Signal-dependent translocation of simian virus 40 large-T antigen into rat liver nuclei in a cell-free system

Nuclear protein accumulation by facilitated transport and intranuclear binding

Nuclear proteins are transported from the cytoplasm into the nucleus via nuclear envelope pore complexes (NPCs). At the molecular level, the mechanisms responsible for this transport remain obscure. However, it is known that, for many proteins, the process requires ATP and proceeds against formidable nucleocytoplasmic concentration gradients. Therefore, the NPC is often thought of as an active transport site. In this article, Philip Paine presents the alternative hypothesis that, on current evidence, protein translocation across the nuclear envelope and accumulation in the nucleus can equally well be explained by facilitated transport through the NPC and subsequent intranuclear binding.

Nuclear transport of myelin basic protein

The multiple myelin basic protein (MBP) isoforms expressed by myelinating cells are now known to have different expression patterns. The relative abundance of the isoforms containing exon II is greater early in myelinogenesis, whereas in compact myelin the isoforms lacking this exon are more abundant. Further, the individual MBPs exhibit different intracellular localizations, indicating that the isoforms may not be functionally equivalent in myelinating cells. The major MBPs (14 kD and 18.5 kD) have strong affinity for membranes, while on the other hand, the less abundant isoforms (17 kD and 21.5 kD) localize to the nucleus of young oligodendrocytes, suggesting a regulatory role in the myelination program. The same intracellular distribution patterns have been observed when the MBPs are expressed in Hela cells and in shiverer oligodendrocytes. Thus, the intracellular fate of these proteins seems to be generally directed through alternative expression of exon II. Furthermore, the extent of MBPexII entry into the nucleus was found to be directly related to the growth state of host cells. In this paper, we demonstrate that nuclear proteins constitutively expressed by Hela cells also exhibit an apparently growth-related nucleo-cytoplasmic distribution revealing that MBPexII exhibits the same behavior as bona fide nuclear proteins. Also, to further characterize MBP nuclear transport, we explored various parameters of the translocation of MBP into the nucleus using an in vitro system. This experimental paradigm permits the uncoupling of synthesis and translocation events; thus, the transport of MBP into cell nuclei can be studied as a function of time. We also evaluated how changes in temperature as well as energy depletion affect the in vitro nuclear transport of MBP.

Subcellular distribution of the glucocorticoid receptor and evidence for its association with microtubules

The cellular distribution of the glucocorticoid receptor (GR) has not yet been firmly established. The extensive literature indicates that GR is present both in the cytoplasm and the cell nucleus, however, some studies have failed to detect cytoplasmic GR. It is still controversial as to whether GR is randomly diffusing in the cytoplasm and nucleus, or if the GR-distribution is organized or controlled in some way, which may be of importance for the transduction of glucocorticoid effects to cells. There is evidence that both non-activated and activated GR is associated with the plasma membrane, a number of cytoplasmic organelles and the nucleus. Both morphological and biochemical evidence show that GR is associated with microtubules during different stages of the cell cycle, i.e. GR co-localizes, co-purifies and co-polymerizes with tubulin. This indicates that GR is structurally linked to the intracellular MT-network which may be of importance in the mechanism of action of glucocorticoid hormones. The literature in this field is reviewed including the reported data on subcellular GR-localization.

Nucleolar accumulation of core protein in cells naturally infected with Semliki Forest virus. Quantitative aspects

The core (C) protein of Semliki Forest virus (SFV) is known to exert several important functions with regard to both the virus and the host. This paper shows that migration of parental and progeny C protein to the nucleolus is a common feature in infected vertebrate and invertebrate cells. The amount of C protein accumulating to the nucleolus is small, always less than 1% of the intra- and extracellular C protein at various times post infection. Migration to the nucleolus is a fast process; 1.5 h post infection a prominent amount of parental C protein is already incorporated into nucleolar fractions.

