Two separate regions essential for nuclear import of the hnRNP D nucleocytoplasmic shuttling sequence

Heterogeneous nuclear ribonucleoprotein (hnRNP) D/AUF1 functions in mRNA genesis in the nucleus and modulates mRNA decay in the cytoplasm. Although it is primarily nuclear, it shuttles between the nucleus and cytoplasm. We studied the nuclear import and export of the last exon-encoding sequence common to all its isoforms by its expression as a green fluorescent protein-fusion protein in HeLa cells and by heterokaryon assay. The C-terminal 19-residue sequence (SGYGKVSRRGGHQNSYKPY) was identified as an hnRNP D nucleocytoplasmic shuttling sequence (DNS). In vitro nuclear transport using permeabilized cells indicated that nuclear import of DNS is mediated by transportin-1 (Trn-1). DNS accumulation in the nucleus was dependent on Trn-1, Ran, and energy in multiple rounds of nuclear transport. Use of DNS with deletions, alanine scanning mutagenesis and point mutations revealed that two separate regions (the N-terminal seven residues and the C-terminal two residues) are crucial for in vivo and in vitro transport as well as for interaction with Trn-1. The N- and C-terminal motifs are conserved in the shuttling sequences of hnRNP A1 and JKTBP.     

Transportins 1 and 2 are redundant nuclear import factors for hnRNP A1 and HuR

Several mRNA-binding proteins, including hnRNP A1 and HuR, contain bidirectional transport signals that mediate both their nuclear import and export. Previously, Transportin 1 (Trn1) was identified as a mediator of hnRNP A1 import, whereas the closely related protein Transportin 2 (Trn2) was shown to interact with HuR. Here we have investigated the subfamily of transportins that consists of Trn1 (or Kap beta2A) and two alternatively spliced Trn2 isoforms (Trn2a and Trn2b), also called Trn2 and Kap beta2B. The sequence differences among these proteins could alter either their cargo specificity or their response to RanGTP and thus their function as import or export receptors. Using in vitro binding assays, we show that hnRNP A1 preferentially binds Trn1 and Trn2b versus Trn2a. HuR interacts with all three transportins, as well as weakly with Imp beta. The hnRNP A1 and HuR shuttling domains, called M9 and HNS, respectively, are sufficient for these interactions. Despite small differences in the binding of HuR and hnRNP A1 to the three transportins, in vitro interaction studies performed in the presence and absence of RanQ69LGTP indicate that all three transportins most likely act as import factors for HuR and hnRNP A1. In digitonin-permeabilized HeLa cells, both M9 and HNS peptides compete for the import of recombinant hnRNP A1 and HuR, indicating that HuR and hnRNP A1 import pathways are at least partially overlapping. Possible nucleocytoplasmic shuttling mechanisms for hnRNP A1 and HuR are discussed.     

Nup153 is an M9-containing mobile nucleoporin with a novel Ran-binding domain

We employed a phage display system to search for proteins that interact with transportin 1 (TRN1), the import receptor for shuttling hnRNP proteins with an M9 nuclear localization sequence (NLS), and identified a short region within the N-terminus of the nucleoporin Nup153 which binds TRN1. Nup153 is located at the nucleoplasmic face of the nuclear pore complex (NPC), in the distal basket structure, and functions in mRNA export. We show that this Nup153 TRN1-interacting region is an M9 NLS. We found that both import and export receptors interact with several regions of Nup153, in a RanGTP-regulated fashion. RanGTP dissociates Nup153-import receptor complexes, but is required for Nup153-export receptor interactions. We also show that Nup153 is a RanGDP-binding protein, and that the interaction is mediated by the zinc finger region of Nup153. This represents a novel Ran-binding domain, which we term the zinc finger Ran-binding motif. We provide evidence that Nup153 shuttles between the nuclear and cytoplasmic faces of the NPC. The presence of an M9 shuttling domain in Nup153, together with its ability to move within the NPC and to interact with export receptors, suggests that this nucleoporin is a mobile component of the pore which carries export cargos towards the cytoplasm.     

