Identification of cytosolic factors required for nuclear location sequence-mediated binding to the nuclear envelope

Nuclear protein import

The defining feature of eukaryotic organisms is the cell nucleus. All nuclear proteins are synthesized in the cytoplasm and need to be imported through the nuclear pore complexes (NPCs) into the nucleus. Import can be directed by various signals, of which the classical nuclear localization signal (NLS) and the M9 import signal are the best characterized. The past year has provided insight into the functions of the key players in NLS- and M9-dependent import, the interactions of these key players and possible implications of these interactions for the import mechanism. Although an understanding of some of the steps in the import process is emerging, the molecular mechanism of the actual translocation through the NPC is still obscure.

Importin alpha from Arabidopsis thaliana is a nuclear import receptor that recognizes three classes of import signals

Protein import into the nucleus is a two-step process. In vitro import systems from vertebrate cell extracts have shown several soluble factors are required. One of these factors is the receptor importin alpha, which binds to nuclear localization signals (NLS) in vitro. We previously cloned an importin alpha homolog from Arabidopsis thaliana (At-IMP alpha) and demonstrated that this protein was not depleted from tobacco (Nicotiana tabacum) protoplasts after permeabilization of the plasma membrane, (Hicks et al., 1996). To determine if At-IMP alpha is functional, we used an in vitro NLS-binding assay. We found that At-IMP alpha is specific, and the receptor is able to recognize three classes of NLS identified in plants. Purified antibodies to At-IMP alpha were used to determine the in vivo location of importin alpha in tobacco protoplasts. Importin alpha is found in the cytoplasm and nucleus, and it is most highly concentrated at the nuclear envelope. The biochemical properties of nuclear importin alpha and localization studies using purified nuclei demonstrate that importin alpha is tightly associated with the plant nucleus. Moreover, these results suggest that a fraction of nuclear importin alpha interacts with the nuclear pore complex.

A distinct nuclear import pathway used by ribosomal proteins

Protein transport into the nucleus is governed by the interaction of soluble transport factors with their import substrates and nuclear pore complexes. Here, we identify a major distinct nuclear import pathway, mediated by a previously uncharacterized yeast beta karyopherin Kap123p. The predominant substrates for this pathway are ribosomal proteins, which must be imported into the nucleus prior to assembly into pre-ribosomes. Kap123p binds directly to its transport substrates, repeat motif-containing nucleoporins, and Ran-GTP. We show that the related protein Pse1p is also a karyopherin and can functionally substitute for Kap123p; both are capable of specifically directing a ribosomal nuclear localization signal reporter to the nucleus in vivo.

A nuclear export signal in Kap95p is required for both recycling the import factor and interaction with the nucleoporin GLFG repeat regions of Nup116p and Nup100p

During nuclear import, cytosolic transport factors move through the nuclear pore complex (NPC) to the nuclear compartment. Kap95p is required during import for docking the nuclear localization signal-receptor and ligand to the NPC. Recycling of this factor back to the cytoplasm is necessary for continued rounds of import; however, the mechanism for Kap95p recycling is unknown. We have determined that recycling of Kap95p requires a nuclear export signal (NES). A region containing the NES in Kap95p was sufficient to mediate active nuclear export in a microinjection assay. Moreover, the NES was necessary for function. Mutation of the NES in Kap95p resulted in a temperaturesensitive import mutant, and immunofluorescence microscopy experiments showed that the mutated Kap95p was not recycled but instead localized in the nucleus and at the nuclear envelope. Srp1p, the yeast nuclear localization signal-receptor, also accumulated in the nuclei of the arrested kap95 mutant cells. Wild-type and NES-mutated Kap95p both bound Gsp1p (the yeast Ran/TC4 homologue), Srp1p, and the FXFG repeat region of the nucleoporin Nup1p. In contrast, the NES mutation abolished Kap95p interaction with the GLFG repeat regions from the nucleoporins Nup116p and Nup100p. In vivo interaction was demonstrated by isolation of Kap95p from yeast nuclear lysates in either protein A-tagged Nup116p or protein A-tagged Nup100p complexes. The protein A-tagged Nup116p complex also specifically contained Gle2p. These results support a model in which a step in the recycling of Kap95p is mediated by interaction of an NES with GLFG regions. Analysis of genetic interactions suggests Nup116p has a primary role in Kap95p recycling, with Nup100p compensating in the absence of Nup116p. This finding highlights an important role for a subfamily of GLFG nucleoporins in nuclear export processes.

Karyopherin beta2 mediates nuclear import of a mRNA binding protein

We have cloned and sequenced cDNA for human karyopherin beta2, also known as transportin. In a solution binding assay, recombinant beta2 bound directly to recombinant nuclear mRNA-binding protein A1. Binding was inhibited by a peptide representing A1's previously characterized M9 nuclear localization sequence (NLS), but not by a peptide representing a classical NLS. As previously shown for karyopherin beta1, karyopherin beta2 bound to several nucleoporins containing characteristic peptide repeat motifs. In a solution binding assay, both beta1 and beta2 competed with each other for binding to immobilized repeat nucleoporin Nup98. In digitonin-permeabilized cells, beta2 was able to dock A1 at the nuclear rim and to import it into the nucleoplasm. At low concentrations of beta2, there was no stimulation of import by the exogenous addition of the GTPase Ran. However, at higher concentrations of beta2 there was marked stimulation of import by Ran. Import was inhibited by the nonhydrolyzable GTP analog guanylyl imidodiphosphate by a Ran mutant that is unable to hydrolyze GTP and also by wheat germ agglutinin. Consistent with the solution binding results, karyopherin beta2 inhibited karyopherin alpha/beta1-mediated import of a classical NLS containing substrate and, vice versa, beta1 inhibited beta2-mediated import of A1 substrate, suggesting that the two import pathways merge at the level of docking of beta1 and beta2 to repeat nucleoporins.

Phosphorylation of Srp1p, the yeast nuclear localization signal receptor, in vitro and in vivo

Srp1p, the protein encoded by SRP1 of the yeast Saccharomyces cerevisiae, is a yeast nuclear localization signal (NLS) receptor protein. We have previously reported isolation of a protein kinase from yeast extracts that phosphorylates Srp1p complexed with NLS peptides/proteins. From partial amino acid sequences of the four subunits of the purified kinase, we have now identified this protein kinase to be identical to yeast casein kinase II (CKII). It was previously thought that autophosphorylation of the 36 kDa subunit of the yeast enzyme was stimulated by the substrate, GST-Srp1p. However, with the use of a more refined system, no stimulation of autophosphorylation of the 36 kDa subunit of yeast CKII was observed. Biochemical and mutational analyses localized the in vitro phosphorylation site of Srp1p by CKII to serine 67. It was shown that, in the absence of NLS peptides/proteins, phosphorylation of the intact Srp1p protein is very weak, but deletion of the C-terminal end causes great stimulation of phosphorylation without NLS peptides/proteins. Thus, the CKII phosphorylation site is apparently masked in the intact protein structure by the presence of a C-terminal region, probably between amino acids 403 and 516. Binding of NLS peptides/proteins most likely causes a change in protein conformation, exposing the CKII phosphorylation site. Mutational alterations of serine 67, the CKII phosphorylation site, to valine (S67V) and aspartic acid (S67D) were not found to cause any significant deleterious effects on cell growth. Analysis of in vivo phosphorylation showed that at least 30% of the wild type Srp1p molecules are phosphorylated in growing cells, and that the phosphorylation is mostly at the serine 67 CKII site. The ability of Srp1p purified from E coli and treated with calf intestinal phosphatase to bind a SV40 T-antigen NLS peptide was compared with that of Srp1p which was almost fully phosphorylated by CKII. No significant difference was observed. It appears that NLS binding does not require any phosphorylation of Srp1p, either by CKII or by some other protein kinase.

