Localization of nucleolar phosphoproteins B23 and C23 during mitosis

Nucleolar phosphoproteins B23 and C23 were simultaneously localized in unsynchronized male rat-kangaroo PtK2 cells during mitosis using a mouse monoclonal antibody against protein B23 and a rabbit antibody against protein C23. The distribution of proteins B23 and C23 during mitosis was compared with the distribution of the silver staining protein. During interphase, proteins B23 and C23 were both localized to the nucleolus. As the nucleolus disappeared in prophase, the distribution of protein B23 became nucleoplasmic, whereas most of protein C23 remained associated with the disappearing nucleolus. Throughout metaphase and anaphase protein B23 was found associated with the chromosomes, whereas protein C23 seemed to disappear. When the nucleolus reformed during telophase, protein C23 appeared first in ‘prenucleolar bodies’ and then in the nucleolus, whereas protein B23 did not appear in the nucleolus until late telophase or early G1 phase. Silver staining during mitosis closely paralleled the distribution of protein C23, supporting previous conclusions that protein C23 is a silver staining nucleolus organizer region (NOR) protein [19, 20].     

Origin of nucleolus-like bodies found in the nucleoplasm and cytoplasm of Vicia faba meristematic cells

Cytohistochemical staining and RNase-gold labelling have been applied to root-tip meristematic cells of Vicia faba to study the origin and biological significance of 2 types of inclusions: one seen in the nucleoplasm and the other in the cytoplasm of early telophase cells. They have been termed "dense bodies" and "cytoplasmic nucleolus-like bodies" (NLB), respectively. Both types of inclusions respond positively to silver staining and ribonucleoprotein (RNP) staining in a similar fashion to nucleolus. Interestingly, the dense bodies label heavily with the RNase-gold complex, as does the nucleolus, while the cytoplasmic NLB have no affinity with the label. In most cases, the dense bodies label more heavily than the nucleolus. Light microscope surveys reveal that the dense bodies sometimes appear to be released from the surface of the nucleolus. On the other hand, prenucleolar material showing the same silver staining and RNP preferential staining characteristics as the dense bodies begin to accumulate on the surface of chromosomes in mid-anaphase. This material does not label with RNase-gold. These data are discussed in terms of the hypothesis that the dense bodies are derived from the nucleolus by direct budding or fragmentation, and the cytoplasmic NLB are composed of prenucleolar material that failed to attach to chromosomes.     

Differences in the fine structure and chemical constitution of nucleolar bodies and the true nucleolus in Xenopus laevis embryos

Numerous bodies resembling nucleoli, named “prenucleolar bodies”, were seen in the interphase nucleus of Xenopus laevis embryos between stages 7 and 11 of Nieuwkoop and Faber (1956) but not at stage 12. These bodies are composed of thick strands, 200 A in diameter, and apparently differ from the fibrillar component of the true nucleolus which consists of thin fibrils, 50 A in diameter. The granular component of the true nucleolus consists of fibers and granules which are both also 150–200 A in diameter, but which differ in chemical nature from the prenucleolar bodies. The granular component and fibrillar component are readily digested by RNase with or without pretreatment with trypsin, while the prenucleolar body is only digested with RNase after pretreatment with trypsin. This suggests that the prenucleolar body consists of strands of RNA coated with protein. At stage 9, another type of nucleolus-like body is formed, which is larger (2–2.6 μ in diameter) than the prenucleolar body (0.2–1 μ) and consists of thin fibrils of 50 A. This body resembles the fibrillar component of the true nucleolus in the size of the elemental fibrils as well as in its susceptibility to actinomycin D, RNase and trypsin. It seems to be a precursor of the true nucleolus and for this reason was named the “primary nucleolus.” From stage 9 to stage 10, each nucleus in the presumptive ectodermal and mesodermal areas contains 2 primary nucleoli together with multiple prenucleolar bodies. At stage 12, the prenucleolar body is not seen at all, but a new type of nucleolus-like body appears. There are usually 2 of these bodies in each nucleus, and they consist of 2 components: a network of 50 A fibrils, and a group of strands, 150–200 A in diameter, containing some granule-like elements. The former has the same susceptibility to actinomycin D, RNase and/or trypsin as the fibrillar component of the definitive nucleolus and the primary nucleolus, while the latter has the same susceptibility as the granular component of the definitive nucleolus. Thus, this body may     

cDNA cloning and characterization of a novel nucleolar protein.

