporting this hypothesis, Mlp1 was reported to interact with the branchpoint-binding protein Msl5, albeit in a RNA-dependent manner,6 while the Pml1 subunit of the Retention and Splicing (RES) complex was shown to contribute to Mlp1/Pml39-mediated pre-mRNA retention.7,34 Strikingly, the presence of the 50 splice site motif was recently reported to trigger nuclear retention of transcripts in mammalian cells,35 suggesting that the presence of intron-associated factors may be a conserved feature

457

recognized in retained mRNPs. Nuclear pore components would not only sense unspliced mRNAs, but also improperly packaged mRNPs, as revealed by the increased interaction of the nuclear basket with aberrant mRNPs formed in yra1 mutant cells.26 These two models, albeit exclusive at first glance, could be reconciled if the residence time at the nuclear basket of distinct kinds of mRNPs would vary depending on their composition, and thereby on their processing. An extended or stronger interaction would stably tether to NPCs those mRNPs that are not fully mature or packaged, preventing their translocation, and providing an additional time window for processing reactions – such as splicing - or for degradation by the NPC-associated endonuclease Swt136 (Fig. 1C). Such a model would be in agreement with recent single-molecule microscopy analyses of mRNA export in animal cells, which have detected a mRNP docking step at the nuclear side of the nuclear envelope.37

Similar transport studies for mRNAs expressed from intronless or intron-containing genes, in wt and mutants affecting the nuclear pore basket or any of the above-mentioned players, would certainly provide insights into the mechanism of quality control at NPCs.

A Role for the Nup84 Complex and Ulp1 in Gene Transcription Our study has also revealed a decreased expression of LacZ reporter constructs in the absence of the Nup84 complex. Several reports had previously indicated that the Nup84 complex contributes to different stages of transcription, namely transcriptional activation by the Rap1/Gcr1/Gcr2 complex,19 repression of subtelomeric transcription,38 and transcription elongation.20 However, the underlying mechanisms were poorly documented.

In view of its well-known roles in nuclear envelope organization, mRNA export or maintenance of the SUMOprotease Ulp1 at nuclear pores,27,39 several hypotheses could account for the function of the Nup84 complex in gene expression. However, our data revealing the phenotypic similarity between Nup84 and ulp1 mutants in the intronless/intron-containing reporter assay rather favor a model in which the Nup84 complex tethers Ulp1 at NPCs, thereby regulating the sumoylation of specific targets involved in transcription. Of note, a number of reports have indicated that central players in the abovementioned processes are regulated in a SUMO-dependent manner (Fig. 2). Sumoylation of Rap1 favors TFIID recruitment, thereby potentiating its transcriptional activation.40 Sumoylation of the Sir2 histone deacetylase disrupts its interaction with the telomeric silencing complex, further promoting transcriptional derepression at

Figure 2. Possible functions of the Nup84 complex and Ulp1 in gene transcription. The sumoylated components of the transcription machinery which could mediate the roles of the Nup84 complex and Ulp1 in gene expression are represented. While Ulp1 was shown to target both Ssn6 and the THO complex for desumoylation,21,28 its activity toward Rap1 and Sir2 has not been investigated. The different boxes illustrate the positive role of sumoylated Rap1 in transcriptional activation (left), as well as the function of sumoylated Ssn6 and desumoylated Sir2 in transcriptional repression at glucoserepressed genes and subtelomeres, respectively (center). THO complex sumoylation differentially affects the expression of intron-containing and intronless reporters, most likely at the transcriptional elongation stage23 (right). RNAP II, RNA polymerase II.

458

Nucleus

Volume 6 Issue 6

subtelomeres.41 Sumoylation of the Hpr1 subunit of the THO complex regulates mRNP assembly,28 possibly impacting on transcriptional elongation. Epistasis analyses further support the fact that some of the contributions of Ulp1 to gene expression depend on Hpr1 sumoylation.23 Additional analyses of non-sumoylatable mutants of these different targets, in combination with Nup84 complex or Ulp1 inactivation, could indicate to which extent SUMO-dependent processes actually connect the NPC to gene transcription. In this respect, an elegant study recently reported that Ulp1-mediated desumoylation of the transcriptional repressor Ssn6 contributes to derepression of the GAL locus.21 In the future, systematic identification of Ulp1 targets within the transcription and mRNA processing machineries will certainly shed a new light on the intimate relationships between gene expression and nuclear pores.