Cloning and characterization of human karyopherin beta3

Nuclear import of classical nuclear localization sequence-bearing proteins is mediated by karyopherin alpha/beta1 heterodimers. A second nuclear import pathway, mediated by karyopherin beta2 (transportin), recently was described for mRNA-binding proteins. Here we report the cloning and characterization of human karyopherin beta3, which may be involved in a third pathway for nuclear import. Karyopherin beta3 was localized mainly to the cytosol and the nucleus, particularly the nuclear rim. It bound to several of the repeat-containing nucleoporins (Nup358, Nup214, Nup153, Nup98, and p62) in overlay and solution-binding assays and was competed away by karyopherin beta1. For Nup98, we localized this binding to the peptide repeat-containing region. Karyopherin beta3 contains two putative Ran-binding homology regions and bound to Ran-GTP in a solution-binding assay with much higher affinity than to Ran-GDP. Furthermore, it interacted with two ribosomal proteins in an overlay assay. We suggest that karyopherin beta3 is a nuclear transport factor that may mediate the import of some ribosomal proteins into the nucleus.

Three-dimensional visualization of the route of protein import: the role of nuclear pore complex substructures

The three-dimensional localization of nucleoplasmin and wheat germ agglutinin (WGA) at the nuclear envelope of Xenopus oocytes is demonstrated by microinjecting protein coated gold colloids and examining their distribution using both stereo transmission electron microscopy and field emission in-lens scanning electron microscopy. Localization of many WGA gold particles and nucleoplasmin gold particles at the same nuclear pore complex (NPC) following coinjection is demonstrated. Binding of the WGA gold in the central region of the NPCs appears to form a barrier, preventing the import of nucleoplasmin gold, and includes central localization along radial "tracks" which correspond to the internal filaments connecting the cytoplasmic ring and the central region of the NPC. We suggest that these filaments may in some way be involved in opening and closing of the central channel of the NPC for transport. Transport of nucleoplasmin through the central region of the NPCs appears to be in "single file" regardless of the size of the colloidal gold, and distribution into the nucleoplasm appears to be through the basket rings with no association of the nucleoplasmin gold with the basket filaments being observed.

Different binding domains for Ran-GTP and Ran-GDP/RanBP1 on nuclear import factor p97

Several proteins are required for the transport of nuclear proteins from the cytoplasm to the nucleus, including the nuclear location sequence receptor (NLS receptor), p97, the small nuclear GTPase Ran/TC4, and several nucleoporins. The interaction of Ran with p97 is thought to regulate the interaction of these transport components. Ran-GTP alone binds p97, but Ran-GDP binds p97 only in conjunction with RanBP1. Using site-directed mutagenesis and deletion analysis, we have identified two distinct but overlapping binding domains for Ran-GTP and Ran-GDP/RanBP1 on p97. A short acidic sequence in p97 is part of the Ran-GDP/RanBP1 binding domain, possibly functioning in a similar manner as the C-terminal acidic sequence in Ran. A conserved cysteine residue in p97, Cys-158, is required for binding Ran-GDP/RanBP1, but not for binding of Ran-GTP to p97. In a permeabilized cell protein import assay, a mutant p97 with alanine substituted for Cys-158 is unable to support import in the presence of NLS receptor and Ran. These results support a direct active role for Ran-GDP in the receptor complex and provide evidence that the activity of downstream effectors of small GTPases may be regulated by both GTP- and GDP-bound forms of the protein.

Molecular interactions between the importin alpha/beta heterodimer and proteins involved in vertebrate nuclear protein import

We have used in vitro binding assays to examine specific interactions between a number of cytoplasmic and nuclear pore proteins involved in nuclear protein import in vertebrates. We demonstrate that nuclear transport factor 2 (NTF2), nucleoporin p62 and the Ras-like GTPase Ran bind to the importin heterodimer via its beta subunit. The binding behaviour of p62 truncation mutants indicated that importin-beta interacts primarily with the alpha-helical coiled-coil rod domain of nucleoporin p62 and not with the N-terminal domain that contains a number of degenerate repeats based on the xFxFG sequence motif. The binding of Ran to importin-beta was sensitive to its nucleotide state, with RanGTP binding strongly, whereas RanGDP binding could not be detected using our assay conditions. RanGTP, but not RanGDP, was able to displace p62 bound to the importin alpha/beta complex, suggesting that the binding sites for p62 and RanGTP on importin-beta overlap. Moreover, RanGTP, but not RanGDP, weakened the interaction between importin-alpha and importin-beta in a concentration-dependent manner. NTF2 bound to the importin heterodimer but did not displace p62, suggesting that the NTF2 and p62 binding sites on importin-beta do not overlap. The set of interactions we observed was not altered by the binding of NLS-containing substrates such as transcription factor IIIA to the importin heterodimer. Our results are consistent with models for nuclear protein import in which Ran nucleotide exchange modulates the binding of the importin-substrate complexes during translocation through nuclear pore complexes.

The human homologue of yeast CRM1 is in a dynamic subcomplex with CAN/Nup214 and a novel nuclear pore component Nup88

The oncogenic nucleoporin CAN/Nup214 is essential in vertebrate cells. Its depletion results in defective nuclear protein import, inhibition of messenger RNA export and cell cycle arrest. We recently found that CAN associates with proteins of 88 and 112 kDa, which we have now cloned and characterized. The 88 kDa protein is a novel nuclear pore complex (NPC) component, which we have named Nup88. Depletion of CAN from the NPC results in concomitant loss of Nup88, indicating that the localization of Nup88 to the NPC is dependent on CAN binding. The 112 kDa protein is the human homologue of yeast CRM1, a protein known to be required for maintenance of correct chromosome structure. This human CRM1 (hCRM1) localized to the NPC as well as to the nucleoplasm. Nuclear overexpression of the FG-repeat region of CAN, containing its hCRM1-interaction domain, resulted in depletion of hCRM1 from the NPC. In CAN-/- mouse embryos lacking CAN, hCRM1 remained in the nuclear envelope, suggesting that this protein can also bind to other repeat-containing nucleoporins. Lastly, hCRM1 shares a domain of significant homology with importin-beta, a cytoplasmic transport factor that interacts with nucleoporin repeat regions. We propose that hCRM1 is a soluble nuclear transport factor that interacts with the NPC.

