A single gene codes for two forms of rat nucleolar protein B23 mRNA

The Multifunctional Nucleolar Protein Nucleophosmin/NPM/B23 and the Nucleoplasmin Family of Proteins

The nucleophosmin (NPM)/nucleoplasmin family of nuclear chaperones has three members: NPM1, NPM2, and NPM3. Nuclear chaperones serve to ensure proper assembly of nucleosomes and proper formation of higher order structures of chromatin. In fact, this family of proteins has such diverse functions in cellular processes such as chromatin remodeling, ribosome biogenesis, genome stability, centrosome replication, cell cycle, transcriptional regulation, apoptosis, and tumor suppression. Of the members of this family, NPM1 is the most studied and is the main focus of this review. NPM2 and NPM3 are less well characterized, and are also discussed wherever appropriate. The structure–function relationship of NPM proteins has largely been worked out. Other than the many processes in which NPM1 takes part, the major interest comes from its involvement in human cancers, particularly acute myeloid leukemia (AML). Its significance stems from the fact that AML with mutated NPM1 accounts for ∼30% of all AML cases and usually has good prognosis. Its clinical importance also comes from its involvement in virus replication, particularly in the era of outbreaks of infectious diseases.

Viral nucleolar localisation signals determine dynamic trafficking within the nucleolus

Localisation of both viral and cellular proteins to the nucleolus is determined by a variety of factors including nucleolar localisation signals (NoLSs), but how these signals operate is not clearly understood. The nucleolar trafficking of wild type viral proteins and chimeric proteins, which contain altered NoLSs, were compared to investigate the role of NoLSs in dynamic nucleolar trafficking. Three viral proteins from diverse viruses were selected which localised to the nucleolus; the coronavirus infectious bronchitis virus nucleocapsid (N) protein, the herpesvirus saimiri ORF57 protein and the HIV-1 Rev protein. The chimeric proteins were N protein and ORF57 protein which had their own NoLS replaced with those from ORF57 and Rev proteins, respectively. By analysing the sub-cellular localisation and trafficking of these viral proteins and their chimeras within and between nucleoli using confocal microscopy and photo-bleaching we show that NoLSs are responsible for different nucleolar localisations and trafficking rates.

Relationship between adenovirus DNA replication proteins and nucleolar proteins B23.1 and B23.2

Adenovirus infection subverts nucleolar structure and function. B23 is a nucleolar protein present in two isoforms (B23.1 and B23.2) and both isoforms have been identified as stimulatory factors for adenovirus DNA replication. Here, it is demonstrated that the two isoforms of B23, B23.1 and B23.2, interact and co-localize differently with viral DNA replication proteins pTP and DBP in adenovirus-infected cells. Thus, the mechanism by which the two proteins stimulate viral DNA replication is likely to differ. These data also demonstrate the importance of testing both isoforms of B23 for interactions with viral proteins and nucleic acids.

New insights into the nucleophosmin/nucleoplasmin family of nuclear chaperones

Basic proteins and nucleic acids are assembled into complexes in a reaction that must be facilitated by nuclear chaperones in order to prevent protein aggregation and formation of non-specific nucleoprotein complexes. The nucleophosmin/nucleoplasmin (NPM) family of chaperones [NPM1 (nucleophosmin), NPM2 (nucleoplasmin) and NPM3] have diverse functions in the cell and are ubiquitously represented throughout the animal kingdom. The importance of this family in cellular processes such as chromatin remodeling, genome stability, ribosome biogenesis, DNA duplication and transcriptional regulation has led to the rapid growth of information available on their structure and function. The present review covers different aspects related to the structure, evolution and function of the NPM family. Emphasis is placed on the long-term evolutionary mechanisms leading to the functional diversification of the family members, their role as chaperones (particularly as it pertains to their ability to aid in the reprogramming of chromatin), and the importance of NPM2 as an essential component of the amphibian chromatin remodeling machinery during fertilization and early embryonic development.

