Involvement of N-terminal-extended form of sphingosine kinase 2 in serum-dependent regulation of cell proliferation and apoptosis

Sphingosine kinase (SPHK) 1 is implicated in the regulation of cell proliferation and anti-apoptotic processes by catalyzing the formation of an important bioactive messenger, sphingosine 1-phosphate. Unlike the proliferative action of SPHK1, another isozyme, SPHK2, has been shown to possess anti-proliferative or pro-apoptotic action. Molecular mechanisms of SPHK2 action, however, are largely unknown. The present studies were undertaken to characterize the N-terminal-extended form of SPHK2 (SPHK2-L) by comparing it with the originally reported form, SPHK2-S. Real-time quantitative PCR analysis revealed that SPHK2-L mRNA is the major form in several human cell lines and tissues. From sequence analyses it was concluded that SPHK2-L is a species-specific isoform that is expressed in human but not in mouse. At the protein level it has been demonstrated by immunoprecipitation studies that SPHK2-L is the major isoform in human hepatoma HepG2 cells. SPHK2-L, when expressed in human embryonic kidney (HEK) 293 cells, did not show any inhibition of DNA synthesis in the presence of serum, whereas it showed marked inhibition in the absence of serum. Moreover, serum deprivation resulted in the translocation of SPHK2-L into the nuclei. In addition, serum deprivation induced SPHK2-L expression in HEK293 cells. Furthermore, suppression of SPHK2 by small interfering RNA treatment prevented serum deprivation- or drug-induced apoptosis in HEK293 cells. Taken together, these results indicate that a major form of SPHK2 splice variant, SPHK2-L, in human cells does not inhibit DNA synthesis under normal conditions and that SPHK2-L accumulation in the nucleus induced by serum deprivation may be involved in the cessation of cell proliferation or apoptosis depending on the cell type.     

Two nuclear localization signals required for transport from the cytosol to the nucleus of externally added FGF-1 translocated into cells

Externally added FGF-1 is transported into the nucleus of cells. It was earlier shown that FGF-1 contains an N-terminal nuclear localization signal (NLS) implicated in the stimulation of DNA synthesis. We here provide evidence that FGF-1 contains a second putative NLS (NLS2), which is located near the C-terminus. It is a bipartite NLS consisting of two clusters of lysines separated by a spacer of 10 amino acids. A fusion protein of GFP and the bipartite NLS was more efficiently transported into the nucleus than GFP alone, indicating that it can act as an NLS in the living cell. FGF-1 mutated in the N-terminal NLS (NLS1) or in the first cluster of the bipartite NLS2 bound to heparin and FGF receptors and activated downstream signaling similarly to the wild-type growth factor. Mutations in the second cluster of NLS2 resulted in impaired interaction with heparin and reduced stability. When radiolabeled FGF-1 with mutated NLS1 or the first lysine cluster of NLS2 was added to NIH/3T3 cells, it was translocated into the cytosol, but not transported efficiently to the nucleus. Phosphorylation of FGF-1 occurs normally in the nucleus, and while wild-type FGF-1 was phosphorylated after addition to cells, the NLS mutants were not. It therefore appears that both NLS1 and NLS2 are important for efficient transport of FGF-1 to the nucleus. Stimulation of DNA synthesis by FGF-1 with mutations in both NLSs was reduced considerably indicating that efficient transport to the nucleus may be involved in the stimulation of DNA synthesis.     