Import of plasmid DNA into the nucleus is sequence specific

Nuclear import of plasmid DNA in nondividing cells is a process essential to the success of numerous viral life cycles, gene therapy protocols, and gene expression experiments. Here, intact protein-free SV40 DNA was cytoplasmically injected into cells and its subcellular localization was followed by in situ hybridization. SV40 DNA localized to the nucleus consistent with a mechanism of transport through the nuclear pore complex (NPC): import was inhibited by the addition of the NPC-inhibitory agents wheat germ agglutinin and an anti-nucleoporin antibody as well as by energy depletion. DNA transport appeared to be a multistep process with the DNA accumulating at the nuclear periphery before its import. Most importantly, nuclear import was sequence specific: a region of SV40 DNA containing the origin of replication and the early and late promoters supported import, whereas bacterial sequences alone and other SV40-derived sequences did not. The majority of the imported DNA colocalized with the SC-35 splicing complex antigen, suggesting that the intranuclear DNA localizes to areas of transcription or message processing. This link to transcription was strengthened by the finding that inhibition of transcription blocked DNA import but not protein nuclear import. Taken together, these results support a model in which plasmid DNA nuclear import occurs by a mechanism similar to that used by nuclear localization signal-containing proteins but is also dependent on transcription.

Ran-binding protein 1 (RanBP1) forms a ternary complex with Ran and karyopherin beta and reduces Ran GTPase-activating protein (RanGAP) inhibition by karyopherin beta

The nuclear accumulation of proteins containing nuclear localization signals requires the Ran GTPase and a complex of proteins assembled at the nuclear pore. RanBP1 is a cytosolic Ran-binding protein that inhibits RCC1-stimulated release of GTP from Ran. RanBP1 also promotes the binding of Ran to karyopherin beta (also called importin beta and p97) and is a co-stimulator of RanGAP activity. Yeast karyopherin beta inhibits the GTP hydrolysis by Ran catalyzed by RanGAP. To further define the roles of RanBP1 and karyopherin beta in Ran function, we explored the effects of RanBP1 and karyopherin beta on mammalian proteins known to regulate Ran. Like RanBP1, karyopherin beta prevented the release of GTP from Ran stimulated by RCC1 or EDTA. As with the yeast protein, mammalian karyopherin beta completely blocked RanGAP activity. However, the addition of RanBP1 to this assay partially rescued the inhibited RanGAP activity. Kinetic analysis of the effects on RanGAP activity by karyopherin beta and RanBP1 revealed a combination of competitive and noncompetitive interactions. Solution binding assays confirmed the ability of RanBP1 to associate with Ran and karyopherin beta in a ternary complex, and RanBP1 binding was not competed out by the addition of karyopherin beta. These results demonstrate that RanBP1 and karyopherin beta interact with distinct sites of Ran and suggest that RanBP1 plays an essential role in nuclear transport by permitting RanGAP-mediated hydrolysis of GTP on Ran complexed to karyopherin beta.

Calmodulin activates nuclear protein import: a link between signal transduction and nuclear transport

In addition to the well-characterized GTP-dependent nuclear transport observed in permeabilized cells, we detected a mode of nuclear transport that was GTP-independent at elevated cytoplasmic calcium concentrations. Nuclear transport under these conditions was blocked by calmodulin inhibitors. Recombinant calmodulin restored ATP-dependent nuclear transport in the absence of cytosol. Calmodulin-dependent transport was inhibited by wheat germ agglutinin consistent with transport proceeding through nuclear pores. We propose that release of intracellular calcium stores upon cell activation inhibits GTP-dependent nuclear transport; the elevated cytosolic calcium then acts through calmodulin to stimulate the novel GTP-independent mode of import.

A novel ubiquitin-like modification modulates the partitioning of the Ran-GTPase-activating protein RanGAP1 between the cytosol and the nuclear pore complex

Ran is a nuclear Ras-like GTPase that is required for the bidirectional transport of proteins and ribnucleoproteins across the nuclear pore complex (NPC). A key regulator of the Ran GTP/GDP cycle is the 70-kD Ran-GTPase-activating protein RanGAP1. Here, we report the identification and localization of a novel form of RanGAP1. Using peptide sequence analysis and specific mAbs, RanGAP1 was found to be modified by conjugation to a ubiquitin-like protein. Immunoblot analysis and immunolocalization by light and EM demonstrated that the 70-kD unmodified from of RanGAP1 is exclusively cytoplasmic, whereas the 90-kD modified form of RanGAP1 is associated with the cytoplasmic fibers of the NPC. The modified form of RanGAP1 also appeared to associated with the mitotic spindle apparatus during mitosis. These findings have specific implications for Ran function and broad implications for protein regulation by ubiquitin-like modifications. Moreover, the variety and function of ubiquitin-like protein modifications in the cell may be more diverse than previously realized.

GLE2, a Saccharomyces cerevisiae homologue of the Schizosaccharomyces pombe export factor RAE1, is required for nuclear pore complex structure and function

To identify and characterize novel factors required for nuclear transport, a genetic screen was conducted in the yeast Saccharomyces cerevisiae. Mutations that were lethal in combination with a null allele of the gene encoding the nucleoporin Nup100p were isolated using a colony-sectoring assay. Three complementation groups of gle (for GLFG lethal) mutants were identified. In this report, the characterization of GLE2 is detailed. GLE2 encodes a 40.5-kDa polypeptide with striking similarity to that of Schizosaccharomyces pombe RAE1. In indirect immunofluorescence and nuclear pore complex fractionation experiments, Gle2p was associated with nuclear pore complexes. Mutated alleles of GLE2 displayed blockage of polyadenylated RNA export; however, nuclear protein import was not apparently diminished. Immunofluorescence and thin-section electron microscopic analysis revealed that the nuclear pore complex and nuclear envelope structure was grossly perturbed in gle2 mutants. Because the clusters of herniated pore complexes appeared subsequent to the export block, the structural perturbations were likely indirect consequences of the export phenotype. Interestingly, a two-hybrid interaction was detected between Gle2p and Srp1p, the nuclear localization signal receptor, as well as Rip1p, a nuclear export signal-interacting protein. We propose that Gle2p has a novel role in mediating nuclear transport.

Nuclear localization signal of SV40 T antigen directs import of plasmid DNA into sea urchin male pronuclei in vitro

Nuclear import of plasmid DNA mediated by a nuclear localization signal (NLS) derived from SV40 T antigen was investigated in a cell-free extract. In vitro assembled sea urchin male pronuclei were incubated in a 100,000g supernatant of a zebrafish fertilized egg lysate, together with fluorescently labeled plasmid DNA bound to NLS or nuclear import deficient reverse NLS (revNLS) peptides. After 3 hr, DNA-NLS, but not DNA-revNLS, complexes were bound around the nuclear periphery. We demonstrate that nuclear import of DNA-NLS complexes is a two-step process involving binding to, and translocation across, the nuclear envelope. Binding is ATP-independent, occurs at 0 degree C and is Ca(2+)-independent. By contrast, translocation requires ATP hydrolysis, Ca2+, is temperature dependent and is blocked by the lectin wheat germ agglutinin. Both binding and translocation are competitively inhibited by albumin-NLS conjugates, require heat-labile cytosolic factors, and are inhibited by N-ethylmaleimide treatment of the cytosol. Binding and translocation are differentially affected by cytosol dilutions, suggesting that at least two distinct soluble fractions are required for nuclear import. The requirements for NLS-mediated nuclear import of plasmid DNA are similar to those for nuclear import of protein-NLS conjugates in permeabilized cells.