In an initial study of anti-nuclear antibodies in the chronic inflammatory bladder disease interstitial cystitis, we reported that 7% of interstitial cystitis patients studied had autoantibodies to the nucleolus. We now report that, using an autoimmune serum from a patient with interstitial cystitis, we have identified and partially characterized a novel protein with an M(r) of approximately 55 kDa (hereafter referred to as No55) localized to the granular component of the nucleolus. No55 was initially characterized by diffuse nucleolar immunofluorescence staining in interphase cells and by Western blotting as a 55-kDa doublet on whole-cell extracts. During mitosis, No55 was associated with chromosomes and appeared in prenucleolar bodies during telophase, but it did not colocalize with p80-coilin in coiled bodies. Immunoelectron microscopy revealed that No55 was localized uniformly throughout the granular component of the nucleolus compared with a more peripheral localization of nucleolar granular component protein B23. On segregation of the nucleolus with actinomycin D, No55 remained with the granular component of the segregated nucleolus, whereas protein B23 was found predominantly in the nucleoplasm. Finally, a cDNA expression library was screened with the human autoantibody against No55, and a 2.4-kb insert was isolated, subcloned to homogeneity, and then sequenced. Analysis of this sequence showed an open reading frame of approximately 1.3 kb coding for 437 amino acids with a predicted molecular weight of 50 kDa. A search of the gene sequence database indicated homology with SC65, a rat synaptonemal complex protein. Therefore, on the basis of molecular weight, nucleolar sublocalization, response to actinomycin D, and cDNA sequence determination, No55 is a novel protein of the interphase nucleolus.     

Nucleologenesis: Composition and fate of prenucleolar bodies

A time course study was conducted on nucleologenesis after release from a mitotic block in the presence and absence of actinomycin D to determine the composition and fate of prenucleolar bodies (PNBs). Prenucleolar bodies, whether naturally occurring or induced by actinomycin D treatment, stain with silver and contain phosphoproteins B23 and C23, two of the major proteins of the interphase nucleolus as determined by double label immunofluorescence with specific antibodies. The nucleolus is formed by fusion of PNBs, which subsequently reorganize and form internal fibrillar and peripheral granular regions. Actinomycin D prevents fusion of PNBs, which are then randomly dispersed throughout the nucleus but they still contain proteins B23 and C23. These results demonstrate that the nucleolus is formed by fusion of prenucleolar structures whose biochemical composition resembles the mature nucleolus, since PNBs contain at least two of the major nucleolar proteins.     

The nucleolus: a model for the organization of nuclear functions

Nucleoli are the prominent contrasted structures of the cell nucleus. In the nucleolus, ribosomal RNAs (rRNAs) are synthesized, processed and assembled with ribosomal proteins. The size and organization of the nucleolus are directly related to ribosome production. The organization of the nucleolus reveals the functional compartmentation of the nucleolar machineries that depends on nucleolar activity. When this activity is blocked, disrupted or impossible, the nucleolar proteins have the capacity to interact independently of the processing activity. In addition, nucleoli are dynamic structures in which nucleolar proteins rapidly associate and dissociate with nucleolar components in continuous exchanges with the nucleoplasm. At the time of nucleolar assembly, the processing machineries are recruited in a regulated manner in time and space, controlled by different kinases and form intermediate structures, the prenucleolar bodies. The participation of stable pre-rRNAs in nucleolar assembly was demonstrated after mitosis and during development but this is an intriguing observation since the role of these pre-rRNAs is presently unknown. A brief report on the nucleolus and diseases is proposed as well as of nucleolar functions different from ribosome biogenesis.Robert Feulgen Lecture presented at the 48th Symposium of the Society for Histochemistry in Stresa, Lake Maggiore, Italy, 7–10 September 2006.     