CArG box-binding factor-A interacts with multiple motifs in immunoglobulin promoters and has a regulated subcellular distribution

CArG box-binding factor-A (CBF-A) is a protein involved in transcriptional control and interacts specifically with the penta-decameric (pd) element in kappa promoters. We show here that CBF-A will also bind specifically to a second region in the kappa promoter that overlaps with an early B cell factor binding site. Furthermore, the same region is present in multiple Ig promoters and we show that CBF-A can bind to several of these. Mitogenic stimulation of untransformed B lymphocytes promoted nuclear localisation of CBF-A. Using enhanced GFP (EGFP)-tagged constructs and transfection into COS7 cells, a nuclear localisation signal was defined in the C terminus of CBF-A. Deletion of only 13 amino acids from the C terminus of CBF-A led to the accumulation of the protein in bright speckles at the nuclear/cytoplasmic border. We also identified the heterogeneous ribonucleoprotein H as a specific interaction partner of CBF-A, but this interaction could be detected in the cytoplasm only. Thus, CBF-A has the potential to regulate the expression of multiple Ig V genes and has a complex, mitogen-responsive regulation of its intracellular localisation.

Adeno-associated virus interactions with B23/Nucleophosmin: identification of sub-nucleolar virion regions

Adeno-associated virus (AAV) is a human parvovirus that normally requires a helper virus such as adenovirus (Ad) for replication. The four replication proteins (Rep78, 68, 52 and 40) encoded by AAV are pleiotropic effectors of virus integration, replication, transcription and virion assembly. Using Rep68 column chromatography and mass spectrometry, we have identified the nucleolar, B23/Nucleophosmin (NPM) protein as an Rep-interacting partner. Rep-NPM interactions were verified by co-immunofluorescence and chemical cross-linking studies. We have found that there is demonstrable, but limited co-localization between Rep and NPM in co-infected cells. In contrast, there was significant co-localization between NPM and AAV Cap proteins. In vitro experiments using purified MBPRep78 and NPM show that NPM stimulates MBPRep78 interactions with the AAV ITR as well as endonuclease activity. These studies suggest that NPM plays a role in AAV amplification affecting Rep function and virion assembly.

Effects of interphase and mitotic phosphorylation on the mobility and location of nucleolar protein B23

B23 (or nucleophosmin, NPM) is a multifunctional protein involved in ribosome biogenesis, control of centrosome duplication and in sensing cellular stress. It is phosphorylated during interphase by casein kinase 2 (CK2) and during mitosis by cyclin-dependent kinase (CDK). In this study we have addressed the role of these phosphorylation events in the dynamics and location of protein B23. Mutation of the CK2 phosphorylation site to alanine results in slower recovery of the mutant compared with the wild-type protein as measured by fluorescence recovery after photobleaching (FRAP). Immunofluorescence studies using an antibody against phosphorylated Thr199 revealed that B23 is phosphorylated at this CDK1 site at the start of mitosis and is dephosphorylated during anaphase. The CDK1-type phosphorylation sites are in the nucleic acid binding region of B23 and may contribute to its dissociation from the nucleolus during mitosis. A Thr to Glu mutant of the CDK1-type sites as well as other members of the nucleoplasmin family that lack the C-terminal nucleic-acid-binding region showed a greater mobility and/or faster recovery than wild-type B23.1, the longer variant. These results provide evidence that phosphorylation at these sites reduces the affinity of B23 for nucleolar components and might be a factor in regulating its location during the cell cycle.

Proteomic analysis of macrophages stimulated by lipopolysaccharide: Lipopolysaccharide inhibits the cleavage of nucleophosmin