Exogenously injected nuclear import factor p10/NTF2 inhibits signal-mediated nuclear import and export of proteins in living cells

p10/NTF2 is a cytosolic factor which is required for the translocation step in nuclear protein import in an in vitro assay with digitonin-permeabilized cells. To study the functional roles of p10/NTF2 on protein transport between the nucleus and cytoplasm in living cells, recombinant p10/NTF2 was micro-injected into cultured mammalian cells. Cytoplasmically injected p10/NTF2 strongly inhibited the nuclear import of co-injected NLS-containing substrates in a dose-dependent manner but had no effect on the diffusive import of small non-nuclear proteins. Moreover, when injected into the cell nucleus, p10/NTF2 inhibited the nuclear export of NES-containing substrates. The results suggest that the nuclear import factor p10/NTF2 may also be involved in the nuclear export of proteins and that the protein transport efficiency between the nucleus and cytoplasm may be regulated by the intracellular level of p10/NTF2.

Expression in yeast of binding regions of karyopherins alpha and beta inhibits nuclear import and cell growth

Using truncated forms of recombinant yeast karyopherins alpha and beta in in vitro binding assays, we mapped the regions of karyopherin alpha that bind to karyopherin beta and the regions of karyopherin beta that interact with karyopherin alpha and with Ran-GTP. Karyopherin alpha's binding region for karyopherin beta was localized to its N-terminal domain, which contains several clusters of basic residues, whereas karyopherin beta's binding region for karyopherin alpha was localized to an internal region containing two clusters of acidic residues. Karyopherin beta's binding region for Ran-GTP overlaps with that for karyopherin alpha and comprises at least one of the two acidic clusters required for karyopherin alpha binding in addition to further downstream determinants not required for karyopherin alpha binding. Overexpression in yeast of fragments containing either karyopherin beta's binding region for alpha and Ran-GTP or karyopherin alpha's binding region for beta resulted in sequestration of most of the cytosolic karyopherin alpha or karyopherin beta, respectively, in complexes containing the truncated proteins. As these binding region-containing fragments lack other domains required for function of the corresponding protein, the overexpression of either fragment also inhibited in vivo nuclear import of a model reporter protein as well as cell growth.

RanBP1 stabilizes the interaction of Ran with p97 nuclear protein import

Three factors have been identified that reconstitute nuclear protein import in a permeabilized cell assay: the NLS receptor, p97, and Ran/TC4. Ran/TC4, in turn, interacts with a number of proteins that are involved in the regulation of GTP hydrolysis or are components of the nuclear pore. Two Ran-binding proteins, RanBP1 and RanBP2, form discrete complexes with p97 as demonstrated by immunoadsorption from HeLa cell extracts fractionated by gel filtration chromatography. A > 400-kD complex contains p97, Ran, and RanBP2. Another complex of 150-300 kD was comprised of p97, Ran, and RanBP1. This second trimeric complex could be reconstituted from recombinant proteins. In solution binding assays, Ran-GTP bound p97 with high affinity, but the binding of Ran-GDP to p97 was undetectable. The addition of RanBP1 with Ran-GDP or Ran-GTP increased the affinity of both forms of Ran for p97 to the same level. Binding of Ran-GTP to p97 dissociated p97 from immobilized NLS receptor while the Ran-GDP/RanBP1/p97 complex did not dissociate from the receptor. In a digitonin-permeabilized cell docking assay, RanBP1 stabilizes the receptor complex against temperature-dependent release from the pore. When added to an import assay with recombinant NLS receptor, p97 and Ran-GDP, RanBP1 significantly stimulates transport. These results suggest that RanBP1 promotes both the docking and translocation steps in nuclear protein import by stabilizing the interaction of Ran-GDP with p97.

Kap104p: a karyopherin involved in the nuclear transport of messenger RNA binding proteins

A cytosolic yeast karyopherin, Kap104p, was isolated and shown to function in the nuclear import of a specific class of proteins. The protein bound directly to repeat-containing nucleoporins and to a cytosolic pool of two nuclear messenger RNA (mRNA) binding proteins, Nab2p and Nab4p. Depletion of Kap104p resulted in a rapid shift of Nab2p from the nucleus to the cytoplasm without affecting the localization of other nuclear proteins tested. This finding suggests that the major function of Kap104p lies in returning mRNA binding proteins to the nucleus after mRNA export.

Critical role of reverse transcriptase in the inhibitory mechanism of CNI-H0294 on HIV-1 nuclear translocation

HIV-1 replication requires the translocation of viral genome into the nucleus of a target cell. We recently reported the synthesis of an arylene bis(methyl ketone) compound (CNI-H0294) that inhibits nuclear targeting of the HIV-1 genome and thus HIV-1 replication in monocyte cultures. Here we demonstrate that CNI-H0294 inhibits nuclear targeting of HIV-1-derived preintegration complexes by inactivating the nuclear localization sequence of the HIV-1 matrix antigen in a reaction that absolutely requires reverse transcriptase. This drug/reverse transcriptase interaction defines the specificity of its antiviral effect and is most likely mediated by the pyrimidine side-chain of CNI-H0294. After binding to reverse transcriptase, the carbonyl groups of CNI-H0294 react with the nuclear localization sequence of matrix antigen and prevent its binding to karyopherin alpha, the cellular receptor for nuclear localization sequences that carries proteins into the nucleus. Our results provide a basis for the development of a novel class of compounds that inhibit nuclear translocation and that can, in principle, be modified to target specific infectious agents.

G2 arrest and impaired nucleocytoplasmic transport in mouse embryos lacking the proto-oncogene CAN/Nup214

The vertebrate nucleopore complex (NPC) is a 125 MDa multiprotein assembly that mediates nucleocytoplasmic transport. One of its components, CAN/Nup214, is an FXFG repeat-containing protein known to be involved in myeloid leukemia in humans. We have devised a powerful genetic approach, using maternally derived protein in murine null embryos, to show that CAN/ Nup214 is essential for NPC function in vivo. We demonstrate that CAN-/- mouse embryonic stem (ES) cells are not viable and that CAN-/- embryos die in utero between 4.0 and 4.5 days postcoitum, following the depletion of their CAN from maternal sources. In 3.5-day-old mutant embryos, cultured in vitro, progressive depletion of CAN leads to cell cycle arrest in G2 phase, and eventually to blastocoel collapse, impaired NLS-mediated protein uptake and nuclear accumulation of polyadenylated RNA. Remarkably, these defective CAN-depleted embryos do not display any gross morphological abnormalities in their nuclear envelopes or NPCs. Our data suggest that CAN is critical to cell cycle progression and required for both nuclear protein import and mRNA export.

