The NPI-1/NPI-3 (karyopherin alpha) binding site on the influenza a virus nucleoprotein NP is a nonconventional nuclear localization signal.

Two cellular proteins, NPI-1 and NPI-3, were previously identified through their interaction with the influenza virus nucleoprotein (NP) by using the yeast two-hybrid system. These proteins were then shown to act as general transport factors (karyopherin alpha) and nuclear pore-docking proteins to facilitate the transport of the NP and of viral RNA into the nucleus. The yeast two-hybrid assay has now been used to identify the specific domains on the NP that bind to the NPI proteins. Mutational analysis including alanine scanning identified the motifs SxGTKRSYxxM and TKRSxxxM, which are required for binding to NPI-1 and NPI-3, respectively. These sequences were shown to possess nuclear localization signal (NLS) activity following expression of fusion proteins in HeLa cells. These sequences represent a novel nonconventional NLS motif. Another NLS activity not mediated by the NPI binding sites is associated with noncontiguous sequences in the NP.     

Characterization of the maize Mutator transposable element MURA transposase as a DNA-binding protein.

The autonomous MuDR element of the Mutator (Mu) transposable element family of maize encodes at least two proteins, MURA and MURB. Based on amino acid sequence similarity, previous studies have reported that MURA is likely to be a transposase. The functional characterization of MURA has been hindered by the instability of its cDNA, mudrA, in Escherichia coli. In this study, we report the first successful stabilization and expression of MURA in Saccharomyces cerevisiae. Gel mobility shift assays demonstrate that MURA is a DNA-binding protein that specifically binds to sequences within the highly conserved Mu element terminal inverted repeats (TIRs). DNase I and 1,10-phenanthroline-copper footprinting of MURA-Mu1 TIR complexes indicate that MURA binds to a conserved approximately 32-bp region in the TIR of Mu1. In addition, MURA can bind to the same region in the TIRs of all tested actively transposing Mu elements but binds poorly to the diverged Mu TIRs of inactive elements. Previous studies have reported a correlation between Mu transposon inactivation and methylation of the Mu element TIRs. Gel mobility shift assays demonstrate that MURA can interact differentially with unmethylated, hemimethylated, and homomethylated TIR substrates. The significance of MURA's interaction with the TIRs of Mu elements is discussed in the context of what is known about the regulation and mechanisms of Mutator activities in maize.     

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     

Identification of a karyopherin alpha 2 recognition site in PLAG1, which functions as a nuclear localization signal

The activation of the pleomorphic adenoma gene 1 (PLAG1) is the most frequent gain-of-function mutation found in pleomorphic adenomas of the salivary glands. To gain more insight into the regulation of PLAG1 function, we searched for PLAG1-interacting proteins. Using the yeast two-hybrid system, we identified karyopherin alpha2 as a PLAG1-interacting protein. Physical interaction between PLAG1 and karyopherin alpha2 was confirmed by an in vitro glutathione S-transferase pull-down assay. Karyopherin alpha2 escorts proteins into the nucleus via interaction with a nuclear localization sequence (NLS) composed of short stretches of basic amino acids. Two putative NLSs were identified in PLAG1. The predicted NLS1 (KRKR) was essential for physical interaction with karyopherin alpha2 in glutathione S-transferase pull-down assay, and its mutation resulted in decreased nuclear import of PLAG1. Moreover, NLS1 was able to drive the nuclear import of the cytoplasmic protein beta-galactosidase. In contrast, predicted NLS2 of PLAG1 (KPRK) was not involved in karyopherin alpha2 binding nor in its nuclear import. The residual nuclear import of PLAG1 after mutation of the NLS1 was assigned to the zinc finger domain of PLAG1. These observations indicate that the nuclear import of PLAG1 is governed by its zinc finger domain and by NLS1, a karyopherin alpha2 recognition site.     

Interactions and nuclear import of the N and P proteins of sonchus yellow net virus, a plant nucleorhabdovirus

We have characterized the interaction and nuclear localization of the nucleocapsid (N) protein and phosphoprotein (P) of sonchus yellow net nucleorhabdovirus. Expression studies with plant and yeast cells revealed that both N and P are capable of independent nuclear import. Site-specific mutagenesis and deletion analyses demonstrated that N contains a carboxy-terminal bipartite nuclear localization signal (NLS) located between amino acids 465 and 481 and that P contains a karyophillic region between amino acids 40 and 124. The N NLS was fully capable of functioning outside of the context of the N protein and was able to direct the nuclear import of a synthetic protein fusion consisting of green fluorescent protein fused to glutathione S-transferase (GST). Expression and mapping studies suggested that the karyophillic domain in P is located within the N-binding domain. Coexpression of N and P drastically affected their localization patterns relative to those of individually expressed proteins and resulted in a shift of both proteins to a subnuclear region. Yeast two-hybrid and GST pulldown experiments verified the N-P and P-P interactions, and deletion analyses have identified the N and P interacting domains. N NLS mutants were not transported to the nucleus by import-competent P, presumably because N binding masks the P NLS. Taken together, our results support a model for independent entry of N and P into the nucleus followed by associations that mediate subnuclear localization.     

