Abundance of protein-bound sulfhydryl and bisulfide groups at chromosomal nucleolus organizing regions

Silver stainability of the chromosomal nucleolus organizing regions that contain the structural genes for ribosomal RNA can be abolished by proteolytic and oxidative treatments. Histone extraction has no effect. This indicates that reducing groups of non-histone chromosomal proteins are responsible for silver staining. Treatment with fluorescent sulfhydryl and disulfide specific reagents followed by silver staining demonstrates coincidence of silver dots and brightly fluorescent spots at the short arms of human acrocentric chromosomes where ribosomal RNA-genes are located. After treatment with cupric sulfite reagent in the presence of urea fluorescence and silver staining was no longer possible. Silver staining has been reported to be associated with ribosomal RNA-gene activity. Acrocentric chromosomes that are negative in silver staining also lack the brightly fluorescent spots. Therefore, we conclude that an abundance of protein-bound sulfhydryl and disulfide groups occur at nucleolar organizing regions with active genes. Differentially fluorescing spots could not be observed after staining with fluorescamine. So, either the sulfhydryl reagents used in this study are much more sensitive than fluorescamine to study protein distributions in cytological preparations, or our observations point to a local accumulation of some specific protein(s) rich in sulfhydryls. The presence of many sulfhydryl and disulfide groups at the nucleolus organizing regions seems suggestive of a great flexibility of protein(s) by transition of sulfhydryl groups to disulfide bridges and vice versa at these highly active regions of the genome.     

银染技术在生殖细胞研究中的应用

新近对传统的银染技术作出改良,以氨银反应观察精子发生及受精过程中碱性蛋白的更替,以Ａｇ－Ａｓ反应观察精子发生过程中ＮＯＲ,嗜银细胞器,细胞骨架及其它嗜银成份的变化以及皮层皮应中嗜银成分的变化。     

Silver staining of the lampbrush chromosomes ofTriturus cristatus carnifex

Lampbrush chromosomes fromTriturus cristatus carnifex were stained using the ammoniacal silver staining (AgAS) technique. Many of the recognized marker structures proved to be silver positive, plus between six and fifteen lateral loop pairs. None of the stained loop pairs corresponded to known sites of the nucleolus organizers, although the extrachromosomal nucleoli were silver positive. The ammoniacal silver staining technique does not demonstrate the specificity for active ribosomal cistrons in lampbrush chromosomes that it does in a wide variety of mammalian mitotic chromosomes.     

Differentiation of interphase nucleolus organizers in embryonic pig kidney cells (PK cell line)

The prometaphase karyotype of cell line PK contains two heteromorphous pairs of nucleolus organizers that belong to chromosomes 8a and 8, and to 10L and 10s. It was proposed that such heteromorphism may promote chromosome differentiating of interphase nucleolus organizers (INOs) with linear configuration. To test this assumption, we used two-dimensional (2D) preparations of methanol fixed PK cells surface stretched without hypotonic treatment. It was shown that in these preparations the large bulk of interphase PK cells contained 3-4 necklace-like linear structures arranged in nucleolar domains. The observed structures were positive in phase contrast and after DAPI-staining. Complimentary rDNA-FISH revealed that these structures were INOs, the largest iNO in individual cells containing prominent terminal rDNA FISH/DAPI signal. In accordance with the data on prometaphase analysis, the latter INOs belong to chromosomes 8a. As reported by Smetana and coworkers (1999), proteins of the nucleolar fibrillar center reacted preferentially with silver in methanol fixed unwashed smears of human peripheral lymphocytes. It was established that the same specific silver reaction is characteristic most probably of 2D preparations of methanol fixed PK cells. Both silver stained and rDNA-FISH linearized INOs had necklace-like or banded structure with different degrees of resolution. Banded INOs consisted of transverse argyrophilic structures: dense bands and loose interbands. High resolved banded INOs revealed a longitudinal splitting (binemic structure) of interband zone. Necklace-like INOs consisted of argyrophilic beads nearly two-fold more narrow than argyrophilic bands, and uninemic or silver-negative interbead zones. Our findings evidence that necklace-like INOs are typical for G1 and S phase cells, whereas banded INOs are characteristic of G2 cells. Among high resolved linear INOs, we found four reproducible patterns of silver staining, which could be combined it two homologous groups. Because each given pattern is unique for individual PK cells, we concluded that the patterns under study were chromosome specific. Using prometaphase analysis data, we determined chromosome affiliation for each of the four tested patterns of INO silver staining. High resolved INOs, belonging to different chromosomes, were further compared with regard to their average length and the mean of argyrophilic bead number per individual INO, in addition to the length and argyrophilic bead number ratios calculated for different INO pairs of individual cells. Surprisingly, we found that both the ratios, detected for most heteromorphous pair of homologous chromosomes 8a and 8, made only 1.26 +/- 0.02. In comparison, the similar length ratio for nucleolus organizers in chromosomes 8a and 8, calculated for individual prometaphase cells, reached 2.92 +/- 0.30.     

