The nucleolar architecture of polymerase I transcription and processing (original) (raw)
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Single ribosomal transcription units are linear, compacted Christmas trees in plant nucleoli
The Plant Journal, 2001
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 mm 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 ®xed specimens in order to wash out the proteins and RNA, thus speci®cally revealing DNA strands after uranyl acetate staining. Using this technique, followed by post-embedding in situ hybridization, we observed that the nucleolar rDNA ®bres are not extended but show a coiled, thread-like appearance. Our results show for the ®rst time that native rDNA transcription units are linear, compacted Christmas trees.
Visualization of transcription sites at the electron microscope
European journal of histochemistry : EJH, 2003
In order to localize at EM level the sites of transcription of both pre-mRNA and pre-rRNA, we have detected the DNA/RNA hybrid molecules and m3Gcapped structures by means of specific antibodies after short bromo-uridine (BrU) incorporation. In addition, the sections have been stained by a selective RNA stain, terbium citrate. Our data indicate that perichromatin fibrils incorporate BrU and are labeled by the anti-hybrid probe; this supports the idea that they are the pre-mRNA transcription sites. On the contrary, interchromatin granules do not incorporate BrU after short pulses and are not labeled by the anti-hybrid probe. Concerning the nucleolus, anti-hybrid and anti-BrdU antibodies colocalize only on the dense fibrillar component, suggesting that this is the site of rRNA transcription. Interestingly, the dense fibrillar component and the granular component, after specific RNA staining, show remarkable structural similarities, both containing fibrogranular RNA structures.
Journal of Structural Biology, 1999
Nucleolar transcription in isolated onion cell nuclei was visualized, after Br-UTP incorporation, under the conventional fluorescence microscope, the confocal microscope, and the transmission electron microscope. The confocal microscopy study of transcription was combined with immunodetection of fibrillarin, a component of the RNP complex involved in the early processing of pre-rRNA. Superposition of transcription and fibrillarin images from the same optical section showed some small ''black holes'' in the nucleolus, around which a lateral and radial differentiation of labeling was observed: laterally, zones corresponding to transcription labeling alternated with zones of fibrillarin labeling; radially, areas of transcription gradually became areas of colocalization of transcription and fibrillarin, and, further outward, of fibrillarin alone, which occupied the major part of the labeled nucleolar area. Three-dimensional reconstruction of the nucleolar transcription labeling, from confocal optical sections, showed clusters of foci arranged around an area of low or no labeling. Thin labeled extensions, connecting single foci, were observed. Visualization of transcription at the ultrastructural level identified the black holes as fibrillar centers, in view of their size and the absence of labeling in them. In fact, most of the labeling was observed in discrete areas of the dense fibrillar component, near fibrillar centers, including the transition area between these two components. This observation was supported by a quantitative study. Otherwise, the outline of fibrillar centers did not appear entirely surrounded by particles, and a minor proportion of particles was detected dispersed throughout the dense fibrillar component. As a complementary study, the transcription factor upstream binding factor (UBF) and the protein NopA64, a plant nucleolin homologue, were immunolocalized. Small foci of UBF localization alone and other foci in which the two protein markers overlapped were observed. The outer areas of the nucleolus showed the exclusive presence of NopA64. Under the electron microscope, UBF labeling, quantitatively assessed, appeared as clusters of particles, most of them surrounding fibrillar centers. A graphic model is presented to give a molecular interpretation of these data. 1999 Academic Press
The Transcription Unit of Ribosomal Genes Is Attached to the Nuclear Skeleton
Experimental Cell Research, 1996
proposed that active polymerases form part of the The relationship between various loci of the ribo-nucleoskeleton while the genes pass through such fixed somal gene repeat and the nucleoskeleton was exam-polymerizing sites [for review, see 22]. Thus, there is ined in agarose-embedded HeLa cells. The accessibilconvincing evidence that the nucleoskeleton is more ity of intranucleolar structures to molecular probes than a passive network with only structural functions.