Transportin: Nuclear Transport Receptor of a Novel Nuclear Protein Import Pathway

Many nuclear proteins are imported into the cell nucleus by the “classical” nuclear localization signal (NLS)-mediated import pathway. In this pathway, a sequence rich in basic residues in the protein interacts with a heterodimeric complex termed importin and this, along with the GTPase Ran, mediates nuclear import of the NLS-bearing protein. The heterogeneous nuclear ribonucleoprotein (hnRNP) A1 protein contains a novel nuclear localization sequence, termed M9, that does not contain any clusters of basic residues. Very recently, we showed that M9 directs import into the nucleus by a novel protein import pathway distinct from the classical NLS pathway. A 90-kilodalton protein termed transportin was identified as a protein that specifically interacts with wild-type M9 but not transport-defective M9 mutants. Transportin and an ATP-regenerating system were found to be necessary and sufficient for import of M9-containing proteins in anin vitroimport assay. In this report, we provide additional evidence that transportin can interact directly with M9-containing proteins and also show that it can mediate import of full-length hnRNP A1. In addition, Ran, or a Ran-binding protein, is identified as a second protein component of this novel nuclear import pathway. Transportin relatives fromSaccharomyces cerevisiaewhich likely serve as additional nuclear transport receptors are described.     

The human tap nuclear RNA export factor contains a novel transportin-dependent nuclear localization signal that lacks nuclear export signal function.

The human Tap protein mediates the sequence-specific nuclear export of RNAs containing the constitutive transport element and is likely also critical for general mRNA export. Here, we demonstrate that a previously defined arginine-rich nuclear localization signal (NLS) present in Tap acts exclusively via the transportin import factor. Previously, transportin has been shown to mediate the nuclear import of several heterogeneous nuclear ribonucleoproteins, including heterogeneous nuclear ribonucleoprotein (hnRNP) A1, by binding to a sequence element termed M9. Although the Tap NLS and the hnRNP A1 M9 element are shown to compete for transportin binding, they show no sequence homology, and the Tap NLS does not conform to the recently defined M9 consensus. The Tap NLS also differs from M9 in that only the latter is able to act as a nuclear export signal. The Tap NLS is therefore the first member of a novel class of transportin-specific NLSs that lack nuclear export signal function.     

Functional Conservation of the Transportin Nuclear Import Pathway in Divergent Organisms

Human transportin1 (hTRN1) is the nuclear import receptor for a group of pre-mRNA/mRNA-binding proteins (heterogeneous nuclear ribonucleoproteins [hnRNP]) represented by hnRNP A1, which shuttle continuously between the nucleus and the cytoplasm. hTRN1 interacts with the M9 region of hnRNP A1, a 38-amino-acid domain rich in Gly, Ser, and Asn, and mediates the nuclear import of M9-bearing proteins in vitro. Saccharomyces cerevisiae transportin (yTRN; also known as YBR017c or Kap104p) has been identified and cloned. To understanding the nuclear import mediated by yTRN, we searched with a yeast two-hybrid system for proteins that interact with it. In an exhaustive screen of the S. cerevisiae genome, the most frequently selected open reading frame was the nuclear mRNA-binding protein, Nab2p. We delineated a ca.-50-amino-acid region in Nab2p, termed NAB35, which specifically binds yTRN and is similar to the M9 motif. NAB35 also interacts with hTRN1 and functions as a nuclear localization signal in mammalian cells. Interestingly, yTRN can also mediate the import of NAB35-bearing proteins into mammalian nuclei in vitro. We also report on additional substrates for TRN as well as sequences of Drosophila melanogaster, Xenopus laevis, and Schizosaccharomyces pombe TRNs. Together, these findings demonstrate that both the M9 signal and the nuclear import machinery utilized by the transportin pathway are conserved in evolution.     

