Hervé Le Hir

The spliceosome deposits multiple proteins 20–24 nucleotides upstream of mRNA exon–exon junctions

Eukaryotic mRNAs exist in vivo as ribonucleoprotein particles (mRNPs). The protein components of mRNPs have important functions in mRNA metabolism, including effects on subcellular localization, translational efficiency and mRNA half‐life. There is accumulating evidence that pre‐mRNA splicing can alter mRNP structure and thereby affect downstream mRNA metabolism. Here, we report that the spliceosome stably deposits several proteins on mRNAs, probably as a single complex of ∼335 kDa. This complex protects 8 nucleotides of mRNA from complete RNase digestion at a conserved position 20–24 nucleotides upstream of exon–exon junctions. Splicing‐dependent RNase protection of this region was observed in both HeLa cell nuclear extracts and Xenopus laevis oocyte nuclei. Immunoprecipitations revealed that five components of the complex are the splicing‐associated factors SRm160, DEK and RNPS1, the mRNA‐associated shuttling protein Y14 and the mRNA export factor REF. Possible functions for this complex in nucleocytoplasmic transport of spliced mRNA, as well as the nonsense‐mediated mRNA decay pathway, are discussed.

The exon–exon junction complex provides a binding platform for factors involved in mRNA export and nonsense‐mediated mRNA decay

We recently reported that spliceosomes alter messenger ribonucleoprotein particle (mRNP) composition by depositing several proteins 20–24 nucleotides upstream of mRNA exon–exon junctions. When assembled in vitro, this so‐called ‘exon–exon junction complex’ (EJC) contains at least five proteins: SRm160, DEK, RNPS1, Y14 and REF. To better investigate its functional attributes, we now describe a method for generating spliced mRNAs both in vitro and in vivo that either do or do not carry the EJC. Analysis of these mRNAs in Xenopus laevis oocytes revealed that this complex is the species responsible for enhancing nucleocytoplasmic export of spliced mRNAs. It does so by providing a strong binding site for the mRNA export factors REF and TAP/p15. Moreover, by serving as an anchoring point for the factors Upf2 and Upf3, the EJC provides a direct link between splicing and nonsense‐mediated mRNA decay. Finally, we show that the composition of the EJC is dynamic in vivo and is subject to significant evolution upon mRNA export to the cytoplasm.

How introns influence and enhance eukaryotic gene expression

Although it has been known since the late 1970s that intron-containing and intronless versions of otherwise identical genes can exhibit dramatically different expression profiles, the underlying molecular mechanisms have only lately come to light. This review summarizes recent progress in our understanding of how introns and the act of their removal by the spliceosome can influence and enhance almost every step of mRNA metabolism. A rudimentary understanding of these effects can prove invaluable to researchers interested in optimizing transgene expression in eukaryotic systems.

Structure of the exon junction core complex with a trapped DEAD-box ATPase bound to RNA.

In higher eukaryotes, a multiprotein exon junction complex is deposited on spliced messenger RNAs. The complex is organized around a stable core, which serves as a binding platform for numerous factors that influence messenger RNA function. Here, we present the crystal structure of a tetrameric exon junction core complex containing the DEAD-box adenosine triphosphatase (ATPase) eukaryotic initiation factor 4AIII (eIF4AIII) bound to an ATP analog, MAGOH, Y14, a fragment of MLN51, and a polyuracil mRNA mimic. eIF4AIII interacts with the phosphate-ribose backbone of six consecutive nucleotides and prevents part of the bound RNA from being double stranded. The MAGOH and Y14 subunits lock eIF4AIII in a prehydrolysis state, and activation of the ATPase probably requires only modest conformational changes in eIF4AIII motif I.