A Differential Requirement of the THO Complex for IntronContaining and Intronless Gene Expression Beyond an alteration of transcription, our study revealed a lower impact of Nup84 complex, ulp1 and THO complex mutants on the expression of distinct intron-containing reporters as compared to their intronless counterpart.23 The THO complex is a conserved multiprotein assembly, which is recruited onto transcribed chromatin and mRNAs, and contributes to mRNP assembly, stability and export. Improper mRNP formation in tho mutants is believed to trigger the accumulation of mRNA::DNA hybrids (or Rloops), which are detrimental for transcription elongation, interfere with replication and further enhance genetic instability.42 Previous studies have indicated that the THO complex is mainly required for the expression of highly expressed genes,42,43 suggesting that a complete mRNP packaging machinery is critical in case of elevated levels of mRNA production. Consistently, a reduction in the rates of transcription

www.tandfonline.com

initiation or elongation has been reported to suppress the recombination and expression defects associated with THO inactivation.43,44,45 Our observation that introns can also alleviate the phenotypes of tho mutants could thus be easily explained if the presence of introns led to lowered transcription rates. However, this hypothesis is not currently supported by our data: first, tho phenotypes have been suppressed in the context of strong decreases in transcription initiation, achieved by either mutating the essential initiation factor TFIIH or modifying the promoter,44,45 whereas our chromatin immunoprecipitation assays have revealed that the presence of the intron does not lead to a detectable decrease in transcription initiation.23 Second, tho mutant gene expression defects were previously suppressed by treatment with mycophenolic acid (MPA), an inhibitor of transcription elongation44; in contrast, similar MPA treatment of tho cells did not alleviate the expression defects of the LacZ intronless reporter as an intron did (our unpublished results). Another mechanism may explain how introns alleviate the transcriptional defects of tho mutants: alternative mRNP assembly pathways may contribute to the packaging of intron-containing mRNAs, in particular upon THO complex deficiencies. Consistent with this hypothesis, an earlier report suggested differences in mRNP composition between mRNAs expressed from intron-containing and intronless genes in wt cells.46 Candidate factors that may take over mRNP assembly at intron-containing mRNAs in case of improper function of the THO complex include: (i) the SR-protein Npl3, which has been identified in association with the spliceosome47 and can function as an adaptor for the mRNA export receptor Mex6748; (ii) the splicing helicase Sub2, which can interact with the mRNA export adaptor Yra149; and (iii) the spliceosome-associated Prp19-complex,50 whose inactivation is lethal in the context of yeast tho mutants. Gene-specific analyses of mRNP composition should further allow to determine how introns can impact on mRNA biogenesis and export, in normal and challenged situations.

Nucleus

Conclusion Multiple reports have revealed that distinct nuclear pore components can modulate gene expression, either directly, through interactions between Nups and genes/mRNPs, or indirectly, by targeting the sumoylation of the transcription machinery. Of note, each of these different mechanisms connecting NPCs and gene expression appears individually dispensable for cell viability.6,7,15,17 However, they may be collectively required for cell fitness, as suggested by the synthetic lethality triggered by the combined inactivation of the Mlp1/Pml39 pathway, involved in mRNA quality control, and Ulp1, which is important for optimal mRNA synthesis.23 Some of these studies have notably shown that intron-containing and intronless genes do not similarly require the function of NPCs components. The importance of the nuclear pore complex in the control of intron-containing mRNA export is expected to be even more crucial in metazoans in view of their highly complex exon-intron gene organization. In the future, the combination of dedicated biochemical and microscopybased analyses in distant species should further unravel the differences between intron-containing and intronless mRNA metabolism, from transcription to mRNP assembly and export.

Disclosure of Potential Conflicts of Interest

No potential conflicts of interest were disclosed.