Karyopherin-alpha2 protein interacts with Chk2 and contributes to its nuclear import

Chk2 is a nuclear protein kinase involved in the DNA damage-induced ataxia telangiectasia mutated-dependent checkpoint arrest at multiple cell cycle phases. Searching for Chk2-binding proteins by a yeast two-hybrid system, we identified a strong interaction with karyopherin-alpha2 (KPNA-2), a gene product involved in active nuclear import of proteins bearing a nuclear localization signal (NLS). This finding was confirmed by glutathione S-transferase pull-down and co-immunoprecipitation assays. Of the three predicted Chk2 NLSs, located at amino acids 179-182 (NLS-1), 240-256 (NLS-2), and 515-522 (NLS-3), only the latter mediated the interaction with KPNA-2 in the yeast two-hybrid system, and in particular with its C terminus. Unlike mutations in NLS-1 or NLS-2, which left the nuclear localization of Chk2 unaffected, mutations in NLS-3 caused a cytoplasmic relocalization, indicating that the NLS-3 motif acts indeed as NLS for Chk2 in vivo. Finally, co-transfection experiments with green fluorescent protein (GFP)-Chk2 and wild type or mutant KPNA-2 confirmed the role of KPNA-2 in nuclear import of Chk2.     

Tsp57: a novel gene induced during a specific stage of spermatogenesis

Recently, we described the identification of a novel protein, nuclear receptor-associated protein 80 (RAP80), which is highly expressed in spermatocytes and appears to have a role in regulating gene expression. To identify proteins interacting with this protein, we performed yeast two-hybrid screening using full-length RAP80 as bait. This screen identified one in-frame clone encoding a novel testis-specific protein (Tsp), referred to as Tsp57. Tsp57 encodes a basic protein with a mass of 56.8 kDa. The amino acid sequence of Tsp57 is highly conserved (87%) between mouse and human. The mouse and human Tsp57 genes map to chromosomes 9A1 and 11q21, respectively. Northern blot analysis showed that the expression of Tsp57 mRNA was highly restricted to the testis and temporally regulated during testicular development. Tsp57 mRNA was greatly induced between Day 21 and Day 25 of postnatal testicular development. In situ hybridization analysis demonstrated that the hybridization signal for Tsp57 mRNA was strongest in sections of seminiferous tubules at stages VI-VIII of spermatogenesis, consistent with the conclusion that Tsp57 is most highly expressed in round spermatids. Study of Tsp57 expression in several purified subpopulations of spermatogenic cells confirmed maximum levels of expression in round spermatids. Consistently, Tsp57 expression was absent in testes from vitamin A-deficient mice, which do not have any round spermatids, and was reduced in RARalpha null mice, which have lowered numbers of round spermatids in their testes. These results indicate the possibility that Tsp57 protein plays a role in the postmeiotic phase of germ cell differentiation. Tsp57 contains two putative nuclear localization signals: NLS1 and NLS2. Examination of the cellular localization showed that the green fluorescent protein-Tsp57 fusion protein localized to both cytoplasm and nucleus. After deletion of NLS1 but not NLS2, Tsp57 localized solely to the cytoplasm, indicating a role for NLS1 in the nuclear localization of Tsp57. The localization suggests a nuclear function for Tsp57. Pull-down analysis demonstrated that Tsp57 and RAP80 form a complex in intact cells.     

Molecular Control of Nuclear and Subnuclear Targeting of the Plant CDK Inhibitor ICK1 and ICK1-Mediated Nuclear Transport of CDKA

ICK1 is the first member of a family of plant cyclin-dependent kinase (CDK) inhibitors. It has been shown that ICK1 is localized in the nuclei of transgenic Arabidopsis plants. Since cellular localization is important for the functions of cell cycle regulators, a comprehensive analysis was undertaken to identify specific sequences regulating the cellular localization of ICK1. Deletion and site-specific mutants fused to the green fluorescent protein (GFP) were used in transgenic Arabidopsis plants and transfected tobacco cells. Surprisingly, three separate sequences in the N-terminal, central and C-terminal regions of ICK1 could independently confer nuclear localization of the GFP fusion proteins. The central nuclear localization signal NLS^ICK1 could transport the much larger GUS (β-glucuronidase)-GFP fusion protein into nuclei, while the other two sequences were unable to. These results suggest that NLS^ICK1 is a strong NLS that actively transports the fusion protein into nuclei, while the other two sequences are either a weaker NLS or confer the nuclear localization of GFP indirectly. It was further observed that the N-terminal sequence specifies a punctate pattern of subnuclear localization, while the C-terminal sequence suppresses it. Furthermore, co-expression of ICK1 and Arabidopsis CDKA, tagged with different GFP variants, showed that ICK1 could mediate the transport of CDKA into nuclei while a mutant ICK1^1–162 that does not interact with CDKA lost this ability. These results illustrate how the nuclear localization of ICK1 is regulated and also suggest a possible role of ICK1 in regulating the cellular distribution of CDKA.     