The exon junction core complex is locked onto RNA by inhibition of eIF4AIII ATPase activity

The multiprotein exon junction complex (EJC) is assembled on mRNAs as a consequence of splicing. EJC core components maintain a stable grip on mRNAs even as the overall EJC protein composition evolves while mRNAs travel to the cytoplasm. Here we show that recombinant EJC subunits MLN51, MAGOH and Y14, together with the DEAD-box protein eIF4AIII bound to ATP, are necessary and sufficient to form a highly stable complex on single-stranded RNA. Cross-linking and RNase protection studies indicate that this recombinant complex recapitulates the EJC core. The stable association of the recombinant EJC core with RNA is maintained by inhibition of eIF4AIII ATPase activity by MAGOH-Y14. We elucidate the modalities of EJC binding to RNA and provide the first example of how cellular machineries may use RNA helicases to clamp several proteins onto RNA in stable and sequence-independent manners.

NMD factors UPF2 and UPF3 bridge UPF1 to the exon junction complex and stimulate its RNA helicase activity

Nonsense-mediated mRNA decay (NMD) eliminates mRNAs containing a premature translation termination codon through the recruitment of the conserved NMD factors UPF1, UPF2 and UPF3. In humans, a dynamic assembly pathway allows UPF1 to join UPF2 and UPF3 recruited to the mRNA by the exon-junction complex (EJC). Here we show that the recombinant EJC core is sufficient to reconstitute, with the three UPF proteins, a stable heptameric complex on RNA. The EJC proteins MAGOH, Y14 and eIF4AIII provide a composite binding site for UPF3b that serves as a bridge to UPF2 and UPF1. In the UPF trimeric complex, UPF2 and UPF3b cooperatively stimulate both ATPase and RNA helicase activities of UPF1. This work demonstrates that the EJC core is sufficient to stably anchor the UPF proteins to mRNA and provides insights into the regulation of its central effector, UPF1.

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.

The protein Mago provides a link between splicing and mRNA localization

The proteins Mago and Y14 are evolutionarily conserved binding partners. Y14 is a component of the exon–exon junction complex (EJC), deposited by the spliceosome upstream of messenger RNA (mRNA) exon–exon junctions. The EJC is implicated in post‐splicing events such as mRNA nuclear export and nonsense‐mediated mRNA decay. Drosophila Mago is essential for the localization of oskar mRNA to the posterior pole of the oocyte, but the functional role of Mago in other species is unknown. We show that Mago is a bona fide component of the EJC. Like Y14, Mago escorts spliced mRNAs to the cytoplasm, providing a direct functional link between splicing and the downstream process of mRNA localization. Mago/Y14 heterodimers are essential in cultured Drosophila cells. Taken together, these results suggest that, in addition to its specialized function in mRNA localization, Mago plays an essential role in other steps of mRNA metabolism.

EJCs at the Heart of Translational Control

In mammalian cells, the splicing machinery deposits the exon junction complex (EJC) on mRNA splice junctions. Two studies in this issue now link the EJC to different aspects of translational control. Ma et al. (2008) show that the EJC activates translation downstream of the mTOR signaling pathway, whereas Isken et al. (2008) establish that translation is repressed by partners of the EJC that are implicated in nonsense mediated decay (NMD).

CLIP-seq of eIF4AIII reveals transcriptome-wide mapping of the human exon junction complex

The exon junction complex (EJC) is a central effector of the fate of mRNAs, linking nuclear processing to mRNA transport, translation and surveillance. However, little is known about its transcriptome-wide targets. We used cross-linking and immunoprecipitation methods coupled to high-throughput sequencing (CLIP-seq) in human cells to identify the binding sites of the DEAD-box helicase eIF4AIII, an EJC core component. CLIP reads form peaks that are located mainly in spliced mRNAs. Most expressed exons harbor peaks either in the canonical EJC region, located ~24 nucleotides upstream of exonic junctions, or in other noncanonical regions. Notably, both of these types of peaks are preferentially associated with unstructured and purine-rich sequences containing the motif GAAGA, which is a potential binding site for EJC-associated factors. Therefore, EJC positions vary spatially and quantitatively between exons. This transcriptome-wide mapping of human eIF4AIII reveals unanticipated aspects of the EJC and broadens its potential impact on post-transcriptional regulation.