Acknowledgments

We apologize to colleagues whose work could not be directly cited due to space limitations. We are much indebted to Valerie Doye and Anna Babour for critical reading of the manuscript.

Funding

This work was supported by CNRS, Fondation ARC pour la Recherche sur le Cancer and Ligue Nationale contre le Cancer. A.B. was the recipient of a post-

459

doctoral fellowship from Ligue Nationale contre le Cancer. 16.

References 1. Wente SR, Rout MP. The nuclear pore complex and nuclear transport. Cold Spring Harb Perspect Biol 2010; 2:a000562; PMID:20630994; http://dx.doi.org/ 10.1101/cshperspect.a000562 2. Ptak C, Aitchison JD, Wozniak RW. The multifunctional nuclear pore complex: a platform for controlling gene expression. Curr Opin Cell Biol 2014; 28:46-53; PMID:24657998; http://dx.doi. org/10.1016/j.ceb.2014.02.001 3. Burns LT, Wente SR. From hypothesis to mechanism: uncovering nuclear pore complex links to gene expression. Mol Cell Biol 2014; 34:2114-20; PMID:24615017; http://dx.doi.org/10.1128/MCB.01730-13 4. Strambio-De-Castillia C, Niepel M, Rout MP. The nuclear pore complex: bridging nuclear transport and gene regulation. Nat Rev Mol Cell Biol 2010; 11:490501; PMID:20571586; http://dx.doi.org/10.1038/ nrm2928 5. Bonnet A, Palancade B. Regulation of mRNA trafficking by nuclear pore complexes. Genes (Basel) 2014; 5:767-91; PMID:25184662; http://dx.doi.org/ 10.3390/genes5030767 6. Galy V, Gadal O, Fromont-Racine M, Romano A, Jacquier A, Nehrbass U. Nuclear retention of unspliced mRNAs in yeast is mediated by perinuclear Mlp1. Cell 2004; 116:63-73; PMID:14718167; http://dx.doi.org/ 10.1016/S0092-8674(03)01026-2 7. Palancade B, Zuccolo M, Loeillet S, Nicolas A, Doye V. Pml39, a novel protein of the nuclear periphery required for nuclear retention of improper messenger ribonucleoparticles. Mol Biol Cell 2005; 16:5258-68; PMID:16162818; http://dx.doi.org/10.1091/mbc.E05-06-0527 8. Lewis A, Felberbaum R, Hochstrasser M. A nuclear envelope protein linking nuclear pore basket assembly, SUMO protease regulation, and mRNA surveillance. J Cell Biol 2007; 178:813-27; PMID:17724121; http:// dx.doi.org/10.1083/jcb.200702154 9. Braunschweig U, Barbosa-Morais NL, Pan Q, Nachman EN, Alipanahi B, Gonatopoulos-Pournatzis T, Frey B, Irimia M, Blencowe BJ. Widespread intron retention in mammals functionally tunes transcriptomes. Genome Res 2014; 24:1774-86; PMID:25258385; http://dx.doi.org/ 10.1101/gr.177790.114 10. Nilsen TW, Graveley BR. Expansion of the eukaryotic proteome by alternative splicing. Nature 2010; 463:457-63; PMID:20110989; http://dx.doi.org/ 10.1038/nature08909 11. Palazzo AF, Mahadevan K, Tarnawsky SP. ALREX-elements and introns: two identity elements that promote mRNA nuclear export. Wiley Interdiscip Rev RNA 2013; 4:523-33; PMID:23913896; http://dx.doi.org/ 10.1002/wrna.1176 12. Ishii K, Arib G, Lin C, Van Houwe G, Laemmli UK. Chromatin boundaries in budding yeast: the nuclear pore connection. Cell 2002; 109:551-62; PMID:12062099; http://dx.doi.org/10.1016/S00928674(02)00756-0 13. Casolari JM, Brown CR, Komili S, West J, Hieronymus H, Silver PA. Genome-wide localization of the nuclear transport machinery couples transcriptional status and nuclear organization. Cell 2004; 117:427-39; PMID:15137937; http://dx.doi.org/10.1016/S00928674(04)00448-9 14. Rougemaille M, Dieppois G, Kisseleva-Romanova E, Gudipati RK, Lemoine S, Blugeon C, Boulay J, Jensen TH, Stutz F, Devaux F, et al. THO/Sub2p functions to coordinate 3’-end processing with gene-nuclear pore association. Cell 2008; 135:308-21; PMID:18957205; http://dx.doi.org/10.1016/j.cell.2008.08.005 15. Cabal GG, Genovesio A, Rodriguez-Navarro S, Zimmer C, Gadal O, Lesne A, Buc H, Feuerbach-Fournier F, OlivoMarin JC, Hurt EC, et al. SAGA interacting factors confine

