Detection of fibrillarin in nucleolar remnants and the nucleolar matrix

In order to gain further insights into the fundamental structure of the nucleolus, nucleolar remnants of Xenopus and chickens were examined for the presence of fibrillarin and nucleolus organizer region (NOR) silver staining. Nucleolar remnants of Xenopus nucleated red blood cells were found to contain easily detectable amounts of fibrillarin and NOR silver staining. Upon examination of various tissues, fibrillarin and NOR silver staining were detected in nucleoli of Xenopus liver hepatocytes and within nucleoli of oocytes and follicle cells from ovaries of mature female toads. By comparison, nucleolar remnants of adult chicken nucleated red blood cells contained only trace amounts of fibrillarin and NOR silver staining, whereas red blood cell nucleolar remnants of immature chicks had easily detectable amounts of fibrillarin and NOR silver staining. Nucleoli from hepatocytes of both adult and immature chickens demonstrated comparable levels of fibrillarin and NOR silver staining. Since fibrillarin was found in nucleolar remnant structures, we tested for (and detected) its presence in residual nucleoli of in situ nuclear matrix derived from HeLa cells. These findings are discussed in terms of the basic structural and functional organization of the nucleolus.     

Altered gravity affects subnucleolus localization of fibrillarin and NopA64, the most important proteins of rRNA processing

Fibrillarin and plant nucleolin homologue NopA64 are two important nucleolar proteins involved in pre-rRNA processing. To understand better the effects of the altered gravity environment on the nucleolus functioning we have investigated the location of fibrillarin and NopA64 in nucleolar subcomponents of cress (Lepidium sativum L.) root meristematic cells grown under simulated microgravity that was compared to the control cells grown in normal conditions at I g. Cress fibrillarin was first shown to have the molecular weight 41 kDa. Both fibrillarin and NopA64 in the cress cell nucleolus are located in the zones known to contain processing pre-rRNA molecules as it has been previously reported in other species. The data confirm participation of these proteins in processomes--RNP complex particles involved in pre-rRNA processing. Under altered gravity a decrease in the quantity of both fibrillarin and NopA64 in the transition zone between fibrillar centres and the dense fibrillar component was observed, compared to control, which could point out to a lowering of the level of early pre-rRNA processing in these experimental conditions. This decrease was also detected in the bulk of the dense fibrillar component. These data support the idea that altered (reduced) gravity results in lowering the level of functional activity of the nucleolus.     

Subnucleolar location of fibrillarin and NopA64 in Lepidium sativum root meristematic cells is changed in altered gravity

Summary. Fibrillarin and the plant nucleolin homolog NopA64 are two important nucleolar proteins involved in pre-rRNA processing. In order to determine the effects of the altered gravity environment on the nucleolus, we have investigated the location of fibrillarin and NopA64 in nucleolar subcomponents of cress (Lepidium sativum L.) root meristematic cells grown under clinorotation, which reproduces an important feature of microgravity, namely, the absence of the orienting action of a gravity vector, and compared it to the location in control cells grown in normal 1 g conditions. Prior to these experiments, we report here the characterization of cress fibrillarin as a 41 kDa protein which can be isolated from meristematic cells in three nuclear fractions, namely, the soluble ribonucleoprotein fraction, the chromatin fraction, and the nuclear-matrix fraction. Furthermore, as reported for other species, the location of both fibrillarin and NopA64 in the cress cell nucleolus was in zones known to contain complex ribonucleoprotein particles involved in early pre-rRNA processing, i.e., processomes. Under altered gravity, a decrease in the quantity of both fibrillarin and NopA64 compared to controls was observed in the transition zone between fibrillar centers and the dense fibrillar component, as well as in the bulk of the dense fibrillar component. These data suggest that altered (reduced) gravity results in a lowered level of functional activity in the nucleolus. Correspondence and reprints: Centro de Investigaciones Biológicas, Consejo Superior de Investigaciones Cientificas, Ramiro de Maeztu 9, 28040 Madrid, Spain.     

