多头绒泡菌SC35类蛋白的免疫电镜研究

经抗SC35单克隆抗体标记后,在电子显微镜下观察到多头绒泡菌S、G2、前期、中期和后末期细胞核中存在大量金颗粒,说明多头绒泡菌细胞核含有SC35类蛋白。在G2期和前期时,SC35类蛋白主要分布在细胞核的核仁区域和非核仁区域的染色质间区域;中期和后-末期时,SC35类蛋白主要分布在细胞核内染色体间区域;说明染色质(体)间区域和核仁区域是富含SC35类蛋白的区域。对核仁的进一步观察指出,在核仁中金颗粒主要分布在DFC,FC中的金颗粒很少,说明在核仁中SC35类蛋白主要存在于DFC组分中。     

Subnucleolar distribution and organization of Vicia faba L. rDNA in situ

The distribution and organization of nucleolar DNA in Vicia faba L. was analyzed by specific cytochemical staining using NAMA-Ur. The results showed that nucleolar DNA was distributed in the FCs and at the FC/DFC junctions. Statistical analysis showed that the rRNA genes occupied about one-third of the total dense fibrillar component region. The rDNA was condensed in some regions and uncondensed in others. Nucleolus-associated chromatin extended from outside the nucleolus to the periphery of the FCs via nucleolar channels, suggesting a possible origin for nucleolar DNA.     

Dynamic change and derivation process of FC and DFC through G1, S and G2 phases in HeLa cells

In order to get a deeper understanding of the relationship between nucleolus structure and its function, the dynamic change and derivation of FC (fibrillar center) and DFC (dense fibrillar component) through interphase were investigated in HeLa cells synchronized at the ultrastructural level. The results showed that there was a process of FC and DFC derivation in the nucleolus of HeLa cells during interphase. In G1 phase there were a few big FCs in the nucleolus of the HeLa cell. In S phase DFC around the FC got thickened and the configuration of the DFC changed. A lot of tiny FCs were derived from parts of the thickened DFC. We called the FC and DFC formed in G1 phase as primary FC (pri-FC) and primary DFC (pri-DFC) and the FC and DFC derived from the thickened pri-DFC as secondary FC (sec-FC) and secondary DFC (sec-DFC). In G2 phase sec-FC and sec-DFC were gradually separated from pri-DFC and scattered evenly in the nucleolus. Few large pri-FCs coexisted with numerous tiny sec-FCs in the nucleolus of HeLa cells in G2 phase. Based on the results of our observation, we suggest here a model of the dynamic change and the process of derivation of FC and DFC through interphase.     

Mininucleolus: An Intranuclear Body Enriched with the Splicing Factor SC35

The mininucleolus (MN) is a distinct intranuclear body often observed in cells of higher plants. Previous studies indicated MN as a non-chromatin structure composed of RNA and proteins, and suggested that it may be involved in the transportation and storage of ribosomal RNA. However, its characteristic protein component and functional significance remain to be clarified. The authors investigated the characteristic protein component of MNs in the nuclei of the meristematic cells of root in Vicia faba L. approaching with an anti- SC35 monoclonal antibody and immunoelectron microscopic observation. A large number of gold particles were observed over the MNs of the specimens labelled with the antibody and protein A-gold, while only a few gold particles were found in the MNs of the control specimens in which labelling of the antibody was omitted. The density of gold particles in MNs of the labelled specimens (300/μm2) was much higher than that of the control specimens (3.76/μm2), demonstrating that SC35 is a constituent of the MN. The identification of the MN highly enriched with the splicing factor will help us understanding the function of this structure.     

Subnucleolar location of fibrillarin and variation in its levels during the cell cycle and during differentiation of plant cells

The nucleolar protein fibrillarin has been studied in onion cells; it is detected as an Mr 37,000 protein by immunoblotting using a human autoimmune serum. Quantitative immunoelectron microscopy showed that most fibrillarin is localized in the transition zone between the fibrillar center (FC) and the dense fibrillar component (DFC) as well as in the priximal zone of the DFC, where the labeling shows a gradual decrease out-ward until it reaches insignificant levels in the distal zone of the DFC. Thus, fibrillarin is not uniformly distributed throughout the DFC of plant cells. This result supports the hypothesis that the morphologically homogeneous DFC may not be uniform in function; it is also in agreement with the hypothesized vectorial flow of ribosome biogenesis through the same compartments. Data are also presented showing that the amount of fibrillarin increase when nucleolar activity increases in G2, and probably decreases when nucleolar activity decreases during differentiation.