核定位信号及其分析策略

真核细胞核膜上的核孔复合体 (nuclear pore complex, NPC) 是细胞核内外进行物质交换的主要通道, 分子量较小的化合物可自由通过NPC或采取被动扩散的方式进入细胞核, 而分子量为50 kD以上的蛋白质则只能通过主动转运进入细胞核. 以这种方式进入细胞核的 蛋白质必须在其氨基酸序列上拥有特殊的核定位信号(nuclear localization signal, NLS)以被相应的核转运蛋白(karyopherins) 识别. 核定位信号具有多样性, 包括经典核定位信号(classical NLS,cNLS), 内输蛋白β2识别的核定位信号（又称PY模体-NLS）和其它类型的NLS. 每一类NLS具有相似的特征, 但并不具有完全保守的氨基酸组成. 不同的NLS, 往往对应着各不相同的核输入机制. 而对同一蛋白质来说, 也可能同时拥有几个功能性的NLS. 研究核定位信号一方面可以帮助揭示新的大分子物质核转运机制, 另一方面也有助于发现一些蛋白质的新功能. 本文对常见NLS的分类进行了总结, 并介绍了两种常用的NLS预测软件及鉴定NLS的一般策略.     

核孔蛋白p62促进非受体酪氨酸激酶c-Abl进入细胞核

非受体酪氨酸激酶c-Abl广泛表达于各组织细胞中,其序列高度保守,它的亚细胞定位与其功能密切相关。c-Abl借助其C端的3个核定位信号（NLS）和1个核输出信号（NES）完成细胞核一细胞质问的穿梭过程。关于c-Abl核-质穿梭的详细机制还不清楚。通过酵母双杂交系统,以人类Ib型c-Abl作为诱饵蛋白进行HeLa细胞eDNA文库的筛选,获得了可能在c-Abl核-质穿梭过程中具有调控怍用核孔蛋白p62。核孔复合物（NPC）是大分子物质进行核-质运输的惟一通道,p62是NPC的重要组成部分,它位于中央通道内侧,在许多物质的核-质穿梭过程中具有调节作用。免疫共沉淀和体外结合实验证实,c-Abl和p62之间具有相互作用,而且这种相互作用是通过c-Abl的SH3结构域与p62的P299位点之间的结合实现的;p62可被c-Abl部分磷酸化此外,在293和DKO细胞株中共转染c-Abl和p62,发现核内的c-Abl分布增多。以上结果表明,p62具有促进e-Abl进入细咆核的作用。     

The Effector Domain of MARCKS Is a Nuclear Localization Signal that Regulates Cellular PIP2 Levels and Nuclear PIP2 Localization

Translocation to the nucleus of diacylglycerol kinase (DGK)– ζ is dependent on a sequence homologous to the effector domain of Myristoylated Alanine Rich C-Kinase Substrate (MARCKS). These data would suggest that MARCKS could also localize to the nucleus. A single report demonstrated immunofluorescence staining of MARCKS in the nucleus; however, further experimental evidence confirming the specific domain responsible for this localization has not been reported. Here, we report that MARCKS is present in the nucleus in GBM cell lines. We then over-expressed wild-type MARCKS (WT) and MARCKS with the effector domain deleted (ΔED), both tagged with V5-epitope in a GBM cell line with low endogenous MARCKS expression (U87). We found that MARCKS-WT localized to the nucleus, while the MARCKS construct without the effector domain remained in the cytoplasm. We also found that over-expression of MARCKS-WT resulted in a significant increase in total cellular phosphatidyl-inositol (4,5) bisphosphate (PIP₂) levels, consistent with prior evidence that MARCKS can regulate PIP₂ levels. We also found increased staining for PIP₂ in the nucleus with MARCKS-WT over-expression compared to MARCKS ΔED by immunofluorescence. Interestingly, we observed MARCKS and PIP₂ co-localization in the nucleus. Lastly, we found changes in gene expression when MARCKS was not present in the nucleus (MARCKS ΔED). These data indicate that the MARCKS effector domain can function as a nuclear localization signal and that this sequence is critical for the ability of MARCKS to regulate PIP₂ levels, nuclear localization, and gene expression. These data suggests a novel role for MARCKS in regulating nuclear functions such as gene expression.     