In the present work we perform in situ hybridization with probes to different stretches of rDNA and electron microscopy of nucleoli with different activities, to gain insight into the ultrastructural organization of transcription and processing in the plant nucleolus. The main ultrastructural nucleolar components: fibrillar centers (FC), dense fibrillar component (DFC), and granular component (GC), are arranged in different ways depending on nucleolar activity. Heterogeneous FCs containing RNI' fibrils and nucleolar perichromatin granules are frequently seen in nucleoli in the process of activation. DNA-RNA in situ hy-bridization with biotinylated probes spanning different sequences of the rDNA unit followed by immu-nogold detection of biotin, demonstrated the localization of the ribosomal transcripts in DFC, mainly in the zones around the FCs, in GC, and in the periphery of pale FC. The internal region of the heterogeneous FCs is labeled only in cells in the process of activation of transcription after dormancy. The distribution of the U3 probe indicates that the processing of the rRNA takes place in the DFC and inside the heterogeneous FCs, in which transcription occurs. DNA-DNA hybridization demonstrates the presence of rDNA in the compact and extended chromatin located in the interior and at the periphery of FCs and in nucleolar associated chromatin. Our results support the view that the plant nucleolus has a highly dynamic morphological and functional organization composed of a bipartite domain formed by KS surrounded by DFC, which is associate< with rRNA transcription and processing, and the GC representing a store of preribosomal particles. 2000 0 Editions scientifiques et mgdicales Elsevier SAS plant cells / nucleolus / rRNA / rDNA / ultrastructure
Journal of cell science, 1993
The distribution of ribosomal transcripts in the plant nucleolus has been studied by non-isotopic in situ hybridization in ultrathin Lowicryl K4M sections and by high-resolution autoradiography after labelling with tritiated uridine. In parallel, cytochemical techniques were applied to localize RNA on different plant nucleolar components of Allium cepa L. root meristematic cells and Capsicum annuum L. pollen grains. For RNA/RNA in situ hybridization, several biotinylated single-stranded ribosomal RNA probes were used for mapping different fragments of the 18 S and the 25 S rRNA gene transcribed regions. Ribosomal RNAs (from pre-rRNAs to mature 18 and 25 S RNAs) were found in the nucleolus, in the dense fibrillar (DFC) and granular components (GC). Hybridization signal was found at the periphery of some fibrillar centres (FCs) with probes recognizing both 18 and 25 S rRNA sequences. A quantitative study was performed to analyze the significance of this labelling. Incorporation of tri...
Biology of the Cell, 2000
In the present work we perform in situ hybridization with probes to different stretches of rDNA and electron microscopy of nucleoli with different activities, to gain insight into the ultrastructural organization of transcription and processing in the plant nucleolus. The main ultrastructural nucleolar components: fibrillar centers (FC), dense fibrillar component (DFC), and granular component (GC), are arranged in different ways depending on nucleolar activity. Heterogeneous FCs containing RNP fibrils and nucleolar perichromatin granules are frequently seen in nucleoli in the process of activation. DNA-RNA in situ hybridization with biotinylated probes spanning different sequences of the rDNA unit followed by immunogold detection of biotin, demonstrated the localization of the ribosomal transcripts in DFC, mainly in the zones around the FCs, in GC, and in the periphery of pale FC. The internal region of the heterogeneous FCs is labeled only in cells in the process of activation of transcription after dormancy. The distribution of the U3 probe indicates that the processing of the rRNA takes place in the DFC and inside the heterogeneous FCs, in which transcription occurs. DNA-DNA hybridization demonstrates the presence of rDNA in the compact and extended chromatin located in the interior and at the periphery of FCs and in nucleolar associated chromatin. Our results support the view that the plant nucleolus has a highly dynamic morphological and functional organization composed of a bipartite domain formed by FCs surrounded by DFC, which is associated with rRNA transcription and processing, and the GC representing a store of preribosomal particles.