Lipopolysaccharide (LPS) is a complex glycolipid composed of a hydrophilic polysaccharide and a hydrophobic domain that is responsible for the biological activity of LPS. There are many reports about LPS stimulation, and many activated proteins have been detected after LPS stimulation in various cell types. Furthermore, most of the LPS signaling pathways are clear. However, we were interested in examining the changes of LPS-induced total cytosolic proteins expression and the LPS signaling pathway by the proteomics technique during LPS-induced macrophage activation. Our study employed two-dimensional gel electrophoresis and mass spectrometry to analyze the proteins involved in LPS-induced activation in RAW 264.7 cells. We found 11 protein spots whose expression was different between untreated cells and LPS-treated cells. Ten protein spots were identified, seven of which, tubulin beta-4 chain (49.6 kDa, pI 4.78), nucleophosmin (32.6 kDa, pI 4.62, two spots), 40S ribosomal protein SA (P40) (32.7 kDa, pI 4.74), transforming protein RhoA (21.8 kDa, pI 5.83), nucleolin (76.6 kDa, pI 4.69), and T-complex protein 1 zeta subunit (58 kDa, pI 6.63) were down-regulated, and three of which, nucleophosmin (32.6 kDa, pI 4.62, two spots) and proteosome subunit alpha type-1 (29.5 kDa, pI 6.00), were up-regulated. The suppression of the proteolytic degradation of nucleophosmin was associated with LPS-induced RAW 264.7 cell activation. Cleaved caspase-3 decreased, thus it might be involved in proteolysis of nucleophosmin in LPS-induced macrophage activation. Our study also demonstrated that there was no change of the expression of nucleophosmin at the mRNA level.

Shiga toxin B-subunit binds to the chaperone BiP and the nucleolar protein B23

BACKGROUND INFORMATION

In many cell lines, such as HeLa cells, STxB (Shiga toxin B-subunit) is transported from the plasma membrane to the ER (endoplasmic reticulum), via early/recycling endosomes and the Golgi apparatus, bypassing the late endocytic pathway. In human monocyte-derived macrophages and dendritic cells that are not sensitive to Shiga toxin-induced protein biosynthesis inhibition, STxB is not detectably targeted to the retrograde route and is degraded in late endosomes/lysosomes.

RESULTS

We have identified B-subunit interacting proteins in HeLa cells and macrophages. In HeLa cells, the ER-localized chaperone BiP (binding protein) was co-immunoprecipitated with the B-subunit. This interaction was not observed in macrophages, consistent with our previous trafficking results. In both cell types, the B-subunit also interacted with the nucleolar protein B23. Consistently, the B-subunit could be detected on nucleoli, suggesting that it could serve to bring the holotoxin to the site of synthesis of its molecular target, rRNA. The nucleolar localization data are critically discussed.

CONCLUSION

The interaction of STxB with BiP, involved in the retrotranslocation process to the cytosol and nucleolar B23, as described in this study, might be of relevance for explaining the efficiency of even low doses of Shiga toxin to inactivate cellular ribosomes, and for the use of STxB as a vector for targeting antigens to cytosolic proteasomes of the MHC I-restricted antigen presentation pathway.

Delocalization and Destabilization of the Arf Tumor Suppressor by the Leukemia-Associated NPM Mutant

One third of acute myeloid leukemias (AMLs) are characterized by the aberrant cytoplasmic localization of nucleophosmin (NPM) due to mutations within its putative nucleolar localization signal. NPM mutations are mutually exclusive with major AML-associated chromosome rearrangements and are frequently associated with a normal karyotype, suggesting that they are critical during leukemogenesis. The underlying molecular mechanisms are, however, unknown. NPM is a nucleocytoplasmic shuttling protein that has been implicated in several cellular processes, including ribosome biogenesis, centrosome duplication, cell cycle progression, and stress response. It has been recently shown that NPM is required for the stabilization and proper nucleolar localization of the tumor suppressor p19(Arf). We report here that the AML-associated NPM mutant localizes mainly in the cytoplasm due to an alteration of its nucleus-cytoplasmic shuttling equilibrium, forms a direct complex with p19(Arf), but is unable to protect it from degradation. Consequently, cells or leukemic blasts expressing the NPM mutant have low levels of cytoplasmic Arf. Furthermore, we show that expression of the NPM mutant reduces the ability of Arf to initiate a p53 response and to induce cell cycle arrest. Inactivation of p19(Arf), a key regulator of the p53-dependent cellular response to oncogene expression, might therefore contribute to leukemogenesis in AMLs with mutated NPM.

