Multiple roles for the yeast SUB2/yUAP56 gene in splicing

Nuclear localization of poly(A)+ mRNA following siRNA reduction of expression of the mammalian RNA helicases UAP56 and URH49

UAP56 is a eukaryotic RNA helicase that is important for mRNA splicing and nuclear export. Although most eukaryotes have a single protein corresponding to UAP56, we have shown previously that in human and mouse cells there is a second protein, URH49, which is 90% identical to UAP56. Both proteins interact with the mRNA export factor Aly and both are able to rescue the loss of Sub2p (the yeast homolog of UAP56), suggesting that both proteins have similar functions. However, the two helicases have different expression profiles in different tissues and in growth-stimulated cells, which raises the possibility that they might be involved in the splicing and export of non-identical populations of mRNA. In the present study, we have used RNA interference to further explore the functions of these two helicases. Reducing the expression of either URH49 or UAP56 in HeLa cells had little effect on cell proliferation or expression of a co-transfected gene. However, analysis of poly(A)+ RNA localization by fluorescent in situ hybridization revealed a speckled pattern of RNA accumulation throughout the nucleus. Reducing the expression of both helicases resulted in a major reduction in reporter gene expression as well as cell death within 72 h. We also observed a more prominent speckled pattern of nuclear poly(A)+ RNA accumulation as well as reduced accumulation in the cytoplasmic compartment. These observations suggest that both helicases have essential but largely overlapping functions in the processing and export of mammalian mRNAs.

Tho1, a novel hnRNP, and Sub2 provide alternative pathways for mRNP biogenesis in yeast THO mutants

THO is a protein complex that functions in cotranscriptional mRNP formation. Yeast THO1 and SUB2 (Saccharomyces cerevisiae) were identified as multicopy suppressors of the expression defects of the hpr1Delta mutant of THO. Here we show that multicopy THO1 suppresses the mRNA accumulation and export defects and the hyperrecombination phenotype of THO mutants but not those of sub2Delta, thp1Delta, or spt4Delta. Similarly, Sub2 overexpression suppresses the RNA export defect of hpr1Delta. Tho1 is a conserved RNA binding nuclear protein that specifically binds to transcribed chromatin in a THO- and RNA-dependent manner and genetically interacts with the shuttling hnRNP Nab2. The ability of Tho1 to suppress hpr1Delta resides in its C-terminal half, which contains the RNA binding activity and is located after a SAP/SAF (scaffold-associated protein/scaffold-associated factor) domain. Altogether, these results suggest that Tho1 is an hnRNP that, similarly to Sub2, assembles onto the nascent mRNA during transcription and participates in mRNP biogenesis and export. Overexpression of Tho1 or Sub2 may provide alternative ways for mRNP formation and export in the absence of a functional THO complex.

Autoregulation of the mRNA export factor Yra1p requires inefficient splicing of its pre-mRNA

Yra1p is an essential RNA-binding protein that couples transcription to export. The YRA1 gene is one of only approximately 5% of genes that undergo splicing in budding yeast, and its intron is unusual in several respects, including its large size and anomalous branchpoint sequence. We showed previously that the intron is required for autogenous regulation of Yra1p levels, which cause a dominant negative growth phenotype when elevated. The mechanism of this regulation, however, remains unknown. Here we demonstrate that growth is inversely correlated with splicing efficiency. Substitution of a canonical branchpoint moderately improves splicing but compromises autoregulation. Shortening the intron from 766 to approximately 350 nt significantly improves splicing but abolishes autoregulation. Notably, proper regulation can be restored by insertion of unrelated sequences into the shortened intron. In that the current paradigm for regulated splicing involves the binding of protein factors to specific elements in the pre-mRNA, the regulation of YRA1 expression appears to occur by a novel mechanism. We propose that appropriate levels of Yra1p are maintained by inefficient cotranscriptional splicing.

The splicing ATPase prp43p is a component of multiple preribosomal particles

Prp43p is a putative helicase of the DEAH family which is required for the release of the lariat intron from the spliceosome. Prp43p could also play a role in ribosome synthesis, since it accumulates in the nucleolus. Consistent with this hypothesis, we find that depletion of Prp43p leads to accumulation of 35S pre-rRNA and strongly reduces levels of all downstream pre-rRNA processing intermediates. As a result, the steady-state levels of mature rRNAs are greatly diminished following Prp43p depletion. We present data arguing that such effects are unlikely to be solely due to splicing defects. Moreover, we demonstrate by a combination of a comprehensive two-hybrid screen, tandem-affinity purification followed by mass spectrometry, and Northern analyses that Prp43p is associated with 90S, pre-60S, and pre-40S ribosomal particles. Prp43p seems preferentially associated with Pfa1p, a novel specific component of pre-40S ribosomal particles. In addition, Prp43p interacts with components of the RNA polymerase I (Pol I) transcription machinery and with mature 18S and 25S rRNAs. Hence, Prp43p might be delivered to nascent 90S ribosomal particles during pre-rRNA transcription and remain associated with preribosomal particles until their final maturation steps in the cytoplasm. Our data also suggest that the ATPase activity of Prp43p is required for early steps of pre-rRNA processing and normal accumulation of mature rRNAs.

The DEAD-box protein family of RNA helicases

RNA helicases of the DEAD-box protein family have been shown to participate in every aspect of RNA metabolism. They are present in most organisms where they work as RNA helicases or RNPases. The properties of these enzymes in vivo remains poorly described, however some were extensively characterized in vitro, and the solved crystal structures of a few are now available. Taken together, this information gives insight into the regulation of ATP and RNA binding as well as in the ATPase and helicase activities. This review will focus on the description of the molecular characteristics of members of the DEAD-box protein family and on the enzymatic activities they possess.

Quality control of messenger ribonucleoprotein particles in the nucleus and at the pore

The spatial separation of nuclear transcription and cytoplasmic translation in eukaryotic cells implies that mRNAs have to travel. On their journey, proteins involved in the various steps of transcript formation, processing and transport dynamically interact with mRNAs to form diverse messenger ribonucleoprotein complexes (mRNPs). Increasing evidence indicates that the protein complexes involved in distinct phases of manufacturing a bona fide mRNA in the nucleus are tightly coupled. Moreover, the recent demonstration that active genes migrate into preassembled, shared nuclear sub-compartments suggests that mRNAs are churned out in large 'transcription factories' with distinct but interconnected divisions. Nuclear factors have now been identified that specifically control the quality of mRNAs without affecting mRNP biogenesis or export.