PNRC1核定位信号序列的鉴定

为鉴定富含脯氨酸核受体辅调节蛋白1(PNRC1)分子的核定位信号序列（nuclear localization signal sequence, NLS）,在生物信息学方法预测的基础上,先构建野生型PNRC1及删除预测NLS的PNRC1突变体的绿色荧光蛋白（GFP）重组表达载体,转染细胞后通过激光共聚焦显微镜观察PNRC1分子在删除预测NLS后细胞内的定位变化.然后,将预测的NLS编码序列直接连到GFP表达载体上,以及将预测的NLS加到胞浆蛋白上构建其GFP重组表达载体,转染细胞,观察预测的NLS能否把构建的重组体都带到细胞核内.结果显示,删除PNRC1中预测的NLS后,其定位从细胞核中变为主要定位在细胞浆中,而预测的NLS能把GFP或胞浆中的蛋白带到细胞核中.研究表明,预测的NLS为PNRC1分子真正的NLS.     

核定位信号筛选系统的构建

建立了一酵母克隆系统用于克隆含核定位信号 (NLS)的蛋白质的基因 .用表达转录因子GAL4 DNA结合域 - p53(GAL4- DBD- p53)融合蛋白的质粒转化酵母 HF7c,使 GAL4- DBD- p53可结合于报告基因的启动子但因无转录激活域而不能激活转录 .构建一酵母穿梭载体 ,可表达无NLS的 GAL4转录激活域 -大 T抗原 (GAL4- AD- LT)融合蛋白 .融合蛋白基因的下游插入一多克隆位点 .将 c DNA文库插入多克隆位点后 ,如果 c DNA片段可编码 NLS,则 GAL4- AD- LT分子可进入细胞核 ,并通过 LT与 p53的相互作用而使 GAL4- AD结合于启动子和激活报告基因的转录 .构建了这一克隆系统的各质粒 ,并用绿色荧光蛋白 (GFP)验证了其对核内蛋白和胞浆蛋白的甄别能力 .这一系统将有助于从 c DNA文库中筛选编码带有 NLS的蛋白质的基因     

Constitutive Nuclear Localization of an Alternatively Spliced Sirtuin-2 Isoform

Sirtuin-2 (SIRT2), the cytoplasmic member of the sirtuin family, has been implicated in the deacetylation of nuclear proteins. Although the enzyme has been reported to be located to the nucleus during G₂/M phase, its spectrum of targets suggests functions in the nucleus throughout the cell cycle. While a nucleocytoplasmic shuttling mechanism has been proposed for SIRT2, recent studies have indicated the presence of a constitutively nuclear isoform. Here we report the identification of a novel splice variant (isoform 5) of SIRT2 that lacks a nuclear export signal and encodes a predominantly nuclear isoform. This novel isoform 5 fails to show deacetylase activity using several assays, both in vitro and in vivo, and we are led to conclude that this isoform is catalytically inactive. Nevertheless, it retains the ability to interact with p300, a known interaction partner. Moreover, changes in intrinsic tryptophan fluorescence upon denaturation indicate that the protein is properly folded. These data, together with computational analyses, confirm the structural integrity of the catalytic domain. Our results suggest an activity-independent nuclear function of the novel isoform.     

Nuclear Localization of Brain-type Glycogen Phosphorylase in Some Gastrointestinal Carcinoma