The kappa promoter penta-decamer binding protein CBF-A interacts specifically with nucleophosmin in the nucleus only

CArG box-binding factor-A (CBF-A) interacts with the penta-decamer (pd) element that is a conserved sequence element within mouse Vkappa promoters. The pd element acts in synergy with the octamer element to stimulate kappa transcription, especially in later stages of B cell development. To get further insight in the mechanism for CBF-A action we have characterised its protein-protein interactions. We show here that CBF-A interacts specifically with nucleophosmin (NPM). This interaction occurs via the homo-oligomerisation domain of NPM and the N-terminus of CBF-A and was exclusive for the nuclear compartment while the two proteins failed to interact in the cytosol. In contrast, CBF-A formed homocomplexes in this compartment. CBF-A was also shown to localise to the nucleoli, most likely dependent on a functional interaction with NPM. Lastly, the sequence fine specificity of CBF-A complexes in the nucleus and cytoplasm were found to differ and nuclear protein-DNA complexes were shown to contain NPM. Thus, CBF-A participates in several protein-protein interactions that may modulate its subcellular localisation and target gene specificity.

Nucleolar protein NPM interacts with HDM2 and protects tumor suppressor protein p53 from HDM2-mediated degradation

Nucleophosmin (NPM, B23) is an abundant nucleolar phosphoprotein involved in ribosome biogenesis, and interacts with tumor suppressor proteins p53 and Rb. Here we show that NPM is a UV damage response protein that undergoes nucleoplasmic redistribution and regulates p53 and HDM2 levels and their interaction. By utilizing RNAi approaches and analyses of endogenous and ectopically expressed proteins, we demonstrate that NPM binds HDM2 and acts as a negative regulator of p53-HDM2 interaction. Viral stress, enforced by expression of Kaposi's sarcoma virus K cyclin, causes NPM redistribution, K cyclin-NPM association, and p53 stabilization by dissociation of HDM2-p53 complexes. The results demonstrate novel associations of HDM2 and K cyclin with NPM and implicate NPM as a crucial controller of p53 through inhibition of HDM2.

Tryptophans 286 and 288 in the C-terminal region of protein B23.1 are important for its nucleolar localization

Nucleolar protein B23 can shuttle between the nucleolus and cytoplasm. However, the mechanism involved in the protein moving and staying in the nucleolus is not fully understood. To identify the nucleolar localization signal sequence of protein B23, we examined the subnuclear location of B23.1 mutant proteins fused with green fluorescent protein in HeLa cells. The results suggested that the two C-terminal tryptophan residues (Trp-286 and Trp-288) of protein B23.1 were important in this phenomenon.

Increased expression of a COOH-truncated nucleophosmin resulting from alternative splicing is associated with cellular resistance to ionizing radiation in HeLa cells

We previously demonstrated that transfecting HeLa cells with the 24 kDa basic fibroblast growth factor-2 (FGF-2) isoform dramatically increased cell survival after irradiation. To investigate genes implicated in this radioresistance acquisition, we compared mRNA expression between radioresistant 24 kDa FGF-2-expressing cells (HeLa 3A) and radiosensitive control HeLa PINA cells using the differential display technique. Of the 32 differentially expressed mRNAs, 1 presented a significant homology with a known gene. This 378 bp fragment presented 100% identity with exon 11 and 12 of human nucleophosmin (NPM) but differed by including a part of intron 9 in its 5' end. The differential expression of this fragment was confirmed using an RNase protection assay. We then cloned the entire corresponding mRNA and showed that it contained all the exons of NPM plus intron 9, suggesting that it was a splicing product of the NPM gene. This variant encoded for a 35-amino acid truncated NPM (NPM2). NPM2 expression was increased in HeLa 3A. To investigate NPM2's role in radioresistance acquisition, we transfected HeLa cells with NPM2 cDNA and analyzed survival after irradiation of the clones obtained. After transfection with NPM2, radiosensitive HeLa cells exhibited a dramatic increase in cell survival after irradiation. Taken together, our results demonstrate that expression of a COOH-truncated NPM form resulting from the alternative splicing of NPM mRNA is able to increase cell survival after irradiation and suggests that it might be involved in cellular response to ionizing radiation.