Distinct RNP complexes of shuttling hnRNP proteins with pre-mRNA and mRNA: candidate intermediates in formation and export of mRNA

Nascent pre-mRNAs associate with hnRNP proteins in hnRNP complexes, the natural substrates for mRNA processing. Several lines of evidence indicate that hnRNP complexes undergo substantial remodeling during mRNA formation and export. Here we report the isolation of three distinct types of pre-mRNP and mRNP complexes from HeLa cells associated with hnRNP A1, a shuttling hnRNP protein. Based on their RNA and protein compositions, these complexes are likely to represent distinct stages in the nucleocytoplasmic shuttling pathway of hnRNP A1 with its bound RNAs. In the cytoplasm, A1 is associated with its nuclear import receptor (transportin), the cytoplasmic poly(A)-binding protein, and mRNA. In the nucleus, A1 is found in two distinct types of complexes that are differently associated with nuclear structures. One class contains pre-mRNA and mRNA and is identical to previously described hnRNP complexes. The other class behaves as freely diffusible nuclear mRNPs (nmRNPs) at late nuclear stages of maturation and possibly associated with nuclear mRNA export. These nmRNPs differ from hnRNPs in that while they contain shuttling hnRNP proteins, the mRNA export factor REF, and mRNA, they do not contain nonshuttling hnRNP proteins or pre-mRNA. Importantly, nmRNPs also contain proteins not found in hnRNP complexes. These include the alternatively spliced isoforms D01 and D02 of the hnRNP D proteins, the E0 isoform of the hnRNP E proteins, and LRP130, a previously reported protein with unknown function that appears to have a novel type of RNA-binding domain. The characteristics of these complexes indicate that they result from RNP remodeling associated with mRNA maturation and delineate specific changes in RNP protein composition during formation and transport of mRNA in vivo.     

Arabidopsis transportin1 is the nuclear import receptor for the circadian clock-regulated RNA-binding protein AtGRP7

We characterized the Arabidopsis orthologue of the human nuclear import receptor transportin1 (TRN1). Like the human receptor, Arabidopsis TRN1 recognizes nuclear import signals on proteins that are different from the classical basic nuclear localization signals. The M9 domain of human heterogeneous nuclear ribonucleoprotein A1 (hnRNP A1) is the prototype of such signals. We show that AtTRN1 binds to similar domains in hnRNP-like proteins from plants. AtTRN1 also interacts with human hnRNP A1 and with yeast Nab2p, two classical import cargo proteins of transportin in these organisms. Like all nuclear transport receptors of the importin-beta family, AtTRN1 binds to the regulatory GTPase Ran from Arabidopsis. We demonstrated that the amino terminus of AtTRN1 is necessary for this interaction. Recombinant AtTRN1 conferred nuclear import of fluorescently labelled BSA-M9 peptide conjugates in permeabilized HeLa cells, functionally replacing human TRN1 in these in vitro nuclear import assays. We identified three plant substrate proteins that interact with AtTRN1 and contain M9-like domains: a novel Arabidopsis hnRNP that shows high similarity to human hnRNP A1 and two small RNA-binding proteins from Arabidopsis, AtGRP7 and AtGRP8. Nuclear import activity of the M9-like domains of these plant proteins was demonstrated in vivo by their ability to confer partial nuclear re-localisation of a GFP fusion protein containing a nuclear export signal. In addition, fluorescently labelled AtGRP7 was specifically imported into nuclei of permeabilized HeLa cells by Arabidopsis AtTRN1 and human TRN1. These results suggest that the transportin-mediated nuclear import pathway is highly conserved between man, yeast and plants.     

Nuclear targeting peptide scaffolds for lipofection of nondividing mammalian cells.

Lipofection of nondividing cells is inefficient because much of the transfected DNA is retained in endosomes, and that which escapes to the cytoplasm enters the nucleus at low rates. To improve the final rate-limiting step of nuclear import, we conjugated a nonclassical nuclear localization signal (NLS) containing the M9 sequence of heterogeneous nuclear ribonucleoprotein (hnRNP) A1, to a cationic peptide scaffold derived from a scrambled sequence of the SV40 T-antigen consensus NLS (ScT). The ScT was added to improve DNA binding of the M9 sequence. Lipofection of confluent endothelium with plasmid complexed with the M9-ScT conjugate resulted in 83% transfection and a 63-fold increase in marker gene expression. The M9-ScT conjugate localized fluorescent plasmid into the nucleus of permeabilized cells, and addition of the nuclear pore blocker wheat germ agglutinin prevented nuclear import. This method of gene transfer may lead to viral- and lipid-free transfection of nondividing cells.     

