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.     

Nuclear localization of enhanced green fluorescent protein homomultimers

The green fluorescent protein (GFP) and its variants are used in many studies to determine the subcellular localization of other proteins by analyzing fusion proteins. The main problem for nuclear localization studies is the fact that, to some extent, GFP translocates to the nucleus on its own. Because the nuclear import could be due to unspecific diffusion of the relatively small GFP through the nuclear pores, we analyzed the localization of multimers of a GFP variant, the enhanced GFP (EGFP). By detecting the fluorescence of the expressed proteins in gels after nonreducing SDS-PAGE, we demonstrate the integrity of the expressed proteins. Nevertheless, even EGFP homotetramers and homohexamers are found in the nuclei of the five analyzed mammalian cell lines. The use of fusion constructs of small proteins with multimeric EGFP alone, therefore, is not adequate to prove nuclear import processes. Fusion to tetrameric EGFP in combination with a careful quantification of the fluorescence intensities in the nucleus and cytoplasm might be sufficient in many cases to identify a significant difference between the fusion protein and tetrameric EGFP alone to deduce a nuclear localization signal.     

Visual and both non-visual arrestins in their "inactive" conformation bind JNK3 and Mdm2 and relocalize them from the nucleus to the cytoplasm

Arrestins bind active phosphorylated G protein-coupled receptors, terminating G protein activation. Receptor-bound non-visual arrestins interact with numerous partners, redirecting signaling to alternative pathways. Arrestins also have nuclear localization and nuclear exclusion signals and shuttle between the nucleus and the cytoplasm. Constitutively shuttling proteins often redistribute their interaction partners between the two compartments. Here we took advantage of the nucleoplasmic shuttling of free arrestins and used a "nuclear exclusion assay" to study their interactions with two proteins involved in "life-and-death" decisions in the cell, the kinase JNK3 and the ubiquitin ligase Mdm2. In human embryonic kidney 293 cells green fluorescent protein (GFP)-JNK3 and GFP-Mdm2 predominantly localize in the nucleus, whereas visual arrestin, arrestin2(Q394L) mutant equipped with the nuclear exclusion signal, and arrestin3 localize exclusively to the cytoplasm. Coexpression of arrestins moves both GFP-JNK3 and GFP-Mdm2 to the cytoplasm. Arrestin mutants "frozen" in the basal conformation are the most efficacious. Thus, arrestins in their basal state interact with JNK3 and Mdm2, suggesting that arrestins are likely "preloaded" with their interaction partners when they bind the receptor. Robust interaction of free arrestins with JNK3 and Mdm2 and their ability to regulate subcellular localization of these proteins may play an important role in the survival of photoreceptors and other neurons, as well as in retinal and neuronal degeneration.     

Nuclear targeting is required for hepatoma-derived growth factor-stimulated mitogenesis in vascular smooth muscle cells

We recently identified hepatoma-derived growth factor (HDGF) as a nuclear targeted vascular smooth muscle cell (VSM) mitogen that is expressed in developing vascular lesions. In the present study, VSM in culture express endogenous HDGF only in the nucleus and target a green fluorescent protein (GFP)-HDGF fusion to the nucleus. To define the features of the HDGF molecule that are essential for nuclear localization and mitogenic function, deletion and site-directed mutagenesis were performed. Deletion analysis identified the carboxyl-terminal half of HDGF to be responsible for nuclear targeting in VSM. Overexpression of tagged HDGF proteins with point mutations in the putative bipartite nuclear localization sequence in the carboxyl terminus demonstrated that single Lys --> Asn mutations randomized HDGF expression to both the nucleus and cytoplasm similar to the empty vector. Importantly, the Lys --> Asn mutation of all three lysines blocked nuclear entry. Point mutation of a p34(cdc2) kinase consensus motif within the nuclear localization sequence had no effect on nuclear targeting. Moreover, nuclear entry was essential for the HDGF mitogenic effect, as transfection with the triple Lys --> Asn mutant HA-HDGF significantly attenuated bromodeoxyuridine uptake when compared with transfection with wild type HA-HDGF. We conclude that HDGF contains a true bipartite nuclear localization sequence with all three lysines necessary for nuclear targeting. Nuclear targeting of HDGF is required for HDGF stimulation of DNA replication in VSM.     