Phosphorylation-dependent migration of retinoblastoma protein into the nucleolus triggered by binding to nucleophosmin/B23

Underphosphorylated retinoblastoma (Rb) protein inhibits progression around the cell cycle by binding to transcription factors like E2F; subsequent hyperphosphorylation of Rb protein releases E2F from the complex so that it can then drive the cell into S phase. We immunolocalized Rb protein in human cells during the cell cycle. Rb protein translocated into nucleoli after DNA replication completed, and the nucleolar Rb was shown to be in the hyperphosphorylated form by immunoblotting. This form, but not its underphosphorylated counterpart, interacted with the nucleolar protein nucleophosmin/B23. The two formed a salt-resistant complex in vitro, and the two could be immunoprecipitated together from nucleolar extracts. These results suggest that hyperphosphorylated Rb protein is imported into nucleoli late in S or G2 phase with nucleophosmin/B23. Analysis of the nucleolar location of Rb protein using various deletion mutants tagged with the green fluorescent protein implicated pocket A of Rb protein as the region responsible for nucleolar targeting; this region also interacted with nucleophosmin/B23. Nucleolar translocation of Rb mutant was inhibited by introducing nucleophosmin/B23 antisense oligomer. These results suggest that nucleolar translocation of Rb protein is promoted by the binding with nucleophosmin/B23 via the pocket A region.

Two splice variants of Nopp140 in Drosophila melanogaster

The Nopp140 gene of Drosophila maps within 79A5 of chromosome 3. Alternative splicing yields two variants. DmNopp140 (654 residues) is the sequence homolog of vertebrate Nopp140. Its carboxy terminus is 64% identical to that of the prototypical rat Nopp140. DmNopp140-RGG (688 residues) is identical to DmNopp140 throughout its first 551 residues, but its carboxy terminus contains a glycine/arginine-rich domain that is often found in RNA-binding proteins such as vertebrate nucleolin. Both Drosophila variants localize to nucleoli in Drosophila Schneider II cells and Xenopus oocytes, specifically within the dense fibrillar components. In HeLa cells, DmNopp140-RGG localizes to intact nucleoli, whereas DmNopp140 partitions HeLa nucleoli into phase-light and phase-dark regions. The phase-light regions contain DmNopp140 and endogenous fibrillarin, whereas the phase-dark regions contain endogenous nucleolin. When coexpressed, both Drosophila variants colocalize to HeLa cell nucleoli. Both variants fail to localize to endogenous Cajal bodies in Xenopus oocyte nuclei and in HeLa cell nuclei. Endogenous HeLa coilin, however, accumulates around the periphery of phase-light regions in cells expressing DmNopp140. The carboxy truncation (DmNopp140DeltaRGG) also fails to localize to Cajal bodies, but it forms similar phase-light regions that peripherally accumulate endogenous coilin. Conversely, we see no unusual accumulation of coilin in cells expressing DmNopp140-RGG.

Identification of nucleophosmin/B23, an acidic nucleolar protein, as a stimulatory factor for in vitro replication of adenovirus DNA complexed with viral basic core proteins

The processes governing chromatin remodeling and assembly, which occur prior to and/or after transcription and replication, are not completely understood. To understand the mechanisms of transcription and replication from chromatin templates, we have established in vitro replication and transcription systems using adenovirus (Ad) DNA complexed with viral basic core proteins, called Ad core, as a template. Using this system, we have previously identified, from HeLa cells, template activating factor-I as a stimulatory factor for the Ad core DNA replication. Here, using this system as a tool, we identified and purified a novel template activating factor activity that consists of two acidic polypeptides whose apparent molecular masses are 38 kDa and 37 kDa. These two polypeptides correspond to two splicing variants of nucleolar phosphoprotein, nucleophosmin/B23. Recombinant B23 proteins stimulate the Ad core DNA replication, and the acidic regions of B23 proteins are important for its activity. In addition, B23 proteins directly bind to core histones and transfer them to naked DNA. Furthermore, chromatin components such as histones and topoisomerase II are co-immunoprecipitated with B23 from cell extracts. These observations lead to a hypothesis that nucleophosmin/B23 is involved in structural changes of chromatin, thereby regulating transcription and replication within the ribosomal DNA region or maintaining the nucleolar structure.

