Mutsuhito Ohno

hnRNP C tetramer measures RNA length to classify RNA polymerase II transcripts for export.

Choosing the Right Path RNA molecules are synthesized in the cell nucleus, yet many have to be moved to the cytoplasm to be processed and/or to effect their function. Different classes of RNA are transported from the nucleus by different transport systems. Messenger RNAs (mRNAs) and uridine-rich small nuclear RNAs (U snRNAs) are transcribed by RNA polymerase II and are capped and bound by the cap-binding machinery in the nucleus but are exported by different protein complexes. The feature that distinguishes the two classes of RNA is their length: U snRNAs are short and mRNAs are long. Using an in vitro system and human tissue culture cells, McCloskey et al. (p. 1643) show that the length of the RNAs is measured by the heterogeneous nuclear ribonicleoprotein (hnRNP) C tetrameric protein complex. The hnRNP C cannot bind to the short U snRNAs, allowing the U snRNA-specific export adaptor protein, PHAX, to bind and mediate export. Longer mRNAs are bound by hnRNP C, which prevents the binding of PHAX, thus identifying these RNAs for export from the nucleus via the mRNA pathway. A nuclear protein measures the length of newly made RNAs and sorts them into distinct pathways for export. Specific RNA recognition is usually achieved by specific RNA sequences and/or structures. However, we show here a mechanism by which RNA polymerase II (Pol II) transcripts are classified according to their length. The heterotetramer of the heterogeneous nuclear ribonucleoprotein (hnRNP) C1/C2 measures the length of the transcripts like a molecular ruler, by selectively binding to the unstructured RNA regions longer than 200 to 300 nucleotides. Thus, the tetramer sorts the transcripts into two RNA categories, to be exported as either messenger RNA or uridine-rich small nuclear RNA (U snRNA), depending on whether or not they are longer than the threshold, respectively. Our findings reveal a new function of the C tetramer and highlight the biological importance of RNA recognition by the length.

A role for ubiquitin in the clearance of nonfunctional rRNAs

Quality control mechanisms operate in various steps of ribosomal biogenesis to ensure the production of functional ribosome particles. It was reported previously that mature ribosome particles containing nonfunctional mutant rRNAs are also recognized and selectively removed by a cellular quality control system (nonfunctional rRNA decay [NRD]). Here, we show that the NRD of 25S rRNA requires a ubiquitin E3 ligase component Rtt101p and its associated protein Mms1p, identified previously as factors involved in DNA repair. We revealed that a group of proteins associated with nonfunctional ribosome particles are ubiquitinated in a Rtt101-Mms1-dependent manner. 25S NRD was disrupted when ubiquitination was inhibited by the overexpression of modified ubiquitin molecules, demonstrating a direct role for ubiquitin in this pathway. These results uncovered an unexpected connection between DNA repair and the quality control of rRNAs. Our findings support a model in which responses to DNA and rRNA damages are triggered by a common ubiquitin ligase complex during genotoxic stress harmful to both molecules.

ATP-Dependent Recruitment of Export Factor Aly/REF onto Intronless mRNAs by RNA Helicase UAP56

ABSTRACT Loading of export factors onto mRNAs is a key step in gene expression. In vertebrates, splicing plays a role in this process. Specific protein complexes, exon junction complex and transcription/export complex, are loaded onto mRNAs in a splicing-dependent manner, and adaptor proteins such as Aly/REF in the complexes in turn recruit mRNA exporter TAP-p15 onto the RNA. By contrast, how export factors are recruited onto intronless mRNAs is largely unknown. We previously showed that Aly/REF is preferentially associated with intronless mRNAs in the nucleus. Here we show that Aly/REF could preferentially bind intronless mRNAs in vitro and that this binding was stimulated by RNA helicase UAP56 in an ATP-dependent manner. Consistently, an ATP binding-deficient UAP56 mutant specifically inhibited mRNA export in Xenopus oocytes. Interestingly, ATP activated the RNA binding activity of UAP56 itself. ATP-bound UAP56 therefore bound to both RNA and Aly/REF, and as a result ATPase activity of UAP56 was cooperatively stimulated. These results are consistent with a model in which ATP-bound UAP56 chaperones Aly/REF onto RNA, ATP is then hydrolyzed, and UAP56 dissociates from RNA for the next round of Aly/REF recruitment. Our finding provides a mechanistic insight into how export factors are recruited onto mRNAs.

