Single ribosomal transcription units are linear, compacted Christmas trees in plant nucleoli.

The rDNA transcription units are enormous macromolecular structures located in the nucleolus and containing 50-100 RNA polymerases together with the nascent pre-rRNA attached to the rDNA. It has not previously been possible to visualize nucleolar transcription units directly in intact nucleoli, although highly spread preparations in the electron microscope have been imaged as "Christmas trees" 2-3 microm long. Here we determine the relative conformation of individual transcription units in Pisum sativum plant nucleoli using a novel labelling technique. Nascent transcripts were detected by a highly sensitive silver-enhanced 1 nm gold procedure, followed by 3D electron microscopy of entire nucleoli. Individual transcription units are seen as conical, elongated clusters approximately 300 nm in length and 130 nm in width at the thickest end. We further show that there were approximately 300 active ribosomal genes in the nucleoli examined. The underlying chromatin structure of the transcribing rDNA was directly visualized by applying a novel limited extraction procedure to fixed specimens in order to wash out the proteins and RNA, thus specifically revealing DNA strands after uranyl acetate staining. Using this technique, followed by post-embedding in situ hybridization, we observed that the nucleolar rDNA fibres are not extended but show a coiled, thread-like appearance. Our results show for the first time that native rDNA transcription units are linear, compacted Christmas trees.

A pea homologue of human DNA helicase I is localized within the dense fibrillar component of the nucleolus and stimulated by phosphorylation with CK2 and cdc2 protein kinases.

DNA helicases catalyse the transient opening of duplex DNA during nucleic acid transactions. Here we report the isolation of a second nuclear DNA helicase (65 kDa) from Pisum sativum (pea) designated pea DNA helicase 65 (PDH65). The enzyme was immunoaffinity purified using an antihuman DNA helicase I (HDH I) antibody column. The purified PDH65 showed ATP- and Mg(2+)-dependent DNA and RNA unwinding activities, as well as ssDNA-dependent ATPase activity. The direction of DNA unwinding was 3' to 5' along the bound strand. Antibodies against HDH I recognized the purified PDH65, and immunodepletion with these antibodies removed the DNA and RNA unwinding and ATPase activities from purified preparations of PDH65. The DNA and RNA unwinding activities were upregulated after phosphorylation of PDH65 with CK2 and cdc2 protein kinases. By incorporation of BrUTP into pea root tissue, followed by double immunofluorescence labelling and confocal microscopy, PDH65 was shown to be localized within the dense fibrillar component of pea root nucleoli in the regions around the rDNA transcription sites. These observations suggest that PDH65 may be involved both in rDNA transcription and in the early stages of pre-rRNA processing.

Association of phosphatidylinositol 3-kinase with nuclear transcription sites in higher plants.

The kinases responsible for phosphorylation of inositol-containing lipids are essential for many aspects of normal eukaryotic cell function. Genetic and biochemical studies have established that the phosphatidylinositol (PtdIns) 3-kinase encoded by the yeast VPS34 gene is essential for the efficient sorting and delivery of proteins to the vacuole; the kinase encoded by the human VPS34 homolog has been equally implicated in the control of intracellular vesicle traffic. The plant VPS34 homolog also is required for normal growth and development, and although a role for PtdIns 3-kinase in vesicle trafficking is likely, it has not been established. In this study, we have shown that considerable PtdIns 3-kinase activity is associated with the internal matrix of nuclei isolated from carrot suspension cells. Immunocytochemical and confocal laser scanning microscopy studies using the monoclonal antibody JIM135 (John Innes Monoclonal 135), raised against a truncated version of the soybean PtdIns 3-kinase, SPI3K-5p, revealed that this kinase appears to have a distinct and punctate distribution within the plant nucleus and nucleolus. Dual probing of root sections with JIM135 and anti-bromo-UTP antibodies, after in vitro transcription had been allowed to proceed in the presence of bromo-UTP, showed that SPI3K-5p associates with active nuclear and nucleolar transcription sites. These findings suggest a possible link between PtdIns 3-kinase activity and nuclear transcription in plants.

ATP-dependent regulation of nuclear Ca(2+) levels in plant cells.