A nuclear localization domain in the hnRNP A1 protein

The heterogeneous nuclear RNP (hnRNP) A1 protein is one of the major pre-mRNA/mRNA binding proteins in eukaryotic cells and one of the most abundant proteins in the nucleus. It is localized to the nucleoplasm and it also shuttles between the nucleus and the cytoplasm. The amino acid sequence of A1 contains two RNP motif RNA-binding domains (RBDs) at the amino terminus and a glycine-rich domain at the carboxyl terminus. This configuration, designated 2x RBD-Gly, is representative of perhaps the largest family of hnRNP proteins. Unlike most nuclear proteins characterized so far, A1 (and most 2x RBD-Gly proteins) does not contain a recognizable nuclear localization signal (NLS). We have found that a segment of ca. 40 amino acids near the carboxyl end of the protein (designated M9) is necessary and sufficient for nuclear localization; attaching this segment to the bacterial protein beta- galactosidase or to pyruvate kinase completely localized these otherwise cytoplasmic proteins to the nucleus. The RBDs and another RNA binding motif found in the glycine-rich domain, the RGG box, are not required for A1 nuclear localization. M9 is a novel type of nuclear localization domain as it does not contain sequences similar to classical basic-type NLS. Interestingly, sequences similar to M9 are found in other nuclear RNA-binding proteins including hnRNP A2.     

Characterization of a novel transferable CRM-1-independent nuclear export signal in a herpesvirus tegument protein that shuttles between the nucleus and cytoplasm

A new group of nucleocytoplasmic shuttling proteins has recently been identified in the structural proteins encoded by several alphaherpesvirus UL47 genes. Nuclear import and export signals for the bovine herpesvirus type 1 UL47 protein (VP8 or bUL47) have been described previously. Here, we study the trafficking of bUL47 in detail and identify an import signal different from that shown before. It comprises a 20-residue N-terminal peptide that is fully transferable and targets a large, normally cytosolic protein to the nucleus. A conserved RRPRRS motif within this peptide was shown to be essential but not sufficient for nuclear targeting. Using interspecies heterokaryon assays, we further demonstrate that the export activity of the published leucine-rich nuclear export signal (NES) is also transferable to a large protein but is functionally weak compared to the activity of the HIV-1 Rev NES. We show that nuclear export dictated by this bUL47 NES is sensitive to leptomycin B (LMB) and therefore dependent on the export receptor CRM-1. However, nuclear export of full-length bUL47 is fully resistant to LMB, suggesting the presence of an additional NES. We go on to identify a second NES in bUL47 within a 28-residue peptide that is in close proximity to but entirely separable from the N-terminal import signal, and we use fluorescence loss in photobleaching to confirm its activity. This NES is resistant to leptomycin B, and therefore utilizes an export receptor other than CRM-1. As this new sequence bears little similarity to other export signals so far defined, we suggest it may be involved in bUL47 export from the nucleus via a novel cellular receptor.     