Cotranscriptional spliceosome assembly dynamics and the role of U1 snRNA:5'ss base pairing in yeast

To investigate the mechanism of spliceosome assembly in vivo, we performed chromatin immunoprecipitation (ChIP) analysis of U1, U2, and U5 small nuclear ribonucleoprotein particles (snRNPs) to intron-containing yeast (S. cerevisiae) genes. The snRNPs display patterns that indicate a cotranscriptional assembly model: U1 first, then U2, and the U4/U6*U5 tri-snRNP followed by U1 destabilization. cis-splicing mutations also support a role of U2 and/or the tri-snRNP in U1 destabilization. Moreover, they indicate that splicing efficiency has a major impact on cotranscriptional snRNP recruitment and suggest that cotranscriptional recruitment of U2 or the tri-snRNP is required to commit the pre-mRNA to splicing. Branchpoint (BP) mutations had a major effect on the U1 pattern, whereas 5' splice site (5'ss) mutations had a stronger effect on the U2 pattern. A 5'ss-U1 snRNA complementation experiment suggests that pairing between U1 and the 5'ss occurs after U1 recruitment and contributes to a specific U1:substrate conformation required for efficient U2 and tri-snRNP recruitment.

Homolog of BRCA2-interacting Dss1p and Uap56p link Mlo3p and Rae1p for mRNA export in fission yeast

The breast cancer tumor suppressor BRCA2-interacting protein, DSS1, and its homologs are critical for DNA recombination in eukaryotic cells. We found that Dss1p, along with Mlo3p and Uap56p, Schizosaccharomyces pombe homologs of two messenger RNA (mRNA) export factors of the NXF-NXT pathway, is required for mRNA export in S. pombe. Previously, we showed that the nuclear pore-associated Rae1p is an essential mRNA export factor in S. pombe. Here, we show that Dss1p and Uap56p function by linking mRNA adapter Mlo3p to Rae1p for targeting mRNA-protein complex (mRNP) to the proteins of the nuclear pore complex (NPC). Dss1p preferentially recruits to genes in vivo and interacts with -FG (phenylalanine glycine) nucleoporins in vivo and in vitro. Thus, Dss1p may function at multiple steps of mRNA export, from mRNP biogenesis to their targeting and translocation through the NPC.

Genetic analysis reveals a role for the C terminus of the Saccharomyces cerevisiae GTPase Snu114 during spliceosome activation

Snu114 is the only GTPase required for mRNA splicing. As a homolog of elongation factor G, it contains three domains (III-V) predicted to undergo a large rearrangement following GTP hydrolysis. To assess the functional importance of the domains of Snu114, we used random mutagenesis to create conditionally lethal alleles. We identified three main classes: (1) mutations that are predicted to affect GTP binding and hydrolysis, (2) mutations that are clustered in 10- to 20-amino-acid stretches in each of domains III-V, and (3) mutations that result in deletion of up to 70 amino acids from the C terminus. Representative mutations from each of these classes blocked the first step of splicing in vivo and in vitro. The growth defects caused by most alleles were synthetically exacerbated by mutations in PRP8, a U5 snRNP protein that physically interacts with Snu114, as well as in genes involved in snRNP biogenesis, including SAD1 and BRR1. The allele snu114-60, which truncates the C terminus, was synthetically lethal with factors required for activation of the spliceosome, including the DExD/H-box ATPases BRR2 and PRP28. We propose that GTP hydrolysis results in a rearrangement between Prp8 and the C terminus of Snu114 that leads to release of U1 and U4, thus activating the spliceosome for catalysis.

Exploring functional relationships between components of the gene expression machinery

Eukaryotic gene expression requires the coordinated activity of many macromolecular machines including transcription factors and RNA polymerase, the spliceosome, mRNA export factors, the nuclear pore, the ribosome and decay machineries. Yeast carrying mutations in genes encoding components of these machineries were examined using microarrays to measure changes in both pre-mRNA and mRNA levels. We used these measurements as a quantitative phenotype to ask how steps in the gene expression pathway are functionally connected. A multiclass support vector machine was trained to recognize the gene expression phenotypes caused by these mutations. In several cases, unexpected phenotype assignments by the computer revealed functional roles for specific factors at multiple steps in the gene expression pathway. The ability to resolve gene expression pathway phenotypes provides insight into how the major machineries of gene expression communicate with each other.

Crystal structure of UAP56, a DExD/H-box protein involved in pre-mRNA splicing and mRNA export

UAP56 is an essential eukaryotic pre-mRNA splicing factor and mRNA export factor. The mechanisms of its functions are not well understood. We determined the crystal structures of the N- and C-terminal domains of human UAP56 (comprising 90% of the full-length UAP56) at 1.9 A resolution. The two domains each have a RecA-like fold and are connected by a flexible linker. The overall fold of each domain is highly similar to the corresponding domains of eIF4A (a prototypic DExD/H-box protein), with differences at the loops and termini. This structural similarity suggests that UAP56 is likely to possess ATPase and helicase activity similar to eIF4A. The NTP binding pocket of UAP56 is occupied by a citrate ion, mimicking the phosphates of NTP and retaining the P loop in an open conformation. The crystal structure of the N-terminal domain of UAP56 also reveals a dimer interface that is potentially important for UAP56's function.

TheSaccharomyces cerevisiae Sub2 protein suppresses heterochromatic silencing at telomeres and subtelomeric genes

We show that overexpression of Sub2p, a multifunctional Saccharomyces cerevisiae helicase family member that is involved in mRNA elongation and transport, also suppresses heterochromatic silencing at telomeres. Genetic assays show cells that overexpress SUB2 from a high copy plasmid exhibit increased survival rates when selecting for a telomere-silenced URA3 reporter. Two temperature-sensitive sub2 mutations that affect different helicase domains were also examined at the permissive temperature; these mutants also overcome silencing of the URA3 reporter. The degree to which silencing is suppressed correlates with SUB2 RNA and protein levels. Additionally, we find that Sub2p localizes to the telomeres, as determined by chromatin immunoprecipitation assays, suggesting that Sub2p has a direct effect at telomeres. Genome-wide analysis of transcripts was used to assess whether Sub2p overproduction affects only the silenced URA3 reporter gene, or whether other subtelomeric genes are also affected. Of the 70 RNA transcripts elevated in the Sub2p overexpressing cells, 28% are encoded by subtelomeric genes that are located within 5 Kbp of a core X or Y' repeat. The remainder of the transcripts clustered into several functional groups, including the iron homeostasis pathway, purine nucleotide metabolism, and miscellaneous transport genes, among others. These results suggest a targeted effect of Sub2p on transcription. Our results also confirm that Sub2p affects heterochromatic gene expression, similar to that observed with the Drosophila Hel25E homologue. The above observations imply that Sub2p affects chromatin structure in addition to, or in parallel with, its functions in transcription elongation, splicing and mRNA transport.

