The nucleoporin Nup60p functions as a Gsp1p-GTP-sensitive tether for Nup2p at the nuclear pore complex

The nucleoporins Nup60p, Nup2p, and Nup1p form part of the nuclear basket structure of the Saccharomyces cerevisiae nuclear pore complex (NPC). Here, we show that these necleoporins can be isolated from yeast extracts by affinity chromatography on karyopherin Kap95p-coated beads. To characterize Nup60p further, Nup60p-coated beads were used to capture its interacting proteins from extracts. We find that Nup60p binds to Nup2p and serves as a docking site for Kap95p-Kap60p heterodimers and Kap123p. Nup60p also binds Gsp1p-GTP and its guanine nucleotide exchange factor Prp20p, and functions as a Gsp1p guanine nucleotide dissociation inhibitor by reducing the activity of Prp20p. Yeast lacking Nup60p exhibit minor defects in nuclear export of Kap60p, nuclear import of Kap95p-Kap60p-dependent cargoes, and diffusion of small proteins across the NPC. Yeast lacking Nup60p also fail to anchor Nup2p at the NPC, resulting in the mislocalization of Nup2p to the nucleoplasm and cytoplasm. Purified Nup60p and Nup2p bind each other directly, but the stability of the complex is compromised when Kap60p binds Nup2p. Gsp1p-GTP enhances by 10-fold the affinity between Nup60p and Nup2p, and restores binding of Nup2p-Kap60p complexes to Nup60p. The results suggest a dynamic interaction, controlled by the nucleoplasmic concentration of Gsp1p-GTP, between Nup60p and Nup2p at the NPC.

Proteomic analysis of nucleoporin interacting proteins

The Saccharomyces cerevisiae nuclear pore complex is a supramolecular assembly of 30 nucleoporins that cooperatively facilitate nucleocytoplasmic transport. Thirteen nucleoporins that contain FG peptide repeats (FG Nups) are proposed to function as stepping stones in karyopherin-mediated transport pathways. Here, protein interactions that occur at individual FG Nups were sampled using immobilized nucleoporins and yeast extracts. We find that many proteins bind to FG Nups in highly reproducible patterns. Among 135 proteins identified by mass spectrometry, most were karyopherins and nucleoporins. The PSFG nucleoporin Nup42p and the GLFG nucleoporins Nup49p, Nup57p, Nup100p, and Nup116p exhibited generic interactions with karyopherins; each bound 6--10 different karyopherin betas, including importins as well as exportins. Unexpectedly, the same Nups also captured the hexameric Nup84p complex and Nup2p. In contrast, the FXFG nucleoporins Nup1p, Nup2p, and Nup60p were more selective and captured mostly the Kap95p.Kap60p heterodimer. When the concentration of Gsp1p-GTP was elevated in the extracts to mimic the nucleoplasmic environment, the patterns of interacting proteins changed; exportins exhibited enhanced binding to FG Nups, and importins exhibited reduced binding. The results demonstrate a global role for Gsp1p-GTP on karyopherin-nucleoporin interactions and provide a rudimentary map of the routes that karyopherins take as they cross the nuclear pore complex.

Viral protein R regulates docking of the HIV-1 preintegration complex to the nuclear pore complex

Replication of human immunodeficiency virus type 1 (HIV-1) in non-dividing cells depends critically on import of the viral preintegration complex into the nucleus. Recent evidence suggests that viral protein R (Vpr) plays a key regulatory role in this process by binding to karyopherin alpha, a cellular receptor for nuclear localization signals, and increasing its affinity for the nuclear localization signals. An in vitro binding assay was used to investigate the role of Vpr in docking of the HIV-1 preintegration complex (PIC) to the nuclear pore complex. Mutant HIV-1 PICs that lack Vpr were impaired in the ability to dock to isolated nuclei and recombinant nucleoporins. Although Vpr by itself associated with nucleoporins, the docking of Vpr+ PICs was dependent on karyopherin beta and was blocked by antibodies to beta. Vpr stabilized docking by preventing nucleoporin-stimulated dissociation of the import complex. These results suggest a biochemical mechanism for Vpr function in transport of the HIV-1 genome across the nuclear pore complex.

Viral protein R regulates nuclear import of the HIV-1 pre-integration complex

Replication of human immunodeficiency virus type 1 (HIV-1) in non-dividing cells critically depends on import of the viral pre-integration complex into the nucleus. Genetic evidence suggests that viral protein R (Vpr) and matrix antigen (MA) are directly involved in the import process. An in vitro assay that reconstitutes nuclear import of HIV-1 pre-integration complexes in digitonin-permeabilized cells was used to demonstrate that Vpr is the key regulator of the viral nuclear import process. Mutant HIV-1 pre-integration complexes that lack Vpr failed to be imported in vitro, whereas mutants that lack a functional MA nuclear localization sequence (NLS) were only partially defective. Strikingly, the import defect of the Vpr- mutant was rescued when recombinant Vpr was re-added. In addition, import of Vpr- virus was rescued by adding the cytosol of HeLa cells, where HIV-1 replication had been shown to be Vpr-independent. In a solution binding assay, Vpr associated with karyopherin alpha, a cellular receptor for NLSs. This association increased the affinity of karyopherin alpha for basic-type NLSs, including that of MA, thus explaining the positive effect of Vpr on nuclear import of the HIV-1 pre-integration complex and BSA-NLS conjugates. These results identify the biochemical mechanism of Vpr function in transport of the viral pre-integration complex to, and across, the nuclear membrane.