Organization of argyrophilic nucleolar material throughout the division cycle of meristematic cells

Summary The silver impregnation of nucleolar material facilitated the study of the morphological changes which take place in the nucleolus throughout the division cycle in root tip cells ofAllium cepa. The nucleolus appears to undergo no morphological changes throughout the interphase. It undergoes disorganization during the prophase, while in the telophase it appears uniformly on the chromatin as condensing into prenucleolar bodies.The appearance of the prenucleolar bodies is unaffected by puromycin, cordycepin, or ethidium bromide. This suggests that the argyrophilic material does not undergo synthesis during the telophase, nor require RNA or protein synthesis to effect the aggregation into prenucleolar bodies. However, the organization of nucleoli from prenucleolar bodies is inhibited by both cordycepin and ethidium bromide, suggesting that RNA synthesis is involved in this proccess.In aneuploid nuclei induced by treatment with colchicine we observed the appearance of prenucleolar bodies during the telophase even in the absence of the nucleolar organizer, but in this case the formation of nucleoli fails to take place. The nucleolar organizers proved to be capable of acting only in the nucleus to which they belong, but not on other nuclei within the same cytoplasm belonging to multinucleate cells.It seems logical to assume that one of the roles of the nucleolar organizer is related with the above-mentioned RNA synthesis, which is required to the aggregation of prenucleolar bodies into nucleoli.The work reported in the paper was undertaken during the tenure of a Research Training Fellowship awarded by the International Agency for Research on Cancer.     

In nucleoli, the steady state of nucleolar proteins is leptomycin B-sensitive.

BACKGROUND INFORMATION: The nucleolus is a dynamic structure. It has been demonstrated that nucleolar proteins rapidly associate with and dissociate from nucleolar components in continuous exchanges with the nucleoplasm using GFP (green fluorescent protein)-tagged proteins. However, how the exchanges within one nucleolus and between nucleoli within the nuclear volume occurred is still poorly understood. RESULTS: The movement of PAGFP (photoactivatable GFP)-tagged proteins that become visible after photoactivation can be followed. In the present study, we establish the protocol allowing quantification of the traffic of PAGFP-tagged nucleolar proteins in nuclei containing two nucleoli. The traffic in the activated area, at the periphery of the activated area and to the neighbouring nucleolus is measured. Protein B23 is rapidly replaced in the activated area, and at the periphery of the activated area the steady state suggests intranucleolar recycling of B23; this recycling is LMB (leptomycin B)-sensitive. The pool of activated B23 is equally distributed in the volume of the two nucleoli within 2 min. The three-dimensional distribution of the proteins Nop52 and fibrillarin is less rapid than that of B23 but is also LMB-sensitive. In contrast, traffic of fibrillarin from the nucleoli to the CB (Cajal body) was not modified by LMB. CONCLUSIONS: We propose that the steady state of nucleolar proteins in nucleoli depends on the affinity of the proteins for their partners and on intranucleolar recycling. This steady state can be impaired by LMB but not the uptake in the neighbouring nucleolus or the CB.     

In nucleoli, the steady state of nucleolar proteins is leptomycin B-sensitive

Background information. The nucleolus is a dynamic structure. It has been demonstrated that nucleolar proteins rapidly associate with and dissociate from nucleolar components in continuous exchanges with the nucleoplasm using GFP (green fluorescent protein)‐tagged proteins. However, how the exchanges within one nucleolus and between nucleoli within the nuclear volume occurred is still poorly understood. Results. The movement of PAGFP (photoactivatable GFP)‐tagged proteins that become visible after photoactivation can be followed. In the present study, we establish the protocol allowing quantification of the traffic of PAGFP‐tagged nucleolar proteins in nuclei containing two nucleoli. The traffic in the activated area, at the periphery of the activated area and to the neighbouring nucleolus is measured. Protein B23 is rapidly replaced in the activated area, and at the periphery of the activated area the steady state suggests intranucleolar recycling of B23; this recycling is LMB (leptomycin B)‐sensitive. The pool of activated B23 is equally distributed in the volume of the two nucleoli within 2 min. The three‐dimensional distribution of the proteins Nop52 and fibrillarin is less rapid than that of B23 but is also LMB‐sensitive. In contrast, traffic of fibrillarin from the nucleoli to the CB (Cajal body) was not modified by LMB. Conclusions. We propose that the steady state of nucleolar proteins in nucleoli depends on the affinity of the proteins for their partners and on intranucleolar recycling. This steady state can be impaired by LMB but not the uptake in the neighbouring nucleolus or the CB.     