Nuclear transport of plant potyviral proteins.

We have used immunoblotting, immunocytochemical, and gene fusion methods to examine the differential subcellular partitioning of tobacco etch potyvirus proteins that are potentially associated with RNA replication. From the earliest timepoints at which viral proteins could be detected, proteins Nla (49-kilodalton proteinase) and Nlb (58-kilodalton polymerase) were localized primarily in the nucleus, whereas the 71-kilodalton cylindrical inclusion protein was identified in the cytoplasm. The Nla and Nlb coding regions were fused to the beta-glucuronidase (GUS) sequence in a plant expression vector, resulting in synthesis of chimeric proteins in transfected protoplasts and in transgenic plants. In situ localization of GUS activity revealed nuclear localization of the GUS-Nla and GUS-Nlb fusion proteins and cytoplasmic localization of nonfused GUS. These results indicate that both Nla and Nlb contain nuclear targeting signals, and that they may serve as useful models for studies of plant cell nuclear transport. A discussion of the general utility of the nuclear transport system described here, as well as the role of nuclear translocation of potyviral proteins, is presented.     

Live-cell nucleocytoplasmic protein shuttle assay utilizing laser confocal microscopy and FRAP.

In eukaryotes, protein trafficking to and from the nucleus, or shuttling, has been demonstrated to be an important function for proteins that have vital roles in one or both subcellular compartments. Current techniques of detecting protein nuclear shuttling are extremely labor intensive and only statically visualize evidence of shuttling. Fluorescence recovery after photobleaching (FRAP), or fluorescence microphotolysis, has proven to be an effective method of analyzing protein dynamics in live cells, especially when coupled to GFP technology. Here, we describe a relatively simple in vivo protein nuclear shuttling assay that utilizes red fluorescent and green fluorescent protein fusions as substrates for FRAP using a laser confocal microscope. This technique is less time consuming than established shuttle assays, is internally controlled, and visualizes nucleocytoplasmic shuttling in living cells of the same species and cell type. This technique can be potentially used to detect the ability of any nuclear protein to shuttle from the nucleus to any other subcellular compartment for any eukaryotic species in which GFP or dsRed1 fusion protein can be expressed.     

Nuclear import and export signals enable rapid nucleocytoplasmic shuttling of the atypical protein kinase C lambda

The atypical protein kinase C (PKC) isoenzymes, lambda/iota- and zetaPKC, play important roles in cellular signaling pathways regulating proliferation, differentiation, and cell survival. By using green fluorescent protein (GFP) fusion proteins, we found that wild-type lambdaPKC localized predominantly to the cytoplasm, whereas both a kinase-defective mutant and an activation loop mutant accumulated in the nucleus. We have mapped a functional nuclear localization signal (NLS) to the N-terminal part of the zinc finger domain of lambdaPKC. Leptomycin B treatment induced rapid nuclear accumulation of GFP-lambda as well as endogenous lambdaPKC suggesting the existence of a CRM1-dependent nuclear export signal (NES). Consequently, we identified a functional leucine-rich NES in the linker region between the zinc finger and the catalytic domain of lambdaPKC. The presence of both the NLS and NES enables a continuous shuttling of lambdaPKC between the cytoplasm and nucleus. Our results suggest that the exposure of the NLS in both lambda- and zetaPKC is regulated by intramolecular interactions between the N-terminal part, including the pseudosubstrate sequence, and the catalytic domain. Thus, either deletion of the N-terminal region, including the pseudosubstrate sequence, or a point mutation in this sequence leads to nuclear accumulation of lambdaPKC. The ability of the two atypical PKC isoforms to enter the nucleus in HeLa cells upon leptomycin B treatment differs substantially. Although lambdaPKC is able to enter the nucleus very rapidly, zetaPKC is much less efficiently imported into the nucleus. This difference can be explained by the different relative strengths of the NLS and NES in lambdaPKC compared with zetaPKC.     