460

17.

18.

19.

20.

21.

22.

23.

24.

25.

26.

27.

28.

29.

30.

sub-diffusion of transcribed genes to the nuclear envelope. Nature 2006; 441:770-3; PMID:16760982; http://dx.doi. org/10.1038/nature04752 Taddei A, Van Houwe G, Hediger F, Kalck V, Cubizolles F, Schober H, Gasser SM. Nuclear pore association confers optimal expression levels for an inducible yeast gene. Nature 2006; 441:774-8; PMID:16760983; http://dx.doi.org/10.1038/nature04845 Dieppois G, Iglesias N, Stutz F. Cotranscriptional recruitment to the mRNA export receptor Mex67p contributes to nuclear pore anchoring of activated genes. Mol Cell Biol 2006; 26:7858-70; PMID:16954382; http://dx.doi.org/ 10.1128/MCB.00870-06 Brickner DG, Brickner JH. Cdk phosphorylation of a nucleoporin controls localization of active genes through the cell cycle. Mol Biol Cell 2010; 21:342132; PMID:20702586; http://dx.doi.org/10.1091/mbc. E10-01-0065 Menon BB, Sarma NJ, Pasula S, Deminoff SJ, Willis KA, Barbara KE, Andrews B, Santangelo GM. Reverse recruitment: the Nup84 nuclear pore subcomplex mediates Rap1/Gcr1/Gcr2 transcriptional activation. Proc Natl Acad Sci U S A 2005; 102:5749-54; PMID: 15817685; http://dx.doi.org/ 10.1073/pnas.0501768102 Tous C, Rondon AG, Garcia-Rubio M, GonzalezAguilera C, Luna R, Aguilera A. A novel assay identifies transcript elongation roles for the Nup84 complex and RNA processing factors. EMBO J 2011; 30:1953-64; PMID:21478823; http://dx.doi.org/10.1038/ emboj.2011.109 Texari L, Dieppois G, Vinciguerra P, Contreras MP, Groner A, Letourneau A, Stutz F. The nuclear pore regulates GAL1 gene transcription by controlling the localization of the SUMO protease Ulp1. Mol Cell 2013; 51:807-18; PMID:24074957; http://dx.doi.org/ 10.1016/j.molcel.2013.08.047 Van de Vosse DW, Wan Y, Lapetina DL, Chen WM, Chiang JH, Aitchison JD, Wozniak RW. A role for the nucleoporin Nup170p in chromatin structure and gene silencing. Cell 2013; 152:969-83; PMID:23452847; http://dx.doi.org/10.1016/j.cell.2013.01.049 Bonnet A, Bretes H, Palancade B. Nuclear pore components affect distinct stages of intron-containing gene expression. Nucleic Acids Res 2015; 43:4249-61; PMID:25845599; http://dx.doi.org/10.1093/nar/gkv280 Legrain P, Rosbash M. Some cis- and trans-acting mutants for splicing target pre-mRNA to the cytoplasm. Cell 1989; 57:573-83; PMID:2655924; http:// dx.doi.org/10.1016/0092-8674(89)90127-X Luna R, Jimeno S, Marin M, Huertas P, Garcia-Rubio M, Aguilera A. Interdependence between transcription and mRNP processing and export, and its impact on genetic stability. Mol Cell 2005; 18:711-22; PMID:15949445; http://dx.doi.org/10.1016/j. molcel.2005.05.001 Vinciguerra P, Iglesias N, Camblong J, Zenklusen D, Stutz F. Perinuclear Mlp proteins downregulate gene expression in response to a defect in mRNA export. EMBO J 2005; 24:813-23; PMID:15692572; http:// dx.doi.org/10.1038/sj.emboj.7600527 Palancade B, Liu X, Garcia-Rubio ML, Aguilera A, Zhao X, Doye V. Nucleoporins prevent accumulation of DNA damages by modulating Ulp1-dependent sumoylation processes. Mol Biol Cell 2007; 18:291223; PMID:17538013; http://dx.doi.org/10.1091/mbc. E07-02-0123 Bretes H, Rouviere JO, Leger T, Oeffinger M, Devaux F, Doye V, Palancade B. Sumoylation of the THO complex regulates the biogenesis of a subset of mRNPs. Nucleic Acids Res 2014; 42:5043-58; PMID:24500206; http://dx.doi. org/10.1093/nar/gku124 Sorenson MR, Stevens SW. Rapid identification of mRNA processing defects with a novel single-cell yeast reporter. RNA 2014; 20:732-45; PMID:24671766; http://dx.doi.org/10.1261/rna.042663.113 Fasken MB, Corbett AH. Mechanisms of nuclear mRNA quality control. RNA Biol 2009; 6:237-41;