Identification of different roles for RanGDP and RanGTP in nuclear protein import

The importin-alpha/beta heterodimer and the GTPase Ran play key roles in nuclear protein import. Importin binds the nuclear localization signal (NLS). Translocation of the resulting import ligand complex through the nuclear pore complex (NPC) requires Ran and is terminated at the nucleoplasmic side by its disassembly. The principal GTP exchange factor for Ran is the nuclear protein RCC1, whereas the major RanGAP is cytoplasmic, predicting that nuclear Ran is mainly in the GTP form and cytoplasmic Ran is in the GDP-bound form. Here, we show that nuclear import depends on cytoplasmic RanGDP and free GTP, and that RanGDP binds to the NPC. Therefore, import might involve nucleotide exchange and GTP hydrolysis on NPC-bound Ran. RanGDP binding to the NPC is not mediated by the Ran binding sites of importin-beta, suggesting that translocation is not driven from these sites. Consistently, a mutant importin-beta deficient in Ran binding can deliver its cargo up to the nucleoplasmic side of the NPC. However, the mutant is unable to release the import substrate into the nucleoplasm. Thus, binding of nucleoplasmic RanGTP to importin-beta probably triggers termination, i.e. the dissociation of importin-alpha from importin-beta and the subsequent release of the import substrate into the nucleoplasm.

In vivo nuclear transport kinetics in Saccharomyces cerevisiae: a role for heat shock protein 70 during targeting and translocation

The transport of proteins into the nucleus is a receptor-mediated process that is likely to involve between 50-100 gene products, including many that comprise the nuclear pore complex. We have developed an assay in Saccharomyces cerevisiae for the nuclear transport of green fluorescent protein fused to the SV-40 large T antigen nuclear localization signal (NLS-GFP). This assay allows the measurement of relative NLS-GFP nuclear import rates in wild-type and mutant cells under various physiological conditions. Probably the best understood component of the nuclear transport apparatus is Srp1p, the NLS receptor, which binds NLS-cargo in the cytoplasm and accompanies it into the nucleus. When compared to SRP1+ cells, NLS-GFP import rates in temperature-sensitive srp1-31 cells were slower and showed a lower temperature optimum. The in vivo transport defect of the srp1-31 cells was correlated with the purified protein's thermal sensitivity, as assayed by in vitro NLS peptide binding. We show that the kinetics of NLS-directed nuclear transport in wild-type cells is stimulated by the elevated expression of SSA1, which encodes a cytoplasmic heat shock protein 70 (Hsp70). Elevated Hsp70 levels are sufficient to suppress the NLS-GFP import defects in srp1-31 and nup82-3 cells. NUP82 encodes a protein that functions within the nuclear pore complex subsequent to docking. These results provide genetic evidence that Hsp70 acts during both targeting and translocation phases of nuclear transport, possibly as a molecular chaperone to promote the formation and stability of the Srp1p-NLS-cargo complex.

Transport of proteins in eukaryotic cells: more questions ahead

Some newly synthesized proteins contain signals that direct their transport to their final location within or outside of the cell. Targeting signals are recognized by specific protein receptors located either in the cytoplasm or in the membrane of the target organelle. Specific membrane protein complexes are involved in insertion and translocation of polypeptides across the membranes. Often, additional targeting signals are required for a polypeptide to be further transported to its site of function. In this review, we will describe the trafficking of proteins to various cellular organelles (nucleus, chloroplasts, mitochondria, peroxisomes) with emphasis on transport to and through the secretory pathway.

Sequential binding of import ligands to distinct nucleopore regions during their nuclear import

Protein import into nuclei is mediated by the nuclear pore complex (NPC) and by cellular factors. To structurally characterize this process, nuclear import of gold-labeled nucleoplasmin was followed by electron microscopy to identify NPC components interacting with the import ligand complex in vivo. Before translocation into the nucleus, nucleoplasmin sequentially bound to two distinct regions: first to the distal part of the cytoplasmic filaments and then at the cytoplasmic entry to the central gated channel. Evidence that the delivery of the import ligand from the first to the second binding region occurred by bending of the cytoplasmic filaments is presented here.

A novel receptor-mediated nuclear protein import pathway

Targeting of most nuclear proteins to the cell nucleus is initiated by interaction between the classical nuclear localization signals (NLSs) contained within them and the importin NLS receptor complex. We have recently delineated a novel 38 amino acid transport signal in the hnRNP A1 protein, termed M9, which confers bidirectional transport across the nuclear envelope. We show here that M9-mediated nuclear import occurs by a novel pathway that is independent of the well-characterized, importin-mediated classical NLS pathway. Additionally, we have identified a specific M9-interacting protein, termed transportin, which binds to wild-type M9 but not to transport-defective M9 mutants. Transportin is a 90 kDa protein, distantly related to importin beta, and we show that it mediates the nuclear import of M9-containing proteins. These findings demonstrate that there are at least two receptor-mediated nuclear protein import pathways. Furthermore, as hnRNP A1 likely participates in mRNA export, it raises the possibility that transportin is a mediator of this process as well.

Direct and indirect association of the small GTPase ran with nuclear pore proteins and soluble transport factors: studies in Xenopus laevis egg extracts

Ran is a small GTPase that is required for protein import, mRNA export, and the maintenance of nuclear structures. To gain a better understanding of Ran's role in the nucleus, we have sought to use Xenopus egg extracts for the purification and characterization of proteins from egg extracts bound with a high affinity to a glutathione-S-transferase-Ran fusion protein (GST-Ran). We found that GST-Ran associates specifically with at least 10 extract proteins. We determined the identifies of six Ran-interacting proteins (Rips), and found that they include RanBP2/Nup358, Nup153, Importin beta, hsc70, RCC1, and RanBP1. On the basis of peptide sequence, a seventh Rip (p88) seems to be similar but not identical to Fug1/RanGAP1, the mammalian Ran-GTPase-activating protein. Gel filtration analysis of endogenous extract proteins suggests that Importin beta acts as a primary GTP-Ran effector. Both Ran and Importin beta are coimmunoprecipitated by anti-p340RanBP2 antibodies in the presence of nonhydrolyzable GTP analogues, suggesting that Ran-Importin beta complexes interact with p340RanBP2. Two other Rips, p18 and p88, are coprecipitated with p340RanBP2 in a nucleotide-independent manner. Analysis of the Ran-GTPase pathway in Xenopus extracts allows the examination of interactions between Ran-associated proteins under conditions that resemble in vivo conditions more closely than in assays with purified components, and it thereby allows additional insights into the molecular mechanism of nuclear transport.

The NTF2 gene encodes an essential, highly conserved protein that functions in nuclear transport in vivo

The small protein p10/Ntf2p has been implicated in protein import in vitro (Moore, M. S., and Blobel, G. (1994) Proc. Natl. Acad. Sci. U. S. A. 91, 10212-10216; Paschal, B. M., and Gerace, L.(1995) J. Cell Biol. 129, 925-937). Here we present the first evidence that demonstrates an essential in vivo role for the NTF2 gene product in nuclear transport. The NTF2 locus was identified in a screen for temperature-sensitive Saccharomyces cerevisiae mutants defective in the localization of nuclear proteins. Genetic analysis demonstrates that the NTF2 gene is essential for viability in budding yeast. Two temperature-sensitive mutants, ntf2-1 and ntf2-2, that each contain single point mutations in highly conserved amino acid residues show defects in the localization of nuclear proteins but not in the export of poly(A)+ RNA following a shift to the nonpermissive temperature. An epitope-tagged version of Ntf2p was used to show that the protein is concentrated at the nuclear envelope. Finally, the human gene under the control of the yeast promoter fully substitutes for the deleted yeast gene. Taken together, these results demonstrate the exquisite functional conservation of this protein throughout evolution and indicate a critical in vivo role in nuclear transport.