Crystal structure of the human ATP-dependent splicing and export factor UAP56

Pre-mRNA splicing requires the function of a number of RNA-dependent ATPases/helicases, yet no three-dimensional structure of any spliceosomal ATPases/helicases is known. The highly conserved DECD-box protein UAP56/Sub2 is an essential splicing factor that is also important for mRNA export. The expected ATPase/helicase activity appears to be essential for the UAP56/Sub2 functions. Here, we show that purified human UAP56 is an active RNA-dependent ATPase, and we also report the crystal structures of UAP56 alone and in complex with ADP, as well as a DECD to DEAD mutant. The structures reveal a unique spatial arrangement of the two conserved helicase domains, and ADP-binding induces significant conformational changes of key residues in the ATP-binding pocket. Our structural analyses suggest a specific protein-RNA displacement model of UAP56/Sub2. The detailed structural information provides important mechanistic insights into the splicing function of UAP56/Sub2. The structures also will be useful for the analysis of other spliceosomal DExD-box ATPases/helicases.

DEAD-box RNA helicases in Arabidopsis thaliana: establishing a link between quantitative expression, gene structure and evolution of a family of genes

The model genome of Arabidopsis thaliana contains a DEAD-box RNA helicase family (RH) of 58 members, i.e. almost twice as many as in the animal or yeast genomes. Transcript profiling using real-time quantitative polymerase chain reaction (PCR) has been obtained for 20 AtRHs from nine different organs. Two AtRHs exhibited plant-specific profiles associated with photosynthetic and sink organs. The other 18 AtRHs had the same transcript profile, and the levels of transcription of these 'housekeeping'AtRHs were under strict quantitative control over a large range of values. Transcript levels may be very different between the most recently duplicated genes. The master regulatory element in the definition of the transcript level is the simultaneous presence of a TATA-box and an intron in the 5' untranslated region (UTR). There is a positive and highly significant correlation between the size of the 5' UTR intron and the transcription level, as long as a characteristic TATA-box is present. Our work on the housekeeping AtRHs suggests a scenario for the evolution of duplicated genes, leading to both highly and poorly transcribed genes in the same terminal branch of the phylogenetic tree. The general evolutionary drive of the AtRH family, after duplication of a highly transcribed ancestral AtRH, was towards an alteration of the transcriptional activity of the divergent duplicates through successive events of suppression of the TATA-box and/or the 5' UTR intron.

Biochemical analysis of TREX complex recruitment to intronless and intron-containing yeast genes

The TREX complex is involved in both transcription elongation and mRNA export and is recruited to nascent transcription complexes. We have examined Yra1p, Sub2p and Hpr1p recruitment to nine genes of varying lengths and transcription frequencies. All three proteins increase from the 5' to the 3' ends of the four intronless genes examined. A modified chromatin immunoprecipitation assay that includes an RNase step indicates that Sub2p is bound to nascent RNA, Yra1p is associated with both RNA and DNA, and Hpr1p is associated with DNA. Although Hpr1p is recruited similarly to both intronless and intron-containing genes, low Yra1p and Sub2p levels are present on a subset of intron-containing genes. The residual Yra1p and Sub2p recruitment is less RNA-associated, and this correlates with high levels of U1 SnRNP on these genes. These experiments support a model in which TREX is recruited via the transcription machinery and then Yra1p and Sub2p are transferred to the nascent RNA. On some intron-containing genes, retention and/or transfer of Yra1p and Sub2p to nascent RNA are inhibited.

In vivo recruitment of exon junction complex proteins to transcription sites in mammalian cell nuclei

Studies over the past years indicate that there is extensive coupling between nuclear export of mRNA and pre-mRNA processing. Here, we visualized the distribution of exon junction complex (EJC) proteins and RNA export factors relative to sites of abundant pre-mRNA synthesis in the nucleus. We analyzed both HeLa cells infected with adenovirus and murine erythroleukemia (MEL) cells stably transfected with the human beta-globin gene. Using in situ hybridization and confocal microscopy, we observe accumulation of EJC proteins (REF/Aly, Y14, SRm160, UAP56, RNPS1, and Magoh) and core spliceosome components (U snRNPs) at sites of transcription. This suggests that EJC proteins bind stably to pre-mRNA cotranscriptionally. No concentration of the export factors NXF1/TAP, p15, and Dbp5 was detected on nascent transcripts, arguing that in mammalian cells these proteins bind the mRNA shortly before or after release from the sites of transcription. These results also suggest that binding of EJC proteins to the mRNA is not sufficient to recruit TAP-p15, consistent with recent findings showing that the EJC does not play a crucial role in mRNA export. Contrasting to the results obtained in MEL cells expressing normal human beta-globin transcripts, mutant pre-mRNAs defective in splicing and 3'end processing do not colocalize with SRm160, REF, UAP56, or Sm proteins. This shows that the accumulation of EJC proteins at transcription sites requires efficient processing of the nascent pre-mRNAs, arguing that transcription per se is not sufficient for the stable assembly of the EJC.

Growth-regulated expression and G0-specific turnover of the mRNA that encodes URH49, a mammalian DExH/D box protein that is highly related to the mRNA export protein UAP56

URH49 is a mammalian protein that is 90% identical to the DExH/D box protein UAP56, an RNA helicase that is important for splicing and nuclear export of mRNA. Although Saccharomyces cerevisiae and Drosophila express only a single protein corresponding to UAP56, mRNAs encoding URH49 and UAP56 are both expressed in human and mouse cells. Both proteins interact with the mRNA export factor Aly and both are able to rescue the loss of Sub2p (the yeast homolog of UAP56), indicating that both proteins have similar functions. UAP56 mRNA is more abundant than URH49 mRNA in many tissues, although in testes URH49 mRNA is much more abundant. UAP56 and URH49 mRNAs are present at similar levels in proliferating cultured cells. However, when the cells enter quiescence, the URH49 mRNA level decreases 3-6-fold while the UAP56 mRNA level remains relatively constant. The amount of URH49 mRNA increases to the level found in proliferating cells within 5 h when quiescent cells are growth-stimulated or when protein synthesis is inhibited. URH49 mRNA is relatively unstable (T(1/2) = 4 h) in quiescent cells, but is stabilized immediately following growth stimulation or inhibition of protein synthesis. In contrast, there is much less change in the content or stability of UAP56 mRNA following growth stimulation. Our observations suggest that in mammalian cells, two UAP56-like RNA helicases are involved in splicing and nuclear export of mRNA. Differential expression of these helicases may lead to quantitative or qualitative changes in mRNA expression.