Nucleus

31.

32.

33.

34.

35.

36.

37.

38.

39.

40.

41.

42.

43.

44.

PMID:19574733; http://dx.doi.org/10.4161/ rna.6.3.8330 Niepel M, Molloy KR, Williams R, Farr JC, Meinema AC, Vecchietti N, Cristea IM, Chait BT, Rout MP, Strambio-De-Castillia C. The nuclear basket proteins Mlp1p and Mlp2p are part of a dynamic interactome including Esc1p and the proteasome. Mol Biol Cell 2013; 24:3920-38; PMID:24152732; http://dx.doi. org/10.1091/mbc.E13-07-0412 Hackmann A, Wu H, Schneider UM, Meyer K, Jung K, Krebber H. Quality control of spliced mRNAs requires the shuttling SR proteins Gbp2 and Hrb1. Nat Commun 2014; 5:3123; PMID:24452287; http://dx. doi.org/10.1038/ncomms4123 Fasken MB, Stewart M, Corbett AH. Functional significance of the interaction between the mRNA-binding protein, Nab2, and the nuclear pore-associated protein, Mlp1, in mRNA export. J Biol Chem 2008; 283:27130-43; PMID:18682389; http://dx.doi.org/ 10.1074/jbc.M803649200 Dziembowski A, Ventura AP, Rutz B, Caspary F, Faux C, Halgand F, Laprevote O, Seraphin B. Proteomic analysis identifies a new complex required for nuclear pre-mRNA retention and splicing. EMBO J 2004; 23:4847-56; PMID:15565172; http://dx.doi.org/ 10.1038/sj.emboj.7600482 Lee ES, Akef A, Mahadevan K, Palazzo AF. The consensus 5’ splice site motif inhibits mRNA nuclear export. PLoS One 2015; 10:e0122743; PMID:25826302; http://dx.doi.org/ 10.1371/journal.pone.0122743 Skruzny M, Schneider C, Racz A, Weng J, Tollervey D, Hurt E. An endoribonuclease functionally linked to perinuclear mRNP quality control associates with the nuclear pore complexes. PLoS Biol 2009; 7:e8; PMID:19127978; http://dx.doi.org/10.1371/journal. pbio.1000008 Schnell SJ, Ma J, Yang W. Three-Dimensional Mapping of mRNA Export through the Nuclear Pore Complex. Genes (Basel) 2014; 5:1032-49; PMID:25393401; http://dx.doi. org/10.3390/genes5041032 Therizols P, Fairhead C, Cabal GG, Genovesio A, Olivo-Marin JC, Dujon B, Fabre E. Telomere tethering at the nuclear periphery is essential for efficient DNA double strand break repair in subtelomeric region. J Cell Biol 2006; 172:189-99; PMID:16418532; http:// dx.doi.org/10.1083/jcb.200505159 Gonzalez-Aguilera C, Askjaer P. Dissecting the NUP107 complex: multiple components and even more functions. Nucleus 2012; 3:340-8; PMID:22713280; http://dx.doi. org/10.4161/nucl.21135 Chymkowitch P, Nguea AP, Aanes H, Koehler CJ, Thiede B, Lorenz S, Meza-Zepeda LA, Klungland A, Enserink JM. Sumoylation of Rap1 mediates the recruitment of TFIID to promote transcription of ribosomal protein genes. Genome Res 2015; 25:897-906; PMID:25800674; http://dx.doi.org/10.1101/ gr.185793.114 Hannan A, Abraham NM, Goyal S, Jamir I, Priyakumar UD, Mishra K. Sumoylation of Sir2 differentially regulates transcriptional silencing in yeast. Nucleic Acids Res 2015; 43(21):10213-26; PMID:26319015; http://dx.doi.org/10.1093/nar/gkv842 Gomez-Gonzalez B, Garcia-Rubio M, Bermejo R, Gaillard H, Shirahige K, Marin A, Foiani M, Aguilera A. Genome-wide function of THO/TREX in active genes prevents R-loop-dependent replication obstacles. EMBO J 2011; 30:3106-19; PMID:21701562; http:// dx.doi.org/10.1038/emboj.2011.206 Mouaikel J, Causse SZ, Rougemaille M, DaubentonCarafa Y, Blugeon C, Lemoine S, Devaux F, Darzacq X, Libri D. High-Frequency Promoter Firing Links THO Complex Function to Heavy Chromatin Formation. Cell Rep 2013; 5:1082-94; PMID:24210826; http://dx.doi.org/10.1016/j.celrep.2013.10.013 Jensen TH, Boulay J, Olesen JR, Colin J, Weyler M, Libri D. Modulation of transcription affects mRNP quality. Mol Cell 2004; 16:235-44; PMID:15494310; http://dx.doi.org/10.1016/j.molcel.2004.09.019