Identification of Signal Sequences Determining the Specific Nucleolar Localization of Fibrillarin in HeLa Cells

Fibrillarin is one of the major nucleolar proteins and is involved in pre-rRNA maturation. Its three main regions are a glycine and arginine-rich (GAR) domain, an RNA-binding domain, and an -helical region, which presumably has a methyltransferase activity. Yet the roles of these regions in nucleolus-specific localization of fibrillarin are still unclear. To elucidate this issue, a series of plasmids was constructed to express human fibrillarin mutants fused with the green fluorescent protein. Localization of the chimeric proteins was studied in interphase and mitotic HeLa cells after single transfection with the plasmids. Deletion or a mutation of any domain proved to alter the specific fibrillarin location coinciding with sites of pre-rRNA synthesis. The GAR domain and the first spacer together were sufficient for fibrillarin migration into the nucleolus. Fibrillarin mutants located within the interphase nucleolus did not differ in mitotic location from the wild-type fibrillarin.     

Identification of signal sequences determining the specific nucleolar localization of fibrillarin in HeLa cells

Fibrillarin is one of the major nucleolar proteins and is involved in pre-rRNA maturation. Its three main regions are a glycine and arginine-rich (GAR) domain, an RNA-binding domain, and an alpha-helical region, which presumably has a methyltransferase activity. Yet the roles of these regions in nucleolus-specific localization of fibrillarin are still unclear. To elucidate this issue, a series of plasmids was constructed to express human fibrillarin mutants fused with the green fluorescent protein. Localization of the chimeric proteins was studied in interphase and mitotic HeLa cells after single transfection with the plasmids. Deletion or a mutation of any domain proved to alter the specific fibrillarin location coinciding with sites of pre-rRNA synthesis. The GAR domain and the first spacer together were sufficient for fibrillarin migration into the nucleolus. Fibrillarin mutants located within the interphase nucleolus did not differ in mitotic location from the wild-type fibrillarin.     

Nucleolar assembly of the rRNA processing machinery in living cells

To understand how nuclear machineries are targeted to accurate locations during nuclear assembly, we investigated the pathway of the ribosomal RNA (rRNA) processing machinery towards ribosomal genes (nucleolar organizer regions [NORs]) at exit of mitosis. To follow in living cells two permanently transfected green fluorescence protein-tagged nucleolar proteins, fibrillarin and Nop52, from metaphase to G1, 4-D time-lapse microscopy was used. In early telophase, fibrillarin is concentrated simultaneously in prenucleolar bodies (PNBs) and NORs, whereas PNB-containing Nop52 forms later. These distinct PNBs assemble at the chromosome surface. Analysis of PNB movement does not reveal the migration of PNBs towards the nucleolus, but rather a directional flow between PNBs and between PNBs and the nucleolus, ensuring progressive delivery of proteins into nucleoli. This delivery appeared organized in morphologically distinct structures visible by electron microscopy, suggesting transfer of large complexes. We propose that the temporal order of PNB assembly and disassembly controls nucleolar delivery of these proteins, and that accumulation of processing complexes in the nucleolus is driven by pre-rRNA concentration. Initial nucleolar formation around competent NORs appears to be followed by regroupment of the NORs into a single nucleolus 1 h later to complete the nucleolar assembly. This demonstrates the formation of one functional domain by cooperative interactions between different chromosome territories.     

Evolutionary conservation of the human nucleolar protein fibrillarin and its functional expression in yeast

NOP1 is an essential nucleolar protein in yeast that is associated with small nucleolar RNA and required for ribosome biogenesis. We have cloned the human nucleolar protein, fibrillarin, from a HeLa cDNA library. Human fibrillarin is 70% identical to yeast NOP1 and is also the functional homologue since either human or Xenopus fibrillarin can complement a yeast nop1- mutant. Human fibrillarin is localized in the yeast nucleolus and associates with yeast small nucleolar RNAs. This shows that the signals within eucaryotic fibrillarin required for nucleolar association and nucleolar function are conserved from yeast to man. However, human fibrillarin only partially complements in yeast resulting in a temperature-sensitive growth, concomitantly altered rRNA processing and aberrant nuclear morphology. A suppressor of the human fibrillarin ts-mutant was isolated and found to map intragenically at a single amino acid position of the human nucleolar protein. The growth rate of yeast nop1- strains expressing Xenopus or human fibrillarin or the human fibrillarin suppressor correlates closely with their ability to efficiently and correctly process pre-rRNA. These findings demonstrate for the first time that vertebrate fibrillarin functions in ribosomal RNA processing in vivo.     