A Role for the M9 Transport Signal of hnRNP A1 in mRNA Nuclear Export

Among the nuclear proteins associated with mRNAs before their export to the cytoplasm are the abundant heterogeneous nuclear (hn) RNPs. Several of these contain the M9 signal that, in the case of hnRNP A1, has been shown to be sufficient to signal both nuclear export and nuclear import in cultured somatic cells. Kinetic competition experiments are used here to demonstrate that M9-directed nuclear import in Xenopus oocytes is a saturable process. Saturating levels of M9 have, however, no effect on the import of either U snRNPs or proteins carrying a classical basic NLS. Previous work demonstrated the existence of nuclear export factors specific for particular classes of RNA. Injection of hnRNP A1 but not of a mutant protein lacking the M9 domain inhibited export of mRNA but not of other classes of RNA. This suggests that hnRNP A1 or other proteins containing an M9 domain play a role in mRNA export from the nucleus. However, the requirement for M9 function in mRNA export is not identical to that in hnRNP A1 protein transport.The transport of macromolecules between the nucleus and cytoplasm is a bi-directional process. The best understood aspect is the import of nuclear proteins that carry a basic nuclear localization signal (NLS)¹ like the simple NLS found in SV-40 T antigen or the bipartite NLS found in nucleoplasmin (Dingwall and Laskey, 1991). Proteins of this class are recognized by the heterodimeric importin receptor, composed of importin α and importin β (for review see Powers and Forbes, 1994; Melchior and Gerace, 1995; Görlich and Mattaj, 1996). The NLS binds directly to the importin α subunit. The importin NLS protein complex docks at the cytoplasmic face of the nuclear pore complex in an energy-independent manner (Newmeyer and Forbes, 1988; Richardson et al., 1988). Subsequently, the small GTPase Ran/TC4 (Melchior et al., 1993; Moore and Blobel, 1993) and a protein of unknown function named variously pp15, p10, or NTF2 (Moore and Blobel, 1994; Paschal and Gerace, 1995) are required for translocation of the NLS-containing complex through the nuclear pore complex.A second major class of imported macromolecules are the uracil rich small nuclear (U sn) RNPs. They do not have a basic NLS but instead have a bipartite nuclear targeting signal. This is composed of an essential signal formed when the Sm core proteins bind to the U snRNA and an additional signal, the trimethyl-guanosine (m₃G) cap, which depending on the cell type or the U snRNA is either essential or required for optimal U snRNP import efficiency (Fischer and Lührmann, 1990; Hamm et al., 1990; Fischer et al., 1993). Kinetic competition experiments have supported the conclusion that U snRNPs require different limiting factors than do NLS-containing proteins for their import and that U snRNPs do not bind to importin α (Fischer et al., 1991, 1993; Michaud and Goldfarb, 1991; van Zee et al., 1993). There is also preliminary evidence that additional different receptors may be required for the nuclear uptake of other RNA species (Michaud and Goldfarb, 1992).Similarly, RNA export from the nucleus relies on recognition of the RNA or RNP export substrates by saturable factors (Zasloff, 1983; Bataillé et al., 1990; Jarmolowski et al., 1994). As for import, evidence for the existence of RNA class-specific export receptors has been obtained from kinetic competition experiments (Jarmolowski et al., 1994). Two RNA-binding proteins have been directly shown to function in RNA export, a nuclear cap binding protein complex in the case of U snRNAs (Izaurralde et al., 1995a ) and the HIV-1 Rev protein in the case of RNAs containing a rev response element (Fischer et al., 1994, 1995). In the case of mRNAs, the best candidates for export mediators are the heterogeneous nuclear (hn) RNP proteins (for review see Piñol-Roma and Dreyfuss, 1993; Izaurralde and Mattaj, 1995).About 20 different hnRNP proteins have been characterized in vertebrate cells (for review see Dreyfuss et al., 1993). The association of hnRNP proteins with mRNA in the nucleus and the cytoplasm suggests that they may regulate and/or facilitate different aspects of gene expression. The possibility that hnRNP proteins might be directly involved in the nucleocytoplasmic trafficking of mRNA molecules was suggested by the observation that several hnRNP proteins, including A1, A2, D, E, I, and K shuttle continuously