Subnuclear Localization and Dynamics of the Pre-mRNA 3′ End Processing Factor Mammalian Cleavage Factor I 68-kDa Subunit

Cardinale, Stefano; Cisterna, Barbara; Bonetti, Paolo; Aringhieri, Chiara; Biggiogera, Marco; Barabino, Silvia M.L.

doi:10.1091/mbc.e06-09-0846

Cited by 74 publications

(77 citation statements)

References 42 publications

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“…In this report we provide first evidence that the 68-kDa subunit of CF I m , a pre-mRNA 3Ј end processing factor, interacts with the mRNA export receptor NXF1 and stimulates mRNA export. On the basis of our observations and on previous data showing that CF I m 68 is associated with BrdU-labeled nascent transcripts (Cardinale et al, 2007), we propose that CF I m 68 is loaded onto the pre-mRNA during cleavage and polyadenylation of the 3Ј end of the transcript and remains bound to the mRNA all the way to the cytoplasm where it is removed by the translation machinery. CF I m 68 may thus act as a mark of correct 3Ј end maturation and contribute to efficient mRNA export via NXF1 recruitment.…”

Section: Discussionsupporting

confidence: 72%

“…Therefore, it is possible that CF I m 68 is leaving the nucleus by "piggy-backing" on RNA molecules being exported by other factors, either in association with the 25-kDa subunit or because of a direct interaction via the C-terminal domain. To determine whether shuttling of CF I m 68 depends on mRNA synthesis, we performed heterokaryon assays in the presence of actinomycin D. As shown in Figure 2B, GFP-CF I m 68 shuttling is blocked in presence of the transcription inhibitor, whereas relocalization of the protein in cap-like structures around the nucleoli of the human cell can be observed, as previously described (Cardinale et al, 2007; Figure 2B). Although we cannot formally rule out the possibility that actinomycin D could affect the synthesis of a short-lived protein required for export, the most likely conclusion of these experiments is that CF I m 68 shuttling is dependent on mRNA synthesis and possibly export.…”

supporting

confidence: 61%

“…The 68-kDa protein possesses an N-terminal RNPtype RNA recognition motif (RRM) and an RS-like C-terminal region enriched in RS/D/E dipeptides that is reminiscent of the RS domain of SR proteins. The RS-like domain of CF I m 68-kDa subunit is sufficient for the localization in nuclear speckles (and in the nucleoplasm) and mediates the interaction in vitro with a subset of shuttling SR proteins (Dettwiler et al, 2004;Cardinale et al, 2007).…”

Section: Introductionmentioning

confidence: 99%

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Mammalian pre-mRNA 3′ End Processing Factor CF I_m68 Functions in mRNA Export

