Ellagic Acid-Changed Epigenome of Ribosomal Genes and Condensed RPA194-Positive Regions of Nucleoli in Tumour Cells

We studied the effect of ellagic acid (EA) on the morphology of nucleoli and on the pattern of major proteins of the nucleolus. After EA treatment of HeLa cells, we observed condensation of nucleoli as documented by the pattern of argyrophilic nucleolar organizer regions (AgNORs). EA also induced condensation of RPA194-positive nucleolar regions, but no morphological changes were observed in nucleolar compartments positive for UBF1/2 proteins or fibrillarin. Studied morphological changes induced by EA were compared with the morphology of control, non-treated cells and with pronounced condensation of all nucleolar domains caused by actinomycin D (ACT-D) treatment. Similarly as ACT-D, but in a lesser extent, EA induced an increased number of 53BP1-positive DNA lesions. However, the main marker of DNA lesions, γH2AX, was not accumulated in body-like nuclear structures. An increased level of γH2AX was found by immunofluorescence and Western blots only after EA treatment. Intriguingly, the levels of fibrillarin, UBF1/2 and γH2AX were increased at the promoters of ribosomal genes, while 53BP1 and CARM1 levels were decreased by EA treatment at these genomic regions. In the entire genome, EA reduced H3R17 dimethylation. Taken together, ellagic acid is capable of significantly changing the nucleolar morphology and protein levels inside the nucleolus.

[The nucleolus in oocytes of multylayer mouse follicles: topography of fibrillarin, RNA polymerase I and coilin]

By electron microscopy, conventional fluorescence and confocal microscopy, some features of structural and molecular organization of the nucleolus in oocyte nucleus from mouse multilayer follicles were examined. The examined nucleolus lacks almost all characteristic nucleolar components, such as fibrillar centers, dense fibrillar and granular components. This nucleolus consists exclusively of a homogenous filamentous material and is penetrated by numerous interstices. Besides, a striking association of the nucleolus with coilin, a marker of Cajal bodies, was observed. We could map the coilin accumulation in three different areas: around, in the periphery, or inside the nucleolus. Additionally, we examined a topological relationship between coilin and two key proteins of nucleolar transcription-processing machinery, RNA polymerase I and fibrillarin. RNA polymerase I rather than fibrillarin was found to be colocalized with coilin. Finally, we propose that data on dynamics of coilin relation with the nucleolus may elucidate a possible role of coilin in functional relationship between the nucleolus and Cajal bodies.

Colocalization of coilin and nucleolar proteins in Cajal body-like structures of micronucleated PtK2 cells

Cajal bodies (CB) are ubiquitous nuclear structures involved in the biogenesis of small nuclear ribonucleoproteins and show narrow association with the nucleolus. To identify possible relationships between CB and the nucleolus, the localization of coilin, a marker of CB, and of a set of nucleolar proteins was investigated in cultured PtK2 cells undergoing micronucleation. Nocodazol-induced micronucleated cells were examined by double indirect immunofluorescence with antibodies against coilin, fibrillarin, NOR-90/hUBF, RNA polymerase I, PM/Scl, and To/Th. Cells were imaged on a BioRad 1024-UV confocal system attached to a Zeiss Axiovert 100 microscope. Since PtK2 cells possess only one nucleolus organizer region, micronucleated cells presented only one or two micronuclei containing nucleolus. By confocal microscopy we showed that in most micronuclei lacking a typical nucleolus a variable number of round structures were stained by antibodies against fibrillarin, NOR-90/hUBF protein, and coilin. These bodies were regarded as CB-like structures and were not stained by anti-PM/Scl and anti-To/Th antibodies. Anti-RNA polymerase I antibodies also reacted with CB-like structures in some micronuclei lacking nucleolus. The demonstration that a set of proteins involved in RNA/RNP biogenesis, namely coilin, fibrillarin, NOR-90/hUBF, and RNA polymerase I gather in CB-like structures present in nucleoli-devoid micronuclei may contribute to shed some light into the understanding of CB function.

The composition of the RNA polymerase I transcription machinery switches from initiation to elongation mode

The amounts of RNA polymerase I (Pol I) and basal rDNA transcription factors were determined in yeast whole cell extracts. A 17-fold excess of Pol I was found compared to the Pol I-specific initiation factors upstream activating factor (UAF) and core factor (CF) which underlines that both initiation factors interact with a minor fraction of Pol I when rDNA transcription is active. Surprisingly, Rrn3p, another Pol I-specific initiation factor, is more abundant in cell lysates than UAF and CF. Our analyses revealed that a large fraction of cellular Rrn3p is not associated with Pol I. However, the amount of initiation-active Rrn3p which forms a stable complex with Pol I corresponds to the levels of UAF and CF which have been shown to bind the promoter. Initiation-active Rrn3p dissociates from the template during or immediately after Pol I has switched from initiation to elongation. Our data support a model in which the elongating Pol I leaves the initiation factors UAF, CF and Rrn3p close by the promoter.