Distribution of rDNA in the nucleus of Giardia lamblia: detection by Ag-I silver stain.

Previous investigations have proved that diplomonads have primitive cell nuclei and lack a nucleolus. We determined the distribution of ribosomal DNA (rDNA) in diplomonad nuclei that lacked a nucleolus. Giardia lamblia was used as the experimental organism with Euglena gracilis as the control. The distribution of rDNA was demonstrated indirectly by the modified Ag-I silver technique that can indicate specifically the nucleolus organizing region (NOR) by both light and electron microscopy. In ultrathin sections of silver stained Euglena cells, all silver grains were concentrated in the fibrosa of the nucleolus, while no silver grains were found in the cytoplasm, nucleoplasm, condensed chromosomes or pars granulosa of the nucleus. In the silver stained Giardia cells, no nucleolus was found, but a few silver grains were scattered in the nucleus. This suggests that the rDNA of Giardia does not form an NOR-like structure and that its nucleus is in a primitive state.     

核糖体蛋白rpS6在核仁中的定位与其磷酸化无关

核糖体蛋白S6(rpS6)是核糖体小亚基40S的一个组成成分。在该研究中,利用免疫荧光和邻位连接技术证明rpS6不仅是核糖体小亚基的组成成分,而且还可与核仁中的U3核蛋白复合体的标志性蛋白Mpp10共定位并且存在相互作用。rpS6蛋白的C端有5个丝氨酸磷酸化位点,为了研究rpS6蛋白在核仁中的分布是否与其磷酸化有关,构建了rpS6蛋白的两个突变体rpS6A和rpS6D分别与EGFP和HA的融合蛋白。rpS6A是将C端的5个丝氨酸位点全部突变为丙氨酸;rpS6D是将C端的5个丝氨酸位点全部突变为天冬氨酸。研究表明:rpS6、rpS6A和rpS6D与EGFP和HA的融合蛋白均可分布在核仁中,与内源性rpS6蛋白的分布情况一致,说明rpS6蛋白在核仁中的定位与其磷酸化无关,为探索rpS6蛋白在核仁中的功能奠定了良好的基础。     

Cytological research on the argentophilic nucleolus-organizer regions of the metaphase chromosomes in parthenogenetic mouse embryos]

Silver staining technique visualizing argentophilic nucleolus organizer regions (Ag-NORs) was used for studying parthenogenetic mouse embryos produced by artificial activation of oocytes in Ca(2+)-Mg(2+)-free medium. Ag-NOR-containing chromosomes were detected in metaphases of parthenogenetic embryos during six successive cleavage divisions starting with the two-cell stage. The frequency of metaphases with varying AG-NOR number in diploid parthenogenones was similar to that in the control (fertilized) embryos. Average number of metaphase Ag-NOR chromosomes (calculated per diploid chromosome set) in haploid parthenogenones exceeded that in the control; in some cases all NORs were stained by silver. This is evidence that latent ribosomal cistrons in some chromosomes can be activated.     

Distribution of rDNA in the nucleus of Giardia lamblia: detection by Ag-I silver stain

Previous investigations have proved that diplomonads have primitive cell nuclei and lack a nucleolus. We determined the distribution of ribosomal DNA (rDNA) in diplomonad nuclei that lacked a nucleolus. Giardia lamblia was used as the experimental organism with Euglena gracilis as the control. The distribution of rDNA was demonstrated indirectly by the modified Ag-I silver technique that can indicate specifically the nucleolus organizing region (NOR) by both light and electron microscopy. In ultrathin sections of silver stained Euglena cells, all silver grains were concentrated in the fibrosa of the nucleolus, while no silver grains were found in the cytoplasm, nucleoplasm, condensed chromosomes or pars granulosa of the nucleus. In the silver stained Giardia cells, no nucleolus was found, but a few silver grains were scattered in the nucleus. This suggests that the rDNA of Giardia does not form an NOR-like structure and that its nucleus is in a primitive state.     

Silver staining in pinealocyte nuclei: Observations and quantitative analysis during the rat oestrous cycle

Summary Morphology, distribution and number of different argyrophilic aggregates appearing in pinealocyte nuclei have been studied during the rat oestrous cycle. Using the Ag-NOR reaction we have found two types of argyrophilic aggregates in pinealocyte nuclei. One of them, corresponding to the fibrillar centres and the surrounding fibrillar component, appears in the nucleoli. The silver grains are more loosely packed in the dense fibrillar component than in the fibrillar centres. A decrease in the number of these nucleolar argyrophilic aggregates was obtained at oestrous. A second type of silver grain aggregate was observed in the pinealocyte nucleoplasm. We call them Ag-granule clusters because they are similar to the interchromatin granule clusters and constitute the only silver deposit forming aggregates apart from the nucleolus. The number of Ag-granule clusters is significantly smaller at oestrous and meta-oestrous than at dioestrous and pro-oestrous.     

