Inhibition Of Nuclear Import Research Articles

Abstract B09: KPNB1-mediated nuclear import is required for inflammatory cytokine expression, invasion and survival of cancer cells

Abstract Karyopherin β1 (KPNB1) is a nuclear transport protein involved in the transport of transcription factors and other proteins containing a nuclear localization sequence (NLS) into the nucleus. Elevated KPNB1 expression has been reported in cancer and transformed cells and is suggested to sustain the increased metabolic and proliferative demands. Transcription factors such as NFκB and AP-1 contain a NLS which is required by KPNB1 for nuclear import. These transcription factors initiate the expression of multiple cytokines and factors associated with inflammation and cancer cell biology. An inflammatory microenvironment, a hallmark of cancer, contributes to factors such as sustained proliferation, invasion and neoangiogenesis. Our study aimed to investigate the effect of inhibiting nuclear import via KPNB1 on cell biology and inflammatory signaling associated with cancer using siRNA and the novel small molecule, Inhibitor of Nuclear Import- 43 (INI-43). Inhibition of KPNB1 lead to reduced migration and invasion of cervical cancer cells while extended inhibition caused decreased proliferation and apoptosis. KPNB1 is essential for the translocation of NFκB into the nucleus as inhibition of nuclear import resulted in its cytoplasmic retention and decreased transcriptional activity of both transcription factors; NFκB and AP-1. DNA-binding studies confirmed a reduced binding-ability or presence of NFκB in the nuclear extract of KPNB1-inhibited cells. Consequently reduced IL-6, IL-1β, TNF-α; and GM-CSF expression, target genes of NFκB and AP-1, was observed. INI-43 significantly inhibited tumor growth in an ectopic xenograft mouse model and histological analysis found the tumor tissue to be less invasive. Immunohistochemical analysis of mice tumors showed reduced overall expression of KPNB1 as well as a shift in cellular localization to be more cytoplasmic following INI-43 treatment. Our study provides evidence that inhibiting KPNB1 has anti-inflammatory and anti-cancer effects and shows promise as a chemotherapeutic target. Citation Format: Tamara Stelma, Alicia Chi, Anwar Mall, Dhiren Govender, Virna D. Leaner. KPNB1-mediated nuclear import is required for inflammatory cytokine expression, invasion and survival of cancer cells [abstract]. In: Proceedings of the AACR International Conference: New Frontiers in Cancer Research; 2017 Jan 18-22; Cape Town, South Africa. Philadelphia (PA): AACR; Cancer Res 2017;77(22 Suppl):Abstract nr B09.

Nuclear transport of cancer extracellular vesicle-derived biomaterials through nuclear envelope invagination-associated late endosomes.

Extracellular membrane vesicles (EVs) function as vehicles of intercellular communication, but how the biomaterials they carry reach the target site in recipient cells is an open question. We report that subdomains of Rab7+ late endosomes and nuclear envelope invaginations come together to create a sub-nuclear compartment, where biomaterials associated with CD9+ EVs are delivered. EV-derived biomaterials were also found in the nuclei of host cells. The inhibition of nuclear import and export pathways abrogated the nuclear localization of EV-derived biomaterials or led to their accumulation therein, respectively, suggesting that their translocation is dependent on nuclear pores. Nuclear envelope invagination-associated late endosomes were observed in ex vivo biopsies in both breast carcinoma and associated stromal cells. The transcriptome of stromal cells exposed to cancer cell-derived CD9+ EVs revealed that the regulation of eleven genes, notably those involved in inflammation, relies on the nuclear translocation of EV-derived biomaterials. Our findings uncover a new cellular pathway used by EVs to reach nuclear compartment.