Localization of the yeast RNA polymerase I-specific subunits

The spatial distribution of four subunits specifically associated to the yeast DNA-dependent RNA polymerase I (RNA pol I) was studied by electron microscopy. A structural model of the native enzyme was determined by cryo-electron microscopy from isolated molecules and was compared with the atomic structure of RNA pol II Delta 4/7, which lacks the specific polypeptides. The two models were aligned and a difference map revealed four additional protein densities present in RNA pol I, which were characterized by immunolabelling. A protruding protein density named stalk was found to contain the RNA pol I-specific subunits A43 and A14. The docking with the atomic structure showed that the stalk protruded from the structure at the same site as the C-terminal domain (CTD) of the largest subunit of RNA pol II. Subunit A49 was placed on top of the clamp whereas subunit A34.5 bound at the entrance of the DNA binding cleft, where it could contact the downstream DNA. The location of the RNA pol I-specific subunits is correlated with their biological activity.

Immunolocalization of nucleolar proteins during bovine oocyte growth, meiotic maturation, and fertilization

During the growth phase of the bovine oocyte transcripts, polypeptides and ribosomes are accumulated in the oocyte to drive and sustain future meiotic maturation, fertilization, and early embryonic development. The oocyte also furnishes the early embryo with the components required to establish a functional transcriptionally active nucleolus at the time of maternal embryonic transition. The aim of the present study was to describe the behavior of key components of the nucleolus. The temporal localization of nucleolar proteins fibrillarin, nucleophosmin, nucleolin, RNA polymerase I (RNA pol I), topoisomerase I, upstream binding factor (UBF), and coilin 5P10 was investigated in growing and fully grown immature bovine oocytes during in vitro maturation and during the first postfertilization cell cycle using whole-mount immunocytochemistry and confocal microscopy. During the oocyte growth phase, fibrillarin, nucleophosmin, nucleolin, RNA pol I, and UBF were localized to the oocyte nucleolus. On completion of the growth phase, nucleolin and nucleophosmin appeared to migrate to the periphery of the nucleolus and into the nucleoplasm, and the proportion of oocytes displaying RNA pol I localization had decreased. Topoisomerase I was not detected at any stage. Fibrillarin appeared to be localized to large foci within the nucleolus and/or nucleoplasm. Nucleophosmin and nucleolin labeling was characterized by a homogeneous signal over the nucleolus. RNA pol I and UBF were characterized by the localization of the antibodies to individual or clustered foci in the nucleolus and/or nucleoplasm. Following oocyte nucleus breakdown (ONBD), the proteins appeared to disperse into the cytoplasm. All proteins were undetectable during meiotic maturation and were not relocalized until 5-10 h postinsemination (hpi). UBF was localized to the fertilizing sperm head of most zygotes at 5 hpi. By 10 hpi, all proteins were detected in most oocytes displaying two pronuclei. Nucleolar protein localization was exclusive to or more abundant in one pronucleus up to 20 hpi; thereafter, the pattern was more evenly distributed. Fibrillarin, nucleophosmin, nucleolin, UBF, and Pol I are present in the nuclei of growing and fully grown bovine oocytes until ONBD. They reappear at the late telophase stage of meiosis II and continue to be present up to the first mitotic division of embryo development.

Nucleolar size indicates the rapidity of cell proliferation in cancer tissues

In order to define the importance of the nucleolus in tumour pathology, the relationship between nucleolar size and function and tumour mass growth rate was studied in vivo. Ten established human cancer cell lines from colon carcinomas and neuroblastomas were inoculated subcutaneously in athymic mice and the doubling time (DT) of the xenograft tumour mass was calculated. The tumour DTs ranged from 3.2 to 15.7 days. Nucleolar size was evaluated in sections from formalin-fixed and paraffin-embedded tumour samples after silver staining for AgNOR proteins, using a specific image analysis system. The nucleolar area values were inversely related to the xenograft tumour mass DTs (r=-0.90; p<0.001). Nucleolar functional activity was also evaluated using rapid, intermediate, and slow growing tumours (one each). The values of RNA polymerase I activity measured in vitro were strongly related to the corresponding tumour DTs (r=-0. 99; p=0.03). The labelling indices (LIs) of three proliferation markers, MIB1, PCNA, and bromodeoxyuridine (BrdU), were also evaluated. As revealed by the MIB1 and PCNA LIs, almost all the cells of the xenograft tumours were cycling (86.6+/-5.6 SD and 95. 5+/-2.0 SD, respectively). Neither the MIB1, PCNA or BrdU LIs were related to the xenograft tumour mass DT, showing that the different growth rates of tumour xenografts were not due to different growth fractions, but were mainly related to different cell proliferation rates. The present data demonstrate that the size and function of the nucleolus are related to the cell proliferation rate of cancer tissue. Evaluation of nucleolar size after silver staining of AgNOR proteins represents a unique parameter for the histological assessment of rapidity of cell proliferation in tumour lesions.