Disassembly of RanGTP-karyopherin beta complex, an intermediate in nuclear protein import

We previously showed that RanGTP forms a 1:1 complex with karyopherin beta that renders RanGTP inaccessible to RanGAP (Floer, M., and Blobel, G. (1996) J. Biol. Chem. 271, 5313-5316) and karyopherin beta functionally inactive (Rexach, M., and Blobel, G. (1995) Cell 83, 683-692). Recycling of both factors for another round of function requires dissociation of the RanGTP-karyopherin beta complex. Here we show using BIAcoreTM, a solution binding assay, and GTP hydrolysis and exchange assays, with yeast proteins, that karyopherin beta and RanGTP are recycled efficiently in a reaction that involves karyopherin alpha, RanBP1, RanGAP, and the C terminus of the nucleoporin Nup1. We find that karyopherin alpha first releases RanGTP from karyopherin beta in a reaction that does not require GTP hydrolysis. The released RanGTP is then sequestered by RanBP1, and the newly formed karyopherin alphabeta binds to the C terminus of Nup1. Finally, RanGTP is converted to RanGDP via nucleotide hydrolysis when RanGAP is present. Conversion of RanGTP to RanGDP can also occur via nucleotide exchange in the presence of RanGEF, an excess of GDP, and if RanBP1 is absent. Additional nucleoporin domains that bind karyopherin alphabeta stimulate recycling of karyopherin beta and Ran in a manner similar to the C terminus of Nup1.

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.

Protein import into nuclei: association and dissociation reactions involving transport substrate, transport factors, and nucleoporins

The molecular dynamics of nuclear protein import were examined in a solution binding assay by testing for interactions between a protein containing a nuclear localization signal (NLS), the transport factors karyopherin alpha, karyopherin beta, and Ran, and FXFG or GLFG repeat regions of nucleoporins. We found that karyopherins alpha and beta cooperate to bind FXFG but not GLFG repeat regions. Binding of the NLS protein to karyopherin alpha was enhanced by karyopherin beta. Two novel reactions were discovered. First, incubation of a karyopherin heterodimer-NLS protein complex with an FXFG repeat region stimulated the dissociation of the NLS protein from the karyopherin heterodimer. Second, incubation of the karyopherin heterodimer with RanGTP (or with a Ran mutant that cannot hydrolyze GTP) led to the dissociation of karyopherin alpha from beta and to an association of Ran with karyopherin beta; RanGDP had no effect. We propose that movement of NLS proteins across the nuclear pore complex is a stochastic process that operates via repeated association-dissociation reactions.

Identification of a yeast karyopherin heterodimer that targets import substrate to mammalian nuclear pore complexes

Targeting of import substrate to nuclear pore complexes of permeabilized vertebrate cells was previously shown to require a protein complex composed of two subunits, termed karyopherin. Yeast contain a homologue of karyopherin alpha named Srp1p, which was initially identified as a genetic suppressor of mutations in a subunit of RNA polymerase I. To determine whether yeast contain a karyopherin complex that includes Srp1p as the karyopherin alpha homologue, we genetically replaced Srp1p with a Srp1-Protein A chimera. Cytosol from this strain contained a complex, composed of the chimera and a protein of 95 kDa, that was purified using affinity chromatography on IgG Sepharose. Microsequence analysis showed that the 95-kDa protein was identical with a yeast protein encoded by gene L8300.15 on chromosome XII. Sequence comparison revealed that the L8300.15 gene product is the closest structural homologue of vertebrate karyopherin beta. The yeast alpha and beta karyopherin subunits were expressed in Escherichia coli and were purified. When combined, they formed a heterodimeric complex and were active in targeting import substrate to nuclear envelopes of mammalian cells. We propose that all karyopherins function as alpha/beta heterodimers.

Reconstitution of SEC gene product-dependent intercompartmental protein transport

Transport of alpha-factor precursor from the endoplasmic reticulum to the Golgi apparatus has been reconstituted in gently lysed yeast spheroplasts. Transport is measured through the coupled addition of outer-chain carbohydrate to [35S]methionine-labeled alpha-factor precursor translocated into the endoplasmic reticulum of broken spheroplasts. The reaction is absolutely dependent on ATP, stimulated 6-fold by cytosol, and occurs between physically separable sealed compartments. Transport is inhibited by the guanine nucleotide analog GTP gamma S. sec23 mutant cells have a temperature-sensitive defect in endoplasmic reticulum-to-Golgi transport in vivo. This defect has been reproduced in vitro using sec23 membranes and cytosol. Transport at 30 degrees C with sec23 membranes requires addition of cytosol containing the SEC23 (wild-type) gene product. This demonstrates that an in vitro inter-organelle transport reaction depends on a factor required for transport in vivo. Complementation of sec mutations in vitro provides a functional assay for the purification of individual intercompartmental transport factors.