Molecular and functional characterization of the p62 complex, an assembly of nuclear pore complex glycoproteins

Macromolecular trafficking across the nuclear envelope involves interactions between cytosolic transport factors and nuclear pore complex proteins. The p62 complex, an assembly of 62, 58, 54, and 45-kD O-linked glycoproteins-localized near the central gated channel of the nuclear pore complex, has been directly implicated in nuclear protein import. The cDNA cloning of rat p62 was reported previously. We have now carried out cDNA cloning of rat p58, p54, and p45. We found that p58 contains regions with FG (Phe, Gly) and PA (Pro, Ala) repeats at both its NH2 and COOH termini separated by a predicted alpha-helical coiled-coil region, while p54 has an NH2-terminal FG and PA repeat region and a COOH-terminal predicted coiled-coil region. p45 and p58 appear to be generated by alternative splicing, with p45 containing the NH2-terminal FG repeat region and the coiled-coil region of p58. Using immunogold electron microscopy, we found that p58/p45 and p54 are localized on both sides of the nuclear pore complex, like p62. Previous studies have shown that immobilized recombinant p62 can bind the cytosolic nuclear import factor NTF2 and thereby deplete transport activity from cytosol. We have now found that immobilized recombinant p58 and p54 also can deplete nuclear transport activity from cytosol, and that p62, p58, and p54 bind directly to the cytosolic nuclear import factors p97 and NTF2. At least in the case of p58, this involves FG repeat regions. Moreover, p58 can bind to a complex containing transport ligand, the nuclear localization sequence receptor (Srp1 alpha) and p97. These data support a model in which the p62 complex binds to a multicomponent particle consisting of transport ligand and cytosolic factors to achieve accumulation of ligand near the central gated channel of the nuclear pore complex.

Nuclear import in permeabilized protoplasts from higher plants has unique features

The import of proteins into the nucleus is a poorly understood process that is thought to require soluble cytosolic factors in vertebrates and yeast. To test this model in plants and to identify components of the import apparatus, we developed a direct in vitro nuclear import assay by using tobacco protoplasts that were permeabilized without detergents such as digitonin or Triton X-100. Substrates were imported specifically by a mechanism that required only guanine nucleotides. Moreover, in vitro import did not require exogenous cytosol. To investigate this novel finding, we isolated a full-length cDNA encoding an Arabidopsis homolog of vertebrate and yeast nuclear localization signal receptors and produced an affinity-purified antibody. The plant receptor was tightly associated with cellular components in permeabilized protoplasts, even in the presence of 0.1% Triton X-100, indicating that this factor and probably others were retained to an extent sufficient to support import. The lectin wheat germ agglutinin bound to the nucleus; however, it did not block translocation in our system, indicating that direct interaction with polysaccharide modifications at the nuclear pore complex was probably not essential for import in plants. Other features of in vitro import included reduced but significant import at low temperature.

Nucleotide-specific interaction of Ran/TC4 with nuclear transport factors NTF2 and p97

The use of permeabilized cell models to study nuclear protein import has led to the identification of cytosolic components of the import machinery, including the NLS receptor, p97, Ran/TC4, and nuclear transport factor 2 (NTF2). These proteins are required to reconstitute docking of transport ligand at the nuclear pore complex and subsequent translocation through the nuclear pore. However, a detailed molecular understanding of how these factors mediate protein import is lacking. Here we describe the results of solution and solid phase binding assays, which demonstrate that the small GTPase Ran/TC4 interacts directly with the cytosolic transport factors p97 and NTF2. By preloading recombinant Ran/TC4 with [gamma-32P]GTP or [3H]GDP, we show that the interactions with p97 and NTF2 are specific for the GTP- and GDP-bound forms, respectively. These data together with previous studies lead us to suggest that the interaction of the GTP-bound form of Ran/TC4 with p97 is linked to an early step in the nuclear protein import pathway and that the association of the GDP-bound form of Ran/TC4 with NTF2 helps define vectorial transport.

Identification of the nuclear localization signal of the POU domain protein Tst-1/Oct6

POU domain proteins are important regulators of development and terminal differentiation based upon their transcriptional activity in the nucleus. Here, we analyzed the mechanism underlying the nuclear localization of Tst-1/Oct6, a member of this family that regulates events during neurogenesis and myelination. Nuclear localization of Tst-1/Oct6 was dependent on the POU domain, as its deletion prevented access to the nucleus, whereas its transfer to the amino terminus of beta-galactosidase was sufficient to prompt nuclear accumulation of this normally cytosolic protein. Interestingly, nuclear localization and high affinity DNA binding were two independent functions of the POU domain and could be separated in several mutants. While specific high affinity binding to DNA required the presence of both the POU-specific and the POU homeodomain, the POU-specific domain was dispensable for nuclear localization of Tst-1/Oct6. Rather, the nuclear localization function was selectively contained within the POU homeodomain. Specifically, a basic cluster (GRKRKKRT) preceding helix 1 of the homeodomain was shown by deletion mutagenesis to be involved in the nuclear localization of Tst-1/Oct6. This sequence, which is highly conserved among POU domain proteins, was by itself capable of translocating beta-galactosidase to the nucleus defining it as the bona fide nuclear localization signal of Tst-1/Oct6 and presumably other POU domain factors.

Nuclear protein import: Ran-GTP dissociates the karyopherin alphabeta heterodimer by displacing alpha from an overlapping binding site on beta

The alpha subunit of the karyopherin heterodimer functions in recognition of the protein import substrate and the beta subunit serves to dock the trimeric complex to one of many sites on nuclear pore complex fibers. The small GTPase Ran and the Ran interactive protein, p10, function in the release of the docked complex. Repeated cycles of docking and release are thought to concentrate the transport substrate for subsequent diffusion into the nucleus. Ran-GTP dissociates the karyopherin heterodimer and forms a stoichiometric complex with Ran-GTP. Here we report the mapping of karyopherin beta's binding sites both for Ran-GTP and for karyopherin alpha. We discovered that karyopherin beta's binding site for Ran-GTP shows a striking sequence similarity to the cytoplasmic Ran-GTP binding protein, RanBP1. Moreover, we found that Ran-GTP and karyopherin alpha bind to overlapping sites on karyopherin beta. Having a higher affinity to the overlapping site, Ran-GTP displaces karyopherin alpha and binds to karyopherin beta. Competition for overlapping binding sites may be the mechanism by which GTP bound forms of other small GTPases function in corresponding dissociation-association reactions. We also mapped Ran's binding site for karyopherin beta to a cluster of basic residues analogous to those previously shown to constitute karyopherin alpha's binding site to karyopherin beta.