Motifs IV and V in the DEAH Box Splicing Factor Prp22 Are Important for RNA Unwinding, and Helicase-defective Prp22 Mutants Are Suppressed by Prp8

The yeast pre-mRNA splicing factor Prp22 is a member of the DEAH box family of nucleic acid-stimulated ATPases and RNA helicases. Here we report a mutational analysis of 16 conserved residues in motifs Ia ((534)TQPRRVAA(541)), IV ((695)LVFLTG(700)), and V ((757)TNIAETSIT(765)). Mutants T757A, I764A, and T765A were lethal, and F697A cells did not grow at < or =30 degrees C. The mutant proteins failed to catalyze mRNA release from the spliceosome in vitro, and they were deficient for RNA unwinding. The F697A, I764A, and T765A proteins were active for ATP hydrolysis in the presence of RNA cofactor. The T757A mutant retained basal ATPase activity but was not stimulated by RNA, whereas ATP hydrolysis by T765A was strictly dependent on the RNA cofactor. Thus Thr-757 and Thr-765 in motif V link ATP hydrolysis to the RNA cofactor. To illuminate the mechanism of Prp22-catalyzed mRNA release, we performed a genetic screen to identify extragenic suppressors of the cold-sensitive growth defect of a helicase/release-defective Prp22 mutant. We identified one of the suppressors as a missense mutation of PRP8 (R1753K), a protein component of the U5 small nuclear ribonucleoprotein. We show that PRP8-R1753K suppressed multiple helicase-deficient prp22 mutations, including the lethal I764A mutation. Replacing Arg-1753 of Prp8 by either Lys, Ala, Gln, or Glu resulted in suppression of helicase-defective Prp22 mutants. Prp8-Arg1753 mutations by themselves caused temperature-sensitive growth defects in a PRP22 strain. These findings suggest a model whereby Prp22 disrupts an RNA/protein or RNA/RNA interaction in the spliceosome that is normally stabilized by Prp8.

Nuclear retention of unspliced mRNAs in yeast is mediated by perinuclear Mlp1

The molecular mechanism underlying the retention of intron-containing mRNAs in the nucleus is not understood. Here, we show that retention of intron-containing mRNAs in yeast is mediated by perinuclearly located Mlp1. Deletion of MLP1 impairs retention while having no effect on mRNA splicing. The Mlp1-dependent leakage of intron-containing RNAs is increased in presence of ts-prp18 delta, a splicing mutant. When overall pre-mRNA levels are increased by deletion of RRP6, a nuclear exosome component, MLP1 deletion augments leakage of only the intron-containing portion of mRNAs. Our data suggest, moreover, that Mlp1-dependent retention is mediated via the 5' splice site. Intriguingly, we found Mlp-proteins to be present only on sections of the NE adjacent to chromatin. We propose that at this confined site the perinuclear Mlp1 implements a quality control step prior to export, physically retaining faulty pre-mRNAs.

Cotranscriptional recruitment of the serine-arginine-rich (SR)-like proteins Gbp2 and Hrb1 to nascent mRNA via the TREX complex

The TREX (transcription/export) complex couples transcription elongation to the nuclear export of mRNAs. In this article, we show that the poly(A)(+) RNA-binding proteins Gbp2 and Hrb1, which resemble the serine-arginine-rich (SR) family of splicing factors found in higher eukaryotes, are specifically associated with the yeast TREX complex. We also show that Gbp2 and Hrb1 interact with Ctk1, a kinase that phosphorylates the C-terminal domain of RNA polymerase II during transcription elongation. Consistent with these findings, Gbp2 and Hrb1 associate with actively transcribed genes throughout their entire lengths. By using an RNA immunoprecipitation assay, we show that Gbp2 and Hrb1 also are bound to transcripts that are derived from these genes. We conclude that recruitment of the SR-like proteins Gbp2 and Hrb1 to mRNA occurs cotranscriptionally by means of association with the TREX complex and/or Ctk1.

A Simple Whole Cell Lysate System for in Vitro Splicing Reveals a Stepwise Assembly of the Exon-Exon Junction Complex

Pre-mRNA splicing removes introns and leaves in its wake a multiprotein complex near the exon-exon junctions of mRNAs. This complex, termed the exon-exon junction complex (EJC), contains at least seven proteins and provides a link between pre-mRNA splicing and downstream events, including transport, localization, and nonsense-mediated mRNA decay. Using a simple whole cell lysate system we developed for in vitro splicing, we prepared lysates from cells transfected with tagged EJC proteins and studied the association of these proteins with pre-mRNA, splicing intermediates, and mRNA, as well as formation of the EJC during splicing. Three of the EJC components, Aly/REF, RNPS1, and SRm160, are found on pre-mRNA by the time the spliceosome is formed, whereas Upf3b associates with splicing intermediates during or immediately after the first catalytic step of the splicing reaction (cleavage of exon 1 and intron-lariat formation). In contrast, Y14 and magoh, which remain stably associated with mRNA after export to the cytoplasm, join the EJC during or after completion of exon-exon ligation. These findings indicate that EJC formation is an ordered pathway that involves stepwise association of components and is coupled to specific intermediates of the splicing reaction.

ATP requirement for Prp5p function is determined by Cus2p and the structure of U2 small nuclear RNA

Stable addition of U2 small nuclear ribonucleoprotein (snRNP) to form the prespliceosome is the first ATP-dependent step in splicing, and it requires the DEXD/H box ATPase Prp5p. However, prespliceosome formation occurs without ATP in extracts lacking the U2 snRNP protein Cus2p. Here we show that Prp5p is required for the ATP-independent prespliceosome assembly that occurs in the absence of Cus2p. Addition of recombinant Cus2p can restore the ATP dependence of prespliceosome assembly, but only if it is added before Prp5p. Prp5p with an altered ATP-binding domain (Prp5-GNTp) can support growth in vivo, but only in a cus2 deletion strain, mirroring the in vitro results. Other Prp5 ATP-binding domain substitutions are lethal, even in the cus2 deletion strain, but can be suppressed by U2 small nuclear RNA mutations that hyperstabilize U2 stem IIa. We infer that the presence of Cus2p and stem IIa-destabilized forms of U2 small nuclear RNA places high demands on the ATP-driven function of Prp5p. Because Prp5p is not dispensable in vitro even in the absence of ATP, we propose that the core Prp5p function in bringing U2 to the branchpoint is not directly ATP-dependent. The positive role of Cus2p in rescuing mutant U2 can be reconciled with its antagonistic effect on Prp5 function in a model whereby Cus2p first helps Prp5p to activate the U2 snRNP for prespliceosome formation but then is displaced by Prp5p before or during the stabilization of U2 at the branchpoint.