The Movement of Coiled Bodies Visualized in Living Plant Cells by the Green Fluorescent Protein

Coiled bodies are nuclear organelles that contain components of at least three RNA-processing pathways: pre-mRNA splicing, histone mRNA 3'- maturation, and pre-rRNA processing. Their function remains unknown. However, it has been speculated that coiled bodies may be sites of splicing factor assembly and/or recycling, play a role in histone mRNA 3'-processing, or act as nuclear transport or sorting structures. To study the dynamics of coiled bodies in living cells, we have stably expressed a U2B"-green fluorescent protein fusion in tobacco BY-2 cells and in Arabidopsis plants. Time-lapse confocal microscopy has shown that coiled bodies are mobile organelles in plant cells. We have observed movements of coiled bodies in the nucleolus, in the nucleoplasm, and from the periphery of the nucleus into the nucleolus, which suggests a transport function for coiled bodies. Furthermore, we have observed coalescence of coiled bodies, which suggests a mechanism for the decrease in coiled body number during the cell cycle. Deletion analysis of the U2B" gene construct has shown that the first RNP-80 motif is sufficient for localization to the coiled body.     

Nucleolar distribution of proteins B23 and nucleolin in mouse preimplantation embryos as visualized by immunoelectron microscopy

The ultrastructural distribution of proteins B23 and nucleolin in the nucleolus of mouse embryos from the zygote to the early blastocyst has been analyzed by means of specific antibodies and immunocytochemistry using colloidal gold complexes as markers. In parallel, silver staining of nucleoli was carried out on ultrathin sections. Our results show that the compact prenucleolar bodies at 1- and 2-cell stage as well as the compact residual fibrillar masses observed up to the morula stage, are labelled with the two antibodies. These masses, however, are not stained with silver up to the 4-cell stage. In well-developed nucleoli, the two antibodies co-localize in the dense fibrillar component (DFC) and the granular component (GC) while fibrillar centers (FCs) are devoid of label. On the contrary, silver staining occurs in the FCs and DFC but not in the GC. Our observations suggest that there is no direct relationship between the occurrence of silver staining and the distribution of protein B23 or nucleolin. Moreover, neither the localization of the two above proteins nor silver staining are unequivocally related to the nucleolar activity.     

Immunolocalization of the 100 kDa nucleolar protein during the mitotic cycle in CHO cells

The localization of a major nucleolar protein with a molecular weight of 100,000 has been followed during mitosis in Chinese hamster ovary CHO cells using specific antibodies to this protein and immunocytochemical techniques. The 100 kDa protein was visualized at discrete sites on metaphase chromosomes, corresponding to nucleolus organizer regions, and in large, immunostained nucleolar remnants that are discarded in the cytoplasm after nucleolar disintegration. After mitosis, the 100 kDa protein was shown to play an early role in nucleolar reformation. It was first detected in small deposits around the anaphase chromosomes. In telophase, the protein accumulated simultaneously in prenucleolar bodies and in the reforming nucleoli. The early presence of the 100 kDa protein in the telophase nucleus suggests that it is essential for the reestablishment of nucleolar function after mitosis. Thus this protein is present throughout the CHO cell cycle, an observation which supports the hypothesis that it plays a fundamental role in cell organization.     

Nucleolar translocalization of GRA10 of Toxoplasma gondii transfectionally expressed in HeLa cells

Toxoplasma gondii GRA10 expressed as a GFP-GRA10 fusion protein in HeLa cells moved to the nucleoli within the nucleus rapidly and entirely. GRA10 was concentrated specifically in the dense fibrillar component of the nucleolus morphologically by the overlap of GFP-GRA10 transfection image with IFA images by monoclonal antibodies against GRA10 (Tg378), B23 (nucleophosmin) and C23 (nucleolin). The nucleolar translocalization of GRA10 was caused by a putative nucleolar localizing sequence (NoLS) of GRA10. Interaction of GRA10 with TATA-binding protein associated factor 1B (TAF1B) in the yeast two-hybrid technique was confirmed by GST pull-down assay and immunoprecipitation assay. GRA10 and TAF1B were also co-localized in the nucleolus after co-transfection. The nucleolar condensation of GRA10 was affected by actinomycin D. Expressed GFP-GRA10 was evenly distributed over the nucleoplasm and the nucleolar locations remained as hollows in the nucleoplasm under a low dose of actinomycin D. Nucleolar localizing and interacting of GRA10 with TAF1B suggested the participation of GRA10 in rRNA synthesis of host cells to favor the parasitism of T. gondii.     

