Cationic lipid-mediated gene transfer: Analysis of cellular uptake and nuclear import of plasmid DNA

Cationic lipids are widely used for gene transfer in vitro and show promise as vectors for in vivo gene therapy applications. However, there is limited understanding of the cellular mechanisms involved in nonviral gene transfer. We investigated two major steps that could be limiting barriers to cationic lipid-mediated gene transfer in vitro. We used a fluorescent plasmid to study the cellular uptake and the intracellular fate of lipoplexes during in vitro transfection of fibroblast cells and found that 100% of the cells take up lipoplexes. The intracellular staining observed with lipoplexes was clearly different from that obtained with endocytosed fluorescent dextran. This suggests that cells readily take up lipoplexes by a mechanism that could be different from endocytosis in our conditions. However, the escape of DNA from intracellular vesicles could be a major limiting barrier to gene transfer. Direct injection of plasmid DNA into the nucleus and cytoplasm of cells indicated that DNA traffic from the cytoplasm to the nucleus might be also an important limiting step.     

Influence of cargo size on Ran and energy requirements for nuclear protein import

Previous work has shown that the transport of some small protein cargoes through the nuclear pore complex (NPC) can occur in vitro in the absence of nucleoside triphosphate hydrolysis. We now demonstrate that in the importin alpha/beta and transportin import pathways, efficient in vitro transport of large proteins, in contrast to smaller proteins, requires hydrolyzable GTP and the small GTPase Ran. Morphological and biochemical analysis indicates that the presence of Ran and GTP allows large cargo to efficiently cross central regions of the NPC. We further demonstrate that this function of RanGTP at least partly involves its direct binding to importin beta and transportin. We suggest that RanGTP functions in these pathways to promote the transport of large cargo by enhancing the ability of import complexes to traverse diffusionally restricted areas of the NPC.     

Intracellular fate and nuclear targeting of plasmid DNA

One of the major steps limiting nonviral gene transfer efficiency is the entry of plasmid DNA from the cytoplasm into the nucleus of the transfected cells. The nuclear localization signal (NLS) of the SV40 large T antigen is known to efficiently induce nuclear targeting of proteins. We have developed two chemical strategies for covalent coupling of NLS peptides to plasmid DNA. One method involves a site-specific labeling of plasmid DNA by formation of a triple helix with an oligonucleotide–NLS peptide conjugate. After such modification with one NLS peptide per plasmid molecule, plasmid DNA remained fully active in cationic lipid-mediated transfection. In the other method, we randomly coupled 5–115 p-azidotetrafluorobenzyllissamine–NLS peptide molecules per plasmid DNA by photoactivation. Oligonucleotide–NLS and plasmid–lissamine–NLS conjugates interacted specifically with the NLS-receptor importin . Plasmid–lissamine–NLS conjugates were not detected in the nucleus, after cytoplasmic microinjection. Plasmids did not diffuse from the site of injection and plasmid–lissamine–NLS conjugates appeared to be progressively degraded in the cytoplasm. The process of plasmid DNA sequestration/degradation stressed in this study might be as important in limiting the efficiency of nonviral gene transfer as the generally recognized entry step of plasmid DNA from the cytoplasm into the nucleus     

Karyopherins and nuclear import

Proteins of the karyopherin alpha and karyopherin beta families play a central role in nucleocytoplasmic transport. Recently, crystal structures of karyopherin alpha and its complexes with nuclear localization signal peptides, a karyopherin beta2-Ran complex and complexes of full-length and fragments of karyopherin beta1 with import substrates, Ran and nucleoporins have been solved. These karyopherin structures provide valuable insights into understanding the molecular mechanism of nuclear import, especially substrate recognition, substrate release by GTPase and interactions with the nuclear pore complex.     