Glucocorticoid receptor binding to rat liver nuclei occurs without nuclear transport

The binding of cell-free activated glucocorticoid receptor-steroid complexes from HTC cells to various preparations of HTC and rat liver nuclei has been examined under conditions that did or did not support the nuclear translocation of macromolecules via nuclear pores. To the best of our knowledge, this is the first such study with functionally active isolated nuclei. Conventionally prepared HTC nuclei were found to be porous, as determined from their inability to exclude the fluorescent macromolecule phycoerythrin (PE) at 4 degrees C. Thus the nuclear binding of activated complexes to these nuclei can not involve nuclear translocation. Further studies, using established conditions with sealed nuclei prepared from rat liver, revealed that nuclear translocation of PE containing a covalently linked, authentic nuclear translocation sequence could be obtained at 22 degrees C, but not at 4 degrees C. However, under the same conditions, activated glucocorticoid complexes displayed equal levels of nuclear binding at both temperatures. We therefore conclude that the current translocation conditions with intact rat liver nuclei are not sufficient to reproduce the nuclear transport of glucocorticoid complexes observed in intact cells. The nuclear binding that was seen with intact rat liver nuclei was not affected by aurintricarboxylic acid, which selectively inhibits protein-nucleic acid interactions. The antibody AP-64, shown to be specific for amino acids 506-514 of the nuclear translocation sequence of the rat glucocorticoid receptor, inhibited the nuclear binding of activated complexes, apparently by blocking receptor access to the nuclear membrane. Collectively, these data argue that activated complex binding to nuclei capable of nuclear translocation involves only an association with nuclear membrane components such as nuclear pores. Thus this system, and these reagents, may be useful in future studies of activated complex binding to nuclear pores.

Specific binding of nuclear localization sequences to plant nuclei

We have begun to dissect the import apparatus of higher plants by examining the specific association of nuclear localization sequences (NLSs) with purified plant nuclei. Peptides to the simian virus 40 (SV40) large T antigen NLS and a bipartite NLS of maize were allowed to associate with tobacco and maize nuclei. Wild-type NLSs were found to compete for a single class of low-affinity binding sites having a dissociation constant (Kd) of approximately 200 microM. Peptides to mutant NLSs, which are inefficient in stimulating import, were poor competitors, as were reverse wild-type and non-NLS peptides. The NLS binding site was proteinaceous and resistant to extraction under conditions where pores were still associated. In addition, immunofluorescence and immunoelectron microscopy indicated that binding was at the nuclear envelope. Overall, plant nuclei may be an excellent system to identify components of the import apparatus.

Cytosolic proteins that specifically bind nuclear location signals are receptors for nuclear import

We have purified two major polypeptides of 54 and 56 kd from bovine erythrocytes that specifically bind the nuclear location sequence (NLS) of the SV40 large T antigen. When added to a permeabilized cell system for nuclear import, the purified proteins increase by 2- to 3-fold the nuclear accumulation of a fluorescent protein containing the large T antigen NLS. The import stimulation is saturable and dependent upon the presence of cytosol. Nuclear protein accumulation in vitro is sensitive to inactivation by N-ethylmaleimide (NEM). NEM inactivation can be overcome by addition of the purified NLS-binding proteins to the import system. NEM treatment of the purified proteins abolishes their ability to stimulate import but does not affect NLS binding. Our results indicate that the NLS-binding proteins are NEM-sensitive receptors for nuclear import. At least one other NEM-sensitive cytosolic activity and an NEM-insensitive cytosolic activity are also necessary for protein import in vitro.

Identification and characterization of nuclear location signal-binding proteins in nuclear envelopes

A radioiodinated, photoactivable synthetic nonapeptide corresponding to the nuclear location signal (NLS) of SV40 large T antigen has been used in photolabelling reactions with purified mouse liver nuclei, nuclear envelopes and other cellular fractions, to identify specific NLS-binding proteins which may be involved in selective transport of karyophilic proteins. SDS-polyacrylamide gel analysis of photolabelled products demonstrates that a 60 kDa nuclear protein and four nuclear envelope proteins (67, 60, 53 and 47 kDa) bind specifically to the native NLS and not to a mutant NLS or unrelated sequences. This binding shows saturation kinetics, with highest affinity of the NLS for the 60 and 67 kDa proteins. The nuclear 60 kDa NLS-binding protein is identical to the nuclear envelope 60 kDa NLS-binding protein by two-dimensional gel analysis of labelled proteins. Biochemical fractionation of labelled nuclear envelopes suggests that the 53 and 47 kDa proteins are peripheral membrane proteins whereas the 67 and 60 kDa proteins can be localized to the pore complex. The NLS also binds to solubilized 67, 60, 53 and 47 kDa proteins but with decreased affinity. Our results suggest that one of the early steps in selective nuclear transport of proteins may be the recognition of the NLS by the 60 kDa and/or 67 kDa binding proteins present in the nuclear pore complex.