Our previous reports have demonstrated frequent and strong expression of glycogen phosphorylase (EC 2.4.1.1) activity mainly in the cytoplasm of gastric carcinoma. Although previous studies have suggested the phosphorylase glyco-syltransferase system to be in the nucleus from enzyme histochemical analyses, intranuclear localization of the phosphorylase has not been fully established. The aims of the present study are to investigate the nuclear localization of glycogen phosphorylase and to identify the isoform of phosphorylase in the nucleus of gastrointestinal carcinoma. The activity of glycogen phosphorylase in carcinoma cells corresponding to the nucleus was demonstrated using enzyme cytochemical analysis. The phosphorylase activity coincided with localization revealed by immunocytochemistry using affinity-purified specific anti-human brain-type glycogen phosphorylase antibody. The isoform expressed in the nuclei of carcinoma cells was identified as bei ng only the brain type according to a polymerase chain reaction-based assay using RNA obtained from gastric carcinoma cells and primers specific to muscle, liver and brain types of glycogen phosphorylase. The intranuclear localization of the brain-type isoform was confirmed by immunoelectron microscopical analyses. Further investigation to examine the nuclear localization in human carcinoma tissue (145 and 25 specimens with gastric and colonic carcinoma respectively) was carried out by immunohistochemistry using specific anti-brain-type antibody. Nuclear immunostaining was observed in seven cases out of 145 gastric carcinoma. The present study is the first to clarify the nuclear localization of glycogen phosphorylase with enzymatic activity in gastrointestinal carcinoma. The isoform of the enzyme expressed in the carcinoma was identified as the brain type. These results warrant further studies on the mechanisms for transporting the large molecule of brain-type glycogen phosphorylase to nuclei and its function in the nucleus of carcinoma cells.     

Sumoylation of SAE2 C Terminus Regulates SAE Nuclear Localization

SUMOylation occurs predominantly in the nucleus, but non-nuclear proteins can also be SUMOylated. It is unclear how intracellular trafficking of the SUMOylation enzymes is regulated to catalyze SUMOylation in different cellular compartments. Here we report that the SAE2 subunit of human SUMO activation enzyme (SAE) underwent rapid nucleocytoplasmic shuttling and its nuclear accumulation depended on SUMO modification at the C terminus. The SUMOylation sites included three Lys residues on the bipartite nuclear localization sequence (NLS) and two Lys residues outside of but adjacent to the NLS, and their SUMOylation was catalyzed by Ubc9. Because SAE2 forms a tight heterodimer with SAE1 and it controls the trafficking of the heterodimer, this study has identified the mechanism used to localize SAE to the nucleus. Similar mechanisms are likely to exist for other proteins that depend on SUMOylation for nuclear localization.     

Serotype-specific Differences in Dengue Virus Non-structural Protein 5 Nuclear Localization

The four serotypes of dengue virus (DENV-1 to -4) cause the most important arthropod-borne viral disease of humans. DENV non-structural protein 5 (NS5) contains enzymatic activities required for capping and replication of the viral RNA genome that occurs in the host cytoplasm. However, previous studies have shown that DENV-2 NS5 accumulates in the nucleus during infection. In this study, we examined the nuclear localization of NS5 for all four DENV serotypes. We demonstrate for the first time that there are serotypic differences in NS5 nuclear localization. Whereas the DENV-2 and -3 proteins accumulate in the nucleus, DENV-1 and -4 NS5 are predominantly if not exclusively localized to the cytoplasm. Comparative studies on the DENV-2 and -4 NS5 proteins revealed that the difference in DENV-4 NS5 nuclear localization was not due to rapid nuclear export but rather the lack of a functional nuclear localization sequence. Interaction studies using DENV-2 and -4 NS5 and human importin-α isoforms failed to identify an interaction that supported the differential nuclear localization of NS5. siRNA knockdown of the human importin-α isoform KPNA2, corresponding to the murine importin-α isoform previously shown to bind to DENV-2 NS5, did not substantially affect DENV-2 NS5 nuclear localization, whereas knockdown of importin-β did. The serotypic differences in NS5 nuclear localization did not correlate with differences in IL-8 gene expression. The results show that NS5 nuclear localization is not strictly required for virus replication but is more likely to have an auxiliary function in the life cycle of specific DENV serotypes.     

Nuclear Localization of Fructose 1,6-bisphosphatase in Smooth Muscle Cells

Summary Fructose 1,6-bisphosphatase (FBPase) – a key enzyme of gluconeogenesis – for a long time was regarded to be soluble, and freely diffused in the cytoplasm. Our recent investigation revealed however, that in skeletal muscles of mammals, FBPase is located on both sides of the Z-line and, in cardiomyocytes, it is also present inside the cells’ nuclei. In the current paper we demonstrate that, in smooth muscle cells, FBPase is located in the cytoplasm and the nucleus, and that the presence of the enzyme in the nucleus is almost completely restricted to the heterochromatin area. In search for additional evidence for the nuclear localization of FBPase and for a possible explanation of its role in the nucleus, we have analyzed the primary structures of muscle FBPases, finding on their molecular surface a number of domains specific for proteins transported into the nucleus.     