The binding site of karyopherin alpha for karyopherin beta overlaps with a nuclear localization sequence

By using proteolysis, recombinant mutant proteins, or synthetic peptides and by testing these reagents in liquid phase binding or nuclear import assays, we have mapped binding regions of karyopherin alpha. We found that the C-terminal region of karyopherin alpha recognizes the nuclear localization sequence (NLS), whereas its N-terminal region binds karyopherin beta. Surprisingly, karyopherin alpha also contains an NLS. Thus, karyopherin alpha belongs to a group of proteins that contain both a ligand (NLS) and a cognate receptor (NLS recognition site) in one molecule with a potential for autologous ligand-receptor interactions. The NLS of karyopherin alpha overlaps with the binding site of karyopherin alpha for karyopherin beta. Hence, binding of karyopherin beta to karyopherin alpha covers the NLS of karyopherin alpha. This prevents autologous ligand receptor interactions and explains the observed cooperative binding of karyopherin alpha to a heterologous NLS protein in the presence of karyopherin beta.

Protein import into the nucleus

The transport of proteins from the cytoplasm into the nucleus is a multistep process. The nuclear localization sequence (NLS) of a transport substrate associates with the heterodimeric NLS-receptor which binds to a subset of proteins of the nuclear pore complex (NPC). Translocation through the NPC is energy-dependent and requires the small GTPase Ran. Proteins that interact with Ran in either the GDP-bound or the GTP-bound state coordinate transfer through the NPC. Lastly, the NLS-receptor/ substrate complex and Ran reach the nuclear side of the NPC where the complex disassembles.

Nic96p is required for nuclear pore formation and functionally interacts with a novel nucleoporin, Nup188p

The amino-terminal domain of Nic96p physically interacts with the Nsp1p complex which is involved in nucleocytoplasmic transport. Here we show that thermosensitive mutations mapping in the central domain of Nic96p inhibit nuclear pore formation at the nonpermissive temperature. Furthermore, the carboxyterminal domain of Nic96p functionally interacts with a novel nucleoporin Nup188p in an allele-specific fashion, and when ProtA-Nup188p was affinity purified, a fraction of Nic96p was found in physical interaction. Although NUP188 is not essential for viability, a null mutant exhibits striking abnormalities in nuclear envelope and nuclear pore morphology. We propose that Nic96p is a multivalent protein of the nuclear pore complex linked to several nuclear pore proteins via its different domains.

A GTPase distinct from Ran is involved in nuclear protein import

Signal-dependent transport of proteins into the nucleus is a multi-step process mediated by nuclear pore complexes and cytosolic transport factors. One of the cytosolic factors, Ran, is the only GTPase that has a characterized role in the nuclear import pathway. We have used a mutant form of Ran with altered nucleotide binding specificity to investigate whether any other GTPases are involved in nuclear protein import. D125N Ran (XTP-Ran) binds specifically to xanthosine triphosphate (XTP) and has a greatly reduced affinity for GTP, so it is no longer sensitive to inhibition by nonhydrolyzable analogues of GTP such as guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S). using in vitro transport assays, we have found that nuclear import supported by XTP-Ran is nevertheless inhibited by the addition of non-hydrolyzable GTP analogues. This in conjunction with the properties of the inhibitory effect indicates that at least one additional GTPase is involved in the import process. Initial characterization suggests that the inhibited GTPase plays a direct role in protein import and could be a component of the nuclear pore complex.

Evidence using a green fluorescent protein-glucocorticoid receptor chimera that the Ran/TC4 GTPase mediates an essential function independent of nuclear protein import

The Ran/TC4 GTPase is required for the nuclear accumulation of artificial karyophiles in permeabilized cell assays. To investigate Ran function in a physiologically intact setting using mammalian cells, we examined the effects of several Ran mutants on cell growth and on the nuclear translocation of a glucocorticoid receptor-green fluorescent protein fusion (GR-GFP). Glucocorticoid receptor is cytosolic in the absence of ligand, but translocates to the nucleus on binding the agonist dexamethasone. After transfection into baby hamster kidney cells (BHK21), GR-GFP was detectable in living cells by direct fluorescence microscopy. Addition of dexamethasone caused a rapid translocation of the chimeric protein from the cytosol into the nucleus (t1/2 approximately 5 min). Cotransfection with epitope-tagged, wild-type Ran led to expression of HA1-Ran that was approximately 1.6-fold higher than the level of the endogenous protein, but it had no deleterious effect on nuclear import of the GR-GFP. However, expression of the Ran mutants G19V, T24N, or a COOH-terminal deletion (delta C) mutant dramatically reduced the accumulation of GR-GFP in the nuclei. An L43E mutant of Ran was without significant effect on nuclear GR-GFP import. Identical results were obtained following micro-injection of recombinant Ran mutants into cells expressing GR-GFP. Significantly, all of the Ran mutants, including L43E, strongly inhibited cell growth. These results demonstrate the use of GR-GFP in real-time imaging of nuclear transport. They also show that multiple types of Ran mutant exert dominant effects on this process, and that normal Ran function requires cycling between the GTP- and GDP-bound states of the protein. Most importantly, the results with the L43E Ran mutant provide strong evidence that Ran mediates a function essential to cell viability that is independent of nuclear protein import.

The thermolability of nuclear protein import in tsBN2 cells is suppressed by microinjected Ran-GTP or Ran-GDP, but not by RanQ69L or RanT24N

The nuclear protein regulator of chromosome condensation 1 (RCC1) stimulates guanine nucleotide exchange on a protein, Ran, that is required for nuclear protein import. In the present report, we confirm that RCC1 is also required for nuclear protein import in tsBN2 hamster cells in vivo. The thermolability of nuclear protein import in tsBN2 cells was suppressed by microinjection of purified Ran-GTP into the cytoplasm, but Ran-GDP also relieved the import deficiency, suggesting either that both forms of Ran are active in import in vivo or that tsBN2 cells at restrictive temperature retain a mechanism to convert Ran-GDP to Ran-GTP. To distinguish between these possibilities, nuclear protein import in tsBN2 cells was tested in the presence of Ran mutants, one deficient in GTP hydrolysis (RanQ69L), and one with weak binding to GDP and little or no binding to GTP (RanT24N). Microinjection of the mutant RanQ69L inhibited import in vivo in either the GTP- or GDP-bound form at both the permissive and nonpermissive temperatures. RanT24N-GDP inhibited import in vivo at the permissive temperature and failed to stimulate nuclear protein import at the nonpermissive temperature. The implications of these results for the roles of RCC1 and Ran in nuclear protein import in vivo are discussed.

Toward the molecular dissection of protein import into nuclei

Transport of proteins, RNAs and ribonucleoprotein particles into and out of the nucleus is essential for many cellular functions to proceed. Recent progress in this area of research has led to the identification of a number of signals and cytosolic factors that mediate the nuclear import of proteins through the nuclear pore complexes. However, as the sites on the nuclear pore complex at which these signals and factors exert their function are still largely unidentified, the molecular mechanisms underlying this nuclear import pathway remain to be elucidated.