Simian virus 40 Vp2/3 small structural proteins harbor their own nuclear transport signal

We have used a microinjection approach to identify a domain of the simian virus 40 (SV40) structural proteins Vp2 and Vp3(Vp2/3) responsible for their nuclear transport. By using both synthetic peptides, containing small regions of Vp2/3 conjugated to bovine serum albumin (BSA), and beta-galactosidase-Vp3 fusion proteins, we have narrowed this nuclear transport signal (NTS) to 9 amino acids (198 to 206 of Vp3 or 316 to 324 of Vp2), Gly-Pro-Asn-Lys-Lys-Lys-Arg-Lys-Leu. The porter proteins carrying the NTS or mutant NTS were microinjected into the cytoplasm of TC7 cells and their subcellular localization following the subsequent incubation period was determined immunologically using anti-BSA IgG or anti-beta-galactosidase. The 9-residue NTS peptide localized BSA into the nucleus of injected cells, changing lysine-202 to threonine or valine abolished this accumulation while changing arginine-204 to lysine did not grossly affect transport. A peptide containing the carboxyl-terminal 13 residues of Vp3 failed to localize BSA to the nucleus. Several single or double point mutations at Vp3 residues 202 and 204 have been introduced by site-directed mutagenesis. Vp3 residues 194-234, containing either a wild-type or mutated sequence at 202 and/or 204, were expressed in Escherichia coli as Vp3-beta-galactosidase fusion proteins. Addition of the carboxyl-terminal 40 residues, but not an internal 150 residues, to otherwise cytoplasmic beta-galactosidase promoted entry of the fusion protein into the nucleus. Changing lysine-202 into threonine, valine, or methionine abolished this nuclear accumulation as did changing arginine-204 into lysine. A double mutant at both positions was also blocked. We have also observed that the lectin wheat germ agglutinin inhibits the nuclear accumulation of BSA carrying the Vp2/3 NTS while the lectin concanavalin A had no effect. These data indicate that even small nuclear proteins can contain NTS's which most likely utilize a mechanism for nuclear import similar to that described for other larger proteins.

Yeast cell-free nuclear protein import requires ATP hydrolysis

Saccharomyces cerevisiae nuclear proteins are shown to localize specifically to isolated yeast nuclei under conditions selective for nuclear proteins. Nuclear association is time- and temperature-dependent, requires ATP hydrolysis, and is abolished by protease pretreatment of nuclei. The nucleus-localized protein is translocated across the nuclear envelope as determined by inaccessibility to externally added immobilized protease. This cell-free system, consisting of components from an organism amenable to genetic analysis, will facilitate the study of the poorly understood mechanism of nuclear protein localization. The finding that ATP hydrolysis is required for nuclear import is the most direct evidence that nuclear localization is energy-dependent.

Active transport of proteins into the nucleus

Nuclear proteins are actively and posttranslationally transported across the nuclear envelope. This transport is a highly selective process that can be divided into two steps, receptor-binding followed by translocation through the nuclear envelope. Receptor-binding is mediated by nuclear localization signals that have been identified in many nuclear proteins. Translocation is energy-dependent and occurs through the nuclear pore complex.

Structure and function of the nuclear pore complex: new perspectives

The double membrane of the nuclear envelope is a formidable barrier separating the nucleus and cytoplasm of eukaryotic cells. However, movement of specific macromolecules across the nuclear envelope is critical for embryonic development, cell growth and differentiation. Transfer of molecules between the nucleus and cytoplasm occurs through the aqueous channel formed by the nuclear pore complex (NPC). Although small molecules may simply diffuse across the NPC, transport of large proteins and RNA requires specific transport signals and is energy dependent. A family of pore glycoproteins modified by O-linked N-acetylglucosamine moieties are essential for transport through the NPC. Recent evidence suggests that the regulation of nuclear transport may also involve the interaction of RNA and nuclear proteins with specific binding proteins that recognize these transport signals. Are these nuclear pore glycoproteins and signal binding proteins the 'gatekeepers' that control access to the genetic material? Recent evidence obtained from a combination of biochemical and genetic approaches suggests--perhaps.