A role for transportin in the nuclear import of adenovirus core proteins and DNA

Adenoviruses target their double-stranded DNA genome and its associated core proteins to the interphase nucleus; this core structure then enters through the nuclear pore complex. We have used digitonin permeabilized cell import assays to study the cellular import factors involved in nuclear entry of virus DNA and the core proteins, protein V and protein VII. We show that inhibition of transportin results in aberrant localization of protein V and that transportin is necessary for protein V to accumulate in the nucleolus. Furthermore, inhibition of transportin results in inhibition of protein VII and DNA import, whereas disruption of the classical importin alpha-importin beta import pathway has little effect. We show that mature protein VII has different import preferences from the precursor protein, preVII from which it is derived by proteolytic processing. While bacterially expressed glutathione S-transferase (GST)-preVII primarily utilizes the pathway mediated by importin alpha-importin beta, bacterially expressed GST-VII favours the transportin pathway. This is significant because while preVII is important during viral replication and assembly only mature VII is available during viral DNA import to a newly infected cell. Our results implicate transportin as a key import receptor for the nuclear localization of adenovirus core.     

A microtubule-facilitated nuclear import pathway for cancer regulatory proteins

Nuclear protein import is dependent on specific targeting signals within cargo proteins recognized by importins (IMPs) that mediate translocation through the nuclear pore. Recent evidence, however, implicates a role for the microtubule (MT) network in facilitating nuclear import of the cancer regulatory proteins parathyroid hormone-related protein (PTHrP) and p53 tumor suppressor. Here we assess the extent to which MT and actin integrity may be generally required for nuclear protein import for the first time. We examine 10 nuclear-localizing proteins with diverse IMP-dependent nuclear import pathways, our results indicating that the cytoskeleton does not have a general mechanistic role in nuclear localization sequence-dependent nuclear protein import. Of the proteins examined, only the p110(Rb) tumor suppressor protein Rb, together with p53 and PTHrP, was found to require MT integrity for optimal nuclear import. Fluorescence recovery after photobleaching experiments indicated that the MT-dependent nuclear transport pathway increases both the rate and extent of Rb nuclear import but does not affect Rb nuclear export. Dynamitin overexpression experiments implicate the MT motor dynein in the import process. The results indicate that, additional to IMP/diffusion-dependent processes, certain cancer regulatory proteins utilize an MT-enhanced pathway for accelerated nuclear import that is presumably required for their nuclear functions.     

A new role for nuclear transport factor 2 and Ran: nuclear import of CapG

The small GTPase Ran plays a central role in nucleocytoplasmic transport. Nuclear transport of Ran itself depends on nuclear transport factor 2 (NTF2). Here, we report that NTF2 and Ran control nuclear import of the filamentous actin capping protein CapG. In digitonin-permeabilized cells, neither GTPγS nor the GTP hydrolysis-deficient Ran mutant RanQ69L affect transit of CapG to the nucleus in the presence of cytosol. Obstruction of nucleoporins prevents nuclear transport of CapG, and we show that CapG binds to nucleoporin62. In addition, CapG interacts with NTF2, associates with Ran and is furthermore able to bind the NTF2–Ran complex. NTF2–Ran interaction is required for CapG nuclear import. This is corroborated by a NTF2 mutant with reduced affinity for Ran and a Ran mutant that does not bind NTF2, both of which prevent CapG import. Thus, a ubiquitously expressed protein shuttles to the nucleus through direct association with NTF2 and Ran. The role of NTF2 may therefore not be solely confined to sustaining the Ran gradient in cells.     