Functional Association of the Microprocessor Complex with the Spliceosome

ABSTRACT The majority of human microRNAs (miRNAs) are located in the introns of other genes (A. Rodriguez, S. Griffiths-Jones, J. L. Ashurst, and A. Bradley, Genome Res. 14:1902-1910, 2004). Based on the discovery that artificial insertion of pre-miRNAs in introns did not hamper mRNA production and that the miRNA-harboring introns were spliced more slowly than the adjacent introns, a model was previously proposed in which Drosha crops the pre-miRNA and the two cropped fragments from the pre-mRNA are subsequently trans spliced (Y. K. Kim and V. N. Kim, EMBO J. 26:775-783, 2007). However, the molecular basis for this model was not elucidated. To analyze the molecular mechanism of intronic miRNA processing, we developed an in vitro system in which both pre-miRNA processing and mRNA splicing are detected simultaneously. Our analysis using this system showed that pre-miRNA cropping from the pre-mRNA could occur kinetically faster than splicing. Glycerol gradient sedimentation experiments revealed that part of the pre-miRNA was cofractionated with the spliceosome. Furthermore, coimmunoprecipitation experiments with an anti-Drosha antibody demonstrated that Drosha was associated not only with the cropping products but also with a Y-shaped branch intron and a Y-shaped splicing intermediate. These results provide a molecular basis for the postulated existence of a pathway in which the Microprocessor complex becomes associated with the spliceosome, pre-miRNA cropping occurs prior to splicing, and trans splicing takes place between the cropped products.

Isolation and characterization of post-splicing lariat–intron complexes

Pre-mRNA splicing occurs in a large complex spliceosome. The steps of both spliceosome assembly and splicing reaction have been extensively analyzed, and many of the factors involved have been identified. However, the post-splicing intron turnover process, especially in vertebrates, remains to be examined. In this paper, we developed a two-tag affinity purification method for purifying lariat intron RNA–protein complexes obtained from an in vitro splicing reaction. Glycerol gradient sedimentation analyses revealed that there are at least two forms of post-splicing intron complexes, which we named the ‘Intron Large (IL)’ and the ‘Intron Small (IS)’ complexes. The IL complex contains U2, U5 and U6 snRNAs and other protein splicing factors, whereas the IS complex contains no such U snRNAs or proteins. We also showed that TFIP11, a human homolog of yeast Ntr1, is present in the IL complex and the TFIP11 mutant protein, which lacks the interaction domain with hPrp43 protein, caused accumulation of the IL complex and reduction of IS complex formation in vitro. Taken together, our results strongly suggest that TFIP11 in cooperation with hPrp43 mediates the transition from the IL complex to the IS complex, leading to efficient debranching and turnover of excised introns.

40S subunit dissociation and proteasome-dependent RNA degradation in nonfunctional 25S rRNA decay

Eukaryotic cells have quality control systems that eliminate nonfunctional rRNAs with deleterious mutations (nonfunctional rRNA decay, NRD). We have previously reported that 25S NRD requires an E3 ubiquitin ligase complex, which is involved in ribosomal ubiquitination. However, the degradation process of nonfunctional ribosomes has remained unknown. Here, using genetic screening, we identified two ubiquitin‐binding complexes, the Cdc48–Npl4–Ufd1 complex (Cdc48 complex) and the proteasome, as the factors involved in 25S NRD. We show that the nonfunctional 60S subunit is dissociated from the 40S subunit in a Cdc48 complex‐dependent manner, before it is attacked by the proteasome. When we examined the nonfunctional 60S subunits that accumulated under proteasome‐depleted conditions, the majority of mutant 25S rRNAs retained their full length at a single‐nucleotide resolution. This indicates that the proteasome is an essential factor triggering rRNA degradation. We further showed that ribosomal ubiquitination can be stimulated solely by the suppression of the proteasome, suggesting that ubiquitin–proteasome‐dependent RNA degradation occurs in broader situations, including in general rRNA turnover.