Yeast karyopherin Kap95 is required for cell cycle progression at Start

Background  

The control of the subcellular localization of cell cycle regulators has emerged as a crucial mechanism in cell division regulation. The active transport of proteins between the nucleus and the cytoplasm is mediated by the transport receptors of the β-karyopherin family. In this work we characterized the terminal phenotype of a mutant strain in β-karyopherin Kap95, a component of the classical nuclear import pathway.     

Cytoplasmic, nuclear, and golgi localization of RGS proteins. Evidence for N-terminal and RGS domain sequences as intracellular targeting motifs

RGS proteins comprise a family of proteins named for their ability to negatively regulate heterotrimeric G protein signaling. Biochemical studies suggest that members of this protein family act as GTPase-activating proteins for certain Galpha subunits, thereby accelerating the turn-off mechanism of Galpha and terminating signaling by both Galpha and Gbetagamma subunits. In the present study, we used confocal microscopy to examine the intracellular distribution of several RGS proteins in COS-7 cells expressing RGS-green fluorescent protein (GFP) fusion proteins and in cells expressing RGS proteins endogenously. RGS2 and RGS10 accumulated in the nucleus of COS-7 cells transfected with GFP constructs of these proteins. In contrast, RGS4 and RGS16 accumulated in the cytoplasm of COS-7 transfectants. As observed in COS-7 cells, RGS4 exhibited cytoplasmic localization in mouse neuroblastoma cells, and RGS10 exhibited nuclear localization in human glioma cells. Deletion or alanine substitution of an N-terminal leucine repeat motif present in both RGS4 and RGS16, a domain identified as a nuclear export sequence in HIV Rev and other proteins, promoted nuclear localization of these proteins in COS-7 cells. In agreement with this observation, treatment of mouse neuroblastoma cells with leptomycin B to inhibit nuclear protein export by exportin1 resulted in accumulation of RGS4 in the nucleus of these cells. GFP fusions of RGS domains of RGS proteins localized in the nucleus, suggesting that nuclear localization of RGS proteins results from nuclear targeting via RGS domain sequences. RGSZ, which shares with RGS-GAIP a cysteine-rich string in its N-terminal region, localized to the Golgi complex in COS-7 cells. Deletion of the N-terminal domain of RGSZ that includes the cysteine motif promoted nuclear localization of RGSZ. None of the RGS proteins examined were localized at the plasma membrane. These results demonstrate that RGS proteins localize in the nucleus, the cytoplasm, or shuttle between the nucleus and cytoplasm as nucleo-cytoplasmic shuttle proteins. RGS proteins localize differentially within cells as a result of structural differences among these proteins that do not appear to be important determinants for their G protein-regulating activities. These findings suggest involvement of RGS proteins in more complex cellular functions than currently envisioned.     

Protein transduction of an antioxidant enzyme: subcellular localization of superoxide dismutase fusion protein in cells

In protein therapy, it is important for exogenous protein to be delivered into the target subcellular localization. To transduce a therapeutic protein into its specific subcellular localization, we synthesized nuclear localization signal (NLS) and membrane translocation sequence signal (MTS) peptides and produced a genetic in-frame SOD fusion protein. The purified SOD fusion proteins were efficiently transduced into mammalian cells with enzymatic activities. Immunofluorescence and Western blot analysis revealed that the SOD fusion proteins successfully transduced into the nucleus and the cytosol in the cells. The viability of cells treated with paraquat was markedly increased by the transduced fusion proteins. Thus, our results suggest that these peptides should be useful for targeting the specific localization of therapeutic proteins in various human diseases.     