Sugar-dependent nuclear import of glycosylated proteins in living cells

The nuclear import of proteins larger than Mr 40,000 depends on the presence of a nuclear localization signal (NLS) corresponding either to a short peptide sequence or to defined sugars. The sugar-dependent nuclear import was previously evidenced by using glycosylated proteins (neoglycoproteins) introduced into the cytosol of cells either by electroporation or on digitonin-permeabilization and was shown to be distinct from the peptide NLS-mediated pathway. In this work, we used a microinjection approach to compare the two nuclear import pathways in intact living cells. The intracellular localization of fluorescent NLS-BSA or Glc-BSA injected into the cytosol was analyzed by confocal microscopy. Novel differences between the two mechanisms were evidenced. First, Glc-BSA migrated less efficiently into the nucleus than NLS-BSA because of a cytosolic retention. Second, the import of neoglycoproteins was not affected by microinjection of antinuclear import factor importin/karyopherin beta antibodies, whereas the NLS-dependent transport was completely abolished. Third, the nuclear import activity of Glc-BSA was found to be cell cycle-dependent in thymidine and hydroxyurea-treated HeLa cells, with greatest efficiency during G1/S transition and S phases, whereas NLS-BSA was imported with the same efficiency during any stage of the cell cycle but the G2 phase. Fourth, we show that after mitosis, nonglycosylated BSA was excluded from the nucleus contrary to Glc-BSA. In both cases, the nuclear import signals (NLS or alpha-glucoside) were grafted onto BSA; such tools led to a clear-cut conclusion, which will reach a full physiological significance when they are confirmed in the case of endogenous (glyco)proteins.     

Multiple nuclear localization sequences allow modulation of 5-lipoxygenase nuclear import

The nuclear import of proteins typically requires the presence of a nuclear localization sequence (NLS). Some proteins have more than one NLS, but the significance of having multiple NLSs is unclear. The enzyme 5-lipoxygenase (5-LO) has three NLSs that, unlike the tight cluster of basic residues of the classical SV40 large T antigen NLS, contain dispersed basic residues. When attached to green fluorescent protein (GFP), individual 5-LO NLSs caused quantitatively and statistically less import than the SV40 NLS. Combined 5-LO NLSs produced nuclear import that was comparable to that of the SV40 NLS. As expected, GFP/NLS proteins displayed relatively uniform import in all cells. However, a fusion protein of GFP plus the 5-LO protein, modified to contain only one functional NLS, produced some cells with import and some cells without import. A GFP/5-LO fusion protein containing two functional NLSs produced four identifiable levels of nuclear import. Quantitative and visual analysis of a population of cells expressing the intact GFP/5-LO protein, with three intact NLSs, indicated five levels of nuclear import. This suggested that the subcellular distribution of 5-LO may vary widely in normal cells of the body. Consistent with this, immunohistochemical staining of lung sections found that individual macrophages, in situ, displayed cell-specific levels of import of 5-LO. Since nuclear accumulation is known to affect 5-LO activity, multiple NLSs may allow graded regulation of activity via controlled import. Multiple NLSs on other proteins may likewise allow fine control of protein action through modulation of the level of import.     

Cytosolic import factor- and Ran-independent nuclear transport of ribosomal protein L5

Ribosomal protein L5 is a shuttling protein that, in Xenopus oocytes, is involved in the nucleocytoplasmic transport of 5S rRNA. As demonstrated earlier, L5 contains three independent nuclear import signals (NLSs), which function in oocytes as well as in somatic cells. Upon physical separation, these NLSs differ in respect to their capacity to bind to nuclear import factors in vitro and to mediate the nuclear import of a heterologous RNP in vivo. As reported in this communication, analysis of the in vitro nuclear import activity of these three NLSs reveals that they also differ in respect to their requirements for cytosolic import factors and Ran. Nuclear import mediated by the N-terminal and the central NLS depends on cytosolic import factor(s) and Ran, whereas import via the C-terminal NLS occurs independently from these factors. Thus, the presence of multiple NLSs in ribosomal protein L5 appears to allow for efficient nuclear transport via utilisation of multiple, mechanistically different import pathways.     