Expanding the Definition of the Classical Bipartite Nuclear Localization Signal

Nuclear localization signals (NLSs) are amino acid sequences that target cargo proteins into the nucleus. Rigorous characterization of NLS motifs is essential to understanding and predicting pathways for nuclear import. The best‐characterized NLS is the classical NLS (cNLS), which is recognized by the cNLS receptor, importin‐α. cNLSs are conventionally defined as having one (monopartite) or two clusters of basic amino acids separated by a 9‐12 aa linker (bipartite). Motivated by the finding that Ty1 integrase, which contains an unconventional putative bipartite cNLS with a 29 aa linker, exploits the classical nuclear import machinery, we assessed the functional boundaries for linker length within a bipartite cNLS. We confirmed that the integrase cNLS is a bona fide bipartite cNLS, then carried out a systematic analysis of linker length in an obligate bipartite cNLS cargo, which revealed that some linkers longer than conventionally defined can function in nuclear import. Linker function is dependent on the sequence and likely the inherent flexibility of the linker. Subsequently, we interrogated the Saccharomyces cerevisiae proteome to identify cellular proteins containing putative long bipartite cNLSs. We experimentally confirmed that Rrp4 contains a bipartite cNLS with a 25 aa linker. Our studies show that the traditional definition of bipartite cNLSs is too restrictive and linker length can vary depending on amino acid composition.     

Recruitment and the Role of Nuclear Localization in Polyglutamine-mediated Aggregation

The inherited neurodegenerative diseases caused by an expanded glutamine repeat share the pathologic feature of intranuclear aggregates or inclusions (NI). Here in cell-based studies of the spinocerebellar ataxia type-3 disease protein, ataxin-3, we address two issues central to aggregation: the role of polyglutamine in recruiting proteins into NI and the role of nuclear localization in promoting aggregation. We demonstrate that full-length ataxin-3 is readily recruited from the cytoplasm into NI seeded either by a pathologic ataxin-3 fragment or by a second unrelated glutamine-repeat disease protein, ataxin-1. Experiments with green fluorescence protein/polyglutamine fusion proteins show that a glutamine repeat is sufficient to recruit an otherwise irrelevant protein into NI, and studies of human disease tissue and a Drosophila transgenic model provide evidence that specific glutamine-repeat–containing proteins, including TATA-binding protein and Eyes Absent protein, are recruited into NI in vivo. Finally, we show that nuclear localization promotes aggregation: an ataxin-3 fragment containing a nonpathologic repeat of 27 glutamines forms inclusions only when targeted to the nucleus. Our findings establish the importance of the polyglutamine domain in mediating recruitment and suggest that pathogenesis may be linked in part to the sequestering of glutamine-containing cellular proteins. In addition, we demonstrate that the nuclear environment may be critical for seeding polyglutamine aggregates.     

Identification of the Nuclear Export and Adjacent Nuclear Localization Signals for ORF45 of Kaposi's Sarcoma-Associated Herpesvirus