Mouse RNA helicase II/Gu: cDNA and genomic sequences, chromosomal localization, and regulation of expression

RNA helicase II/Gu (RH II/Gu) is a mammalian nucleolar RNA helicase previously identified using an autoimmune serum from a patient with watermelon stomach disease. RH II/Gu can unwind double-stranded RNA and can fold or introduce a secondary structure to a single-stranded RNA. These two enzymatic activities reside in two separate domains of the RH II/Gu molecule. The present study reports the molecular analysis of the cDNA and genomic sequences of the mouse RH II/Gu, its chromosomal localization, and the regulation of expression. The cDNA-derived amino acid sequence shows three tandem repeats at the NH(2)-terminal end of the protein, which are not conserved in the human homologue. Each repeat has 37 amino acids that are rich in basic residues. The helicase and foldase domains are highly conserved between the mouse and the human RH II/Gu. The basic promoter region of the mouse RH II/Gu gene is within 300 nucleotides upstream of a putative ATG initiation codon. Upstream of this promoter region is a silencer that represses transcription of the mouse RH II/Gu gene. This inhibitory region contains three 38-nucleotide repeats in tandem. The mouse RH II/Gu consists of 14 exons and 13 introns. The 3' flanking sequence of the gene contains three putative polyadenylation sites but only two sites are probably functional as shown by Northern blot analysis and 3' end sequences of mouse RH II/Gu cDNA in the EST database. These two alternative polyadenylation sites are approximately 240 and 2100 nucleotides from the TGA stop codon. Both mouse and human RH II/Gu genes are localized on chromosome 10. The availability of the mouse RH II/Gu gene will facilitate its functional analysis including creation of a mouse deficient in RH II/Gu protein.

The nucleolar phosphoprotein B23 redistributes in part to the spindle poles during mitosis

B23 is a major phosphoprotein in the interphasic nucleolus where it is involved in the assembly of pre-ribosomes. Using several cultured animal cells, we report that, in addition to the known redistribution of the protein during mitosis, B23 also becomes associated with mitotic spindle poles starting from early prometaphase onwards. Colocalization of B23 with the protein NuMA (Nuclear Mitotic Apparatus protein) was studied in mitotic cells and taxol-arrested cells. During the onset of mitosis, we observed that a fraction of B23 associates with, and dissociates from, the poles later than NuMA. At metaphase, both proteins are colocalized at the poles. The polar redistribution of both B23 and NuMA is mediated by microtubules. In taxol-treated cells, B23 is associated with the microtubule minus ends in the center of mitotic asters together with NuMA. Association of B23 with microtubule minus ends of mitotic asters was further confirmed with an in vitro assay, where B23 was found by western blotting to co-sediment with taxol-induced microtubule asters formed in a mitotic cell extract. Immunolabeling demonstrated that B23 and NuMA were both present at the center of the asters. Furthermore, an additional hyperphosphorylated form of B23 appeared when microtubule asters formed and associated with the asters. Immunodepletion of B23 from the mitotic extract revealed that taxol-induced microtubule asters were still observed in B23-immunodepleted mitotic extract, indicating that the presence of B23 at the poles is unlikely to be essential for spindle formation or stabilisation.

Identification of highly expressed genes in metastasis-suppressed chromosome 6/human malignant melanoma hybrid cells using subtractive hybridization and differential display

Microcell-mediated transfer of chromosome 6 into human melanoma cell lines C8161 and MelJuSo suppresses metastasis by at least 95% without affecting tumorigenicity. Subtractive hybridization and differential display were used to identify the molecule(s) responsible for suppressing metastasis in neo6/melanoma (neo6/C8161 and neo6/MelJuSo) hybrids. Seven cDNA clones exhibiting quantitatively or qualitatively higher expression in neo6/melanoma hybrids were obtained. These genes fell into 2 categories: 1) transcription-related genes (AP-2A, HMG-I(Y) and a novel isoform of nucleophosmin B23), which have previously been shown to regulate metastasis-associated genes; and 2) novel genes. One of the novel genes, designated KiSS-1, significantly suppressed metastasis of the human malignant melanoma cell lines MelJuSo and a highly metastatic subclone of C8161, C8161cl.9, following transfection and constitutive expression. Our results illustrate the power of subtractive hybridization and differential display to identify functional metastasis-controlling genes in human melanoma.