Nuclear import of bovine papillomavirus type 1 E1 protein is mediated by multiple alpha importins and is negatively regulated by phosphorylation near a nuclear localization signal

Papillomavirus DNA replication occurs in the nucleus of infected cells and requires the viral E1 protein, which enters the nuclei of host epithelial cells and carries out enzymatic functions required for the initiation of viral DNA replication. In this study, we investigated the pathway and regulation of the nuclear import of the E1 protein from bovine papillomavirus type 1 (BPV1). Using an in vitro binding assay, we determined that the E1 protein interacted with importins alpha3, alpha4, and alpha5 via its nuclear localization signal (NLS) sequence. In agreement with this result, purified E1 protein was effectively imported into the nucleus of digitonin-permeabilized HeLa cells after incubation with importin alpha3, alpha4, or alpha5 and other necessary import factors. We also observed that in vitro binding of E1 protein to all three alpha importins was significantly decreased by the introduction of pseudophosphorylation mutations in the NLS region. Consistent with the binding defect, pseudophosphorylated E1 protein failed to enter the nucleus of digitonin-permeabilized HeLa cells in vitro. Likewise, the pseudophosphorylation mutant showed aberrant intracellular localization in vivo and accumulated primarily on the nuclear envelope in transfected HeLa cells, while the corresponding alanine replacement mutant displayed the same cellular location pattern as wild-type E1 protein. Collectively, our data demonstrate that BPV1 E1 protein can be transported into the nucleus by more than one importin alpha and suggest that E1 phosphorylation by host cell kinases plays a regulatory role in modulating E1 nucleocytoplasmic localization. This phosphoregulation of nuclear E1 protein uptake may contribute to the coordination of viral replication with keratinocyte proliferation and differentiation.     

The motif of SPARC that inhibits DNA synthesis is not a nuclear localization signal

SPARC (secreted protein acidic and rich in cysteine), although primarily known as a secreted, matricellular protein, has also been identified in urothelial cell nuclei. Many biological activities, including inhibition of cell adhesion and repression of DNA synthesis, have been ascribed to SPARC, but the influence of its intracellular localization on each of these activities is unknown. When exposed by epitope retrieval and nuclear matrix unmasking techniques, endogenous SPARC was found to localize strongly to the nuclei and the nuclear matrix of cultured urothelial cells. Live-cell time-lapse imaging revealed that exogenous fluorescently labeled recombinant (r) SPARC was taken up from medium over a 16 h period and accumulated inside cells. Two variants of rSPARC with alterations in its putative nuclear localization signal (NLS) were generated to investigate the existence and effects of the NLS. These variants demonstrated similar biophysical characteristics as the wild-type protein. Visualization by a variety of techniques, including live-cell imaging, deconvolution microscopy, and cell fractionation, all concurred that exogenous rSPARC was not able to localize to cell nuclei, but instead accumulated as perinuclear clusters. Localization of the rSPARC NLS variants was no different than wild-type, arguing against the presence of an active NLS in rSPARC. Imaging experiments showed that only permeabilized, dead cells avidly took up rSPARC into their nuclei. The rSPARC(no NLS) variant proved ineffective at inhibiting DNA synthesis, whereas the rSPARC(strong NLS) variant was a more potent inhibitor of DNA synthesis than was wild-type rSPARC. The motif of SPARC that inhibits the synthesis of urothelial cell DNA is therefore not a nuclear localization signal, but its manipulation holds therapeutic potential to generate a "Super-SPARC" that can quiesce proliferative tissues.     

Large subunit of translation initiation factor--3 p170 contains potentially functional nuclear localization signals

Eukaryotic translation factors and their subunits can have independent cellular functions, including regulation of nuclear events. We analyzed primary structure of p170 large subunit of human translation initiation factor eIF3 and found four potential bipartite nuclear localization signals (NLS). Then we studied whether these NLS were functional, that is were able to direct protein to cell nucleus. Complementary DNA of p170 fragments were expressed in cultured CV-1 and Cos-1 green monkey cells, and localization of fused with GFP proteins was determined by fluorescent microscopy. We established that p170 molecule possessed at least two functional NLS which determined nuclear localization of p170 fragments. At the same time more long p170 fragments containing the same functional NLS could be retained in cytoplasm. We speculate that either using specific factors or after limited proteolysis p170 can enter cell nucleus and participate in genome expression regulation. Also we do not exclude the possibility that functioning of p170 in cytoplasm can be regulated by reversible binding of importins to its NLS.     

