Showing papers on "Importin published in 1993"

The GTP-binding protein Ran/TC4 is required for protein import into the nucleus.

Abstract: TWO cytosolic fractions (A and B) fromXenopus oocytes are sufficient to support protein import into the nuclei of digitonin-permeabilized cells1. Fraction A recognizes the nuclear localization sequence (NLS) and binds the import substrate to the nuclear envelope, whereas fraction B mediates the subsequent passage of the bound substrate into the nucleus. Here we report that two interacting components are required for full fraction-B activity, purify one of these components to homogeneity, and show that it is the highly abundant GTP-binding protein Ran (Ras-related nuclear protein)/TC4.

Inhibition of nuclear protein import by nonhydrolyzable analogues of GTP and identification of the small GTPase Ran/TC4 as an essential transport factor.

Abstract: We have investigated a possible involvement of GTPases in nuclear protein import using an in vitro transport system involving digitonin-permeabilized cells supplemented with exogenous cytosol. Transport in this system was measured with a novel ELISA-based assay that allows rapid quantitative analysis. GTP gamma S and other nonhydrolyzable analogues of GTP were found to rapidly inhibit the rate of in vitro nuclear import. Transport inhibition by GTP gamma S was dependent on the concentrations of permeabilized cells and cytosol, and was strongly enhanced by a cytosolic factor(s). The predominant cytosolic component responsible for this inhibition was found in a 20-30-kD fraction in molecular sieving chromatography. Furthermore, a component(s) of this 20-30-kD fraction was itself required for efficient nuclear import. Biochemical complementation with bacterially expressed protein demonstrated that this essential GTP gamma S-sensitive transport factor was Ran/TC4, a previously described GTPase of the Ras superfamily found in both nucleus and cytoplasm. Ran/TC4 and its guanine nucleotide release protein RCC1 have previously been implicated in DNA replication, cell cycle checkpoint control, and RNA synthesis, processing and export. Our results suggest that Ran/TC4 serves to integrate nuclear protein import with these other nuclear activities.

Nuclear localization signals (NLS).

Abstract: Available data strongly suggest that simple karyophilic clusters of arginines and lysines in nucleus-targeted proteins signal the anchoring of these proteins to specialized transporter molecules found on the pore complex or in the cytoplasm. These peptides have been termed nuclear localization signals (NLS). Other nuclear proteins contain "split" or "bipartite" NLS hypothesized to be reconstituted by protein folding or conformational change induced by glucocorticoids. The active NLS needs to be exposed to the protein surface, the cell has invented mechanisms to expose a hidden or cryptic NLS by protein phosphorylation, dephosphorylation, dissociation of an inhibitory subunit that masks the NLS, processing of a larger precursor, and binding of a hormone to regulate the nuclear import of a protein transcription factor at a certain stage of development, or cell cycle. It is proposed (1) that a hexapeptide with four arginines and lysines (and histidines, in some cases) is a good candidate for a "core NLS," (2) that acidic domains on proteins to be imported may participate in anchoring them to the transporter cytoplasmic or pore complex NLS-receptor, and (3) that NLS have both a cytoplasmic and a nuclear function. The interaction between nuclear proteins and transporter proteins in the pore appears to be largely electrostatic and to be disrupted by the binding of mRNA molecules to the same transporter protein, functioning also for the cytoplasmic export of RNA.

Ran/TC4: A Small Nuclear GTP-binding Protein That Regulates DNA Synthesis

Abstract: Ran/TC4, first identified as a well-conserved gene distantly related to H-RAS, encodes a protein which has recently been shown in yeast and mammalian systems to interact with RCC1, a protein whose function is required for the normal coupling of the completion of DNA synthesis and the initiation of mitosis. Here, we present data indicating that the nuclear localization of Ran/TC4 requires the presence of RCC1. Transient expression of a Ran/TC4 protein with mutations expected to perturb GTP hydrolysis disrupts host cell DNA synthesis. These results suggest that Ran/TC4 and RCC1 are components of a GTPase switch that monitors the progress of DNA synthesis and couples the completion of DNA synthesis to the onset of mitosis.

A bipartite nuclear localization signal in the retinoblastoma gene product and its importance for biological activity.

Abstract: The retinoblastoma gene product, p110RB1, appears to regulate cell growth by modulating the activities of nuclear transcription factors. The elements that specify the transport of p110RB1 into the nucleus have not yet been explored. We now report the identification of a basic region, KRSAEGGNPPKPLKKLR, in the C terminus of p110RB1, which has sequence similarity to known bipartite nuclear localization signals (NLSs). A two-amino-acid mutation introduced into this putative NLS [to give mutant NLS(NQ)] or deletion of the entire NLS (delta NLS) abrogated exclusive nuclear localization, yielding proteins which were distributed either equally throughout the cell or predominantly in the cytoplasm. A mutant protein [NLS(NQ)/delta 22] containing both the mutated NLS and a deletion of exon 22, previously shown to disrupt the interaction of p110RB1 with several cellular transcription factors and oncoproteins, accumulated only in the cytoplasm. When fused to the C terminus of Escherichia coli beta-galactosidase, the RB1 NLS directed this protein to the nucleus, indicating that the motif is not only necessary but also sufficient for nuclear transport. Neither NLS(NQ) nor delta NLS was hyperphosphorylated in vivo, but both retained their abilities to interact, in vitro, with simian virus 40 large T antigen, adenovirus E1a, and the cellular transcription factor E2F. When transfected at multiple copy number, the NLS mutant alleles displayed reduced biological activity, measured by inhibition of growth of the osteogenic sarcoma cell line Saos-2, which has no wild-type RB1. Naturally occurring mutations and deletions in exon 25 of RB1 which disrupt the NLS may lead to partial or complete inactivation of p110RB1 and may be responsible for some retinoblastoma and other tumors.

Analysis of conserved binding proteins for nuclear localization sequences.

Abstract: Correct targeting of nuclear proteins is mediated by nuclear localization sequences (NLS) which permit specific binding to the nucleus and subsequent translocation across the nuclear envelope via the nuclear pore complex. It is proposed that nuclear import is facilitated by NLS-receptors which reside in the cytoplasm and at the nuclear pore. These NLS-receptors could facilitate an early step of nuclear protein import, i.e. targeting and binding of nuclear proteins at the nuclear pore. We have generated anti-idiotype antibodies against the SV40 T-antigen nuclear localization sequence that allowed us to study NLS-binding proteins in a variety of different organisms. Proteins of similar size are recognized by these antibodies in yeast, Drosophila, rat and human cells. Cytological analysis indicates that the NLS-binding proteins reside in part at nuclear pores. One of the proteins recognized by anti-idiotype antibodies is identical to a previously identified NLS-binding protein. Using isolated yeast nuclei we demonstrate that the anti-idiotype antibodies compete for binding of nuclear proteins in vitro. We show that the yeast mutant npl3, which is defective in nuclear protein localization, has an altered distribution of antigens recognized by these anti-idiotype antibodies, at the semi-permissive temperature. Our results suggest that a set of proteins common to various eukaryotes recognizes nuclear localization sequences.