Molecular evidence that the eukaryotic THO/TREX complex is required for efficient transcription elongation

THO/TREX is a conserved eukaryotic complex formed by the core THO complex plus proteins involved in mRNA metabolism and export such as Sub2 and Yra1. Mutations in any of the THO/TREX structural genes cause pleiotropic phenotypes such as transcription impairment, increased transcription-associated recombination, and mRNA export defects. To assay the relevance of THO/TREX complex in transcription, we performed in vitro transcription elongation assays in mutant cell extracts using supercoiled DNA templates containing two G-less cassettes. With these assays, we demonstrate that hpr1delta, tho2delta, and mft1delta mutants of the THO complex and sub2 mutants show significant reductions in the efficiency of transcription elongation. The mRNA expression defect of hpr1delta mutants was not due to an increase in mRNA decay, as determined by mRNA half-life measurements and mRNA time course accumulation experiments in the absence of Rrp6p exoribonuclease. This work demonstrates that THO and Sub2 are required for efficient transcription elongation, providing further evidence for the coupling between transcription and mRNA metabolism and export.

Nuclear mRNA export: insights from virology

To maximize the production of progeny virions, several viruses have evolved mechanisms that promote the selective nuclear export of viral mRNA transcripts while, in some cases, inhibiting the export of cellular mRNAs. To achieve this goal, viruses have evolved regulatory proteins and cis-acting RNA elements that selectively interact with key cellular nuclear export factors. Efforts to identify the cellular targets of these viral proteins and RNA elements have led to the identification of Crm1 and Tap as essential human nuclear RNA-export factors and continue to provide insights into how mRNAs are selected for export

DExD/H-box proteins and their partners: helping RNA helicases unwind

Members of the DExD/H-box family of RNA helicases are involved in many processes and complexes within the cell. While individual DExD/H helicase family members have been studied extensively, the mechanisms through which helicases affect multiprotein complexes are just beginning to be investigated. Because RNA helicases are both highly conserved and numerous in the cell, study of RNA helicase recruitment and modulation by cofactors is necessary for understanding the mechanisms of helicase action in vivo. This review will focus on cofactor-mediated regulation of helicase target specificity and activity.

Allosteric cascade of spliceosome activation

Introns are removed from precursor messenger RNAs in the cell nucleus by a large ribonucleoprotein complex called the spliceosome. The spliceosome contains five subcomplexes called snRNPs, each with one RNA and several protein components. Interactions of the snRNPs with each other and the intron are highly dynamic, changing in an ordered progression throughout the splicing process. This allosteric cascade of interactions is programmed into the RNA and protein components of the spliceosome, and is driven by a family of DExD/H-box RNA-dependent ATPases. The dependence of cascade progression on multiple intron-recognition events likely serves to enforce the accuracy of splicing. Here, the progression of the allosteric cascade from the first recognition event to the first catalytic step of splicing is reviewed.

UAP56 levels affect viability and mRNA export in Caenorhabditis elegans

Expression of a gfp transgene in the intestines of living Caenorhabditis elegans has been measured following depletion by RNAi of a variety of known splicing factors and mRNA export proteins. Reduction of most splicing factors showed only a small effect on expression of the transgene in the animal injected with dsRNA, although most of these RNAi's resulted in embryonic lethality in their offspring. In contrast, RNAi of nxf-1, the worm homolog of mammalian NXF1/TAP, a key component of the mRNA export machinery, resulted in dramatic suppression of GFP expression in the injected animals. When we tested other proteins previously reported to be involved in marking mRNAs for export, we obtained widely divergent results. Whereas RNAi of the worm REF/Aly homologs had no obvious effect, either in the injected animals or their offspring, RNAi of UAP56, reported to be the partner of REF/Aly, resulted in strong suppression of GFP expression due to nuclear retention of its mRNA. Overexpression of UAP56 also resulted in rapid loss of GFP expression and lethality at all stages of development. We conclude that UAP56 plays a key role in mRNA export in C. elegans, but that REF/Aly may not. It also appears that some RNA processing factors are required for viability (e.g., U2AF, PUF60, SRp54, SAP49, PRP8, U1-70K), whereas others are not (e.g., U2A', CstF50).

The Ref/Aly proteins are dispensable for mRNA export and development in Caenorhabditis elegans

The mRNA export pathway is highly conserved throughout evolution. We have used RNA interference (RNAi) to functionally characterize bona fide RNA export factors and components of the exon-exon junction complex (EJC) in Caenorhabditis elegans. RNAi of CeNXT1/p15, the binding partner of CeNXF1/TAP, caused early embryonic lethality, demonstrating an essential function of this gene during C. elegans development. Moreover, depletion of this protein resulted in nuclear accumulation of poly(A)(+) RNAs, supporting a direct role of NXT1/p15 in mRNA export in C. elegans. Previously, we have shown that RNAi of CeSRm160, a protein of the EJC complex, resulted in wild-type phenotype; in the present study, we demonstrate that RNAi of CeY14, another component of this complex, results in embryonic lethality. In contrast, depletion of the EJC component CeRNPS1 results in no discernible phenotype. Proteins of the REF/Aly family act as adaptor proteins mediating the recruitment of the mRNA export factor, NXF1/TAP, to mRNAs. The C. elegans genome encodes three members of the REF/Aly family. RNAi of individual Ref genes, or codepletion of two Ref genes in different combinations, resulted in wild-type phenotype. Simultaneous suppression of all three Ref genes did not compromise viability or progression through developmental stages in the affected progeny, and only caused a minor defect in larval mobility. Furthermore, no defects in mRNA export were observed upon simultaneous depletion of all three REF proteins. These results suggest the existence of multiple adaptor proteins that mediate mRNA export in C. elegans.

U2 small nuclear ribonucleoprotein particle (snRNP) auxiliary factor of 65 kDa, U2AF65, can promote U1 snRNP recruitment to 5' splice sites

The splicing factor U2AF(65), U2 small nuclear ribonucleoprotein particle (snRNP) auxillary factor of 65 kDa, binds to pyrimidine-rich sequences at 3' splice sites to recruit U2 snRNP to pre-mRNAs. We report that U2AF(65) can also promote the recruitment of U1 snRNP to weak 5' splice sites that are followed by uridine-rich sequences. The arginine- and serine-rich domain of U2AF(65) is critical for U1 recruitment, and we discuss the role of its RNA-RNA annealing activity in this novel function of U2AF(65).