Localised alterations in cytoplasmic Ca(2+) levels are an integral part of the response of eukaryotic cells to a plethora of external stimuli. Due to the large size of nuclear pores, it has generally been assumed that intranuclear Ca(2+) levels reflect the prevailing cytoplasmic Ca(2+) levels. Using nuclei prepared from carrot (Daucus carota L.) cells, we now show that Ca(2+) can be transported across nuclear membranes in an ATP-dependent manner and that over 95% of Ca(2+) is accumulated into a pool releasable by the Ca(2+) ionophore A.23187. ATP-dependent nuclear Ca(2+) uptake did not occur in the presence of ADP or ADPgammaS and was abolished by orthovanadate. Confocal microscopy of nuclei loaded with dextran-linked Indo-1 showed that the initial ATP-induced rise in [Ca(2+)] occurs in the nuclear periphery. The occurrence of ATP-dependent Ca(2+) uptake in plant nuclei suggests that alterations of intranuclear Ca(2+) levels may occur independently of cytoplasmic [Ca(2+)] changes.

Splicing-independent processing of plant box C/D and box H/ACA small nucleolar RNAs.

Small nucleolar RNAs (snoRNAs) are involved in various aspects of ribosome biogenesis and rRNA maturation. Plants have a unique organisation of snoRNA genes where multiple, different genes are tightly clustered at a number of different loci. The maize gene clusters studied here include genes from both of the two major classes of snoRNAs (box C/D and box H/ACA) and are transcribed as a polycistronic pre-snoRNA transcript from an upstream promoter. In contrast to vertebrate and yeast intron-encoded snoRNAs, which are processed from debranched introns by exonuclease activity, the particular organisation of plant snoRNA genes suggests a different mode of expression and processing. Here we show that single and multiple plant snoRNAs can be processed from both non-intronic and intronic transcripts such that processing is splicing-independent and requires endonucleolytic activity. Processing of these different snoRNAs from the same polycistronic transcript suggests that the processing machineries needed by each class are not spatially separated in the nucleolus/nucleus.

Transcription sites are not correlated with chromosome territories in wheat nuclei.

We have determined the relationship between overall nuclear architecture, chromosome territories, and transcription sites within the nucleus, using three-dimensional confocal microscopy of well preserved tissue sections of wheat roots. Chromosome territories were visualized by GISH using rye genomic probe in wheat/rye translocation and addition lines. The chromosomes appeared as elongated regions and showed a clear centromere-telomere polarization, with the two visualized chromosomes lying approximately parallel to one another across the nucleus. Labeling with probes to telomeres and centromeres confirmed a striking Rabl configuration in all cells, with a clear clustering of the centromeres, and cell files often maintained a common polarity through several division cycles. Transcription sites were detected by BrUTP incorporation in unfixed tissue sections and revealed a pattern of numerous foci uniformly distributed throughout the nucleoplasm, as well as more intensely labeled foci in the nucleoli. It has been suggested that the gene-rich regions in wheat chromosomes are clustered towards the telomeres. However, we found no indication of a difference in concentration of transcription sites between telomere and centromere poles of the nucleus. Neither could we detect any evidence that the transcription sites were preferentially localized with respect to the chromosome territorial boundaries.

Localization and processing from a polycistronic precursor of novel snoRNAs in maize.

We have shown previously that groups of U14 snoRNA genes are clustered with other, novel snoRNAs in maize. These genes are transcribed polycistronically from an upstream promoter to give a precursor snoRNA, which is processed by a splicing-independent mechanism. The clusters contain both box C/D snoRNAs, thought to guide rRNA O-ribose methylations, and the first plant box H/ACA snoRNA so far identified, thought to guide an rRNA pseudo-uridylation. Here we show that four novel snoRNAs identified as members of U14-containing gene clusters each show distinct sub-nucleolar localizations. Two of the snoRNAs (snoR2, a box H/ACA snoRNA, and snoR3, a box C/D snoRNA) colocalise closely with nucleolar rDNA transcription sites. A third box C/D snoRNA, U49, is localised to a more extended region which includes the transcription sites. On the other hand snoR1, another box C/D snoRNA, is located in a quite different region of the nucleolus, and shows a similar distribution to that of 7-2/MRP, a snoRNA involved in the later pre-rRNA cleavage reactions. This may indicate that this snoRNA is involved at later stages of processing, whereas the other snoRNAs are involved early or cotranscriptionally. Probes to intergenic spacer regions of the precursor snoRNA have been used to determine the location of the precursor. This shows a clear labelling of both the dense fibrillar component of the nucleolus, and of coiled bodies. This distribution implies that the polycistronic precursor is imported into the nucleolus for processing to the mature snoRNAs, and that the import or processing pathway involves coiled bodies.

Sites of rDNA transcription are widely dispersed through the nucleolus in Pisum sativum and can comprise single genes.