Nuclear trafficking of FGFR1: a role for the transmembrane domain

Several members of the fibroblast growth factor (FGF) family lack signal peptide (SP) sequences and are present only in trace amounts outside the cell. However, these proteins contain nuclear localization signals (NLS) and accumulate in the cell nucleus. Our studies have shown that full length FGF receptor 1 (FGFR1) accumulates within the nuclear interior in parallel with FGF-2. We tested the hypothesis that an atypical transmembrane domain (TM) plays a role in FGFR1 trafficking into the nuclear interior. With FGFR1 destined for constitutive fusion with the plasma membrane due to its SP, how the receptor may enter the nucleus is unclear. Sequence analysis identified that FGFR1 has an atypical TM containing short stretches of hydrophobic amino acids (a.a.) interrupted by polar a.a. The beta-sheet is the predicted conformation of the FGFR1 TM, in contrast to the alpha-helical conformation of other single TM tyrosine kinase receptors, including FGFR4. Receptor trafficking in live cells was studied by confocal microscopy via C-terminal FGFR1 fusions to enhanced green fluorescent protein (EGFP) and confirmed by subcellular fractionation and Western immunoblotting. Nuclear entry of FGFR1-EGFP was independent of karyokinessis, and was observed in rapidly proliferating human TE671 cells, in slower proliferating glioma SF763 and post-mitotic bovine adrenal medullary cells (BAMC). In contrast, a chimeric FGFR1/R4-EGFP, where the TM of FGFR1 was replaced with that of FGFR4, was associated with membranes (golgi-ER, plasma, and nuclear), but was absent from the nucleus and cytosol. FGFR1delta-EGFP mutants, with hydrophobic TM a.a. replaced with polar a.a., showed reduced association with membranes and increased cytosolic/nuclear accumulation with an increase in TM hydrophilicity. FGFR1(TM-)-EGFP (TM deleted), was detected in the golgi-ER vesicles, cytosol, and nuclear interior; thus demonstrating that the FGFR1 TM does not function as a NLS. To test whether cytosolic FGFR1 provides a source of nuclear FGFR1, cells were transfected with FGFR1(SP-) (SP was deleted), resulting in cytosolic, non-membrane, protein accumulation in the cytosol and the cell nucleus. Our results indicate that an unstable association with cellular membranes is responsible for the release of FGFR1 into the cytosol and cytosolic FGFR1 constitutes the source of the nuclear receptor.     

Nuclear Import and Dimerization of Tomato ASR1, a Water Stress-Inducible Protein Exclusive to Plants

The ASR (for ABA/water stress/ripening) protein family, first described in tomato as nuclear and involved in adaptation to dry climates, is widespread in the plant kingdom, including crops of high agronomic relevance. We show both nuclear and cytosolic localization for ASR1 (the most studied member of the family) in histological plant samples by immunodetection, typically found in small proteins readily diffusing through nuclear pores. Indeed, a nuclear localization was expected based on sorting prediction software, which also highlight a monopartite nuclear localization signal (NLS) in the primary sequence. However, here we prove that such an "NLS" of ASR1 from tomato is dispensable and non-functional, being the transport of the protein to the nucleus due to simple diffusion across nuclear pores. We attribute such a targeting deficiency to the misplacing in that cryptic NLS of two conserved contiguous lysine residues. Based on previous in vitro experiments regarding quaternary structure, we also carried out live cell imaging assays through confocal microscopy to explore dimer formation in planta. We found homodimers in both the cytosol and the nucleus and demonstrated that assembly of both subunits together can occur in the cytosol, giving rise to translocation of preformed dimers. The presence of dimers was further corroborated by means of in vivo crosslinking of nuclei followed by SDS-PAGE.     