and rapidly between the nucleus and the cytoplasm and are associated with mRNA in both compartments (Piñol-Roma and Dreyfuss 1992, 1993; Michael et al., 1995a , b). Of these, the best studied example is hnRNP A1. An A1-like hnRNP protein has been shown by immunoelectron microscopy to be associated with a specific mRNA in transit to the cytoplasm through the nuclear pore complex in the insect Chironomus tentans (Visa et al., 1996a ). In mammalian cells, the amount of A1 which is in constant flux between nucleus and cytoplasm is striking. It has been estimated that at least 120,000 molecules of A1 are exported to the cytoplasm per minute but then rapidly reimported such that the steady state localization of A1 is nuclear (Michael et al., 1995a ). Taken together, these results suggest that A1 and other shuttling hnRNP proteins such as A2, D, E, I, and K could play a significant role in the transport of mRNA from the nucleus to the cytoplasm.One key in understanding how hnRNPs may facilitate mRNA export is to determine the signals that mediate their shuttling, i.e., their import into and exit from the nucleus. The nucleocytoplasmic transport of A1 has been recently studied in detail, and the signals that mediate shuttling have been identified (Michael et al., 1995b ; Siomi and Dreyfuss, 1995; Weighardt et al., 1995). Nuclear import of A1 is determined by a 38-amino acid sequence, termed M9, located near the COOH terminus of the protein between amino acids 268 and 305. Its fusion to cytoplasmic reporter proteins such as pyruvate kinase resulted in rapid import of the fusion protein into the nucleus (Siomi and Dreyfuss, 1995). However, the A1 NLS has no sequence similarity to classical protein NLSs such as that of SV-40 large T antigen or nucleoplasmin (Siomi and Dreyfuss, 1995).Surprisingly, M9 also acts as a nuclear export signal (NES). In heterokaryon shuttling assays this domain is necessary and sufficient to allow the export of heterologous proteins, such as the nucleoplasmin core domain (NPLc), which are normally retained in the nucleus (Michael et al., 1995b ). Thus, M9 alone can account for the shuttling of A1. Other hnRNPs such as A2 and B1 bear sequences with striking similarities to M9 (Siomi and Dreyfuss, 1995). Mutagenesis experiments indicate that the NES and NLS activities of M9 are either identical or overlapping as mutants which block M9 NLS activity also abolish NES activity (Michael et al., 1995b ). It is therefore possible that M9 is recognized in the nucleus and the cytoplasm by the same receptor.The second category of NES described was first found in the HIV-1 Rev protein and the inhibitor of protein kinase A (Fischer et al., 1995; Wen et al., 1995; Bogerd et al., 1996; for review see Gerace, 1995). These short, leucine-rich NES sequences bear no relationship to the primary sequence of M9. Furthermore, saturation of the export factor recognized by the Rev NES has no effect on mRNA export (Fischer et al., 1995). A model for mRNA export has been postulated on the basis of the hnRNP data described above. In this model, NES/NLS containing hnRNPs bind in the nucleus to mRNA molecules and deliver them, via the export pathway they access, to the cytoplasm. In the cytoplasm these hnRNP proteins dissociate from the mRNA and return to the nucleus. To further test this model we have analyzed the transport of hnRNP A1 and mRNA in Xenopus laevis oocytes. The oocyte offers a unique opportunity to manipulate specific import or export pathways, like that accessed by M9, and examine the effect on mRNA nuclear export. By using this approach we show here that M9 is, as in somatic cells, a functional NLS in oocytes. Moreover, competition studies indicate that M9 defines a novel class of NLS, since saturation of the M9- mediated import pathway does not interfere with the two previously identified import pathways used by classical NLS-bearing proteins or m₃G-capped-spliceosomal U snRNPs. Injection of an excess of hnRNP A1 but not of a mutant form of the protein lacking the M9 domain, resulted in a specific inhibition of mRNA export, demonstrating that the M9 domain is recognized by a saturable component of the mRNA export machinery. The export of other cellular RNAs such as U snRNAs and tRNA was, in contrast, not affected. Further analysis of mutant hnRNP A1 proteins provides evidence that M9 recognition during mRNA export differs from its recognition during protein transport.     