Brain RNA polymerase and nucleolar structure in perinatal asphyxia of the rat

Ribosomes are integral constitutens of the protein synthesis machinery. Polymerase I (POL I) is located in the nucleolus and transcribes the large ribosomal genes. POL I activity is decreased in ischemia but nothing is known so far on POL I in perinatal asphyxia. We investigated the involvement of POL I in a well-documented model of graded systemic asphyxia at the level of activity, mRNA, protein, and morphology. Caeserean section was performed at the 21st day of gestation. Rat pups still in the uterus horns were immerged in a water bath for asphyctic periods from 5-20 min. Brain was taken for measurement of pH, nuclear POL I activity, and mRNA steady state, and protein levels of RPA40, an essential subunit of POL I and III. Silver staining and transmission electron microscopy with morphometry when appropriate were used to examine the nucleolus. Brain pH and nuclear POL I activity decreased with the length of the asphyctic period while POL-I mRNA and protein levels were unchanged. Accompanying the decrease in brain pH we found significant changes of nucleolar structure in the course of perinatal asphyxia at the light and electron microscopic level. As early as ten min following the asphyctic insult, morphological disintegration of the nucleolus was observed. The changes became more dramatic with longer duration of perinatal asphyxia. We conclude that severe acidosis may be responsible for decreased POL activity and for disintegration of nucleoli in neurons. This condition may lower the ribosome content in neonatal neurons and impair protein synthesis.

The mitotically phosphorylated form of the transcription termination factor TTF-1 is associated with the repressed rDNA transcription machinery

The transcription termination factor TTF-1 exerts two functions in ribosomal gene (rDNA) transcription: facilitating initiation and mediating termination of transcription. Using HeLa cells, we show that TTF-1 protein is colocalized with the active transcription machinery in the nucleolus and also with the inactive machinery present in certain mitotic nucleolar organizer regions (NORs) when rDNA transcription is repressed. We also show that TTF-1 is specifically phosphorylated during mitosis in a manner dependent on the cdc2-cyclin B kinase pathway and on an okadaic acid-sensitive phosphatase. Interestingly, the mitotically phosphorylated form of TTF-1 appearing at the G(2)/M transition phase was more easily solubilized than was the interphase form. This indicates that the chromatin-binding affinity of TTF-1 appears to be different in mitotic chromosomes compared to the interphase nucleolus. Correlated with this, the other DNA-binding factor, UBF, which interferes with chromatin conformation in the rDNA promoter, was more strongly bound to rDNA during mitosis than at interphase. The reorganization of the mitotic rDNA promoter might be induced by phosphorylation of certain components of the rDNA transcription machinery and participate in silencing of rDNA during mitosis.

Association of the nucleolar transcription factor UBF with the transcriptionally inactive rRNA genes of pronuclei and early Xenopus embryos

When nuclei (pronuclei) were assembled from sperm chromatin in Xenopus egg extract and examined by immunofluorescence microscopy, UBF was concentrated at a single intranuclear dot-like or more extended necklace-like structure. These UBF-foci contained rDNA as demonstrated by in situ hybridization and hence represent the chromosomal nucleolus organizing regions (NORs). Besides UBF, other components of the transcription machinery such as the TATA-box binding protein (TBP) and RNA polymerase I (pol I) as well as several nucleolar proteins could not be detected at the NORs. Immuno-depletion experiments indicated the UBF is maternally provided and taken up by the pronuclei. Essentially the same results were obtained when we examined the NORs of early Xenopus embryos up to the midblastula stage. After this stage, when transcription of the rRNA genes has begun, nucleoli developed and the NORs acquired TBP and pol I. Our results support the hypothesis that UBF is an architectural element which converts the rDNA chromatin into a transcriptionally competent form.