Volume 6 Issue 6

45. Jimeno S, Garcia-Rubio M, Luna R, Aguilera A. A reduction in RNA polymerase II initiation rate suppresses hyper-recombination and transcription-elongation impairment of THO mutants. Mol Genet Genomics 2008; 280:327-36; PMID:18682986; http://dx.doi.org/10.1007/s00438-008-0368-8 46. Abruzzi KC, Lacadie S, Rosbash M. Biochemical analysis of TREX complex recruitment to intronless and intron-containing yeast genes. EMBO J 2004; 23:2620-31; PMID:15192704; http://dx.doi.org/ 10.1038/sj.emboj.7600261

www.tandfonline.com

47. Gottschalk A, Tang J, Puig O, Salgado J, Neubauer G, Colot HV, Mann M, Seraphin B, Rosbash M, Luhrmann R, et al. A comprehensive biochemical and genetic analysis of the yeast U1 snRNP reveals five novel proteins. RNA 1998; 4:374-93; PMID:9630245 48. Gilbert W, Guthrie C. The Glc7p nuclear phosphatase promotes mRNA export by facilitating association of Mex67p with mRNA. Mol Cell 2004; 13:201-12; PMID:14759366; http://dx.doi.org/10.1016/S10972765(04)00030-9

Nucleus

49. Strasser K, Hurt E. Splicing factor Sub2p is required for nuclear mRNA export through its interaction with Yra1p. Nature 2001; 413:648-52; PMID:11675790; http://dx.doi.org/10.1038/35098113 50. Chanarat S, Seizl M, Strasser K. The Prp19 complex is a novel transcription elongation factor required for TREX occupancy at transcribed genes. Genes Dev 2011; 25:1147-58; PMID:21576257; http://dx.doi. org/10.1101/gad.623411

461

Intron or no intron: a matter for nuclear pore complexes.

Nuclear pore complexes (NPCs) have been shown to regulate distinct steps of the gene expression process, from transcription to mRNA export. In particu...
NAN Sizes 1 Downloads 7 Views