Major nucleolar proteins shuttle between nucleus and cytoplasm

Nucleolin is a 92 kd nucleolar protein implicated in regulating polymerase I transcription and binding of preribosomal RNA. Another abundant nucleolar protein of 38 kd (B23/No38) is thought to be involved in intranuclear packaging of preribosomal particles. Although both proteins have previously been detected only in nuclei, we conclude that they shuttle constantly between nucleus and cytoplasm. This conclusion is based on monitoring the equilibration of these proteins between nuclei present in interspecies heterokaryons, and on observing the antigen-mediated nuclear accumulation of cytoplasmically injected antibodies. Our unexpected results suggest a role for these major nucleolar proteins in the nucleocytoplasmic transport of ribosomal components. Moreover, they suggest that transient exposure of shuttling proteins to the cytoplasm may provide a mechanism for cytoplasmic regulation of nuclear activities.

Identification of specific binding proteins for a nuclear location sequence

The nuclear envelope is a selective barrier against the movement of macromolecules between the nucleus and cytoplasm. Nuclear proteins larger than relative molecular mass 20,000-40,000 are probably actively transported across the envelope through the nuclear pore complex and are directed by specific nuclear location sequences (NLS) in the proteins. NLS mediate the nuclear import of isolated nuclear proteins after microinjection into whole cells and the nuclear accumulation of chimaeric proteins or of non-nuclear proteins conjugated to synthetic peptides. The best-characterized NLS is the simian virus 40 large T-antigen sequence. We have identified two proteins of rat liver by chemical cross-linking that interact with a synthetic peptide containing this sequence: this interaction is specific for a functional NLS, is saturable, and high affinity. The binding proteins are present in a post-mitochondrial supernatant, in nuclei and in a nuclear envelope fraction, which is consistent with a role in the transport of nuclear proteins from the cytoplasm to the nucleus.

Intracellular receptor binding and nuclear transport of nerve growth factor in intact cells and a cell-free system

Nuclear uptake of 125I-labeled nerve growth factor (NGF) by cells that either express or do not express the cell surface receptor was tested using intact cells and a cell-free system. Intracellular and consequently nuclear uptake of NGF in intact cells was dependent on the presence of surface NGF receptor, whereas nuclear uptake in a cell-free system did not correlate with cell surface receptor expression. In the cell-free system, nuclear transport was inhibited when NGF receptor was being actively synthesized. Preincubation of intact cells with unlabeled NGF, cycloheximide, puromycin, or actinomycin D increased nuclear uptake up to threefold. The data suggest that, in intact cells, NGF transported into the cell via the surface receptors is also bound by the NGF receptor being synthesized in the cytoplasm. NGF taken up by the nucleus inhibited transcription of ribosomal RNA genes by 70% and, in turn, inhibited cell proliferation by 60%. A direct effect of NGF on transcription is discussed.

Nuclear protein transport

The nucleus, like all organelles, is composed of a unique set of proteins. This article discusses the possible mechanisms for localization of only certain proteins to the nucleus, transport of proteins across the nuclear envelope, and retention of proteins in the nuclear interior. In addition, nuclear protein transport is compared with transport of proteins into the endoplasmic reticulum and the mitochondria.

Information transfer in biological systems: targeting of proteins to specific organelles or to the extracellular environment (secretion)

Orderliness is the salient characteristic of living systems. Cells are intolerant of disorder. They express this by rapidly eliminating or degrading out-of-place molecules. When cells are broken apart and their constituent organelles separated and analysed, the same types of macromolecules are always associated with the same subcellular structures. One finds, for example, the same proteins in mitochondria time after time, and these differ from the sets of proteins found in nuclei, secretory granules, or plasma membranes. The information necessary to target each protein to its appropriate intracellular destination is determined primarily by the gene for that protein. Encoded within the DNA structure of genes are signals that specify where each protein molecule belongs. Thus, it is the transfer of information from one macromolecule to another that maintains the integrity and orderliness of living cells.