Nuclear RNA export

Eukaryotic cells export several different classes of RNA molecule from the nucleus, where they are transcribed, to the cytoplasm, where the majority participate in different aspects of protein synthesis. It is now clear that these different classes of RNA, including rRNAs, tRNAs, mRNAs and snRNAs, are specifically directed into distinct but in some cases partially overlapping nuclear export pathways. All non-coding RNAs are now known to depend on members of the karyopherin family of Ran-dependent nucleocytoplasmic transport factors for their nuclear export. In contrast, mRNA export is generally mediated by a distinct, Ran-independent nuclear export pathway that is both complex and, as yet, incompletely understood. However, for all classes of RNA molecules, nuclear export is dependent on the assembly of the RNA into the appropriate ribonucleoprotein complex, and nuclear export therefore also appears to function as an important proofreading mechanism.

Stable mRNP formation and export require cotranscriptional recruitment of the mRNA export factors Yra1p and Sub2p by Hpr1p

Yra1p/REF participates in mRNA export by recruiting the export receptor Mex67p to messenger ribonucleoprotein (mRNP) complexes. Yra1p also binds Sub2p, a DEAD box ATPase/RNA helicase implicated in splicing and required for mRNA export. We identified genetic and physical interactions between Yra1p, Sub2p, and Hpr1p, a protein involved in transcription elongation whose deletion leads to poly(A)(+) RNA accumulation in the nucleus. By chromatin immunoprecipitation (ChIP) experiments, we show that Hpr1p, Sub2p, and Yra1p become associated with active genes during transcription elongation and that Hpr1p is required for the efficient recruitment of Sub2p and Yra1p. The data indicate that transcription and export are functionally linked and that mRNA export defects may be due in part to inefficient loading of essential mRNA export factors on the growing mRNP. We also identified functional interactions between Yra1p and the exosome components Rrp45p and Rrp6p. We show that yra1, sub2, and Deltahpr1 mutants all present defects in mRNA accumulation and that deletion of RRP6 in yra1 mutants restores normal mRNA levels. The data support the hypothesis that an exosome-dependent surveillance mechanism targets improperly assembled mRNPs for degradation.

Role of transcription in plasmid maintenance in the hpr1Delta mutant of Saccharomyces cerevisiae

The Saccharomyces cerevisiae hyperrecombination mutation hpr1Delta results in instability of sequences between direct repeats that is dependent on transcription of the repeat. Here it is shown that the HPR1 gene also functions in plasmid stability in the presence of destabilizing transcription elongation. In the hpr1Delta mutant, plasmid instability results from unchecked transcription elongation, which can be suppressed by a strong transcription terminator. The plasmid system has been used to examine in vivo aspects of transcription in the absence of Hpr1p. Nuclear run-on studies suggest that there is an increased RNA polymerase II density in the hpr1Delta mutant strain, but this is not accompanied by an increase in accumulation of cytoplasmic mRNA. Suppression of plasmid instability in hpr1Delta can also be achieved by high-copy expression of the RNA splicing factor SUB2, which has recently been proposed to function in mRNA export, in addition to its role in pre-mRNA splicing. High-copy-number SUB2 expression is accompanied by an increase in message accumulation from the plasmid, suggesting that the mechanism of suppression by Sub2p involves the formation of mature mRNA. Models for the role of Hpr1p in mature mRNA formation and the cause of plasmid instability in the absence of the Hpr1 protein are discussed.

Interactions between mRNA export commitment, 3'-end quality control, and nuclear degradation

Several aspects of eukaryotic mRNA processing are linked to transcription. In Saccharomyces cerevisiae, overexpression of the mRNA export factor Sub2p suppresses the growth defect of hpr1 null cells, yet the protein Hpr1p and the associated THO protein complex are implicated in transcriptional elongation. Indeed, we find that a pool of heat shock HSP104 transcripts are 3'-end truncated in THO complex mutant as well as sub2 mutant backgrounds. Surprisingly, however, this defect can be suppressed by deletion of the 3'-5' exonuclease Rrp6p. This indicates that incomplete RNAs result from nuclear degradation rather than from a failure to efficiently elongate transcription. RNAs that are not degraded are retained at the transcription site in a Rrp6p-dependent manner. Interestingly, the addition of a RRP6 deletion to sub2 or to THO complex mutants shows a strong synthetic growth phenotype, suggesting that the failure to retain and/or degrade defective mRNAs is deleterious. mRNAs produced in the 3'-end processing mutants rna14-3 and rna15-2, as well as an RNA harboring a 3' end generated by a self-cleaving hammerhead ribozyme, are also retained in Rrp6p-dependent transcription site foci. Taken together, our results show that several classes of defective RNPs are subject to a quality control step that impedes release from transcription site foci and suggest that suboptimal messenger ribonucleoprotein assembly leads to RNA degradation by Rrp6p.

Intron status and 3'-end formation control cotranscriptional export of mRNA

Messenger RNA export factors are recruited to genes in a transcription-dependent manner. To ascertain the mechanism of this process, we show that RNA polymerase II transcription is sufficient to recruit the Saccharomyces cerevisiae hnRNP protein Npl3 to a gene independent of RNA sequence. In contrast, the cotranscriptional recruitment of the RNA-binding protein Yra1 is dependent on pre-mRNA processing. Yra1 associates with introns of intron-containing genes in a splicing-dependent manner. Conversely, Yra1 recruitment to genes without introns is not dependent on splicing. Finally, 3'-end formation is required for Yra1 recruitment to genes regardless of intron status.

5' exon interactions within the human spliceosome establish a framework for exon junction complex structure and assembly

A general consequence of pre-mRNA splicing is the stable deposition of several proteins 20-24 nucleotides (nt) upstream of exon-exon junctions on spliced mRNAs. This exon junction complex (EJC) contains factors involved in mRNA export, cytoplasmic localization, and nonsense-mediated mRNA decay. Here we probed the mechanism and timing of EJC assembly. Over the course of splicing, the 5' exon is subject to numerous dynamic protein-RNA interactions involving at least nine distinct polypeptides. Within the fully assembled spliceosome, these interactions afford protection to the last 25-27 nt of the 5' exon intermediate. Coincident with exon ligation, interactions at the 3' end of the 5' exon disappear, and new species associate with position -24. Mass spectrometry and Western blotting of purified H, C, and mRNP complexes revealed that at least one EJC component, REF/Aly, can interact with pre-mRNA prior to spliceosome assembly, whereas Y14, Magoh, RNPS1, UAP56, and SRm160 are found in intermediate-containing spliceosomes. Upon exon ligation, association of RNPS1, UAP56, and SRm160 is destabilized. In contrast, REF/Aly, Y14, and Magoh remain stably bound to spliced mRNA, indicating that these three proteins are components of the EJC core.