In vivo evidence that TATA-binding protein/SL1 colocalizes with UBF and RNA polymerase I when rRNA synthesis is either active or inactive

Here we show that the TATA-binding protein (TBP) is localized in the nucleoplasm and in the nucleolus of mammalian cells, consistent with its known involvement in transcription by RNA polymerase I, II, and III. In the nucleolus of actively growing cells, TBP colocalizes with upstream binding factor (UBF) and RNA polymerase I at the sites of rRNA transcription. During mitosis, when rRNA synthesis is down-regulated, TBP colocalizes with TBP-associated factors for RNA polymerase I (TAF(I)s), UBF, and RNA polymerase I on the chromosomal regions containing the rRNA genes. Treatment of cells with a low concentration of actinomycin D inhibits rRNA synthesis and causes a redistribution of the rRNA genes that become concentrated in clusters at the periphery of the nucleolus. A similar redistribution was observed for the major components of the rRNA transcription machinery (i.e., TBP, TAF(I)s, UBF, and RNA polymerase I), which still colocalized with each other. Furthermore, anti-TBP antibodies are shown to coimmunoprecipitate TBP and TAF(I)63 in extracts prepared from untreated and actinomycin D-treated cells. Collectively, the data indicate that in vivo TBP/promoter selectivity factor, UBF, and RNA polymerase I remain associated with both active and inactive rRNA genes.

The rDNA transcription machinery is assembled during mitosis in active NORs and absent in inactive NORs

In cycling cells, the rDNAs are expressed from telophase to the end of G2 phase. The early resumption of rDNA transcription at telophase raises the question of the fate of the rDNA transcription machinery during mitosis. At the beginning of mitosis, rDNA transcription is arrested, and the rDNAs are clustered in specific chromosomal sites, the nucleolar organizer regions (NOR). In human cells, we demonstrate that the rDNA transcription machinery, as defined in vitro, is colocalized in some NORs and absent from others whatever the mitotic phase: RNA polymerase I and the RNA polymerase I transcription factors, upstream binding factor and promoter selectivity factor (as verified for TATA-binding protein and TATA-binding protein-associated factor for RNA polymerase I [110]), were colocalized in the same NORs. The RNA polymerase I complex was localized using two different antibodies recognizing the two largest subunits or only the third largest subunit, respectively. These two antibodies immunoprecipitated the RNA polymerase I complex in interphase cells as well as in mitotic cells. These results clearly indicated that the RNA polymerase I complex remained assembled during mitosis. In addition, RNA polymerase I and the transcription factors varied in the same proportions in the positive NORs, suggesting stoichiometric association of these components. The fact that the rDNA transcription machinery is not equally distributed among NORs most likely reflects the implication of the different NORs during the subsequent interphase. Indeed, we demonstrate that only positive NORs exhibit transcription activity at telophase and that the level of transcription activity is related to the amount of rDNA transcription machinery present in the NOR. We propose that assembly of rDNA transcription machinery preceding mitosis determines expression of the rDNAs at the beginning of the next cell cycle. Consequently, the association of rDNAs with the rDNA transcription machinery defines the "active" NORs and the level of activity at the transition telophase/interphase.

20-Hydroxyecdysone stimulates RNA polymerase I activity in silkmoth wing epidermis by increased synthesis and phosphorylation

The activities of RNA polymerases I and II in the wing epidermis of diapausing silkmoth pupae increased about tenfold during the first day after administration of either 20-hydroxyecdysone (20E) or 20E plus juvenile hormone (Katula et al., 1981a). The aim of these studies was to correlate these increases in RNA polymerase I and II activities to their amounts in hormone stimulated wing epidermis. The enzyme activities were measured by standard procedures while their amounts were determined by the application of a modified ELISA with subunit-specific monoclonal antibodies. Results showed that the increase in the amount of RNA polymerase I during the first 24 h accounted for only about 60% of the increase in activity. Alkaline phosphatase decreased the activity of the newly synthesized enzyme by 40-50%. These results indicate that hormone-stimulation of RNA polymerase I activity is due to a combination of synthesis of the enzyme and phosphorylation of the enzyme and/or tightly associated factors. RNA polymerases II and III determined by differential ELISA using a monoclonal antibody specific to a common subunit followed developmental changes similar to those of RNA polymerase I. The amounts and activity of the enzymes during the first 48 h were similar in wing tissue that followed the second pupal development (20E + juvenile hormone) compared to tissue that developed into adult wings (20E).