Staining Plant Cells with Silver. I. The Salt-Nylon Technique

A technique is described for selectively silver staining nucleoli, active nucleolus organizers, nucleolar material attached to chromosomes, kinetochores, synaptonemal complexes, and chromosome cores in plant cells. The technique, called salt-nylon silver staining, involves spreading cells on glass slides, treating the cells with a solution of saline sodium citrate, and incubating the cells in a silver nitrate solution covered with nylon screen. Selected variables important for achieving reliable silver staining are considered.     

Nucleolin is an Ag-NOR protein; this property is determined by its amino-terminal domain independently of its phosphorylation state.

The Ag-NOR proteins are defined as markers of "active" ribosomal genes. They correspond to a set of proteins specifically located in the nucleolar organizer regions (NORs), but have not yet been clearly identified. We adapted the specific detection method of the Ag-NOR proteins to Western blots in order to identify these proteins. Using a purified protein, Western blots, and immunological characterization, the present study brings the first direct evidence leading to the identity of one Ag-NOR protein. We found that nucleolin is specifically revealed by Ag-NOR staining. Using different nucleolin fragments generated by CNBr cleavage and by overexpression in Escherichia coli, we demonstrate that the amino-terminal domain of nucleolin and not the carboxy-part of the protein is involved in silver staining. Moreover, as the pattern of staining does not vary using casein kinase II- and cdc2-phosphorylated nucleolin or dephosphorylated nucleolin, we conclude that the reduction of the silver ions is not linked to the phosphorylation state of the molecule. We propose that the concentration of acidic amino acids in the amino-terminal domain of nucleolin is responsible for Ag-NOR staining. This hypothesis is also supported by the finding that poly L-glutamic acid peptides are silver stained. These results provide data that can be used to explain the specificity of Ag-NOR staining. Furthermore, we clearly establish that proteolysis of the amino-terminal Ag-NOR-sensitive part of nucleolin occurs in vitro, leading to the accumulation of the carboxy-terminal Ag-NOR-negative part of the protein. We argue that this cleavage occurs in vivo as already proposed, bearing in mind that nucleolin is present in the fibrillar and in the granular component of the nucleolus, whereas no Ag-NOR staining is observed in the latter nucleolar component.     

The relationships between ribosomal genes and fibrillar centers in thyroid cells cultivated in vitro

Despite the fact that the fibrillar centers of the nucleolus and the chromosomal nucleolar organisers (NORs) are similarly stained with the NOR-silver technique, there remain some questions about the identification of fibrillar centers as NORs. The distinct delineation of the fibrillar centers in porcine thyroid cells allowed us to determine whether there was a numerical equivalence or correlation between fibrillar centers and NORs. Hybridization in situ and silver staining performed on pig chromosomes showed that pairs 8 and 10 contained rDNA sites. Silver staining of thyroid cells in electron microscopy showed that the fibrillar centers and their surrounding layer of dense fibrils were the sites of silver deposit. Chromatin fibers were demonstrated within the fibrillar centers through the aid of the osmiumammine reaction and with the oxidized diaminobenzidine technique. It was observed that in cultured thyroid cells the fibrillar centers could be identified in the light microscope as argyrophilic spherules, and easily counted. The number of fibrillar centers was variable according to culture conditions. In cells cultured for 5 hr, the mean number of fibrillar centers was 1.7. After 5 days of culture, the number of fibrillar centers increased, reaching a mean value of 5.93. When thyroid cells were stimulated with thyrotropin, the number of fibrillar centers again increased to a mean value of 7.54. These results demonstrate that the relationship between fibrillar centers and NORs is not a simple proportionality: the number of fibrillar centers increases with increased cellular activity. These data imply that in active cells each NOR may pass through several fibrillar centers.     

Simultaneous visualization of rDNA clusters and the nucleolus by combining fluorescence in situ hybridization and silver staining.

We designed two procedures to visualize simultaneously clusters of ribosomal RNA genes (rDNA) and the nucleolus in plant cells. The procedures combine fluorescence in situ hybridization (FISH) to visualize the rDNA clusters and silver staining to observe the nucleolus. When FISH is followed by silver staining, many minute FISH signals are localized in the nucleolus, and several large FISH signals are seen on the nucleolar periphery. When FISH was applied to the specimens with silver nitrate staining, large FISH signals were visualized in the nucleoplasm associated with the nucleolar periphery, but no signals were seen in the nucleoli. Thus, the two combinations of FISH and silver staining provided different details regarding the arrangement of rDNA clusters in the nucleolus of plant cells.     

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.