Nuclear import of aristaless-related homeobox protein via its NLS1 regulates its transcriptional function

Nucleocytoplasmic transport of transcription factors is essential in eukaryotes. We previously reported the presence of two functional NLSs in the homeodomain protein, aristaless-related homeobox (Arx) protein, which is a key transcriptional repressor of LMO1, SHOX2, and PAX4 during development. NLS2, that overlaps the homeodomain, is recognized directly by multiple importin βs, but not by importin αs. In this study, we found that the N-terminal NLS1 of Arx is targeted by multiple importin α proteins, including importin α3 and α5. Both in vivo and in vitro assays demonstrated that nuclear import of Arx via NLS1 is mediated by the importin α/β pathway. Mutagenesis analysis indicated that two basic amino acids, (84)K and (87)R, are essential to the function of NLS1, and that their mutation prevents interactions of Arx with importin αs. Interestingly, inhibition of nuclear import of Arx via NLS1 clearly attenuates its ability of transcriptional repression, suggesting that nuclear import of Arx via NLS1 contributes to its transcriptional function.

Mechanism of Microtubule-facilitated “Fast Track” Nuclear Import

Although the microtubule (MT) cytoskeleton has been shown to facilitate nuclear import of specific cancer-regulatory proteins including p53, retinoblastoma protein, and parathyroid hormone-related protein (PTHrP), the MT association sequences (MTASs) responsible and the nature of the interplay between MT-dependent and conventional importin (IMP)-dependent nuclear translocation are unknown. Here we used site-directed mutagenesis, live cell imaging, and direct IMP and MT binding assays to map the MTAS of PTHrP for the first time, finding that it is within a short modular region (residues 82-108) that overlaps with the IMPβ1-recognized nuclear localization signal (residues 66-108) of PTHrP. Importantly, fluorescence recovery after photobleaching experiments indicated that disruption of the MT network or mutation of the MTAS of PTHrP decreases the rate of nuclear import by 2-fold. Moreover, MTAS functions depend on mutual exclusivity of binding of PTHrP to MTs and IMPβ1 such that, following MT-dependent trafficking toward the nucleus, perinuclear PTHrP can be displaced from MTs by IMPβ1 prior to import into the nucleus. This is the first molecular definition of an MTAS that facilitates protein nuclear import as well as the first delineation of the mechanism whereby cargo is transferred directly from the cytoskeleton to the cellular nuclear import apparatus. The results have broad significance with respect to fundamental processes regulating cell physiology/transformation.

Insulin Increases Nuclear Protein Kinase Cδ in L6 Skeletal Muscle Cells

Protein kinase C (PKC) isoforms are involved in the transduction of a number of signals important for the regulation of cell growth, differentiation, apoptosis, and other cellular functions. PKC proteins reside in the cytoplasm in an inactive state translocate to various membranes to become fully activated in the presence of specific cofactors. Recent evidence indicates that PKC isoforms have an important role in the nucleus. We recently showed that insulin rapidly increases PKCdelta RNA and protein. In this study we initially found that insulin induces an increase in PKCdelta protein in the nuclear fraction. We therefore attempted to elucidate the mechanism of the insulin-induced increase in nuclear PKCdelta. Studies were performed on L6 skeletal myoblasts and myotubes. The increase in nuclear PKCdelta appeared to be unique to insulin because it was not induced by other growth factors or rosiglitazone. Inhibition of transcription or translation blocked the insulin-induced increase in nuclear PKCdelta, whereas inhibition of protein import did not. Inhibition of protein export from the nucleus reduced the insulin-induced increase in PKCdelta in the cytoplasm and increased it in the nucleus. The increase in nuclear PKCdelta induced by insulin was reduced but not abrogated by treatment of isolated nuclei by trypsin digestion. Finally, we showed that insulin induced incorporation of (35)S-methionine into nuclear PKCdelta protein; this effect was not blocked by inhibition of nuclear import. Thus, these results suggest that insulin may induce nuclear-associated, or possibly nuclear, translation of PKCdelta protein.