Three-dimensional co-location of RNA polymerase I and DNA during interphase and mitosis by confocal microscopy

The relative three-dimensional co-location of RNA polymerase I (RPI) and DNA was studied using confocal laser scanning microscopy during interphase and all the steps of mitosis in human cancerous cells. For each step of the cell cycle, immunolabeled RPI molecules and DNA specifically stained with chromomycin A3 were simultaneously imaged at high resolution through numerous optical sections. Then, all the data obtained were used to generate transverse sections, anaglyphs and volumic representations, which are all prerequisite approaches to a representative study of the three-dimensional organization of the nucleolus and the mitotic chromosomes. Our results indicated that in the interphasic nuclei, in which DNA is organized as a regular 3-D network, RPI was present within numerous irregular spheres arranged as several twisted necklaces. During metaphase, RPI labeling was segregated into pairs of spheres and typical crescent-shaped structures; both were centrally located within the set of chromosomes. During anaphase and telophase, a typical central and symmetric arrangement of labeled structures was systematically seen among the decondensing chromosomes, arranged as a regular cylinder and as a hollow half-sphere, respectively. This typical 3-D organization of structures containing RPI relative to DNA is another strong example of the non-random organization of the genome during interphase and mitosis.

HIV-1 Rev is capable of shuttling between the nucleus and cytoplasm

The mechanism by which Rev facilitates the export, and consequently, the translation of the structural protein mRNAs of the human immunodeficiency virus type 1 remains undefined. Previous immunolocalization has determined that Rev is predominantly in the nucleus with significant accumulation in the nucleolus, a localization consistent with the assumed site of Rev action. To determine whether the subcellular distribution is more dynamic than what was indicated by the original studies, the capacity of Rev to shuttle between the nucleus and cytoplasm was examined. It was observed that treatment of cells with DRB or actinomycin D resulted in a dramatic alteration in Rev distribution, the majority of the protein being found in the cytoplasm. Removal of the drug resulted in a rapid accumulation of Rev in the nucleus indicating that the block to nuclear import was reversible. Subsequent studies indicated that the movement of Rev into the cytoplasm was a passive process while its accumulation in the nucleus was an active one, given that only the latter displayed sensitivity to temperature. Finally, it was demonstrated that, while extensive redistribution of Rev could be attained by inhibition of RNA polymerase I alone, Rev was still capable of inducing expression of HIV structural gene expression under these conditions. Consequently, Rev activity does not appear to be dependent on either an intact nucleolus or the accumulation of the protein in the nucleus.

Dexamethasone stimulates rRNA gene transcription in rat myoblasts

The glucocorticoid analogue, dexamethasone, stimulated RNA synthesis more than two-fold in rat L6 myoblasts, without affecting the rate of cell proliferation. Treatment of myoblasts for 24 h with 10(-7) M dexamethasone resulted in a 30% increase in the cellular RNA level. More than a two-fold stimulation of pre-rRNA gene transcription by dexamethasone, as measured in isolated nuclei and by cell-free transcription, was accompanied by a corresponding increase in pre-rRNA levels. Co-incubation of myoblasts with cycloheximide and dexamethasone did not affect the enhanced pre-rRNA gene transcription demonstrating that de novo protein synthesis was unnecessary to manifest the dexamethasone effect on rDNA transcription. Support for this conclusion is provided by the finding that the levels of UBF1 and UBF2, rDNA upstream binding transcription factors, remain unchanged. The glucocorticoid antagonist RU38486 [11 beta-(4-dimethylaminophenyl)17 beta-hydroxy-17 alpha-(prop-1-ynyl)estra- 4,9-dien-3-one] inhibited the dexamethasone-stimulated rRNA gene transcription suggesting that the glucocorticoid receptor is involved in the response mechanism.

A modified PABC immunoassay for the quantitation of DNA dependent RNA polymerase I: a procedure applicable to other proteins present in minute amounts and/or isoforms

An indirect enzyme linked immunoassay (ELISA) has been developed to measure the amount of RNA polymerase I (E.C.2.7.7.6) in silkmoth tissue cell extracts. Subunit specific monoclonal antibodies (MABs) were immobilized on the solid substrate by a variation of the widely used Protein-Avidin-Biotin-Capture (PABC) technique. The use of the commercially available biotinylated anti-mouse antibody as a bridge to bind the monoclonal antibody eliminates the need for the biotinylation of the monoclonal antibody in the laboratory. The RNA polymerase in solution was captured by the monoclonal antibody and was measured by the successive binding of rabbit polyclonal antibody and alkaline phosphatase conjugated anti-rabbit antibody. This procedure is more reliable, reproducible and leads to greater sensitivity compared to the direct binding of the monoclonal antibody to the microtiter plate. RNA polymerase I captured by the antibodies from tissue extracts was measured at levels of 0.5 ng/well. This assay system can be utilized as a general procedure to quantitate the levels of proteins present at very low levels and that are found in different isoforms containing multiple and/or shared subunits.

