Two wobble-splicing events affect ING4 protein subnuclear localization and degradation

ING4 (inhibitor of growth 4) is a candidate tumor suppressor gene that is implicated as a repressor of cell growth, angiogenesis, cell spreading and cell migration and can suppress loss of contact inhibition in vitro. Another group and we identified four wobble-splicing isoforms of ING4 generated by alternative splicing at two tandem splice sites, GC(N)₇GT and NAGNAG, which caused canonical (GT-AG) and non-canonical (GC-AG) splice site wobbling selection. Expression of the four ING4 wobble-splicing isoforms did not vary significantly in any of the cell lines examined. Here we show that ING4_v1 is translocated to the nucleolus, indicating that ING4 contains an intrinsic nucleolar localization signal. We further demonstrate that the subcellular localization of ING4 is modulated by two wobble-splicing events at the exon 4-5 boundary, causing displacement from the nucleolus to the nucleus. We also observed that ING4 is degraded through the ubiquitin-proteasome pathway and that it is subjected to N-terminal ubiquitination. We demonstrate that nucleolar accumulation of ING4 prolongs its half-life, but lack of nucleolar targeting potentially increases ING4 degradation. Taken together, our data suggest that the two wobble-splicing events at the exon 4-5 boundary influence subnuclear localization and degradation of ING4.     

Identification of the subcellular localization of mycobacterial proteins using localization motifs

Mycobacterium, the most common disease-causing genus, infects billions of people and is notoriously difficult to treat. Understanding the subcellular localization of mycobacterial proteins can provide essential clues for protein function and drug discovery. In this article, we present a novel approach that focuses on local sequence information to identify localization motifs that are generated by a merging algorithm and are selected based on a binomially distributed model. These localization motifs are employed as features for identifying the subcellular localization of mycobacterial proteins. Our approach provides more accurate results than previous methods and was tested on an independent dataset recently obtained from an experimental study to provide a first and reasonably accurate prediction of subcellular localization. Our approach can also be used for large-scale prediction of new protein entries in the UniportKB database and of protein sequences obtained experimentally. In addition, our approach identified many local motifs involved with the subcellular localization that also interact with the environment. Thus, our method may have widespread applications both in the study of the functions of mycobacterial proteins and in the search for a potential vaccine target for designing drugs.     

Characterization of nuclear localization and nuclear export signals of yeast actin-binding protein Pan1

Pan1 is an actin patch-associated protein involved in endocytosis. Our studies revealed that in oleate-grown cells Pan1 is located in the nucleus as well as in patches. One of three putative nuclear localization signals (NLS) of Pan1, NLS2, directed beta-galactosidase (beta-gal) to the nucleus. However, GFP-Pan1(886-1219), containing NLS2, was found in the cytoplasm indicating that it may contain a nuclear export signal (NES). A putative Pan1 NES, overlapping with NLS3, re-addressed NLS(H2B)-NES/NLS3-beta-gal from the nucleus to the cytoplasm. Inactivation of the NES allowed NLS3 to be effective. Thus, Pan1 contains functional NLSs and a NES and appears to shuttle in certain circumstances.     

The N-terminal region of eukaryotic translation initiation factor 5A signals to nuclear localization of the protein

The eukaryotic translation initiation factor 5A (eIF5A) is a ubiquitous protein of eukaryotic and archaeal organisms which undergoes hypusination, a unique post-translational modification. We have generated a polyclonal antibody against murine eIF5A, which in immunocytochemical assays in B16-F10 cells revealed that the endogenous protein is preferentially localized to the nuclear region. We therefore analyzed possible structural features present in eIF5A proteins that could be responsible for that characteristic. Multiple sequence alignment analysis of eIF5A proteins from different eukaryotic and archaeal organisms showed that the former sequences have an extended N-terminal segment. We have then performed in silico prediction analyses and constructed different truncated forms of murine eIF5A to verify any possible role that the N-terminal extension might have in determining the subcellular localization of the eIF5A in eukaryotic organisms. Our results indicate that the N-terminal extension of the eukaryotic eIF5A contributes in signaling this protein to nuclear localization, despite of bearing no structural similarity with classical nuclear localization signals.     