Nuclear structure and intranuclear retention of premature RNAs

Eukaryotic cells are highly compartmentalized, each compartment being surrounded by a lipid bilayer. This membrane-based organization allows cells to use their volumes to encode information. The lack of intranuclear membranes suggested that the nucleus was largely devoid of structural organization. However, recent work has defined numerous specialized nuclear subdomains. Importantly, RNA processing factors do not display random distribution but cluster in defined nuclear bodies. Although these structures are well characterized morphologically, their function in relation to RNA metabolism remains elusive. In this review, we will discuss the putative participation of nuclear substructures in a quality control step of RNA biogenesis, the nuclear retention of premature RNA.

p68 RNA helicase is an essential human splicing factor that acts at the U1 snRNA-5' splice site duplex

Modulation of the interaction between U1 snRNP and the 5' splice site (5'ss) is a key event that governs 5'ss recognition and spliceosome assembly. Using the methylene blue-mediated cross-linking method (Z. R. Liu, A. M. Wilkie, M. J. Clemens, and C. W. Smith, RNA 2:611-621, 1996), a 65-kDa protein (p65) was shown to interact with the U1-5'ss duplex during spliceosome assembly (Z. R. Liu, B. Sargueil, and C. W. Smith, Mol. Cell. Biol. 18:6910-6920, 1998). In this report, p65 was identified as p68 RNA helicase and shown to be essential for in vitro pre-mRNA splicing. Depletion of endogenous p68 RNA helicase does not affect the loading of the U1 snRNP to the 5'ss during early stage of splicing. However, dissociation of the U1 from the 5'ss is largely inhibited. The data suggest that p68 RNA helicase functions in destabilizing the U1-5'ss interactions. Furthermore, depletion of p68 RNA helicase arrested spliceosome assembly at the prespliceosome stage, suggesting that p68 may play a role in the transition from prespliceosome to spliceosome.

Expression of the essential mRNA export factor Yra1p is autoregulated by a splicing-dependent mechanism

Recent evidence supports the idea that pre-mRNA splicing and mRNA export are mechanistically coupled. In metazoans, this process appears to be mediated by a multicomponent complex, which associates with the spliced RNA upstream of the exon-exon junction. One of these components (Aly/REF) has a homolog in the budding yeast Saccharomyces cerevisiae known as Yra1p. The YRA1 gene is essential for growth and required for mRNA export. Notably, YRA1 is one of the only approximately 5% intron-containing genes in yeast. Moreover, the YRA1 intron has several unusual features and is conserved in other budding yeast species. Previously, overexpression of intronless YRA1 was shown to be toxic. We show here that overexpression of the intron-containing gene results in increased levels of unspliced pre-mRNA but normal levels of Yra1 protein; conversely, expression of the cDNA results in increased levels of protein and accumulation of nuclear poly(A)+ RNA. Two additional lines of evidence suggest that expression of Yra1p is autoregulated: First, expression of excess Yra1p from a plasmid reduces the level of tagged, chromosomal Yra1p, and, second, this effect requires wild-type protein. Replacement of the YRA1 intron with that of other S. cerevisiae genes cannot rescue the dominant-negative growth defect of intronless YRA1. We conclude that the level of Yra1p is negatively autoregulated by a mechanism that involves splicing of its unusual intron. Tight control of the levels of Yra1p might be necessary to couple the rates of pre-mRNA splicing and mRNA export.

The yeast THO complex and mRNA export factors link RNA metabolism with transcription and genome instability

The THO complex is a multimeric factor containing four polypeptides, Tho2, Hpr1, Mft1 and Thp2. Mutations in any of the genes encoding THO confer impairment of transcription and a transcription-dependent hyper-recombination phenotype, suggesting that THO has a functional role in gene expression. Using an in vivo assay developed to study expression of long and G+C-rich DNA sequences, we have isolated SUB2, a gene involved in mRNA splicing and export, as a multicopy suppressor of the gene expression defect of hpr1 Delta. Further investigation of a putative functional relationship between mRNA metabolism and THO revealed that mRNA export mutants sub2, yra1, mex67 and mtr2 have similar defective transcription and hyper-recombination phenotypes as THO mutants. In addition, THO becomes essential in cells with a defective Mex67 mRNA export er. Finally, we have shown that THO has the ability to associate with RNA and DNA in vitro. These results indicate a functional link between the processes of elongation and metabolism of nascent mRNA mediated by THO and mRNA export proteins, which have important consequences for the maintenance of genome stability.

Probing interactions between the U2 small nuclear ribonucleoprotein and the DEAD-box protein, Prp5

Pre-mRNA binding to the yeast U2 small nuclear ribonucleoprotein (snRNP) during prespliceosome formation requires ATP hydrolysis, the highly conserved UACUAAC box of the branch point region of the pre-mRNA, and several factors. Here we analyzed the binding of a radiolabeled 2'-O-methyl oligonucleotide complementary to U2 small nuclear RNA to study interactions between the UACUAAC box, U2 snRNP, and Prp5p, a DEAD box protein necessary for prespliceosome formation. Binding of the 2'-O-methyl oligonucleotide to the U2 snRNP in yeast cell extract was assayed by gel electrophoresis. Binding was rapid, enhanced by ATP, and dependent on the integrity and conformation of the U2 snRNP. It was also stimulated by Prp5p that was found to associate physically with U2 snRNP. In vitro heat inactivation of the temperature-sensitive prp5-1 mutant extract decreased oligonucleotide binding to U2 and the ATP enhancement of binding by 3-fold. Furthermore, the temperature-sensitive prp5-1 mutation maps to the ATP-binding motif I within the helicase-like domain. Thus the catalytic activity of Prp5p likely promotes a conformational change in the U2 snRNP.

Nucleocytoplasmic transport: cargo trafficking across the border

Transport of macromolecules between the cytoplasm and the nucleus is mediated by at least three different classes of soluble transport receptors, members of the importin-beta protein family, the Mex67/Tap family and the small nuclear transport factor 2 (NFT2). All nuclear transport factors can bidirectionally traverse the nuclear pore complex through specific interactions with phenylalanine/glycine-rich nuclear pore complex components. Recent kinetic and structural analyses revealed novel insight into the details of these interactions. In addition, new biochemical and genetic studies have dramatically improved our understanding of ribosomal and messenger RNA export, unveiling a tight coupling between RNA processing and transport.