One of three nuclear localization signals of maize Activator (Ac) transposase overlaps the DNA-binding domain

The nuclear localization sequences (NLSs) of the Ac transposase (TPase) protein have been characterized by indirect immunofluorescence detection of TPase deletion derivatives and TPase/β-glucuronidase (GUS) fusion proteins in transiently transfected Petunia cells. The TPase contains three NLSs near its amino-terminal end, NLS(44–62), NLS(159–178) and NLS(174–206), each of which is sufficient to redirect GUS to the nucleus. Deletion of the N-terminal 102 TPase residues including NLS(44–62) results in strongly reduced nuclear import of the truncated TPase. NLS(44–62) and NLS(159–178) are bipartite NLSs, whereas the structure of NLS(174–206) does not allow a classification into one of the three major NLS categories. NLS(174–206) overlaps with the basic DNA-binding domain of TPase. A substitution of two amino acids in this segment (HiS₁₉₁→Arg and Arg₁₉₃→His) results in a total loss of DNA-binding activity, but retains reduced NLS activity. Accordingly, the two functions can be separated. In addition, we show that a NLS-deficient 71 kDa TPase derivative is co-imported into the nucleus in the presence of wildtype TPase.     

Identification of a single nuclear localization signal in the C-terminal domain of an Aspergillus DNA topoisomerase II

DNA topoisomerase II (topo II) is a major nuclear protein that plays an important role in DNA metabolism. We have isolated the gene for topo II ( TOP2) from the filamentous fungus Aspergillus terreus. The deduced amino acid sequence revealed that topo II consists of 1,587 amino acids and has a calculated molecular weight of 180 kDa; the protein expressed in Escherichia coli has an estimated molecular weight of 185 kDa. Expression of topo II polypeptides tagged with yellow fluorescent protein (YFP) in budding yeast suggests that the C-terminal region of the topo II is essential for transport of the fusion protein into the nucleus. The nuclear localization signal (NLS) sequence of topo II is a non-classical bipartite type containing two interdependent, positively charged clusters separated by 15 amino acids. Alanine scanning mutagenesis and deletion analyses showed further that a stretch of 23 amino acid residues (positions 1,234-1,256) is necessary for nuclear import. In addition, we confirmed, using co-immunoprecipitation and two-hybrid analysis, that this non-classical NLS interacts with importin alpha in budding yeast. These results suggest that the fungal topo II NLS is functional in yeast cells.     

Phosphorylation mediates the nuclear targeting of the maize Rab17 protein

The maize abscisic acid-responsive Rab17 protein localizes to the nucleus and cytoplasm in maize cells. In-frame fusion of Rab17 to the reporter protein β-glucuronidase (GUS) directed GUS to the nucleus and cytoplasm in transgenic Arabidopsis thaliana and in transiently transformed onion cells. Analysis of chimeric constructs identified one region between amino acid positions 66–96, which was necessary for targeting GUS to the nucleus. This region contains a serine cluster followed by a putative consensus site for protein kinase CK2 phosphorylation, and a stretch of basic amino acids resembling the simian virus 40 large T antigen-type nuclear localization signal (NLS). Mutation of two basic amino acids in the putative NLS had a weak effect on nuclear targeting in the onion cell system and did not modify the percentage of nuclear fusion protein in the Arabidopsis cells. The mutation of three amino acids in the consensus site for CK2 recognition resulted in the absence of in vitro phosphorylated forms of Rab17 and in a strong decrease of GUS enzymatic activity in isolated nuclei of transgenic Arabidopsis. These results suggest that phosphorylation of Rab17 by protein kinase CK2 is the relevant step for its nuclear location, either by facilitating binding to specific proteins or as a direct part of the nuclear targeting apparatus.     

PTEN enters the nucleus by diffusion

Despite much evidence for phosphatidylinositol phosphate (PIP)-triggered signaling pathways in the nucleus, there is little understanding of how the levels and activities of these proteins are regulated. As a first step to elucidating this problem, we determined whether phosphatase and tensin homolog deleted on chromosome 10 (PTEN) enters the nucleus by passive diffusion or active transport. We expressed various PTEN fusion proteins in tsBN2, HeLa, LNCaP, and U87MG cells and determined that the largest PTEN fusion proteins showed little or no nuclear localization. Because diffusion through nuclear pores is limited to proteins of 60,000 Da or less, this suggests that nuclear translocation of PTEN occurs via diffusion. We examined PTEN mutants, seeking to identify a nuclear localization signal (NLS) for PTEN. Mutation of K13 and R14 decreased nuclear localization, but these amino acids do not appear to be part of an NLS. We used fluorescence recovery after photobleaching (FRAP) to demonstrate that GFP-PTEN can passively pass through nuclear pores. Diffusion in the cytoplasm is retarded for the PTEN mutants that show reduced nuclear localization. We conclude that PTEN enters the nucleus by diffusion. In addition, sequestration of PTEN in the cytoplasm likely limits PTEN nuclear translocation.