A 23-amino acid motif spanning the basic domain targets zebrafish myogenic regulatory factor myf5 into nucleolus

Myf5 is a nuclear protein and one of the basic helix-loop-helix (bHLH) myogenic factors that play an important role in muscle specification and differentiation. The motif responsible for the nuclear translocation of Myf5 was unknown. Using on-line monitoring of EGFP (enhanced green fluorescent protein)-tagged zebrafish Myf5 translocation, we demonstrated that Myf5-EGFP protein resided in the nucleoplasm and nucleolus of zebrafish fibroblast cell lines (ZEM2S and ZF4), mammalian nonmuscle cell line (COS1), and muscle cell lines (RD and C2C12). In contrast, zebrafish MyoD-EGFP was localized in the nucleus but did not condense in the nucleolus. Using indirect immunofluorescent staining, we determined that zebrafish Myf5 was colocalized with nucleophosmin/B23, a nucleolus protein. Deletion analysis revealed that amino acid residues 60 to 82 (60KRKASTVDRRRAATMRERRRLKK82) of Myf5 were sufficient and necessary for nucleolus targeting. A GST pulldown assay followed by Western analysis showed that nucleolin/C23 could be pulled down specifically by GST-Myf5, but not by GST-MyoD. Based on these findings, we propose that the distinct functions of Myf5 and MyoD may result from their differential binding affinity to nucleolin/C23.     

Inhibition of nucleolar reformation after microinjection of antibodies to RNA polymerase I into mitotic cells

The formation of daughter nuclei and the reformation of nucleolar structures was studied after microinjection of antibodies to RNA polymerase I into dividing cultured cells (PtK2). The fate of several nucleolar proteins representing the three main structural subcomponents of the nucleolus was examined by immunofluorescence and electron microscopy. The results show that the RNA polymerase I antibodies do not interfere with normal mitotic progression or the early steps of nucleologenesis, i.e., the aggregation of nucleolar material into prenucleolar bodies. However, they inhibit the telophasic coalescence of the prenucleolar bodies into the chromosomal nucleolar organizer regions, thus preventing the formation of new nucleoli. These prenucleolar bodies show a fibrillar organization that also compositionally resembles the dense fibrillar component of interphase nucleoli. We conclude that during normal nucleologenesis the dense fibrillar component forms from preformed entities around nucleolar organizer regions, and that this association seems to be dependent on the presence of an active form of RNA polymerase I.     

Nucleolin in Neurons of the Human Substantia Nigra

Using immunocytochemistry and confocal laser microscopy, the distribution of nucleolin (protein C23) in neurons of the human substantia nigra was investigated. Fragments of the human midbrain (n = 8) with the verified lack of neurodegeneration were used in the study. The material was fixed in zinc ethanol formaldehyde, a special fixative that provides high preservation of antigenic determinants. New morphological data on the distribution of nucleolin in neurons of the human substantia nigra were obtained. Nucleolin was found in the nucleolus and nucleoplasm of dopaminergic neurons but not in the cytoplasm or cell surface. In the nucleolus and nucleoplasm, protein C23 is distributed irregularly in the form of some accumulations (clumps) with fuzzy borders. Moreover, nucleolin distribution varied in structurally similar neurons containing cytoplasmic neuromelanin. The Marinesco bodies typically not exhibiting nucleolin expression were identified in the nucleus, in addition to nucleoli, by confocal laser microscopy with simultaneous use of transmitted light detector. The findings can contribute to elucidation of the role of nucleolin in the specific functions of normal dopaminergic neurons in the human substantia nigra and assessment of probable involvement of C23 in the development of nucleolar stress and neurodegeneration.     