A Drosophila anti-RNA polymerase II antibody recognizes a plant nucleolar antigen, RNA polymerase I, which is mostly localized in fibrillar centres

The distribution of nucleolar RNA polymerase in the nucleolus of onion root meristematic cells has been studied by means of an antibody originally raised against Drosophila RNA polymerase II. This antibody recognizes the homologous domains of the large subunit of the enzyme, which are highly conserved throughout evolution in the three classes of eucaryotic RNA polymerases. Given that RNA polymerase I is confined to the nucleolus, and that the onion cell nucleolus lacks digitations of extranucleolar chromatin, we conclude that the nucleolar enzyme localized is RNA polymerase I. A quantitative approach, independent of the existence of borderlines between nucleolar fibrillar centres and the dense fibrillar component, allowed us to show that the enzyme is localized in fibrillar centres and in the transition area between them and the dense fibrillar component, in parallel with the nucleolar DNA. These results, together with previous autoradiographic, cytochemical and immunocytochemical results, in this and other species, lead us to conclude that the activation of rDNA for transcription occurs in the fibrillar centres and pre-rRNA synthesis is expressed at the transition area between fibrillar centres and the dense fibrillar component. Fibrillar centres are connected to each other by extended RNA polymerase-bound DNA fibres, presumably active in transcription. This work provides evidence of the high evolutionary conservation of some domains of the large subunit of RNA polymerases and of the existence of fibrillar centres in the nucleolus of plant cells, totally homologous to those described in mammalian cells.

Immunolocalization of a subnucleolar nucleoprotein complex containing RNA polymerase 1 in ascites hepatoma cells using monoclonal antibodies

We have isolated a discrete subnucleolar macromolecular nucleoprotein complex by direct treatment of Novikoff ascites hepatoma nucleoli by MspI restriction digestion. Using a monoclonal antibody made against the subnucleolar nucleoprotein complex that was shown to inhibit RNA polymerase (pol) 1 activity in vitro, we localized an Mr approximately 55,000 protein subunit which was demonstrated previously by an enzyme-linked immunosorbent assay and Western blotting to share epitopes with the RNA pol 1 moiety of the subnucleolar complex. By indirect immunofluorescence the distribution of the Mr approximately 55,000 component of the subnucleolar nucleoprotein complex was examined at various phases of the cell cycle. At prophase, it was localized in large (approximately 1.5 microns in diameter) ball-like structures associated with the nuclear periphery and nuclear peripheral chromatin, suggesting that these structures might be related to preribosomal elements. After chromatin condensation and the pairing of daughter chromosomes, the large ball-like spheres increased in size and were associated with propidium iodide staining at one side of the nucleus; whereas throughout and especially at the opposite side of the nucleus, smaller, round, punctate structures of approximately 0.5 micron in diameter were visibly labeled that were not associated with propidium iodide staining. At later stages of the cell cycle, these small round structures were again associated with propidium iodide staining, suggesting that they may be related to prenucleolar and/or preribosomal elements which would likely contain the appropriate nucleic acid in association with RNA pol 1 and cofactors of RNA pol 1.

Active site labeling of the RNA polymerases A, B, and C from yeast

RNA polymerases A, B, and C from yeast were modified by reaction with 4-formylphenyl-gamma-ester of ATP as priming nucleotide followed by reduction with NaBH4. Upon phosphodiester bond formation with [alpha-32P]UTP, only the second largest subunit, A135, B150, or C128, was labeled in a template-dependent reaction. This indicates that these polypeptide chains are functionally homologous. The product covalently bound to B150 subunit was found to consist of a mixture of ApU and a trinucleotide. Enzyme labeling exhibited the characteristic alpha-amanitin sensitivity reported for A and B RNA polymerases. Labeling of both large subunits of enzyme A and B but not of any of the smaller subunits was observed when the reduction step stabilizing the binding of the priming nucleotide was carried out after limited chain elongation. These results illustrate the conservative evolution of the active site of eukaryotic RNA polymerases.

Alteration in the ribonucleic acids in rat liver induced by a methionine-free total parenteral nutrition solution

The effect of infusion of a methionine-free total parenteral nutrition solution for 7 d on ribonucleic acids in liver of rats were investigated. The control solution contained leucine, valine, isoleucine, lysine, phenylalanine, threonine, tryptophan, arginine, histidine, glycine, methionine, glucose and vitamins and minerals. Deprivation of a methionine is known to increase the activity of RNA polymerase I. Infusing the methionine-free solution resulted in the accumulation of RNA molecules larger than 28S in the liver nuclei and resulted in a higher rate of rRNA synthesis than in rats infused with the control solution. A methionine deficiency did not impede either the processing of 45S pre-rRNA or transport of 28S and 18S rRNA into cytoplasm. When rats were infused with the methionine-free solution for 7 d followed by the control solution for 2 d, the level of RNA in the nucleus as well as the rate of RNA polymerase I were similar to the levels in rats receiving the control solution for 9 d. There were no significant changes in the rate of DNA synthesis due to nutritional manipulations.