Cell-cycle-dependent alterations of a highly phosphorylated nucleolar protein p130 are associated with nucleologenesis

We identified a novel human nucleolar phosphoprotein p130 (130 kDa) using a strategy for selecting monoclonal antibodies against nuclear proteins which oscillate in the cell cycle. p130 is localized in interphase nucleoli in a dotted manner. Complete extraction of p130 required a high concentration of salt (0.5 M NaCl) indicating that it binds firmly to the nucleolar components via ionic interaction. p130 is heavily phosphorylated, since alkaline phosphatase treatment converted the purified p130 into a 95 kDa product; this was further supported by the in vitro demonstration that cellular phosphatase and casein kinase II activities were responsible for the interchange of these two forms. Extracts of mitotic cells had lower concentrations of p130 compared to those of interphase cells suggesting that a proportion of p130 might be degraded during mitosis. Moreover, all the remaining p130 in mitotic cells was further phosphorylated, likely by a cdc2 kinase, resulting in increase in its solubility, and its dispersion throughout the entire cytoplasm. Thus, p130 in metaphase and anaphase cells was unable to be detected by immunofluorescence microscopy. At telophase, p130 reappeared and aggregated into a granular structure, resembling the prenucleolar bodies. These granules migrated from the nucleoplasm to the nucleoli in early G1-phase. Actinomycin D was able to induce segregation of p130-containing granules into the nucleoplasm, similar to the well-known behavior of the fibrillarin-containing granules, indicating that p130 is localized in the dense fibrillar component, a subnucleolar region for pre-rRNA synthesis and processing. The cDNA sequence of p130 revealed a remarkable feature, that a serine-rich stretch interspersed with acidic residues is repeated ten times. Such a characteristic is shared with a rat nucleolar phosphoprotein Nopp140, which is thought to shuttle between the nucleolus and the cytoplasm. Although p130 shows 74% identity to Nopp140, our observations suggest that during mitosis the functions of p130 are related to nucleologenesis.

Characterization of seven processed pseudogenes of nucleophosmin/B23 in the human genome

Genomic blot analysis revealed that the nucleophosmin/B23 gene belongs to a multigene family that has about 10 copies per haploid human genome. In searching for human nucleophosmin/B23 functional genes, seven processed pseudogenes (NG1-1.6, NG2-6, NG3-3, NG4-5, NG5-4, NG6-4, and NG7-6) were isolated and characterized. Four of them, NG2-6, NG3-3, NG4-5, and NG7-6, contain the sequences corresponding to the full-length cDNA. NG1-1.6 is 5'-truncated, whereas NG5-4 and NG6-5 are 3'-truncated pseudogenes. Of the seven pseudogenes, NG3-3 clone has the longest 5' untranslated sequence, which contains 104 nucleotides upstream of the translation initiation codon (AUG). Two processed pseudogenes (NG2-6 and NG3-3) have different polyadenylation sites from the mRNA, indicating the usage of alternative polyadenylation signals at the 3' sequence.

Nucleolin is an Ag-NOR protein; this property is determined by its amino-terminal domain independently of its phosphorylation state

The Ag-NOR proteins are defined as markers of "active" ribosomal genes. They correspond to a set of proteins specifically located in the nucleolar organizer regions (NORs), but have not yet been clearly identified. We adapted the specific detection method of the Ag-NOR proteins to Western blots in order to identify these proteins. Using a purified protein, Western blots, and immunological characterization, the present study brings the first direct evidence leading to the identity of one Ag-NOR protein. We found that nucleolin is specifically revealed by Ag-NOR staining. Using different nucleolin fragments generated by CNBr cleavage and by overexpression in Escherichia coli, we demonstrate that the amino-terminal domain of nucleolin and not the carboxy-part of the protein is involved in silver staining. Moreover, as the pattern of staining does not vary using casein kinase II- and cdc2-phosphorylated nucleolin or dephosphorylated nucleolin, we conclude that the reduction of the silver ions is not linked to the phosphorylation state of the molecule. We propose that the concentration of acidic amino acids in the amino-terminal domain of nucleolin is responsible for Ag-NOR staining. This hypothesis is also supported by the finding that poly L-glutamic acid peptides are silver stained. These results provide data that can be used to explain the specificity of Ag-NOR staining. Furthermore, we clearly establish that proteolysis of the amino-terminal Ag-NOR-sensitive part of nucleolin occurs in vitro, leading to the accumulation of the carboxy-terminal Ag-NOR-negative part of the protein. We argue that this cleavage occurs in vivo as already proposed, bearing in mind that nucleolin is present in the fibrillar and in the granular component of the nucleolus, whereas no Ag-NOR staining is observed in the latter nucleolar component.