Incorporation by RNA polymerases of BrUTP into both plant root tissue and isolated plant nuclei as a method for localization of the sites of transcription has been used. In this paper pea root tissue was used, and under the conditions employed, nearly all the incorporation occurs in the nucleolus, and thus must be catalysed by RNA polymerase I. Immunofluorescence and confocal microscopy shows that incorporation occurs in a pattern consisting of many small foci distributed widely through the dense fibrillar component of the nucleoli. Immunogold labelling using silver-enhanced Nanogold probe at the electron microscopic level confirms the sites of transcription as small foci approximately 200 nm in diameter. Simultaneous fluorescence in situ hybridization with a probe to the external transcribed spacer (ETS) region of the pre-rRNA shows that the structures revealed by this probe and the BrUTP immunofluorescence labelling are very similar. A probe to the transcribed portion of the rDNA (18S) also shows a good correlation to the sites of BrUTP incorporation within the nucleolus. On the other hand a probe to the non-transcribed intergenic spacer region (NTS) shows very little coincidence with the sites of BrUTP incorporation, and double fluorescence in situ labelling with both 18S and NTS probes confirms this difference in localization. These results suggest that most BrUTP foci correspond to single transcribed genes.

Clusters of multiple different small nucleolar RNA genes in plants are expressed as and processed from polycistronic pre-snoRNAs.

Small nucleolar RNAs (snoRNAs) are involved in many aspects of rRNA processing and maturation. In animals and yeast, a large number of snoRNAs are encoded within introns of protein-coding genes. These introns contain only single snoRNA genes and their processing involves exonucleolytic release of the snoRNA from debranched intron lariats. In contrast, some U14 genes in plants are found in small clusters and are expressed polycistronically. An examination of U14 flanking sequences in maize has identified four additional snoRNA genes which are closely linked to the U14 genes. The presence of seven and five snoRNA genes respectively on 2.05 and 0.97 kb maize genomic fragments further emphasizes the novel organization of plant snoRNA genes as clusters of multiple different genes encoding both box C/D and box H/ACA snoRNAs. The plant snoRNA gene clusters are transcribed as a polycistronic pre-snoRNA transcript from an upstream promoter. The lack of exon sequences between the genes suggests that processing of polycistronic pre-snoRNAs involves endonucleolytic activity. Consistent with this, U14 snoRNAs can be processed from both non-intronic and intronic transcripts in tobacco protoplasts such that processing is splicing independent.

Nucleolar organizer expression in Allium cepa L. chromosomes.

Roots from Allium cepa L. (cv. Francesa) bulbs in which a maximum of two nucleoli per nucleus developed were selected for this study. Five rDNA clusters were detected by fluorescent in situ hybridization on chromosomal squashes (2n = 16) with a rhodamine-labelled wheat rDNA repeat. The rDNA clusters were located on four chromosomes: the largest cluster occurred on the small arm of a single homologue of the smallest pair 8. Its homologue showed two different small rDNA clusters, one near each telomere. The two homologues of the satellited chromosomes 6 also showed different rDNA contents, which were intermediate to those found in pair 8. The same five well-differentiated hybridization signals were observed in interphase cells that were inactive in transcription because they were in dormant roots, or in proliferating ones in which the synthesis of the large rRNA precursor was prevented. After multipolarizing agent was applied in anaphase followed by inhibition of cytokinesis, multinucleate autotetraploid cells were formed, which often contained more than four nucleoli. Thus, at least two of the three nucleolar organizer regions that consistently failed to develop a nucleolus in normal mononucleate cells were capable of developing nucleoli when segregated into different nuclei in multinucleate cells.

The organization of ribosomal RNA processing correlates with the distribution of nucleolar snRNAs.

We have analyzed the organization of pre-rRNA processing by confocal microscopy in pea root cell nucleoli using a variety of probes for fluorescence in situ hybridization and immunofluorescence. Our results show that transcript processing within the nucleolus is spatially highly organized. Probes to the 5' external transcribed spacer (ETS) and first internal transcribed spacer (ITS1) showed that the excision of the ETS occurred in a sub-region of the dense fibrillar component (DFC), whereas the excision of ITS1 occurred in the surrounding region, broadly corresponding to the granular component. In situ labelling with probes to the snoRNAs U3 and U14, and immunofluorescence labelling with antibodies to fibrillarin and SSB1 showed a high degree of coincidence with the ETS pattern, confirming that ETS cleavage and 18 S rRNA production occur in the DFC. ETS, U14, fibrillarin and SSB1 showed a fine substructure within the DFC comprising closely packed small foci, whereas U3 appeared more diffuse throughout the DFC. A third snoRNA, 7-2/MRP, was localised to the region surrounding the ETS, in agreement with its suggested role in ITS1 cleavage. All three snoRNAs were also frequently observed in numerous small foci in the nucleolar vacuoles, but none was detectable in coiled bodies. Antibodies to fibrillarin and SSB1 labelled coiled bodies strongly, though neither protein was detected in the nucleolar vacuoles. During mitosis, all the components analyzed, including pre-rRNA, were dispersed through the cell at metaphase, then became concentrated around the periphery of all the chromosomes at anaphase, before being localized to the developing nucleoli at late telophase. Pre-rRNA (ETS and ITS1 probes), U3 and U14 were also concentrated into small bodies, presumed to be pre-nucleolar bodies at anaphase.