Differential subcellular targeting and activity-dependent subcellular localization of diacylglycerol kinase isozymes in transfected cells

Diacylglycerol kinase (DGK) plays a pivotal role in cellular signal transduction through regulating levels of the second messenger diacylglycerol (DG). Previous studies have revealed that DGK is composed of a family of isozymes that show remarkable heterogeneity in terms of molecular structure, functional domains, tissue and cellular gene expression. Recently, it has been shown that DG is produced in various subcellular compartments including the plasma membrane, internal membranes, cytoskeleton, and nucleus. However, it remains unclear how DG is regulated at distinct subcellular sites. To address this point, we have used an epitope-tag expression system in cultured cells and investigated the subcellular localization of DGK isozymes under the same experimental conditions. We show here that DGK isozymes are targeted differentially to unique subcellular sites in transfected COS7 cells, including the cytoplasm, actin stress fibers, Golgi complex, endoplasmic reticulum, and nucleus. It is also shown that among the isozymes overexpression of DGKbeta causes fragmentation of actin stress fibers while a kinase-dead mutant of DGKbeta abolishes its colocalization with actin stress fibers. These data strongly suggest that each isozyme may be responsible for the metabolism of DG that is produced upon stimulation at a different and specific subcellular site and that DGKbeta activity might have effects on the reorganization of actin stress fibers in transfected COS7 cells.     

Analytical subcellular fractionation of rat pituitary homogenates with special reference to the subcellular localization and properties of alkaline phosphatases

Alkaline phosphatase activities of the virgin rat anterior pituitary were studied with a highly sensitive fluorometric assay. Tissue whole homogenates were fractionated on sucrose density gradients in a Beaufay automatic zonal rotor and the gradient fractions assayed for alkaline phosphatase, prolactin and various organelle marker enzymes. Alkaline phosphatase was distributed between two peaks on the gradient. The low-density (1.10–1.15 g·cm^?3) alkaline phosphatase component co-sedimented with the plasma membrane marker, 5′-nucleotidase, had an apparent K_m for 4-methylumbelliferyl phosphate of approx. 59 μM, and was inhibited by levamisole. The high-density (1.20–1.25 g·cm^?3) peak was resistant to levamisole-inhibition, had an apparent K_m of approx. 30 μM and its distribution was distinct from plasma membrane, Golgi, lysosome, endoplasmic reticulum, mitochondria and prolactin granule markers on the isopycnic gradients.     

Properties and subcellular localization of adenosine diphosphatase in arterial smooth muscle cells in culture

The properties and subcellular localization of adenosine diphosphatase (ADPase) activity in smooth muscle cells cultured from pig aortas have been investigated. The pH optimum of ADPase activity was 7.3 and the apparent K_m for ADP was 10.3 μM. ADPase activity was inhibited completely by EDTA and was restored by the addition of divalent cations. The enzyme activity was not inhibited by 2-glycerophosphate, a substrate for non-specific phosphatases, nor by levamisole, a specific inhibitor of alkaline phosphatase. Smooth muscle cells were homogenized and a post-nuclear supernatant was applied to a sucrose density gradient in a Beaufay automatic zonal rotor. The distribution of ADPase activity in the density gradient was similar to that of 5′-nucleotidase activity, a marker enzyme for the plasma membrane, and distinct from the distributions of the marker enzymes for the other organelles. When the cells were homogenized in the presence of digitonin, an agent which binds to cholesterol and increases the equilibrium density of the plasma membrane, the modal equilibrium densities of ADPase activity and of 5′-nucleotidase activity were increased to similar extents, thus confirming the plasma membrane localization of ADPase activity.     

The subcellular localization of 3-phosphoinositide-dependent protein kinase is controlled by caveolin-1 binding

3-Phosphoinositide-dependent protein kinase 1 (PDK1), a member of the serine/threonine kinase family, has been demonstrated to be crucial for cellular survival, differentiation, and metabolism. Here, we present evidence that PDK1 is associated with caveolin-1, a 22-kDa integral membrane protein, which is the principal structural and regulatory component of the caveolae membranes in COS-1. First, we noted the presence of two potential caveolin-1 binding motifs (¹⁴¹FFVKLYFTF¹⁴⁹ and ²⁹⁹YDFPEKFF³⁰⁶) in the PDK1 catalytic domain. Using a pull-down approach, we observed that PDK1 interacts physically with caveolin-1 both in vivo and in vitro. Second, we detected the co-localization of PDK1 and caveolin-1 via confocal microscopy. The localization of PDK1 to the plasma membrane was disrupted by caveolin binding. Third, in transient transfection assays, interaction with caveolin-1 induced a substantial reduction in the in vivo serine/threonine phosphorylation of PDK1, whereas the caveolin-1 binding site mutant (¹⁴¹FFVKLYFTF¹⁴⁹ and ²⁹⁹YDFPEKFF³⁰⁶ change to ¹⁴¹AFVKLAFTA¹⁴⁹ and ²⁹⁹ADAPEFLA³⁰⁶) did not. Furthermore, a caveolin-1 scaffolding peptide (amino acids 82-101) functionally suppressed the self-phosphorylation and kinase activities of purified recombinant PDK1 protein. Thus, our observations indicated that PDK1 binds to caveolin-1 through its caveolin-binding motifs, and also that the protein-protein interaction between PDK1 and caveolin-1 regulates PDK1 self-phosphorylation, kinase activity, and subcellular localization.     