Identification of the nuclear localization signal in Xenopus cyclin E and analysis of its role in replication and mitosis

Cyclin-dependent kinase (Cdk)2/cyclin E is imported into nuclei assembled in Xenopus egg extracts by a pathway that requires importin-alpha and -beta. Here, we identify a basic nuclear localization sequence (NLS) in the N-terminus of Xenopus cyclin E. Mutation of the NLS eliminated nuclear accumulation of both cyclin E and Cdk2, and such versions of cyclin E were unable to trigger DNA replication. Addition of a heterologous NLS from SV40 large T antigen restored both nuclear targeting of Cdk2/cyclin E and DNA replication. We present evidence indicating that Cdk2/cyclin E complexes must become highly concentrated within nuclei to support replication and find that cyclin A can trigger replication at much lower intranuclear concentrations. We confirmed that depletion of endogenous cyclin E increases the concentration of cyclin B necessary to promote entry into mitosis. In contrast to its inability to promote DNA replication, cyclin E lacking its NLS was able to cooperate with cyclin B in promoting mitotic entry.     

Identification of a Plant Viral RNA Genome in the Nucleus

Viruses contain either DNA or RNA as genomes. DNA viruses replicate within nucleus, while most RNA viruses, especially (+)-sense single-stranded RNA, replicate and are present within cytoplasm. We proposed a new thought that is contrary to the common notion that (+)-sense single-stranded RNA viruses are present only in the cytoplasm. In this study, we question whether the genome of a plant RNA virus (non-retroviral) is present in the nucleus of infected cells? Hibiscus chlorotic ringspot virus (HCRSV) RNA was detected in the nucleus of infected cells, as shown by fluorescent in situ hybridization. Western blot using anti-histone 3 and anti-phosphoenolpyruvate carboxylase showed that nuclei were highly purified from mock and HCRSV-infected kenaf (Hibiscus cannabilis L.) leaves, respectively. The p23 and HCRSV coat protein (CP) coding regions were both amplified from total RNA extracted from isolated nuclei. Viral RNA in the nucleus may be used to generate viral microRNAs (vir-miRNAs), as five putative vir-miRNAs were predicted from HCRSV using the vir-miRNAs prediction database. The vir-miRNA (hcrsv-miR-H1-5p) was detected using TaqMan® stem-loop real-time PCR, and by northern blot using DIG-end labeled probe in HCRSV-infected kenaf leaves. Finally, a novel nuclear localization signal (NLS) was discovered in p23 of HCRSV. The NLS interacts with importin α and facilitates viral RNA genome to enter nucleus. We demonstrate the presence of a (+)-sense single-stranded viral RNA within nucleus.     

Nuclear translocation of p21 protein prior to its cytosolic degradation by UV enhances DNA repair and survival

We previously reported that UV induced rapid proteasomal degradation of p21 protein in an ubiquitination-independent manner. Here, UV-induced p21 proteolysis was found to occur in the cytosol. Before cytosolic degradation, however, p21 protein translocated to and transiently accumulated in the nucleus. Nuclear translocation of p21 was not required for its degradation, but rather promoted DNA repair and cell survival. Overexpression of the wild type p21, but not the one with defective nuclear localization signal (NLS), reduced UV-induced DNA damage and cell death. Some of p21 protein translocated to the nucleus were associated with chromatin-bound PCNA and saved from UV-induced proteolysis. These data together show that p21 translocates to the nucleus to participate in DNA repair, while the rest is rapidly degraded in the cytosol. We propose that our findings reflect a mechanism to facilitate removal of damaged cells, enhancing DNA repair at the same time.     

Nuclear Import and Export Signals Control the Subcellular Localization of Nurr1 Protein in Response to Oxidative Stress