The nucleolar architecture of polymerase I transcription and processing.

The nucleolus, the site of transcription and processing of the major ribosomal genes, generally reveals three distinct ultrastructural components in conventional thin-section electron micrographs (fibrillar centres, dense fibrillar component and granular component). We show here that different parts of the transcription and transcript processing pathway can be mapped to the different nucleolar components in pea root cells. This study shows the full three-dimensional arrangement of the different domains by in situ hybridization and confocal microscopy, and their correspondence with the major ultrastructural components of the nucleolus is revealed by parallel serial section electron microscopy. The active rDNA is widely dispersed in discrete foci, the larger of which, at least, correspond to well-defined fibrillar centres. A probe to the external transcribed spacer (ETS) sequence of the pre-rRNA transcripts labels clearly demarcated regions surrounding the foci of rDNA, and which we show correspond to the dense fibrillar component. Finally, a probe to the entire 45S transcript shows a higher concentration in regions corresponding to the granular component, surrounding the dense fibrillar component labelled by the ETS probe. The changes in structure that occur with heat shock show that nucleolar organization is dynamic and dependent upon transcriptional activity. These results show that the various RNA processing events are spatially highly organized and suggest a vectorial or radial model of transcription and transcript processing, where nascent and newly completed transcripts occupy zones surrounding the genes, which are in turn surrounded by regions containing the older more mature transcripts.

The organization of spliceosomal components in the nuclei of higher plants.

To analyze the organization of spliceosomal snRNPs in plant nuclei, we have used both immunofluorescence labelling with the antibody 4G3, raised against the human snRNP-specific protein U2B", and in situ hybridization with anti-sense probes to conserved regions of U1, U2 and U6 snRNAs. The organization comprises a fibrous interchromatin network, which may include both interchromatin fibrils and granules, and very prominent nuclear and nucleolar-associated bodies. Double labelling with an anti-p80 coilin antibody shows that these are coiled bodies. Dynamic changes in the labelling pattern were observed through the cell cycle, and in response to and on recovery from heat shock. The similarity of this organization to that observed in mammalian nuclei is strong evidence that it is fundamental to the processing of pre-mRNA in eucaryotes in general.

Localization of 5 S genes and transcripts in Pisum sativum nuclei.

We have investigated the position of the 5 S gene clusters in the nuclei of Pisum sativum root tip cells, and of their transcripts in the nucleolus, using in situ hybridization and confocal microscopy. Single-stranded RNA probes were produced by in vitro transcription, incorporating fluorescein or digoxygenin label. There are known to be 3 pairs of 5 S gene clusters in this species, which would be expected to give 6 sites of hybridization in G1 cells and 12 sites in G2 cells. In presumed G2 cells, many of the sites appeared as paired spots very close together, which we interpret as the sites on sister chromatids. A clear association of one or more clusters with the nucleolar periphery was observed, and it is possible that this has a functional significance. The transcript labelling within the nucleolus showed a reproducible and highly ordered pattern, consisting of cavities devoid of transcript labelling surrounded by sheets of bright labelling, making a characteristic and often very symmetrical cage-work structure. This labelling pattern may represent an underlying organization of transcript processing within the nucleolus, and is highly reminiscent of the distribution of a previously described nucleolar matrix protein.

Identification and localisation of a nucleoporin-like protein component of the plant nuclear matrix.

Salt-detergent extraction of purified plant nuclei yields a fraction enriched in putative structural proteins known as the "nuclear matrix". Compared with mammalian nuclear matrices, which contain three major proteins, plant nuclear matrices are complex, containing at least 100 polypeptides. In order to characterise more fully the plant nuclear matrix we have used antibodies raised against both yeast (Saccharomyces cerevisiae) and mammalian (rat) nuclear pore proteins. We have shown that the nuclear matrix of carrot (Daucus carota L.) contains at least one nucleoporin-like protein of about 100 kDa which is immunologically related to both the yeast nuclear pore protein NSP1 and mammalian nucleoporins (p62). Antibody labelling of a variety of plant cells at the light-microscope and electron-microscope levels confirms that this antigen is located at the nuclear pores. This, to our knowledge, is the first identification of a nuclear pore protein in plants.