Ruepp

Aringhieri

Vivarelli

et al. 2009

MBoC

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Export of mRNA from the nucleus is linked to proper processing and packaging into ribonucleoprotein complexes. Although several observations indicate a coupling between mRNA 3 end formation and export, it is not known how these two processes are mechanistically connected. Here, we show that a subunit of the mammalian pre-mRNA 3 end processing complex, CF I m 68, stimulates mRNA export. CF I m 68 shuttles between the nucleus and the cytoplasm in a transcription-dependent manner and interacts with the mRNA export receptor NXF1/TAP. Consistent with the idea that CF I m 68 may act as a novel adaptor for NXF1/TAP, we show that CF I m 68 promotes the export of a reporter mRNA as well as of endogenous mRNAs, whereas silencing by RNAi results in the accumulation of mRNAs in the nucleus. Moreover, CF I m 68 associates with 80S ribosomes but not polysomes, suggesting that it is part of the mRNP that is remodeled in the cytoplasm during the initial stages of translation. These results reveal a novel function for the pre-mRNA 3 end processing factor CF I m 68 in mRNA export. INTRODUCTIONThe removal of introns by splicing as well as cleavage and polyadenylation at the 3Ј end of RNA polymerase II primary transcripts (pre-mRNAs) are usually required before they can be exported from the nucleus as mature mRNAs (Erkmann and Kutay, 2004). This observation has suggested that transport factors interact with the RNA during premRNA processing. Indeed, recent discoveries have lent support to this hypothesis. The splicing reaction deposits on the mRNA a specific subset of proteins called the exon junction complex (EJC, for review see Tange et al., 2004). REF, a component of the EJC, facilitates mRNA export by interacting with the mRNA export factor NXF1 (also called TAP, for review, see Reed and Hurt, 2002). NXF1 was originally identified as the export receptor for type D retroviral RNAs that associate with NXF1 through a sequence-specific interaction with the constitutive transport element (CTE). However, NXF1 recruitment on cellular mRNAs requires adaptor proteins such as Aly/REF (hereafter named REF). In yeast Mex67 (the homolog of NXF1) is recruited by Yra1 (homolog of REF), which is also essential for the export of poly(A) RNA in Saccharomyces cerevisiae. In contrast in metazoans, REF is dispensable for bulk mRNA export. This raises the possibility that multiple and partially redundant adaptor proteins may be responsible for the recruitment of NXF1. Indeed, spliceosomal proteins, including U2AF35 (Zolotukhin et al., 2002) and some members of the SR family of splicing factors, were shown to interact with NXF1 and act as adaptors for NXF1-dependent export of poly(A) mRNAs (Huang and Steitz, 2001;Huang et al., 2003;Lai and Tarn, 2004;Hargous et al., 2006;Tintaru et al., 2007).Several observations have linked 3Ј end cleavage and polyadenylation to mRNA export (for review see Zhao et al., 1999). For example, RNA polymerase II reporter transcripts lacking a polyadenylation signal are retained in the nucleus of yeast cells. Positioning a...

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Section: Discussionsupporting

confidence: 72%

supporting

confidence: 61%

Section: Introductionmentioning

confidence: 99%

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Mammalian pre-mRNA 3′ End Processing Factor CF I_m68 Functions in mRNA Export

Ruepp

Aringhieri

Vivarelli

et al. 2009

MBoC

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“…An increasing number of studies have shown that dynamic and distinct nuclear compartments are likely to be associated with various pre-mRNA processing activities in many cell types (Boronenkov et al, 1998;Cardinale et al, 2007;Huang and Spector, 1991;Huang and Spector, 1992;Lamond and Spector, 2003;Mellman et al, 2008;Mintz and Spector, 2000;Politz et al, 2006). SYDN-1 could negatively regulate NpolyA activity on selected transcripts via direct interaction with PFS-2, or indirectly via additional proteins.…”

Section: Subnuclear Compartmentalization In Neuronsmentioning

confidence: 99%

Nuclear pre-mRNA 3′-end processing regulates synapse and axon development in C. elegans

Epps

Dai

et al. 2010

Development

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SUMMARYNuclear pre-mRNA 3Ј-end processing is vital for the production of mature mRNA and the generation of the 3Ј untranslated region (UTR). However, the roles and regulation of this event in cellular development remain poorly understood. Here, we report the function of a nuclear pre-mRNA 3Ј-end processing pathway in synapse and axon formation in C. elegans. In a genetic enhancer screen for synaptogenesis mutants, we identified a novel polyproline-rich protein, Synaptic defective enhancer-1 (SYDN-1). Loss of function of sydn-1 causes abnormal synapse and axon development, and displays striking synergistic interactions with several genes that regulate specific aspects of synapses. SYDN-1 is required in neurons and localizes to distinct regions of the nucleus. Through a genetic suppressor screen, we found that the neuronal defects of sydn-1 mutants are suppressed by loss of function in Polyadenylation factor subunit-2 (PFS-2), a conserved WD40-repeat protein that interacts with multiple subcomplexes of the pre-mRNA 3Ј-end processing machinery. PFS-2 partially colocalizes with SYDN-1, and SYDN-1 influences the nuclear abundance of PFS-2. Inactivation of several members of the nuclear 3Ј-end processing complex suppresses sydn-1 mutants. Furthermore, lack of sydn-1 can increase the activity of 3Ј-end processing. Our studies provide in vivo evidence for pre-mRNA 3Ј-end processing in synapse and axon development and identify SYDN-1 as a negative regulator of this cellular event in neurons.