Differential Targeting of Nuclear Pore Complex Proteins in Poliovirus-Infected Cells

Poliovirus disrupts nucleocytoplasmic trafficking and results in the cleavage of two nuclear pore complex (NPC) proteins, Nup153 and Nup62. The NPC is a 125-MDa complex composed of multiple copies of 30 different proteins. Here we have extended the analysis of the NPC in infected cells by examining the status of Nup98, an interferon-induced NPC protein with a major role in mRNA export. Our results indicate that Nup98 is targeted for cleavage after infection but that this occurs much more rapidly than it does for Nup153 and Nup62. In addition, we find that cleavage of these NPC proteins displays differential sensitivity to the viral RNA synthesis inhibitor guanidine hydrochloride. Inhibition of nuclear import and relocalization of host nuclear proteins to the cytoplasm were only apparent at later times after infection when all three nucleoporins (Nups) were cleaved. Surprisingly, analysis of the distribution of mRNA in infected cells revealed that proteolysis of Nup98 did not result in an inhibition of mRNA export. Cleavage of Nup98 could be reconstituted by the addition of purified rhinovirus type 2 2A(pro) to whole-cell lysates prepared from uninfected cells, suggesting that the 2A protease has a role in this process in vivo. These results indicate that poliovirus differentially targets subsets of NPC proteins at early and late times postinfection. In addition, targeting of interferon-inducible NPC proteins, such as Nup98, may be an additional weapon in the arsenal of poliovirus and perhaps other picornaviruses to overcome host defense mechanisms.

Activation of the nuclear transcription factor SP-1 by insulin rapidly increases the expression of protein kinase C delta in skeletal muscle

SP-1, a ubiquitous transcription factor involved in regulation of target genes participating in specific signaling pathways, is utilized by insulin for induction of gene transcription. Transcriptional activation generally occurs only after several (14–24) hours. A major element rapidly activated by insulin in skeletal muscle is PKCδ, which plays a positive regulatory role in insulin signaling. We recently reported that insulin stimulation of skeletal muscle increases PKCδ RNA expression and PKCδ protein levels within 5 min. These effects were blocked by inhibitors of either translation or transcription. In this study, we investigated the possibility that SP-1 may participate in this unusually rapid effect. Studies were performed on myoblasts and myotubes of the L6 skeletal muscle cell line. Insulin rapidly increased SP-1 levels and stimulated SP-1 phosphorylation in the nuclear fraction of L6 myotubes. The increase in nuclear SP-1 was blocked by inhibition of nuclear import. Inhibition of SP-1, either pharmacologically or by suppression of SP-1 by RNAi, nearly completely abrogated insulin-induced increase in PKCδ promoter activity. Insulin induced a rapid association of SP-1 with the PKCα promoter. In addition, SP-1 inhibition blocked insulin-induced increases in both PKCδ RNA expression and PKCδ protein levels. We conclude that insulin rapidly stimulates SP-1, which mediates the ability of this hormone to induce the rapid transcription of a major target gene utilized in the insulin signaling cascade.

422 Withdrawn Inhibition of nuclear import of calcineurin prevents myocardial hypertrophy

422 Withdrawn Inhibition of nuclear import of calcineurin prevents myocardial hypertrophy

Inhibition of nuclear import by the proapoptotic protein CC3.

We report here that the normal cellular protein CC3/TIP30, when in excess, inhibits nuclear import in vitro and in vivo. CC3 binds directly to the karyopherins of the importin beta family in a RanGTP-insensitive manner and associates with nucleoporins in vivo. CC3 inhibits the nuclear import of proteins possessing either the classical nuclear localization signal or the M9 signal recognized by transportin. CC3 also inhibits nuclear translocation of transportin itself. Cells modified to express higher levels of CC3 have a slower rate of nuclear import and, as described earlier, show an increased sensitivity to death signals. A mutant CC3 protein lacking proapoptotic activity has a lower affinity for transportin, is displaced from it by RanGTP, and fails to inhibit nuclear import in vitro and in vivo. Together, our results support a correlation between the ability of CC3 to form a RanGTP-resistant complex with importins, inhibit nuclear import, and induce apoptosis. Significantly, a dominant-negative form of importin beta1 shown previously to inhibit multiple transport pathways induces rapid cell death, strongly indicating that inhibition of nuclear transport serves as a potent apoptotic signal.