Open reading frame 45 (ORF45) of Kaposi''s sarcoma-associated herpesvirus 8 (KSHV) is an immediate-early phosphorylated tegument protein and has been shown to play important roles at both early and late stages of viral infection. Homologues of ORF45 exist only in gammaherpesviruses, and their homology is limited. These homologues differ in their protein lengths and subcellular localizations. We and others have reported that KSHV ORF45 is localized predominantly in the cytoplasm, whereas its homologue in murine herpesvirus 68 is localized exclusively in the nucleus. We observed that ORF45s of rhesus rhadinovirus and herpesvirus saimiri are found exclusively in the nucleus. As a first step toward understanding the mechanism underlying the distinct intracellular distribution of KSHV ORF45, we identified the signals that control its subcellular localization. We found that KSHV ORF45 accumulated rapidly in the nucleus in the presence of leptomycin B, an inhibitor of CRM1 (exportin 1)-dependent nuclear export, suggesting that it could shuttle between the nucleus and cytoplasm. Mutational analysis revealed that KSHV ORF45 contains a CRM1-dependent, leucine-rich-like nuclear export signal and an adjacent nuclear localization signal. Replacement of the key residues with alanines in these motifs of ORF45 disrupts its shuttling between the cytoplasm and nucleus. The resulting ORF45 mutants have restricted subcellular localizations, being found exclusively either in the cytoplasm or in the nucleus. Recombinant viruses were reconstituted by introduction of these mutations into KSHV bacterial artificial chromosome BAC36. The resultant viruses have distinct phenotypes. A mutant virus in which ORF45 is restricted to the cytoplasm behaves as an ORF45-null mutant and produces 5- to 10-fold fewer progeny viruses than the wild type. In contrast, mutants in which the ORF45 protein is mostly restricted to the nucleus produce numbers of progeny viruses similar to those produced by the wild type. These data suggest that the subcellular localization signals of ORF45 have important functional roles in KSHV lytic replication.Kaposi''s sarcoma-associated herpesvirus (KSHV) is a DNA tumor virus and the causative agent of several human cancers, including Kaposi''s sarcoma (KS), primary effusion lymphoma, and multicentric Castleman''s disease (3, 6). Like all herpesviruses, KSHV has two alternative life cycles, a latent and a lytic cycle. During latency, only a few viral genes are expressed, and no progeny viruses are produced. Under appropriate conditions, latent viral genomes are activated, initiate lytic replication, and express a full panel of viral genes, in a process that leads to viral assembly, release of progeny virus particles, and de novo infection of naïve cells (3, 6). KSHV establishes latent infection in the majority of infected cells in cases of KS, primary effusion lymphoma, and multicentric Castleman''s disease, but lytic replications occur in a small fraction. The recurrent and periodic lytic cycles of KSHV are believed to play critical roles in viral pathogenesis (6, 7).Open reading frame 45 (ORF45) is a KSHV-encoded gene product that plays a critical role in the viral lytic cycle. It is an immediate-early protein and is also present in viral particles as tegument protein (26, 27, 30). Disruption of ORF45 has no significant effect on overall viral lytic gene expression or DNA replication in BAC36-reconstituted 293T cells induced with both tetradecanoyl phorbol acetate (TPA) and sodium butyrate together, but the ORF45-null mutant produces 5- to 10-fold fewer progeny viruses than the wild type and the mutant virus has dramatically reduced infectivity, suggesting that ORF45 plays important roles at both early and late stages of viral infection (29). In addition to its roles as a tegument component, which are possibly involved in viral ingress and egress processes, KSHV ORF45 interacts with cellular proteins and modulates the cellular environment. At least two such functions have been described. First, KSHV ORF45 inhibits activation of interferon regulatory factor 7 (IRF-7) and therefore antagonizes the host innate antiviral response (28). Second, KSHV ORF45 interacts with p90 ribosomal kinase 1 and 2 (RSK1/RSK2) and modulates the extracellular signal-regulated kinase/RSK signaling pathway, which is known to play essential roles in KSHV reactivation and lytic replication (12). All of these data suggest that KSHV ORF45 is a multifunctional protein.ORF45 is unique to the gammaherpesviruses; it has no homologue in the alpha- or betaherpesviruses. ORF45 homologues have been identified as virion protein components in other gammaherpesviruses, such as Epstein-Barr virus (EBV), rhesus rhadinovirus (RRV), and murine herpesvirus 68 (MHV-68), suggesting that certain tegument functions of ORF45 are conserved (2, 11, 18). ORF45 homologues differ in protein length. KSHV ORF45 is the longest, at 407 amino acids (aa); RRV, EBV, MHV-68, and herpesvirus saimiri (HVS) have proteins of 353, 217, 206, and 257 aa, respectively. The limited homologies lie mostly at the amino- and carboxyl-terminal ends. The middle portion of KSHV ORF45 diverges from those of its homologues. The homologues differ in subcellular localization. We and others have reported previously that KSHV ORF45 is found predominantly in the cytoplasm (1, 21, 28, 30), whereas ORF45 of MHV-68 is found exclusively in the nucleus (9). Recently, we found KSHV ORF45 also present in the nuclei of BCBL-1 cells in what resembled viral replication compartments, suggesting that ORF45 could shuttle into the nucleus (12).Nucleocytoplasmic trafficking of proteins across the nuclear membrane occurs through nuclear pore complexes. Small molecules of up to approximately 9 nm in diameter, corresponding to a globular protein of approximately 40 to 60 kDa, can in principle enter or leave the nucleus by diffusion through nuclear pores (15, 17, 24). Large molecules are transported with the aid of a related family of transport factors, importins and exportins, which recognize nuclear localization sequence (NLS)-containing or nuclear export sequence (NES)-containing proteins (15, 17, 23). CRM1 (exportin 1) has been identified as a common export receptor that recognizes human immunodeficiency virus Rev-like leucine-rich NES sequences and is responsible for the export of such NES-containing proteins (4, 5, 19, 22). CRM1-dependent nuclear export is specifically inhibited by a pharmacological compound, leptomycin B (LMB), that interacts with CRM1 and thus blocks such NES-mediated protein export (4).To understand the mechanism underlying the distinct intracellular distribution of KSHV ORF45, we attempted to locate the signals that control its subcellular localization. In the research reported here, we identified a leucine-rich NES and an adjacent basic NLS in KSHV ORF45. We demonstrated that the regulated intracellular trafficking of ORF45, especially its translocation into the nucleus, is important for KSHV lytic replication.     