Lampenbürstenchromosomen und multiple Nukleolen bei Orthopteren

Isolated unfixed chromosomes from the oocytes of several grasshopper species, of Gryllus domesticus, and of two cockroaches have been investigated under phase contrast. As demonstrated previously in Locusta migratoria (Kunz, 1967), these chromosomes resemble the lampbrush chromosomes in amphibian oocytes. From these the lateral loops of the orthopteran chromosomes differ in that they are only one third as long (Fig. 3). The distinctness of chromomeres and chiasmata is considerably lower than that in amphibian oocytes (Fig. 4). — Besides the lampbrush chromosomes the oocyte nuclei of Orthoptera contain several hundred spheres or granules which are thought to be the multiple nucleoli (Fig. 6). In young oocytes, these nucleoli are vacuolated spheroids aggregated compactly in the center of the nucleus (Fig. 7). In the oocyte of the cricket, this center contains Feulgen-positive material which disappears in the early growth period when the nucleoli transform from solid structures to several hundred spheres. In oocytes of an intermediate size, both in the grasshoppers and Gryllus such spheroids are present. In the larger mature oocytes these spheres are localized peripherally around the nuclear envelope (Decticus; Fig. 10b), or the become extended into beaded ring forms (Gryllus; Fig. 12), or these rings are opened, stretched and connected in a row to form long “pearl-string” threads (Locusta, Acrida, Homorocoryphus). The spheroids around the nuclear envelope of Decticus look very similar to the solid and spheroidal nucleoli in young oocytes of the axolotl (Callan, 1966). The beaded rings of Gryllus resemble the ring-shaped nucleoli in the amphibian oocytes during their intermediate growing phase. — Following Keyl's (1966) hypothesis for the construction of replication units, these different appearances of multiple nucleoli are proposed to be results of a similar mode of extra-replication, but of different arrangement. In the case of Gryllus and Decticus the nucleolar DNA Anlagen are set free from the chromosomes, but they remain attached one behind the other in Locusta and some other grasshoppers.     

Struktur und Funktion der Oocytenchromosomen und Nukleolen sowie der Extra-DNS während der Oogenese panoistischer und meroistischer Insekten

In panoistic ovaries (without nurse cells) there are three predominating structures: lampbrush chromosomes, multiple nucleoli, and the hitherto undescribed endobody (Binnenkörper). Nucleoli are always multiple during the growth period of the oocyte of panoistic ovaries. This is true even in the case of Blattella which seems to possess only one big nucleolus, if examined in the light microscope (cf. Figs. 2 and 14b).—In the meroistic type of ovary (with nurse cells) the development of nucleoli and lampbrush chromosomes in the oocyte is very reduced. Only in the early growth stages of the oocyte the chromosomes despiralisize in a speciesspecific degree before they condense to a karyosphere (Pigs. 8, 9). On the other hand the endobody is bigger in the meroistic than in the panoistic ovary (Figs. 5, 8,14). — Lampbrush chromosomes and multiple nucleoli are sites of a very intensive RNA-synthesis (Fig. 1). The nucleoli are built up by granules measuring 125 Å in diameter (Figs. 15, 16). In the endobody, no RNA-metabolism could be demonstrated (Figs, 1a, b, 8c). The endobody is very homogeneous in electron microscope pictures and clearly distinct from the granular nucleoli (Fig. 17). The labelling pattern after incubation with ³H-amino acids suggests a permanent exchange of protein molecules between the karyoplasm and the endobody. — In the meroistic type of ovary the oocyte obtains RNA from the nurse cells, and RNA-synthesis in the oocyte nucleus is decreased in the same measure as its chromosomes are condensed. — The water-beetles Dytiscus and Acilius possess extra-DNA and deviate from the rule of restricted RNA-synthesis in the oocyte nucleus of the meroistic ovary albeit their chromosomes form a karyosphere too (Fig. 11) and RNA streams also from the nurse chamber into the ooplasm (Fig. 10). The extra-DNA resolves itselve into a network of fine fibrils no longer stainable by the Feulgen reaction. True multiple nucleoli develop on the fibrils suggesting the extra-DNA contains a huge mass of nucleolus organizers. The case of Dytiscus is very similar to the development of the multiple nucleoli in Gryllus.     