Inhibition of nuclear import and cell-cycle progression by mutated forms of the dynamin-like GTPase MxB.

Mx proteins form a subfamily of the dynamin-like GTPases, which have well established roles in cellular trafficking. Some Mx proteins (e.g., human MxA) have antiviral activity and are tightly regulated by type I IFNs. Others (e.g., human MxB) lack antiviral activity and are thought to have normal cellular functions that remain undefined. Consistent with this hypothesis, we report that MxB is expressed without IFN treatment. MxB seems to be exclusively extranuclear and is concentrated at the cytoplasmic face of nuclear pores, suggesting a role in their regulation. We find that expression of dominant negative (GTPase-defective) MxB mutants efficiently blocks nuclear import and causes a delay in G(1)/S cell-cycle progression. MxB depletion using RNA interference (RNAi) leads to a similar cell-cycle defect but does not block nuclear import. MxB therefore seems not to be required for nuclear import per se but may instead regulate its efficiency and/or kinetics. These studies indicate an unexpected role for a dynamin-like protein in nucleocytoplasmic trafficking and suggest that a related function might be usurped by its antiviral relatives.

Nuclear localisation of cytosolic phospholipase A2-alpha in the EA.hy.926 human endothelial cell line is proliferation dependent and modulated by phosphorylation.

Cytosolic phospholipase A(2)-alpha (cPLA(2)-alpha) is a calcium-sensitive enzyme involved in receptor-mediated eicosanoid production. In resting cells, cPLA(2)-alpha is present in the cytosol and nucleus and translocates to membranes via its calcium-dependent lipid-binding (CaLB) domain following stimulation. cPLA(2)-alpha is also regulated by phosphorylation on several residues, which results in enhanced arachidonic acid release. Little is known about the factors controlling the nuclear localisation of cPLA(2)-alpha. Here the nuclear localisation of cPLA(2)-alpha in the EA.hy.926 human endothelial cell line was investigated. Nuclear localisation was dependent on proliferation, with subconfluent cells containing higher levels of nuclear cPLA(2)-alpha than contact-inhibited confluent or serum-starved cells. The broad-range protein kinase inhibitor staurosporine caused a decrease in the nuclear level of cPLA(2)-alpha, whereas the protein phosphatase inhibitor okadaic acid increased the level of nuclear cPLA(2)-alpha. Using inhibitors for specific mitogen-activated protein (MAP) kinases, both p42/44(MAPK) and p38(MAPK) were shown to be important in modulating nuclear localisation. Finally, inhibition of nuclear import and export using Agaricus bisporus lectin and leptomycin B, respectively, demonstrated that cPLA(2)-alpha contains functional nuclear localisation and export signals. Thus we have identified a novel mode of regulation of cPLA(2)-alpha. This, together with the increasing body of evidence supporting the role of nuclear lipid second messengers in gene expression and proliferation, may have important implications for controlling the growth of endothelial cells in angiogenesis and tumour progression.

Mitotic phosphorylation of chromosomal protein HMGN1 inhibits nuclear import and promotes interaction with 14.3.3 proteins.