Coordinate Nuclear Targeting of the FANCD2 and FANCI Proteins via a FANCD2 Nuclear Localization Signal

Fanconi anemia (FA) is a rare recessive disease, characterized by congenital defects, bone marrow failure, and increased cancer susceptibility. FA is caused by biallelic mutation of any one of sixteen genes. The protein products of these genes function cooperatively in the FA-BRCA pathway to repair DNA interstrand crosslinks (ICLs). A central step in the activation of this pathway is the monoubiquitination of the FANCD2 and FANCI proteins. Monoubiquitinated FANCD2 and FANCI localize to discrete chromatin regions where they function in ICL repair. Despite their critical role in ICL repair, very little is known about the structure, function, and regulation of the FANCD2 and FANCI proteins, or how they are targeted to the nucleus and chromatin. In this study, we describe the functional characterization of an amino-terminal FANCD2 nuclear localization signal (NLS). We demonstrate that the amino terminal 58 amino acids of FANCD2 can promote the nuclear expression of GFP and is necessary for the nuclear localization of FANCD2. Importantly, mutation of this FANCD2 NLS reveals that intact FANCD2 is required for the nuclear localization of a subset of FANCI. In addition, the NLS is necessary for the efficient monoubiquitination of FANCD2 and FANCI and, consequently, for their localization to chromatin. As a result, FANCD2 NLS mutants fail to rescue the ICL sensitivity of FA-D2 patient cells. Our studies yield important insight into the domain structure of the poorly characterized FANCD2 protein, and reveal a previously unknown mechanism for the coordinate nuclear import of a subset of FANCD2 and FANCI, a key early step in the cellular ICL response.     

Nuclear Localization of p38 MAPK in Response to DNA Damage

p38 MAP kinase (MAPK) is activated in response to environmental stress, cytokines and DNA damage, and mediates death, cell differentiation and cell cycle checkpoints. The intracellular localization of p38 MAPK upon activation remains unclear, and may depend on the stimulus. We show here that activation of p38 MAPK by stimuli that induce DNA double strand breaks (DSBs), but not other stimuli, leads to its nuclear translocation. In addition, naturally occurring DSBs generated through V(D)J recombination in immature thymocytes also promote nuclear accumulation of p38 MAPK. Nuclear translocation of p38 MAPK does not require its catalytic activity, but is induced by a conformational change of p38 MAPK triggered by phosphorylation within the active site. The selective nuclear accumulation of p38 MAPK in response to DNA damage could be a mechanism to facilitate the phosphorylation of p38 MAPK nuclear targets for the induction of a G2/M cell cycle checkpoint and DNA repair.