Functional expression of human DNA topoisomerase I and its subcellular localization in HeLa cells

DNA topoisomerase (topo) I plays an important role in DNA metabolism by relieving the torsional restraints of DNA topology through ATP-independent single-strand DNA breakage. In the present study, we expressed human topo I in HeLa cells by fusing it to enhanced green fluorescent protein (EGFP). The EGFP-topo I fusion protein is functionally active in that it relaxes supercoiled plasmid DNA; forms complexes with DNA, as revealed by band depletion assays; and increases the sensitivity of cells to topo I inhibitors such as topotecan, as determined by growth inhibition assays. In contrast, a mutant form of the EGFP-topo I fusion protein, in which the active Tyr has been replaced by Phe (Y723F), has no such activities. Furthermore, the fusion protein localizes to the nucleus at interphase and completely associates with chromatids at every stage of mitosis. Of importance, the mutant fusion protein (Y723F) displays a pattern of subcellular localization identical to that of the wild-type fusion protein, although the mutant fusion protein is catalytically inactive. These results suggest that in addition to its role in DNA metabolism, topo I might also play a structural role in chromosomal organization; moreover, the association of topo I with chromosomal DNA is independent of its catalytic activity. Finally, the fusion constructs may provide a useful tool to study drug action in tumor cells, as demonstrated by nucleolar delocalization of the fusion proteins in response to treatment with the topo I inhibitor topotecan.     

HSP60 interacts with YB-1 and affects its polysome association and subcellular localization

YB-1 is a DNA/RNA-binding protein which, in the cytoplasm, associates with polysomes and regulates translation. However, YB-1 has a novel nuclear localization signal, and its nuclear accumulation is correlated with cancer induction. Here we designated the amino-acid sequence as YB-NLS and demonstrated that YB-NLS is necessary for the nuclear translocation of overexpressed YB-1 in NG108-15 cells. In addition, we found that a heat shock protein, HSP60, binds to YB-NLS in the cytoplasm. Interestingly, when HSP60 expression was repressed, an increase of polysome-associated YB-1 was observed in heavy-sedimenting fractions on a sucrose gradient. Overexpression of HSP60 resulted in a decrease of YB-1 in the heavy-sedimenting fractions and suppression of YB-NLS activity. Furthermore, the NLS-deleted YB-1 was apparently associated with the heavy-sedimenting polysomes. These results suggest that HSP60 interacts with YB-1 at the YB-NLS region and acts as a regulator of polysome association and the subcellular distribution of YB-1.     

Subcellular localization of the Schlafen protein family

Although the first members of the Schlafen gene family were first described almost 10 years ago, the precise molecular/biochemical functions of the proteins they encode still remain largely unknown. Roles in cell growth, haematopoietic cell differentiation, and T cell development/maturation have, with some experimental support, been postulated, but none have been conclusively verified. Here, we have determined the subcellular localization of Schlafens 1, 2, 4, 5, 8, and 9, representing all three of the murine subgroups. We show that the proteins from subgroups I and II localize to the cytoplasm, while the longer forms in subgroup III localize exclusively to the nuclear compartment. We also demonstrate upregulation of Schlafen2 upon differentiation of haematopoietic cells and show this endogenous protein localizes to the cytoplasm. Thus, we propose the different subgroups of Schlafen proteins are likely to have functionally distinct roles, reflecting their differing localizations within the cell.     

蛋白质亚细胞定位预测中的序列编码技术

蛋白质序列的编码是亚细胞定位预测问题中的关键技术之一。该文较为详细地介绍了目前已有的蛋白质序列编码算法;并指出了序列编码中存在的一些问题及可能的发展方向。     

Acetylation regulates subcellular localization of eukaryotic translation initiation factor 5A (eIF5A)

Eukaryotic translation initiation factor 5A (eIF5A) is a protein subject to hypusination, which is essential for its function. eIF5A is also acetylated, but the role of that modification is unknown. Here, we report that acetylation regulates the subcellular localization of eIF5A. We identified PCAF as the major cellular acetyltransferase of eIF5A, and HDAC6 and SIRT2 as its major deacetylases. Inhibition of the deacetylases or impaired hypusination increased acetylation of eIF5A, leading to nuclear accumulation. As eIF5A is constitutively hypusinated under physiological conditions, we suggest that reversible acetylation plays a major role in controlling the subcellular localization of eIF5A.     