HnRNP proteins and the nuclear export of mRNA

Pre-mRNAs associate in the nucleus with specific RNA-binding proteins to form heterogeneous nuclear ribonucleoprotein (hnRNP) complexes. The hnRNP proteins participate directly or indirectly in the processing of pre-mRNAs into mature mRNAs. Recent studies have shown that some hnRNP proteins shuttle continuously between the nucleus and the cytoplasm. The export of shuttling hnRNP proteins from the nucleus is mediated by specific nuclear export sequences (NESs) within the proteins. In addition, shuttling hnRNP proteins appear to remain bound to exported mRNAs in transit through nuclear pores. As discussed in this review, the picture that is emerging is that nuclear export of mRNAs is mediated by the export of NES-containing hnRNP proteins to which they are bound.     

Functional dissection of hnRNP D suggests that nuclear import is required before hnRNP D can modulate mRNA turnover in the cytoplasm

Many shuttling proteins not only function in the nucleus but also control mRNA fates in the cytoplasm. We test whether a link exists between their nuclear association with mRNPs and their cytoplasmic functions using the p37 isoform of hnRNP D, which inhibits the rapid cytoplasmic mRNA decay in NIH3T3 cells. We showed that p37 shuttles between nucleus and cytoplasm, and narrowed down the nuclear import signal to a 50-amino-acid C-terminal domain. A p37 mutant missing this domain, still capable of associating with target mRNAs in vitro, was confined to the cytoplasm, where it was unable to block cytoplasmic mRNA turnover. Introducing heterologous shuttling domains to this mutant, thereby restoring its ability to enter the nucleus, concomitantly restored its cytoplasmic function. Association of p37 with its target mRNAs can only be detected when it can enter the nucleus. Our results suggest that nuclear import of hnRNP D is a prerequisite for it to exert its cytoplasmic function. This study provides a useful model system to elucidate the mechanisms by which "nuclear history" affects cytoplasmic mRNA fates.     

Cytosine-block telomeric type DNA-binding activity of hnRNP proteins from human cell lines

Following the observation of the presence in mammalian nuclear extracts of a DNA binding activity quite specific for the single-stranded C-rich telomeric motif, we have isolated from the K562 human cell line by affinity chromatography and identified by mass spectrometry a number of proteins able to bind to this sequence. All of them belong to different heterogeneous nuclear ribonucleoprotein subgroups (hnRNP). Whereas many of them, namely hnRNP K, two isoforms of hnRNP I, and the factor JKTBP, appear to bind to this sequence with limited specificity after isolation, an isoform of hnRNP D (alias AUF1) and particularly hnRNP E1 (alias PCBP-1) show a remarkable specificity for the (CCCTAA)n repeated motif. Both have been obtained also as recombinant proteins expressed in Escherichia coli and have been shown to retain their binding specificity toward the C-block repeated sequence. In the light of the current knowledge about these proteins, their possible involvement in telomere functioning is discussed.     

Histone deacetylase 4 possesses intrinsic nuclear import and export signals

Nucleocytoplasmic trafficking of histone deacetylase 4 (HDAC4) plays an important role in regulating its function, and binding of 14-3-3 proteins is necessary for its cytoplasmic retention. Here, we report the identification of nuclear import and export sequences of HDAC4. While its N-terminal 118 residues modulate the nuclear localization, residues 244 to 279 constitute an authentic, strong nuclear localization signal. Mutational analysis of this signal revealed that three arginine-lysine clusters are necessary for its nuclear import activity. As for nuclear export, leucine-rich sequences located in the middle part of HDAC4 do not function as nuclear export signals. By contrast, a hydrophobic motif (MXXLXVXV) located at the C-terminal end serves as a nuclear export signal that is necessary for cytoplasmic retention of HDAC4. This motif is required for CRM1-mediated nuclear export of HDAC4. Furthermore, binding of 14-3-3 proteins promotes cytoplasmic localization of HDAC4 by both inhibiting its nuclear import and stimulating its nuclear export. Unlike wild-type HDAC4, a point mutant with abrogated MEF2-binding ability remains cytoplasmic upon exogenous expression of MEF2C, supporting the notion that direct MEF2 binding targets HDAC4 to the nucleus. Therefore, HDAC4 possesses intrinsic nuclear import and export signals for its dynamic nucleocytoplasmic shuttling, and association with 14-3-3 and MEF2 proteins affects such shuttling and thus directs HDAC4 to the cytoplasm and the nucleus, respectively.