An unconventional NLS is critical for the nuclear import of the influenza A virus nucleoprotein and ribonucleoprotein

Replication of the RNAs of influenza virus occurs in the nucleus of infected cells. The nucleoprotein (NP) has been shown to be important for the import of the viral RNA into the nucleus and has been proposed to contain at least three different nuclear localization signals (NLSs). Here, an import assay in digitonin-permeabilized cells was used to further define the contribution of these NLSs. Mutation of the unconventional NLS impaired the nuclear import of the NP. A peptide bearing the unconventional NLS could inhibit the nuclear import of the NP in this import assay and prevent the NP-karyopherin alpha interaction in a binding assay confirming the crucial role of this signal. Interestingly, a peptide containing the SV40 T antigen NLS was unable to inhibit the nuclear import of NP or the NP-karyopherin alpha interaction, suggesting that the NP and the SV40 T antigen do not share a common binding site on karyopherin alpha. We also investigated the question of which NLS(s) is/are necessary for the viral ribonucleoprotein complex to enter the nucleus. We found that the peptide containing the unconventional NLS efficiently inhibited the nuclear import of the ribonucleoprotein complexes. This finding suggests that the unconventional NLS is the major signal necessary not only for the nuclear transport of free NP but also for the import of the ribonucleoprotein complexes. Finally, viral replication could be specifically inhibited by a membrane-permeable peptide containing the unconventional NLS, confirming the crucial role of this signal during the replicative cycle of the virus.     

Active nuclear import of single-stranded oligonucleotides and their complexes with non-karyophilic macromolecules

The objective of this investigation was to characterize intranuclear accumulation of oligonucleotides and their adducts with non-karyophilic compounds in cultured animal cells and thus to present a model system for nucleic acid-mediated nuclear import. In digitonin-permeabilized cells, nuclear uptake of 3′-FITC-labeled, single-stranded 25-mer oligodeoxyribonucleotides was independent of added cytosolic protein, largely energy-dependent, inhibitable by wheat germ agglutinin but not by N-ethylmaleimide, and a function of their base composition. When coupled to FITC-labeled streptavidin or streptavidin-bovine serum albumin conjugates, the oligonucleotides delivered the proteins to the nuclear interior with rates roughly proportional to their karyophilicity as free molecules. Transport activity was also demonstrated for single-stranded oligoribonucleotides. The transport was energy-dependent, inhibited by GMP-PNP and wheat germ agglutinin, but unaffected by N-ethylmaleimide. Nuclear import of oligo(dG)₂₅/protein adducts needed 3 to 4 oligonucleotide signals per complex and the signal had to be at least 15 nucleotides long. Micro-injection experiments showed that the results obtained with digitonin-permeabilized cells are not artifacts of a quasi-intact cellular system. These data were confirmed by electron microscopy employing complexes of oligodeoxyribonucleotides with streptavidin-peroxidase-bovine serum albumin-1 nm gold. In permeabilized cells, the complexes docked to the cytoplasmic face of the nuclear pore complexes, were translocated through the central pore channel and accumulated in large quantities in the nuclear baskets before they were released into the nucleoplasm. These results demonstrate that nuclear uptake of oligonucleotides and their complexes is an active process mediated by nuclear pore complexes, which, at least regarding its cytoplasmic component, is different from the pathway requiring classical nuclear localization signals.     

Evidence for the nuclear import of histones H3.1 and H4 as monomers

Newly synthesised histones are thought to dimerise in the cytosol and undergo nuclear import in complex with histone chaperones. Here, we provide evidence that human H3.1 and H4 are imported into the nucleus as monomers. Using a tether‐and‐release system to study the import dynamics of newly synthesised histones, we find that cytosolic H3.1 and H4 can be maintained as stable monomeric units. Cytosolically tethered histones are bound to importin‐alpha proteins (predominantly IPO4), but not to histone‐specific chaperones NASP, ASF1a, RbAp46 (RBBP7) or HAT1, which reside in the nucleus in interphase cells. Release of monomeric histones from their cytosolic tether results in rapid nuclear translocation, IPO4 dissociation and incorporation into chromatin at sites of replication. Quantitative analysis of histones bound to individual chaperones reveals an excess of H3 specifically associated with sNASP, suggesting that NASP maintains a soluble, monomeric pool of H3 within the nucleus and may act as a nuclear receptor for newly imported histone. In summary, we propose that histones H3 and H4 are rapidly imported as monomeric units, forming heterodimers in the nucleus rather than the cytosol.     

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°C and is Ca²⁺-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. © 1996 Wiley-Liss, Inc.