Orphan receptor Nurr1 participates in the acquisition and maintenance of the dopaminergic cell phenotype, modulation of inflammation, and cytoprotection, but little is known about its regulation. In this study, we report that Nurr1 contains a bipartite nuclear localization signal (NLS) within its DNA binding domain and two leucine-rich nuclear export signals (NES) in its ligand binding domain. Together, these signals regulate Nurr1 shuttling in and out of the nucleus. Immunofluorescence and immunoblot analysis revealed that Nurr1 is mostly nuclear. A Nurr1 mutant lacking the NLS failed to enter the nucleus. The Nurr1 NLS sequence, when fused to green fluorescent protein, led to nuclear accumulation of this chimeric protein, indicating that this sequence was sufficient to direct nuclear localization of Nurr1. Furthermore, two NES were characterized in the ligand binding domain, whose deletion caused Nurr1 to accumulate predominantly in the nucleus. The Nurr1 NES was sensitive to CRM1 and could function as an independent export signal when fused to green fluorescent protein. Sodium arsenite, an agent that induces oxidative stress, promoted nuclear export of ectopically expressed Nurr1 in HEK293T cells, and the antioxidant N-acetylcysteine rescued from this effect. Similarly, in dopaminergic MN9D cells, arsenite induced the export of endogenous Nurr1, resulting in the loss of expression of Nurr1-dependent genes. This study illustrates that Nurr1 shuttling between the cytosol and nucleus is controlled by specific nuclear import and export signals and that oxidative stress can unbalance the distribution of Nurr1 to favor its cytosolic accumulation.     

A conserved phosphoprotein that specifically binds nuclear localization sequences is involved in nuclear import [published erratum appears in J Cell Biol 1992 Jul;118(1):215]

We have purified proteins of 70 kD from Drosophila, HeLa cells, and Z. mays that specifically bind nuclear localization sequences (NLSs). These proteins are recognized by antibodies raised against a previously identified NLS-binding protein (NBP) from the yeast S. cerevisiae. All NBPs are associated with nuclei and also present in the cytosol. NBPs are phosphorylated and phosphatase treatment abolished NLS binding. The requirement for NBPs in nuclear protein uptake is demonstrated in semipermeabilized Drosophila melanogaster tissue culture cells. Proper import of a fluorescent protein containing the large T antigen NLS requires cytosol and ATP. In the absence of cytosol and/or ATP, NLS-containing proteins are bound to cytosolic structures and the nuclear envelope. Addition of cytosol and ATP results in movement of this bound intermediate into the nucleus. Anti-NBP antibodies specifically inhibited the binding part of this import reaction. These results indicate that a phosphoprotein common to several eukaryotes acts as a receptor that recognizes NLSs before their uptake into the nucleus.     

The relationship of DNA synthesis to protein accumulation in the cell nucleus

The relationship between DNA synthesis and protein accumulation in cell nucleus and cytoplasm has been investigated by the use of a combination of ultramicrointerferometric and ultramicrospectrophotometric methods. 5-Fluoro-2'-deoxyuridine (FUdR) inhibited DNA synthesis, resulting in inhibition of cell proliferation in G-1 and early S-phase. However, synthesis and accumulation of protein continued in the presence of FUdR, as indicated by a 54% increase in the average dry mass value per individual cell during 18-hour exposure to FUdR; due primarily to protein accumulation in the cytoplasm, the average cytoplasmic dry mass increased by as much as 85%, while the dry mass of the nucleus increased by only 21%. The dry mass values of individual nuclei were well-correlated to the nuclear DNA content throughout the period of exposure to FUdR. In contrast to the continued accumulation of protein in the cytoplasm during inhibition of DNA synthesis, protein accumulation in the nucleus was inhibited. When cells were released from inhibition of DNA synthesis by the addition of 2'-deoxythymidine, the nuclear DNA content and nuclear dry mass increased in near-synchrony, there being some evidence that DNA synthesis was initiated somewhat prior to initiation of increase in nuclear dry mass. Thus, it appears that DNA synthesis (or an increase in nuclear DNA content) is intimately related to the regulation of protein accumulation in the nucleus.     