Cellular and subcellular localization of gastrointestinal glutathione peroxidase in normal and malignant human intestinal tissue

The gastrointestinal glutathione peroxidase (GI-GPx) is believed to prevent absorption of hydroperoxides. GI-GPx is expressed in the intestine together with the other three glutathione peroxidase isoenzymes, raising the question of the physiological role of the different GPx types. We therefore studied the cellular and subcellular distribution of GI-GPx in normal and malignant tissue obtained from patients with colorectal cancer or familial polyposis by immunohistochemistry. In healthy ileum epithelium GI-GPx was preferentially enriched in Paneth cells. In unaffected crypts of colon and rectum, it decreased gradually from the ground to the luminal surface. In crypt ground, GI-GPx was uniformly distributed, whereas in cells at the luminal surface it was concentrated in structures capping the nuclei at the apical pole. In colorectal cancer, GI-GPx expression depended on the stage of malignant transformation. In early stages, GI-GPx was increased and pronouncedly associated with the vesicular structures. In progressed stages of malignancy, structures disintegrated and GI-GPx distribution became more diffuse. These observations support the hypothesis that GI-GPx, apart from being a barrier against hydroperoxide absorption, might be involved in cell growth and differentiation.     

TransientAgrobacterium-mediated gene expression in theArabidopsis hydroponics root system for subcellular localization studies

To a great extent, the cellular compartmentalization and molecular interactions are indicative of the function of a protein. The development of simple and efficient tools for testing the subcellular location of proteins is indispensable to elucidate the function of genes in plants. In this report, we assessed the feasibility ofAgrobacterium-mediated transformation of hydroponically grown roots to follow intracellular targeting of proteins fused to green fluorescent protein (GFP). We developed a simple in planta assay for subcellular localization of proteins inArabidopsis roots via transient transformation and tested this method by expressing a GFP fusion of a known nuclear protein, IQD1. Visualization of transiently expressed GFP fusion proteins in roots by means of confocal microscopy is superior to the analysis of green tissues because the roots are virtually transparent and free of chlorophyll autofluorescence.     

CRM1-dependent nuclear export and dimerization with hMSH5 contribute to the regulation of hMSH4 subcellular localization

MSH4 and MSH5 are members of the MutS homolog family, a conserved group of proteins involved in DNA mismatch correction and homologous recombination. Although several studies have provided compelling evidences suggesting that MSH4 and MSH5 could act together in early and late stages of meiotic recombination, their precise roles are poorly understood and recent findings suggest that the human MSH4 protein may also exert a cytoplasmic function. Here we show that MSH4 is present in the cytoplasm and the nucleus of both testicular cells and transfected somatic cells. Confocal studies on transfected cells provide the first evidence that the subcellular localization of MSH4 is regulated, at least in part, by an active nuclear export pathway dependent on the exportin CRM1. We used deletion mapping and mutagenesis to define two functional nuclear export sequences within the C-terminal part of hMSH4 that mediate nuclear export through the CRM1 pathway. Our results suggest that CRM1 is also involved in MSH5 nuclear export. In addition, we demonstrate that dimerization of MSH4 and MSH5 facilitates their nuclear localization suggesting that dimerization may regulate the intracellular trafficking of these proteins. Our findings suggest that nucleocytoplasmic traffic may constitute a regulatory mechanism for MSH4 and MSH5 functions.     

Predicting the nuclear localization signals of 107 types of HPV L1 proteins by bioinformatic analysis

In this study, 107 types of human papillomavirus （HPV） L1 protein sequences were obtained from available databases, and the nuclear localization signals （NLSs） of these HPV L1 proteins were analyzed and predicted by bioinformatic analysis. Out of the 107 types, the NLSs of 39 types were predicted by PredictNLS software （35 types of bipartite NLSs and 4 types of monopartite NLSs）. The NLSs of the remaining HPV types were predicted according to the characteristics and the homology of the already predicted NLSs as well as the general rule of NLSs. According to the result, the NLSs of 107 types of HPV L1 proteins were classified into 15 categories. The different types of HPV L1 proteins in the same NLS category could share the similar or the same nucleocytoplasmic transport pathway. They might be used as the same target to prevent and treat different types of HPV infection. The results also showed that bioinformatic technology could be used to analyze and predict NLSs of proteins.