Three-dimensional organization of interphase fibroblast nuclei in two closely related shrew species (<Emphasis Type="Italic">Sorex granarius</Emphasis> and <Emphasis Type="Italic">Sorex araneus</Emphasis>) differing in the structures of their chromosome termini

A FISH with a probe for telomeric and rDNA repeats and immunofluorescence with ANA CREST and antibodies to nucleolae protein B23 were used to study the three-dimensional (3D) organization of fibroblast interphase nuclei in two shrew twin species, Sorex granarius and Sorex araneus, of the Cordon race. Karyotypes of these species are composed of nearly identical chromosomal arms and differ in the number of their metacentrics and the structures of their terminal chromosome regions. In the short arms of S. granarius, 32 of the acrocentrics have large telomeres that contain an average of 218 kb telomere repeats, which alternate with ribosomal repeats. These regions also contain active nucleolar organizing regions (NORs). In contrast, in active NORs in S. araneus are localized at the terminal regions of 8 chromosomal arms (Zhdanova et al., 2005; 2007b). Here, we show that associations of chromosomes by telomeres and the contact of a part of the telomere clusters with the inner nuclear membrane and nucleolus characterize the interphase nuclei of both Sorex granarius and Sorex araneus. We also reveal the partial colocalization of telomere and ribosomal clusters and the spatial proximity of centomeric and telomeric regions in the interphase nuclei of S. granarius. It appears that only ribosomal clusters containing a sufficient number of active ribosomal genes exhibit a connection with the nucleolus. Nucleolus disassembly during the fibroblastís transition to mitosis and the role of the B23 protein in this process have been studied.     

Nucleolar transcriptional activity in mouse Sertoli cells is dependent on centromere arrangement

Experimental evidence suggests that centromere arrangement is relevant to the expression of ribosomal genes in murine Sertoli cells. Nuclei endowed with a nucleolus inactive in rRNA synthesis presented several clusters, each containing a bunch of individual centromeres. RNA polymerase I was not cytochemically detected in the nucleolar structure, which contained only small amounts of fibrillarin. In the course of nucleolar activation, the centromeres within the separate clusters became fused into larger centromeric bodies. Synthesis of precursor rRNAs and their processing were visualized by strong nucleolar fluorescence signals using antibodies to RNA polymerase I and fibrillarin.     

A U3 snoRNP protein with homology to splicing factor PRP4 and G beta domains is required for ribosomal RNA processing.

Yeast fibrillarin (NOP1) is an evolutionarily conserved, nucleolar protein necessary for multiple steps in ribosome biogenesis. Yeast mutants lacking a functional NOP1 gene can be complemented by human fibrillarin but are temperature sensitive for growth and impaired in pre-rRNA processing. In order to identify components which interact functionally with human fibrillarin in yeast, we isolated extragenic suppressors of this phenotype. One dominant suppressor, sof1-56, which is allele-specific for human fibrillarin and restores growth and pre-RNA processing at 35 degrees C, was cloned by in vivo complementation. The wild-type allele of SOF1 is essential for cell growth and encodes a novel 56 kDa protein. In its central domain, SOF1 contains a repeated sequence also found in beta-subunits of trimeric G-proteins and the splicing factor PRP4. A single amino acid exchange in the G beta-like repeat domain is responsible for the suppressing activity of sof1-56. Indirect immunofluorescence shows that SOF1 is located within the yeast nucleolus. Co-immunoprecipitation demonstrates the physical association of SOF1 with U3 small nucleolar RNA and NOP1. In vivo depletion of SOF1 leads to impaired pre-rRNA processing and inhibition of 18S rRNA production. Thus, SOF1 is a new component of the nucleolar rRNA processing machinery.