Characterization and immunolocalization of a nucleolar antigen with anti-NOR serum in HeLa cells

We have used a serum from a patient with rheumatoid arthritis and found it to immunoblot with a 92- to 88-kDa protein doublet with an isoelectric point of around 7.5 after mono- and two-dimensional electrophoresis in whole HeLa cells. By means of immunofluorescence and immunoelectron microscopy we have found it to specifically react with the nucleolar fibrillar component. After quantitative analysis under the electron microscope, we have demonstrated a similar labeling both in the fibrillar centers and the dense fibrillar component, using two different gold-coupled markers. When transcription was inhibited under physiological conditions (mitosis) or after AMD treatment the antigen remained, as shown by immunoblotting and immunolabeling with anti-NOR serum. These biochemical characteristics, which coincide with those of the ribosomal transcription human upstream binding factor, together with the immunolocalization with anti-NOR serum, allow us to discuss the possible role of these antigens in rDNA transcription.

Formation of nucleophosmin/B23 oligomers requires both the amino- and the carboxyl-terminal domains of the protein

Nucleophosmin/B23 is a nucleolar phosphoprotein which forms oligomers. To determine the domain essential for oligomer formation, various deletion and point mutation clones of nucleophosmin/B23 were constructed. Nucleophosmin/B23 and the mutant proteins were produced by (a) coupled in vitro transcription and translation and (b) expression in Escherichia coli with T7 RNA polymerase expression vector (pET-8c). Nucleophosmin/B23 synthesized in vitro has the same peptide map as that synthesized in HeLa cells. Similarly, it formed oligomers which could be detected in SDS/PAGE and were cross-linked with nitrogen mustard in vivo. Substitution of Met5, Met7, and Met9 with Leu or deletion of five amino acids at the C-terminus abolished the oligomerization. Deletion of portions of amino acids in the middle of the molecule (amino acid residues 83-152, 117-186 and 185-240) had little effect on the oligomerization. Co-expression of the N- and C-terminal mutant clones in vitro did not produce oligomers. These results indicate that intra-molecular interactions with both the N- and C-terminal domains are essential for oligomer formation.

Structure and developmental expression of chicken nucleolin and NO38: coordinate expression of two abundant non-ribosomal nucleolar proteins

We report the complete primary structures of two major chicken non-ribosomal nucleolar proteins known as nucleolin/C23 and NO38/B23, respectively. By comparison with homologous proteins from other species, this sequence information contributes to the identification of evolutionarily conserved motifs that may be relevant to the function and subcellular distribution of the two proteins. Using cDNA probes and monoclonal antibodies, we have also studied the expression of nucleolin and NO38 in the course of chicken embryogenesis. In all tissues examined, Northern analyses revealed single hybridization signals for nucleolin (at 3.0 kb) and NO38 (at 1.6 kb), and no evidence was obtained for multiple protein products. In total embryos between days 3 and 11 after egg laying, nucleolin and NO38 mRNA and protein levels decreased in parallel (2-5-fold), suggesting transcriptional down-regulation of expression. Coordinate expression of nucleolin and NO38 was observed also when examining individual tissues at various stages of development. Interestingly, however, there was no consistent correlation between relative mRNA and protein levels. In particular, several adult tissues contained exceedingly low levels of either nucleolin or NO38, despite the presence of large amounts of corresponding mRNAs. From these results we conclude, first, that the expression of nucleolin and NO38 is controlled coordinately, and, second, that regulation is likely to involve both transcriptional and posttranscriptional mechanisms.