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“…The CF I m 25 dimer together with one of the two larger subunits is sufficient to stimulate cleavage, although it is not known in what function the large subunits differ (Rüegsegger et al 1996(Rüegsegger et al , 1998. Analysis of the subnuclear localization of CF I m 68 has identified this protein in speckles and paraspeckles and its location varies during the cell cycle (Cardinale et al 2007). Moreover, sequence-specific RNA binding of the CF I m 68 subunit to motifs within the 39 UTR of its own premRNA has been reported to suppress cleavage (Brown and Gilmartin 2003).…”

Section: Introductionmentioning

confidence: 99%

Arginine methylation in subunits of mammalian pre-mRNA cleavage factor I

Martín

Ostareck-Lederer²,

Chari

et al. 2010

RNA

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Mammalian cleavage factor I (CF I m ) is composed of two polypeptides of 25 kDa and either a 59 or 68 kDa subunit (CF I m 25, CF I m 59, CF I m 68). It is part of the cleavage and polyadenylation complex responsible for processing the 39 ends of messenger RNA precursors. To investigate post-translational modifications in factors of the 39 processing complex, we systematically searched for enzymes that modify arginines by the addition of methyl groups. Protein arginine methyltransferases (PRMTs) are such enzymes that transfer methyl groups from S-adenosyl methionine to arginine residues within polypeptide chains resulting in mono-or dimethylated arginines. We found that CF I m 68 and the nuclear poly(A) binding protein 1 (PABPN1) were methylated by HeLa cell extracts in vitro. By fractionation of these extracts followed by mass spectral analysis, we could demonstrate that the catalytic subunit PRMT5, together with its cofactor WD45, could symmetrically dimethylate CF I m 68, whereas pICln, the third polypeptide of the complex, was stimulatory. As sites of methylation in CF I m 68 we could exclusively identify arginines in a GGRGRGRF or ''GAR'' motif that is conserved in vertebrates. Further in vitro assays revealed a second methyltransferase, PRMT1, which modifies CF I m 68 by asymmetric dimethylation of the GAR motif and also weakly methylates the C-termini of both CF I m 59 and CF I m 68. The results suggest that native-as compared with recombinant-protein substrates may contain additional determinants for methylation by specific PRMTs. A possible involvement of CF I m methylation in the context of RNA export is discussed.

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Subnuclear Localization and Dynamics of the Pre-mRNA 3′ End Processing Factor Mammalian Cleavage Factor I 68-kDa Subunit

Cited by 74 publications

References 42 publications

Mammalian pre-mRNA 3′ End Processing Factor CF I_m68 Functions in mRNA Export

Mammalian pre-mRNA 3′ End Processing Factor CF I_m68 Functions in mRNA Export

Nuclear pre-mRNA 3′-end processing regulates synapse and axon development in C. elegans

Arginine methylation in subunits of mammalian pre-mRNA cleavage factor I

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Subnuclear Localization and Dynamics of the Pre-mRNA 3′ End Processing Factor Mammalian Cleavage Factor I 68-kDa Subunit

Cited by 74 publications

References 42 publications

Mammalian pre-mRNA 3′ End Processing Factor CF Im68 Functions in mRNA Export

Mammalian pre-mRNA 3′ End Processing Factor CF Im68 Functions in mRNA Export

Nuclear pre-mRNA 3′-end processing regulates synapse and axon development in C. elegans

Arginine methylation in subunits of mammalian pre-mRNA cleavage factor I

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Product

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Mammalian pre-mRNA 3′ End Processing Factor CF I_m68 Functions in mRNA Export

Mammalian pre-mRNA 3′ End Processing Factor CF I_m68 Functions in mRNA Export