Monoclonal antibodies directed against mammalian RNA polymerase I. Identification of the catalytic center

Mouse myeloma cells were fused with splenocytes from a mouse that had been immunized with RNA polymerase I purified from a rat hepatoma. Hybridoma cells were selected and colonies secreting antibodies directed against the enzyme were detected by analysis of cell culture supernatants in a solid phase radioimmunoassay. Two of these cell lines were grown on a larger scale and the interaction between the immunoglobulins obtained from them and RNA polymerase I was studied in detail. Antibodies from both of the hybridoma cell lines were able to inhibit DNA-dependent RNA synthesis catalyzed by RNA polymerases I and III, but not that catalyzed by polymerase II. The antibodies were also capable of reducing the RNA chain elongation reaction catalyzed either by RNA polymerase I associated with isolated nucleoli or by enzyme preinitiated in vitro on calf thymus DNA. Inhibition of RNA polymerase I activity by the monoclonal antibodies was inversely related to the nucleotide concentration. In contrast, the DNA concentration had relatively little effect on inhibition by the antibodies. Analysis of immune complex formation between the antibodies and isolated individual enzyme subunits demonstrated that the monoclonal antibodies were directed against the largest (Mr = 190,000) polypeptide of the polymerase I. These data indicate that the largest subunit of RNA polymerase I contains an immunological determinant in common with RNA polymerase III and suggest that the polymerase I polypeptide of Mr = 190,000 contains a catalytic center involved in RNA chain elongation.

Partial purification and characterization of DNA-dependent RNA polymerases I and II from cherry salmon (Oncorhynchus masou)

1. DNA-dependent RNA polymerases I and II were purified approx 3900- and 13,000-fold, respectively, from sonicated nuclear extract of cherry salmon (Oncorhynchus masou) liver by DEAE-Sephadex, heparin-Sepharose and DNA-cellulose column chromatography. 2. The purified RNA polymerases exhibited a requirement for four kinds of ribonucleoside 5'-triphosphates, an exogeneous template and divalent cation. 3. The activities of RNA polymerases I and II were inhibited by Actinomycin D (24 micrograms/ml) but not by Rifampicin (200 micrograms/ml). 4. RNA polymerase I preferred native DNA as template, while polymerase II preferred single-stranded DNA. 5. RNA polymerase II was inhibited by a low concentration of alpha-amanitin (0.02 micrograms/ml). RNA polymerase I was also inhibited by the relatively high concentration of alpha-amanitin (IC50 = 100 micrograms/ml and IC70 = 750 micrograms/ml). 6. RNA polymerases from cherry salmon exhibited a higher activity at low temperature than from rat liver.

Subchronic administration of caffeine and theophylline in drinking water: effects on rat liver RNA polymerase I activity

Administration of caffeine or theophylline, 0.2 mg/ml (an average of 20 mg/kg/d) of drinking water, to male CD rats, 2 months of age, over a 15 week period resulted in the elevation of liver RNA polymerase I activity by 2-3 fold as assayed in isolated nuclei. This increase in activity was already apparent by the fourth week of exposure. The changes in RNA polymerase I activity were accompanied by moderate liver hypertrophy.

Characterization of a nucleolar residue fraction that specifically transcribes preribosomal RNA

Treatment of isolated nucleoli with Sarkosyl (2%) dissociated 99.5% of the proteins. The residual DNA-protein complex contained the endogenous transcriptional activity which had a high fidelity of RNA synthesis. Electron microscopic analysis of this residue fraction showed the presence of 150-200A diameter protein globules present along the length of some of the DNA fibers. SDS-polyacrylamide gel electrophoretic analysis of the proteins of the complex indicated that the subunits of purified RNA polymerase I were only a minor component of this complex. Associated with the complex were the U3 and 5S RNA.

[Reduced catalytic effectiveness of RNA polymerase I in hepatocytes of rats treated with cycloheximide]

Rat liver RNA polymerase I solubilized from isolated nuclei and present in a soluble form in the cytoplasmic fraction has been analyzed by phosphocellulose chromatography 3 hours after the administration of cycloheximide. The antibiotic did not induce any change in the chromatographic properties of both nuclear and cytoplasmic RNA polymerase I. They appeared to remain in the IB and IA forms, characteristic of the transcribing (IB) and non-transscribing (IA) enzyme. While the level of the nuclear enzyme was not modified, the level of the cytoplasmic one appeared significantly increased. These results support previous ones indicating that the cycloheximide-induced inhibition of ribosomal RNA synthesis cannot be merely explained by a decrease in the nuclear or cellular level of RNA polymerase I. The cellular level of RNA polymerase I, taking into account the relative proportion of the enzyme found in nuclei and cytoplasm, appeared to be slightly increased. Cycloheximide administration did not seem to result in the appearance, in intact nuclei, of enzyme molecules in a free form or as blocked transcription complexes. It is concluded that the antibiotic affects the catalytic efficiency rather than the number of RNA polymerase I molecules actually engaged in the transcription of ribosomal cistrone.