Estradiol-induced progesterone receptor synthesis in normal and diabetic ovariectomized rat uterus

Estrogen stimulation of progesterone-receptor (Prog R.) synthesis is an important parameter of the sex hormones activity at the uterine level. Experimental diabetes in the rat has been shown to perturb protein synthesis in some tissues and to reduce, under certain circumstances, estrogen and androgen activity on their respective target tissues. The present work tended to evaluate the effect of streptozotocin diabetes on estradiol (E2) stimulation of Prog. R and on Prog R. kinetics in the rat uterus. Two groups of diabetic rats were primed for three consecutive days with 5 microg. E2 s.c. (EP). One group received an acute i.p. injection of progesterone (P), 1 h before sacrifice (Inj), the other group did not (n Inj). Two other groups, not primed with E2 (nEP) were similarly injected or not with P. Four groups of non diabetic animals served as controls. Estrogen priming induced a 20-25% increase in DNA content, both in controls and in diabetics. Protein content was also increased to almost the same extent in diabetics and controls; protein concentration remained however slightly lower in cytosol of EP diabetics as compared to controls. Prog R. increased about 7-fold in cytosol and 4-5-fold in nuclei of EP control and diabetic groups. Cytosol to nuclei ratios of Prog R. decreased similarly in Inj. EP diabetics and controls, compared to the corresponding n Inj. groups. It is concluded that estrogen priming stimulated Prog R., total protein and DNA synthesis to the same extent in diabetic as in control rats Prog R. kinetics was unaltered in diabetics. This finding might be relevant to situations like early pregnancy, when Prog R. levels change rapidly and specifically in relation with the time and the site of implantation.     

Sphingosine kinase 1 is a negative regulator of CD4+ Th1 cells

CD4+ Th1 cells produce IFN-gamma, TNF-alpha, and IL-2. These Th1 cytokines play critical roles in both protective immunity and inflammatory responses. In this study we report that sphingosine kinase 1 (SPHK1), but not SPHK2, is highly expressed in DO11.10 Th1 cells. The expression of SPHK1 in Th1 cells requires TCR signaling and new protein synthesis. SPHK1 phosphorylates sphingosine to form sphingosine-1-phosphate. Sphingosine-1-phosphate plays important roles in inhibition of apoptosis, promotion of cell proliferation, cell migration, calcium mobilization, and activation of ERK1/2. When SPHK1 expression was knocked down by SPHK1 short interfering RNA, the production of IL-2, TNF-alpha, and IFN-gamma by Th1 cells in response to TCR stimulation was enhanced. Consistently, overexpression of dominant-negative SPHK1 increased the production of IL-2, TNF-alpha, and IFN-gamma in Th1 cells. Furthermore, overexpression of SPHK1 in Th1 and Th0 cells decreased the expression of IL-2, TNF-alpha, and IFN-gamma. Several chemokines, including Th2 chemokines CCL17 and CCL22, were up-regulated by SPHK1 short interfering RNA and down-regulated by overexpression of SPHK1. We also showed that Th2 cells themselves express CCL17 and CCL22. Finally, we conclude that SPHK1 negatively regulates the inflammatory responses of Th1 cells by inhibiting the production of proinflammatory cytokines and chemokines.     

Effect of Ehrlich ascites cell chalone on nascent DNA synthesis in isolated nuclei

Ehrlich Ascites Tumor (EAT) chalone has been shown to inhibit nascent DNA synthesis by inhibiting DNA polymerase alpha and beta (Nakai, 1976), but one of the problems in studying eurkaryotic DNA replication has been the relative impermeability of the cell membrane to precursors and macromolecules; hence, to circumvent this restriction without sacrificing the integrity of the replication process, a broken cell system utilizing nuclei in aqueous media was investigated. Isolated nuclei appear to continue the process of DNA replication that was proceeding in vivo before their isolation and under optimal concitions are able to initiate new synthesis (Fraser & Huberman, 1977). The effects of partially purified EAT chalone on nascent DNA could be studied directly in this nuclear system, which excluded effects of the cell membrane, nucleotide pools and other cytosol elements. A concentration-related inhibition of [3H]thymidine triphosphate ([3H]dTTP) incorporation was noted over a chalone range of 50-200 micrograms/ml. It appears that chalone can inhibit DNA polymerase alpha directly within the nucleus without an intermediate step such as a cell membrane receptor.