Nuclear localization of angiotensinogen in astrocytes

In the brain, angiotensinogen (AGT) is primarily expressed in astrocytes; brain ANG II derived from locally produced AGT has been shown to influence blood pressure. To better understand the molecular basis of AGT expression in the brain, we identified a human astrocytoma cell line, CCF-STTG1, that expresses endogenous AGT mRNA and produces AGT protein. Studies examining CCF-STTG1 cell AGT after N- and O-glycosidase suggest that AGT may not be posttranslationally modified by glycosylation in these cells as it is in plasma. Small amounts of AGT (5% of HepG2) were detected in the culture medium, suggesting a low rate of AGT secretion. Immunocytochemical examination of AGT in CCF-STTG1 cells revealed mainly nuclear localization. Although this has not been previously reported, it is consistent with nuclear localization of other serpin family members. To examine this further, we generated a fusion protein consisting of green fluorescent protein (GFP) and human AGT and examined subcellular localization by confocal microscopy after confirming expression of the fusion protein by Western blot. In CCF-STTG1 cells, a control GFP construct lacking AGT was mainly localized in the cytoplasm, whereas the GFP-AGT fusion protein was primarily localized in the nucleus. To map the location of a potential nuclear localization signal, overlapping 500-bp fragments of human AGT cDNA were fused in frame downstream of GFP. Although four of the fusion proteins exhibited either perinuclear or cytoplasmic localization, one fusion protein encoding the COOH terminus of AGT was localized in the nucleus. Importantly, nuclear localization of human AGT was confirmed in primary cultures of glial cells isolated from transgenic mice expressing the human AGT under the control of its own endogenous promoter. Our results suggest that AGT may have a novel intracellular role in the brain apart from its predicted endocrine function.     

Regulation of subcellular localization of the antiproliferative protein Tob by its nuclear export signal and bipartite nuclear localization signal sequences

Tob, a member of the Tob and BTG antiproliferative protein family, plays an important role in many cellular processes including cell proliferation. In this study, we have addressed molecular mechanisms regulating subcellular localization of Tob. Treatment with leptomycin B, an inhibitor of nuclear export signal (NES) receptor, resulted in a change in subcellular distribution of Tob from its pan-cellular distribution to nuclear accumulation, indicating the existence of NES in Tob. Our results have then identified an N-terminal region (residues 2-14) of Tob as a functional NES. They have also shown that Tob has a functional, bipartite nuclear localization signal (NLS) in residues 18-40. Thus, Tob is shuttling between the nucleus and the cytoplasm by its NES and NLS. To examine a possible relationship between subcellular distribution of Tob and its function, we exogenously added a strong NLS sequence or a strong NES sequence or both to Tob. The obtained results have demonstrated that the strong NLS-added Tob has a much weaker activity to inhibit cell cycle progression from G0/G1 to S phase. These results suggest that cytoplasmic localization or nucleocytoplasmic shuttling is important for the antiproliferative function of Tob.     

Alteration of poly(ADP-ribose) glycohydrolase nucleocytoplasmic shuttling characteristics upon cleavage by apoptotic proteases

Poly(ADP-ribosyl)ation is an important post-translational modification which mostly affects nuclear proteins. The major roles of poly(ADP-ribose) synthesis are assigned to DNA damage signalling during base excision repair, apoptosis and excitotoxicity. The transient nature and modulation of poly(ADP-ribose) levels depend mainly on the activity of poly(ADP-ribose) polymerase-1 (PARP-1) and poly(ADP-ribose) glycohydrolase (PARG), the key catabolic enzyme of poly(ADP-ribose). Given the fact that PARG substrate, poly(ADP-ribose), is found almost exclusively in the nucleus and that PARG is mainly localized in the cytoplasm, we wanted to have a closer look at PARG subcellular localization in order to better understand the mechanism by which PARG regulates intracellular poly(ADP-ribose) levels. We examined the subcellular distribution of PARG and of its two enzymatically active C-terminal apoptotic fragments both biochemically and by fluorescence microscopy. Green fluorescent protein (GFP) fusion proteins were constructed for PARG (GFP-PARG), its 74 kDa (GFP-74) and 85 kDa (GFP-85) apoptotic fragments and transiently expressed in COS-7 cells. Localization experiments reveal that all three fusion proteins localize predominantly to the cytoplasm and that a fraction also co-localizes with the Golgi marker FTCD. Moreover, leptomycin B, a drug that specifically inhibits nuclear export signal (NES)-dependent nuclear export, induces a redistribution of GFP-PARG from the cytoplasm to the nucleus and this nuclear accumulation is even more pronounced for the GFP-74 and GFP-85 apoptotic fragments. This observation confirms our hypothesis for the presence of important regions in the PARG sequence that would allow the protein to engage in CRM1-dependent nuclear export. Moreover, the altered nuclear import kinetics found for the apoptotic fragments highlights the importance of PARG N-terminal sequence in modulating PARG nucleocytoplasmic trafficking properties.