Progression through mitosis is associated with reversible phosphorylation of many nuclear proteins including that of the high-mobility group N (HMGN) nucleosomal binding protein family. Here we use immunofluorescence and in vitro nuclear import studies to demonstrate that mitotic phosphorylation of the nucleosomal binding domain (NBD) of the HMGN1 protein prevents its reentry into the newly formed nucleus in late telophase. By microinjecting wild-type and mutant proteins into the cytoplasm of HeLa cells and expressing these proteins in HmgN1(-/-) cells, we demonstrate that the inability to enter the nucleus is a consequence of phosphorylation and is not due to the presence of negative charges. Using affinity chromatography with recombinant proteins and nuclear extracts prepared from logarithmically growing or mitotically arrested cells, we demonstrate that phosphorylation of the NBD of HMGN1 promotes interaction with specific 14.3.3 isotypes. We conclude that mitotic phosphorylation of HMGN1 protein promotes interaction with 14.3.3 proteins and suggest that this interaction impedes the reentry of the proteins into the nucleus during telophase. Taken together with the results of previous studies, our results suggest a dual role for mitotic phosphorylation of HMGN1: abolishment of chromatin binding and inhibition of nuclear import.

Inhibition of nuclear import and alteration of nuclear pore complex composition by rhinovirus.

Nucleocytoplasmic trafficking pathways and the status of nuclear pore complex (NPC) components were examined in cells infected with rhinovirus type 14. A variety of shuttling and nonshuttling nuclear proteins, using multiple nuclear import pathways, accumulated in the cytoplasm of cells infected with rhinovirus. An in vitro nuclear import assay with semipermeabilized infected cells confirmed that nuclear import was inhibited and that docking of nuclear import receptor-cargo complexes at the cytoplasmic face of the NPC was prevented in rhinovirus-infected cells. The relocation of cellular proteins and inhibition of nuclear import correlated with the degradation of two NPC components, Nup153 and p62. The degradation of Nup153 and p62 was not due to induction of apoptosis, because p62 was not proteolyzed in apoptotic HeLa cells, and Nup153 was cleaved to produce a 130-kDa cleavage product that was not observed in cells infected with poliovirus or rhinovirus. The finding that both poliovirus and rhinovirus cause inhibition of nuclear import and degradation of NPC components suggests that this may be a common feature of the replicative cycle of picornaviruses. Inhibition of nuclear import is predicted to result in the cytoplasmic accumulation of a large number of nuclear proteins that could have functions in viral translation, RNA synthesis, packaging, or assembly. Additionally, inhibition of nuclear import also presents a novel strategy whereby cytoplasmic RNA viruses can evade host immune defenses by preventing signal transduction into the nucleus.

Inhibition of nuclear import by backbone cyclic peptidomimetics derived from the HIV-1 MA NLS sequence

In the present work we have constructed a series of backbone cyclic peptides, which differed in the amino acid residues located at the C-terminal position of the previously described BCvir peptide (A. Friedler, N. Zakai, O. Karni, Y.C. Broder, L. Baraz, M. Kotler, A. Loyter, C. Gilon, Biochemistry 37 (1998)). BCvir is a cyclic peptide, derived from the nuclear localization signal (NLS) of the human immunodeficiency virus type 1 matrix protein. The majority of the cyclic peptides described here inhibited nuclear import in vitro. The most potent inhibitors were those bearing bulky hydrophobic amino acids such as Leu, Phe or Nal (naphthyl Ala) at the C-terminus. On the other hand, peptides bearing polar amino acid residues such as Asn, Cys or a reduced amide bond were not inhibitory. The present studies demonstrate the importance of a bulky hydrophobic C-terminal side chain and an exocyclic amide bond preceding it, to the inhibitory activity of the NLS-derived BC peptides. Being only inhibitory, these BC peptides resemble classic receptor antagonists.

Map kinase inhibition of nuclear import

Map kinase inhibition of nuclear import

Inhibition of nuclear import by protein kinase B (Akt) regulates the subcellular distribution and activity of the forkhead transcription factor AFX.