In vitro and in vivo evidence that protein and U1 snRNP nuclear import in somatic cells differ in their requirement for GTP-hydrolysis, Ran/TC4 and RCC1

GTP-hydrolysis, the small ras-related GTP-binding protein Ran and its cognate guanosine nucleotide exchange factor, the RCC1 gene product, have recently been identified as essential components of the protein nuclear import pathway. In this report we use three independent approaches to investigate the role of these components in U1 snRNP nuclear import in somatic cells. (i) Using a somatic cell based in vitro nuclear import system we show that U1 snRNP nuclear import, in marked contrast to protein transport, is not significantly inhibited by non-hydrolyzable GTP-analogs and is therefore unlikely to require GTP-hydrolysis. (ii) Using the dominant negative Ran mutant RanQ69L, which is defective in GTP-hydrolysis, we show that Ran-mediated GTP-hydrolysis is not essential for the nuclear import of U1 snRNP in microinjected cultured cells. (iii) Using a cell line expressing a thermolabile RCC1 gene product, we show that the nuclear accumulation of microinjected U1 snRNP is not significantly affected by RCC1 depletion at the non-permissive temperature, indicating that RCC1 function is not essential for U-snRNP nuclear import. Based on these observations we conclude that protein and U-snRNP nuclear import in somatic cells differ in their requirements for GTP-hydrolysis, and Ran or RCC1 function. Based on these results, the substrates for nucleocytoplasmic exchange across the NPC can be divided into two classes, those absolutely requiring Ran, including protein import and mRNA export, and those for which Ran is not essential, including U-snRNP nuclear import, together with tRNA and U1 snRNA nuclear export.

RAN/TC4 mutants identify a common requirement for snRNP and protein import into the nucleus

Kinetic competition experiments have demonstrated that at least some factors required for the nuclear import of proteins and U snRNPs are distinct. Both import processes require energy, and in the case of protein import, the energy requirement is known to be at least partly met by GTP hydrolysis by the Ran GTPase. We have compared the effects of nonhydrolyzable GTP analogues and two mutant Ran proteins on the nuclear import of proteins and U snRNPs in vitro. The mutant Ran proteins have different defects; Q69L (glutamine 69 changed to leucine) is defective in GTP hydrolysis while T24N (threonine 24 changed to asparagine) is defective in binding GTP. Both protein and snRNP import are sensitive either to the presence of the two mutant Ran proteins, which act as dominant negative inhibitors of nuclear import, or to incubation with nonhydrolyzable GTP analogues. This demonstrates that there is a requirement for a GTPase activity for the import of U snRNPs, as well as proteins, into the nucleus. The dominant negative effects of the two mutant Ran proteins indicate that the pathways of protein and snRNP import share at lease one common component.

The yeast nucleoporin Nsp1 binds nuclear localization sequences in vitro

Facilitated transport of proteins into the nucleus requires nuclear localization sequences (NLSs) be present in the protein destined for the nucleus. The specific binding of NLSs by components of the nuclear transport apparatus is essential for these targeting reactions. We now report that the yeast nucleoporin Nsp1 binds specifically nuclear localization sequences in vitro. This nucleoporin recognizes several NLSs that are functional for nuclear targeting in vivo, including the NLS of SV40 T-antigen and of the yeast transcription factor Ga14. Nsp1 is organized into three domains, and we have located NLS binding sites to the N-terminal portion and the middle repetitive region of the protein. For the interaction between the NLS of SV40 T-antigen and Nsp1, we obtained association constants of 1.2 x 10(7) M-1 and 5 x 10(7) M-1. An association constant of 5 x 10(7) M-1 was determined for NLS binding to the repetitive domain of Nsp1. We analyzed binding of Nsp1 and its domains to a mutant version of the NLS derived from SV40 T-antigen, which poorly functions for nuclear targeting in vivo. The affinity for the mutant signal was about two orders of magnitude lower than for the wild-type NLS.

Nuclear targeting of SV40 and adenovirus

Import o f viral DNA into the nucleus is essential for the successful replication o f DNA tumour viruses. To achieve this goal, viruses have adapted strategies to traverse the barriers between the plasma membrane and the nucleus o f a host cell. Two DNA tumour viruses, simian virus 40 and adenovirus, achieve the nuclear-entry step in slightly different ways. SV40 DNA enters the nucleus through the nuclear pore complexes (NPCs) in apparently intact virions. By contrast, adenovirus particles dissociate near the NPC before the viral DNA is imported into the nucleus. In both cases, karyophilic protein components o f the viruses appear to mediate nuclear entry o f the viral genomes. In this article, we discuss how an understanding o f the cell biology o f virus entry can help us understand the process o f nuclear transport.

A 41 amino acid motif in importin-alpha confers binding to importin-beta and hence transit into the nucleus

The complex of importin-alpha and -beta is essential for nuclear protein import. It binds the import substrate in the cytosol, and the resulting trimeric complex moves through the nuclear pores, probably as a single entity. Importin-alpha provides the nuclear localization signal binding site, importin-beta the site of initial docking to the pore. Here we show that the conserved, basic N-terminus of importin-alpha is sufficient for importin-beta binding and essential for protein import. The fusion product of this 41 amino acid domain to a heterologous protein if transported into the nucleus in the same way as full-length importin-alpha itself. Transport is dependent on importin-beta but competed by importin-alpha. As no additional part of importin-alpha is needed for translocation, the movement which drives the import substrate complex into the nucleus appears to be generated between importin-beta and structures of the nuclear pore. The domain that binds to importin-beta appears to confer import only, but not re-export out of the nucleus, suggesting that the return of importin-alpha into the cytoplasm is not a simple reversal of its entry.

The conserved amino-terminal domain of hSRP1 alpha is essential for nuclear protein import

Nuclear proteins are targeted through the nuclear pore complex (NPC) in an energy-dependent reaction. The import reaction is mediated by nuclear localization sequences (NLS) in the substrate which are recognized by heterodimeric cytoplasmic receptors. hSRP1 alpha is an NLS-binding subunit of the human NLS receptor complex and is complexed in vivo with a second subunit of 97 kDa (p97). We show here that a short amino-terminal domain in hSRP1 alpha is necessary and sufficient for its interaction with p97. This domain is conserved in other SRP1-like proteins and its fusion to a cytoplasmic reporter protein is sufficient to promote complete nuclear import, circumventing the usual requirement for an NLS receptor interaction. The same amino-terminal domain inhibits import of NLS-containing proteins when added to an in vitro nuclear transport assay. While full-length hSRP alpha is able to leave the nucleus, the amino-terminal domain alone is not sufficient to promote exit. We conclude that hSRP1 alpha functions as an adaptor to tether NLS-containing substrates to the protein import machinery.

Role of the nuclear transport factor p10 in nuclear import

The nuclear import factor p10 was cloned from Saccharomyces cerevisiae and found to be essential. The protein p10 can bind directly to several peptide repeat-containing nucleoporins. It also binds to the guanosine triphosphatase (GTPase) Ran in its guanosine diphosphate (GDP)-bound form and to karyopherin beta. Assembly of the karyopherin heterodimer on immobilized nucleoporin yielded cooperative binding of p10 and Ran-GDP. Addition of GTP to this pentameric complex led to dissociation of karyopherin (chi, presumably via in situ formation of Ran-GTP from Ran-GDP. Thus, p10 appears to coordinate the Ran-dependent association and dissociation reactions underlying nuclear import.