A role for the Psi-U mismatch in the recognition of the 5' splice site of yeast introns by the U1 small nuclear ribonucleoprotein particle

The U1 small nuclear ribonucleoprotein particle (snRNP)/5' splice site (5'SS) interaction in yeast is essential for the splicing process and depends on the formation of a short RNA duplex between the 5' arm of U1 snRNA and the 1st intronic nucleotides. This RNA/RNA interaction is characterized by the presence of a mismatch that occurs with almost all yeast introns and concerns nucleotides 4 on the pre-mRNA (a U) and 5 on U1 snRNA (a Psi). The latter nucleotide is well conserved from yeast to vertebrates, but its role in yeast and the significance of the associated mismatch in the U1 snRNA/5'SS interaction have never been fully explained. We report here that the presence of this mismatch is a determinant of stability that mainly affects the off rate of the interaction. To our knowledge this is the first report assigning a function to this noncanonical interaction. We also performed SELEX (systematic evolution of ligands by exponential enrichment) experiments by immunoprecipitating U1 snRNP and the associated RNA. The artificial phylogeny derived from these experiments allows the isolation of the selective pressure due to U1 snRNP binding on the 5'SS of yeast introns.

TREX is a conserved complex coupling transcription with messenger RNA export

The essential yeast proteins Yra1 and Sub2 are messenger RNA export factors that have conserved counterparts in metazoans, designated Aly and UAP56, respectively. These factors couple the machineries that function in splicing and export of mRNA. Here we show that both Yra1 and Sub2 are stoichiometrically associated with the heterotetrameric THO complex, which functions in transcription in yeast. We also show that Sub2 and Yra1 interact genetically with all four components of the THO complex (Tho2, Hpr1, Mft1 and Thp2). Moreover, these components operate in the export of bulk poly(A)(+) RNA as well as of mRNA derived from intronless genes. Both Aly and UAP56 associate with human counterparts of the THO complex. Together, these data define a conserved complex, designated the TREX ('transcription/export') complex. The TREX complex is specifically recruited to activated genes during transcription and travels the entire length of the gene with RNA polymerase II. Our data indicate that the TREX complex has a conserved role in coupling transcription to mRNA export.

An intron in the YRA1 gene is required to control Yra1 protein expression and mRNA export in yeast

Yra1p is an essential and conserved mRNA export factor in yeast. Strikingly, removal of the intron from YRA1 causes a dominant-negative growth phenotype and a concomitant inhibition of mRNA export. However, both defects are neutralized by replacement of the intron of YRA1 by a different intron. Significantly, Yra1p is overproduced in yeast when expressed from its intronless gene, but Yra1p levels are the same as the wild type when expressed from an intron-containing YRA1 gene. Thus, an intron in YRA1 controls Yra1p expression and mRNA export.

A conserved mRNA export machinery coupled to pre-mRNA splicing

Recent advances have led to a new understanding of how mRNAs are exported from the nucleus to the cytoplasm. This process requires a heterodimeric mRNA export receptor that is part of an elaborate machinery conserved from yeast to humans. Export of mRNAs is coupled to upstream steps in gene expression, such as pre-mRNA splicing, and to downstream events, including nonsense-mediated decay.

mRNA export: travelling with DEAD box proteins

Recent studies have shown that the putative RNA helicase protein UAP56 and its yeast homologue Sub2p are not only involved in pre-mRNA splicing but also required for the export of mRNA out of the nucleus, even if the mRNA is encoded by an intron-less gene.

The DECD box putative ATPase Sub2p is an early mRNA export factor

Nuclear mRNA metabolism relies on the interplay between transcription, processing, and nuclear export. RNA polymerase II transcripts experience major rearrangements within the nucleus, which include alterations in the structure of the mRNA precursors as well as the addition and perhaps even removal of proteins prior to transport across the nuclear membrane. Such mRNP-remodeling steps are thought to require the activity of RNA helicases/ATPases. One such protein, the DECD box RNA-dependent ATPase Sub2p/UAP56, is involved in both early and late steps of spliceosome assembly. Here, we report a more general function of Saccharomyces cerevisiae Sub2p in mRNA nuclear export. We observe a rapid and dramatic nuclear accumulation of poly(A)(+) RNA in strains carrying mutant alleles of sub2. Strikingly, an intronless transcript, HSP104, also accumulates in nuclei, suggesting that Sub2p function is not restricted to splicing events. The HSP104 transcripts are localized in a single nuclear focus that is suggested to be at or near their site of transcription. Intriguingly, Sub2p shows strong genetic and functional interactions with the RNA polymerase II-associated DNA/DNA:RNA helicase Rad3p as well as the nuclear RNA exosome component Rrp6p, which was independently implicated in the retention of mRNAs at transcription sites. Taken together, our data suggest that Sub2p functions at an early step in the mRNA export process.

The DExH/D box protein HEL/UAP56 is essential for mRNA nuclear export in Drosophila

Dbp5 is the only member of the DExH/D box family of RNA helicases that is directly implicated in the export of messenger RNAs from the nucleus of yeast and vertebrate cells. Dbp5 localizes in the cytoplasm and at the cytoplasmic face of the nuclear pore complex (NPC). In an attempt to identify proteins present in a highly enriched NPC fraction, two other helicases were detected: RNA helicase A (RHA) and UAP56. This suggested a role for these proteins in nuclear transport. Contrary to expectation, we show that the Drosophila homolog of Dbp5 is not essential for mRNA export in cultured Schneider cells. In contrast, depletion of HEL, the Drosophila homolog of UAP56, inhibits growth and results in a robust accumulation of polyadenylated RNAs within the nucleus. Consequently, incorporation of [35S]methionine into newly synthesized proteins is inhibited. This inhibition affects the expression of both heat-shock and non-heat-shock mRNAs, as well as intron-containing and intronless mRNAs. In HeLa nuclear extracts, UAP56 preferentially, but not exclusively, associates with spliced mRNAs carrying the exon junction complex (EJC). We conclude that HEL is essential for the export of bulk mRNA in Drosophila. The association of human UAP56 with spliced mRNAs suggests that this protein might provide a functional link between splicing and export.

Splicing factor Sub2p is required for nuclear mRNA export through its interaction with Yra1p

The yeast nuclear protein Yra1p is an essential export factor for mRNA. Yra1p interacts directly with the mRNA transport factor Mex67p/Mtr2p, which is associated with the nuclear pore. Here, we report a genetic interaction between YRA1 and SUB2, the gene for a DEAD box helicase involved in splicing. Mutation of SUB2 as well as its overexpression leads to a defect in mRNA export. Moreover, Yra1p and Sub2p bind directly to each other both in vivo and in vitro. Significantly, Sub2p and Mex67p/Mtr2p bind to the same domains of Yra1p, and the proteins compete for binding to Yra1p. Together, these data indicate that the spliceosomal component Sub2p is also important in mRNA export and may function to recruit Yra1p to the mRNA. Sub2p may then be displaced from Yra1p by the binding of Mex67p/Mtr2p, which participates in the export of mRNA through the nuclear pores.