RNA polymerase from the fungus, Aspergillus nidulans. Large-scale purification of DNA-dependent RNA polymerase I (or A)

The DNA-dependent RNA polymerase I (or A) from the lower eukaryote Aspergillus nidulans has been purified on a large scale to apparent homogeneity by homogenizing the fungal hyphae in liquid nitrogen, extraction of the enzyme at high salt concentration, precipitation of RNA polymerase activity with polymin P (a polyethylene imine), elution of the RNA polymerase from the polymin P precipitate, ammonium sulphate precipitation, molecular sieving on Bio-Gel A-1.5m, binding to ion-exchangers and DNA-cellulose affinity chromatography. By this procedure 1.6 mg of RNA polymerase I can be purified over 2000-fold from 500 g wet weight of starting material with a yield of 30--35%. The isolated RNA polymerase I is stable for several months at -20 degrees C. The subunit compostion has been resolved by polyacrylamide gel electrophoresis on two-dimensional gels, using either non-denaturing of 8 M urea (pH 8.7) cylindrical gels in the first dimension and sodium dodecyl sulphate slab gels in the second dimension. The putative subunits have molecular weights of 190,000, 135,000, 63,000, 62,000, 43,000, 29,000, (28,000), 16,000 and probably 13,000 and 12,000. Two distinct forms of RNA polymerase I (Ia and Ib) have been resolved by DEAE-Sephadex A-25 chromatography showing ample differences in enzymatic properties and subunit pattern. Additional information is given on RNA polymerase II (or B) which appears to be highly insensitive to alpha-amanitin at concentrations up to 400 micrograms/ml.

RNA synthesis in permeable mouse ascites sarcoma cells

A permeable cell system for studying RNA synthesis was established. Mouse ascites sarcoma cells were made permeable to nucleoside triphosphates and alpha-amanitin by treating with a hypotonic buffer. Separate determinations of endogenous RNA polymerase I, II and III activities in permeable cells were conducted using the different sensitivities of these enzymes to alpha-amanitin. The endogenous activity of RNA polymerase II under optimal conditions was one tenth of total RNA synthetic activity in isolated nuclei, and one third of that in permeable cells. The extremely low ratio of RNA polymerase II activity to total RNA synthetic activity in isolated nuclei was thought to be caused by increase of RNA polymerase I activity and decrease of RNA polymerase II activity. These and other results suggested that RNA synthesis in permeable cells reflects more precisely the in vivo state of RNA synthesis than thatin isolated nuclei. The permeable cell system will provide a useful method for studying the separate activities of RNA polymerases I, II and III in situ.

Nucleolar DNA-dependent RNA polymerase from rat liver. 1. Purification and subunit structure

DNA-dependent RNA polymerase I (or A) was purified from rat liver nucleoli. DNA was effectively removed from the solubilized enzyme with a defined concentration of polyethyleneglycol. The enzyme was purified further with successive DEAE-Sephadex and phosphocellulose column chromatography followed by glycerol gradient centrifugation. The procedure yielded an electrophoretically homogeneous enzyme with a specific activity 400 times that of the nucleolar extracts. The recovery of the activity was approximately 20%. The RNA polymerase I eluted as a single peak from DEAE-Sephadex was separated into two distinct peaks by a phosphocellulose column. The first peak eluting at about 0.12 M ammonium sulfate was designated as RNA polymerase IA and the second peak eluting at about 0.18 M as RNA polymerase IB. In normal rat liver nucleoli IA enzyme comprised approximately 20% of the total RNA polymerase I activity and the IB enzyme comprised approximately 80%. On sodium dodecyl sulfate polyacrylamide gel electrophoresis, enzyme IB contained five subunits with molecular weights of 195000 (a), 130000 (b), 65000 (c), 40000 (d), and 19000 (e) at nearly equimolar amounts. The calculated molecular weight of the enzyme (449000) agreed well with that predicted from the sedimentation coefficient of the enzyme. Enzyme IA contained identical subunits except that subunit c was absent. Preliminary studies could not demonstrate any significant differences in template specificity between IA and IB enzyme.