Perichromosomal layer proteins associate with chromosome scaffold and nuclear matrix throughout the cell cycle

According to the radial loop model of chromosome organization, a major role in the formation and maintenance of chromosomes is played by the residual structures (the nuclear matrix in interphase nuclei and the chromosome scaffold in metaphase chromosomes). However, in vivo microscopy has recently revealed that the components of these “static” structures are highly mobile and continuously exchanged between specific target sites and the nucleoplasm or cytoplasm. This contradiction between predicted stability and observed dynamics led us to reexamine the principles underlying the association of proteins with residual structures. In the present paper, we have analyzed the association of two perichromosomal layer proteins, pKi-67 and B23, with the residual structures. The results show that these two proteins are associated with residual structures throughout the cell cycle; only those structures change that contain proteins precipitated by 2 M NaCl (nucleoli, perichromosomal layer, prenucleolar bodies, cytoplasm of mitotic cells). Both pKi-67 and B23 remain associated with the nuclear matrix even when they are translocated to nucleoplasmic foci due to inhibitor action or hypotonic treatment. However, in most cases it remains possible to extract a structurally visible protein fraction with 2 M NaCl (protein distributed in nucleoplasm). One may suppose that the protein fraction associated with residual structures includes molecules interacting with their binding sites at the moment of permeabilization, while the free proteins are extracted (i.e., during the interaction with binding sites, these proteins form salt-resistant complexes; however, on diffusion the same proteins are extractable by the high-salt solution). The residual structures may be considered as a “snapshot” of all proteins transiently (or statically) bound to their target sites at the moment of permeabilization. The article is published in the original.     

Nucleolar localization/retention signal is responsible for transient accumulation of histone H2B in the nucleolus through electrostatic interactions

The majority of known nuclear proteins are highly mobile. The molecular mechanisms by which they accumulate inside stable compartments that are not separated from the nucleoplasm by membranes are obscure. The compartmental retention of some proteins is associated with their biological function; however, some protein interactions within distinct nuclear structures may be non-specific. The non-specific retention may lead to the accumulation of proteins in distinct structural domains, even if the protein does not function inside this domain. In this study, we have shown that histone H2B-EGFP initially accumulated in the nucleolus after ectopic expression, and then gradually incorporated into the chromatin to leave only a small amount of nucleolus-bound histone that was revealed by removing chromatin-bound proteins with DNase I treatment. Nucleolar histone H2B had several characteristics: (i) it preferentially bound to granular component of the nucleolus and interacted with RNA or RNA-containing nucleolar components; (ii) it freely exchanged between the nucleolus and nucleoplasm; (iii) it associated with the nuclear matrix; and (iv) it bound to interphase prenuclear bodies that formed after hypotonic treatment. The region in histone H2B that acts as a nucleolar localization/retention signal (NoRS) was identified. This signal overlapped with a nuclear localization signal (NLS), which appears to be the primary function of this region. The NoRS activity of this region was non-specific, but the molecular mechanism was probably similar to the NoRSs of other nucleolar proteins. All known NoRSs are enriched with basic amino acids, and we demonstrated that positively charged motifs (nona-arginine (R9) and nona-lysine (K9)) were sufficient for the nucleolar accumulation of EGFP. Also, the correlation between measured NoRS activity and the predicted charge was observed. Thus, NoRSs appear to achieve their function through electrostatic interactions with the negatively charged components of the nucleolus. Though these interactions are non-specific, the functionally unrelated retention of a protein can increase the probability of its interaction with specific and functionally related binding sites.     

Inhibition of HDM2 and activation of p53 by ribosomal protein L23

The importance of coordinating cell growth with proliferation has been recognized for a long time. The molecular basis of this relationship, however, is poorly understood. Here we show that the ribosomal protein L23 interacts with HDM2. The interaction involves the central acidic domain of HDM2 and an N-terminal domain of L23. L23 and L11, another HDM2-interacting ribosomal protein, can simultaneously yet distinctly interact with HDM2 together to form a ternary complex. We show that, when overexpressed, L23 inhibits HDM2-induced p53 polyubiquitination and degradation and causes a p53-dependent cell cycle arrest. On the other hand, knocking down L23 causes nucleolar stress and triggers translocation of B23 from the nucleolus to the nucleoplasm, leading to stabilization and activation of p53. Our data suggest that cells may maintain a steady-state level of L23 during normal growth; alternating the levels of L23 in response to changing growth conditions could impinge on the HDM2-p53 pathway by interrupting the integrity of the nucleolus.