AFX belongs to a subfamily of Forkhead transcription factors that are phosphorylated by protein kinase B (PKB), also known as Akt. Phosphorylation inhibits the transcriptional activity of AFX and changes the steady-state localization of the protein from the nucleus to the cytoplasm. Our goal was threefold: to identify the cellular compartment in which PKB phosphorylates AFX, to determine whether the nuclear localization of AFX plays a role in regulating its transcriptional activity, and to elucidate the mechanism by which phosphorylation alters the localization of AFX. We show that phosphorylation of AFX by PKB occurs in the nucleus. In addition, nuclear export mediated by the export receptor, Crm1, is required for the inhibition of AFX transcriptional activity. Both phosphorylated and unphosphorylated AFX, however, bind Crm1 and can be exported from the nucleus. These results suggest that export is unregulated and that phosphorylation by PKB is not required for the nuclear export of AFX. We show that AFX enters the nucleus by an active, Ran-dependent mechanism. Amino acids 180 to 221 of AFX comprise a nonclassical nuclear localization signal (NLS). S193, contained within this atypical NLS, is a PKB-dependent phosphorylation site on AFX. Addition of a negative charge at S193 by mutating the residue to glutamate reduces nuclear accumulation. PKB-mediated phosphorylation of AFX, therefore, attenuates the import of the transcription factor, which shifts the localization of the protein from the nucleus to the cytoplasm and results in the inhibition of AFX transcriptional activity.

Kicked Out by Phosphorylation

AFX, a member of the forkhead family of transcription factors, is inhibited by growth factor signaling through the activation of protein kinase B (PKB), which phosphorylates AFX leading to its redistribution from nucleus to cytosol. In cells treated with insulin, activated PKB was identified in the nucleus. AFX became phosphorylated (AFX-P) in response to insulin, even when nuclear export was inhibited pharmacologically with leptomycin B, suggesting that PKB in the nucleus is responsible for AFX phosphorylation. However, inhibition of nuclear export suppressed inhibition of AFX-activated reporter gene expression in response to insulin, suggesting that the redistribution of AFX, not phosphorylation per se, is responsible for regulation of AFX activity. AFX and AFX-P interacted with the nuclear export receptor Crm1 and were shuttled out of the nucleus. However, phosphorylation of AFX decreases nuclear import. The authors suggest that growth factor signaling leads to nuclear phosphorylation of AFX, which allows nuclear export but prevents import, possibly because of the interaction of AFX-P with cytosolic 14-3-3 proteins. A. M. Brownawell, G. J. P. L. Kops, I. G. Macara, B. M. T. Burgering, Inhibition of nuclear import by protein kinase B (Akt) regulates the subcellular distribution and activity of the forkhead transcription factor AFX. Mol. Cell. Biol. 21 , 3534-3546 (2001). [Abstract] [Full Text]

Stimulation of Nuclear Export and Inhibition of Nuclear Import by a Ran Mutant Deficient in Binding to Ran-binding Protein 1

Receptor-mediated nucleocytoplasmic transport is dependent on the GTPase Ran and Ran-binding protein 1 (RanBP1). The acidic C terminus of Ran is required for high affinity interaction between Ran and RanBP1. We found that a novel Ran mutant with four of its five acidic C-terminal amino acids modified to alanine (RanC4A) has an approximately 20-fold reduced affinity for RanBP1. We investigated the effects of RanC4A on nuclear import and export in permeabilized HeLa cells. Although RanC4A promotes accumulation of the nuclear export receptor CRM1 at the cytoplasmic nucleoporin Nup214, it strongly stimulates nuclear export of GFP-NFAT. Since RanC4A exhibits an elevated affinity for CRM1 and other nuclear transport receptors, this suggests that formation of the export complex containing CRM1, Ran-GTP, and substrate is a rate-limiting step in export, not release from Nup214. Conversely, importin alpha/beta-dependent nuclear import of bovine serum albumin, coupled to a classical nuclear localization sequence is strongly inhibited by RanC4A. Inhibition can be reversed by additional importin alpha, which promotes the formation of an importin alpha/beta complex. These results provide physiological evidence that release of Ran-GTP from importin beta by RanBP1 and importin alpha is critical for the recycling of importin beta to a transport-competent state.