Multiple factors in the early splicing complex are involved in the nuclear retention of pre-mRNAs in mammalian cells

Intron‐containing pre‐mRNAs are retained in the nucleus until they are spliced. This mechanism is essential for proper gene expression. Although the formation of splicing complexes on pre‐mRNAs is thought to be responsible for this nuclear retention activity, the details are poorly understood. In mammalian cells, in particular, very little information is available regarding the retention factors. Using a model reporter gene, we show here that U1 snRNP and U2AF but not U2 snRNP are essential for the nuclear retention of pre‐mRNAs in mammalian cells, showing that E complex is the major entity responsible for the nuclear retention of pre‐mRNAs in mammalian cells. By focusing on factors that bind to the 3′‐splice site region, we found that the 65‐kD subunit of U2AF (U2AF65) is important for nuclear retention and that its multiple domains have nuclear retention activity per se. We also provide evidence that UAP56, a DExD‐box RNA helicase involved in both RNA splicing and export, cooperates with U2AF65 in exerting nuclear retention activity. Our findings provide new information regarding the pre‐mRNA nuclear retention factors in mammalian cells.

Cajal body surveillance of U snRNA export complex assembly

Passage of transcribed U snRNA precursors through Cajal bodies ensures that they are properly bound to the PHAX adaptor protein required for nuclear exit.

Role of purine-rich exonic splicing enhancers in nuclear retention of pre-mRNAs

Intron-containing pre-mRNAs are normally retained in the nucleus until they are spliced to produce mature mRNAs that are exported to the cytoplasm. Although the detailed mechanism is not well understood, the formation of splicing-related complexes on pre-mRNAs is thought to be responsible for the nuclear retention. Therefore, pre-mRNAs containing suboptimal splice sites should tend to leak out to the cytoplasm. Such pre-mRNAs often contain purine-rich exonic splicing enhancers (ESEs) that stimulate splicing of the adjacent intron. Here, we show that ESEs per se possess an activity to retain RNAs in the nucleus through a saturable nuclear retention factor. Cross-competition experiments revealed that intron-containing pre-mRNAs (without ESEs) used the same saturable nuclear retention factor as ESEs. Interestingly, although intronless mRNAs containing ESEs were also poorly exported, spliced mRNAs produced from ESE-containing pre-mRNAs were efficiently exported to the cytoplasm. Thus, the splicing reaction can reset the nuclear retention state caused by ESEs, allowing nuclear export of mature mRNAs. Our results reveal a novel aspect of ESE activity that should contribute to gene expression and RNA quality control.

U1-independent pre-mRNA splicing contributes to the regulation of alternative splicing.

U1 snRNP plays a crucial role in the 5′ splice site recognition during splicing. Here we report the first example of naturally occurring U1-independent U2-type splicing in humans. The U1 components were not included in the pre-spliceosomal E complex formed on the human F1γ (hF1γ) intron 9 in vitro. Moreover, hF1γ intron 9 was efficiently spliced even in U1-disrupted Xenopus oocytes as well as in U1-inactivated HeLa nuclear extracts. Finally, hF1γ exon 9 skipping induced by an alternative splicing regulator Fox-1 was impaired when intron 9 was changed to the U1-dependent one. Our results suggest that U1-independent splicing contributes to the regulation of alternative splicing of a class of pre-mRNAs.