XCAP-C类似蛋白存在于蒜根端细胞核和染色体中

以抗XCAP-C抗体为探针,用SDS-PAGE、免疫印迹、免疫荧光和免疫电镜技术,对蒜(Allium sativa L.)根端细胞核、核骨架、染色体和染色体骨架进行研究.SDS-PAGE和免疫印迹结果表明:细胞核中的165kD多肽是XCAP-C类似蛋白,在核骨架中未检测到XCAP-C类似蛋白.免疫荧光和免疫电镜结果表明:蒜细胞核、染色体和染色体骨架中含有XCAP-C类似蛋白,该蛋白位于细胞核中的染色质区域,但核骨架不含有XCAP-C类似蛋白.     

ScII类似蛋白是洋葱根端细胞核、染色体和染色体骨架的组成成分

采用机械破碎和蔗糖梯度离心方法从洋葱根端分生组织中分离出细胞核并制备出核骨架。细胞核SDS-PAGE谱带中135kD处有一多肽,免疫印迹实验结果表明,该多肽可被抗鸡ScⅡ抗体标记,核骨架中没有此多肽。经抗ScⅡ抗体和FITC偶联的二抗标记后,细胞核发出代表ScⅡ的特异性荧光,而核骨架中无荧光发出。经抗ScⅡ抗体和蛋白A胶体金处理后,金颗粒特异性地结合在核内染色质区域。说明ScⅡ类似蛋白是洋葱根端细胞核的组分,且位于核内染色质上,但该蛋白不是核骨架成分。免疫荧光和免疫电镜实验结果还说明ScⅡ类似蛋白是洋葱根端细胞染色体和染色体骨架的组成成分。     

ScⅡ类似蛋白是洋葱根端细胞核、染色体和染色体骨架的组成成分

采用机械破碎和蔗糖梯度离心方法从洋葱根端分生组织中分离出细胞核并制备出核 骨架。细胞核ＳＤＳ－ＰＡＧＥ谱带中１３５ｋＤ处有一多肽,免疫印迹实验结果表明,该多肽可被抗 鸡ＳｃⅡ抗体标记,核骨架中没有此多肽。经抗ＳｃⅡ抗体和ＦＩＴＣ偶联的二抗标记后,细胞核 发出代表ＳｃⅡ的特异性荧光,而核骨架中无荧光发出。经抗ＳｃⅡ抗体和蛋白Ａ胶体金处理 后,金颗粒特异性地结合在核内染色质区域。说明ＳｃⅡ类似蛋白是洋葱根端细胞核的组分, 且位于核内染色质上,但该蛋白不是核骨架成分。免疫荧光和免疫电镜实验结果还说明ＳｃⅡ 类似蛋白是洋葱根端细胞染色体和染色体骨架的组成成分。     

HeLa细胞核和核骨架含有肌动蛋白

提取HeLa细胞核并制备核骨架标本,以抗肌动蛋白抗体为探针,采用SDS－PAGE、免疫荧光和免疫印迹等方法,对HeLa细胞细胞核和核骨架中的肌动蛋白进行了研究,并用鬼笔环肽荧光染色方法研究了其中的F－肌动蛋白。在荧光显微镜下观察到：代表肌动蛋白的特异性荧光分布在细胞核和核骨架中,说明肌支蛋白是细胞核和核骨架的固有成分;代表F－肌动蛋白的特异性荧光存在于细胞和核骨架中,说明细胞核和核骨架含有F－肌动蛋白。免疫印迹结果进一步肯定了细胞核和核骨架中肌动蛋白的存在。     

肌动蛋白是多头绒泡菌细胞核骨架和染色体骨架的组成成分

自多头绒泡菌(Physarum polycephalum Schw.)的原质团中分离细胞核和染色体,分别经DNaseⅠ消化和2 mol/L NaCl抽提后制备成细胞核骨架和染色体骨架。以抗肌动蛋白的抗体作一抗、FITC标记的羊抗兔IgG抗体作二抗进行的间接免疫荧光实验结果显示,细胞核骨架和染色体骨架都分别与抗体呈阳性反应。间接免疫斑点印迹实验结果进一步证实,细胞核骨架和染色体骨架的蛋白质成分中存在与肌动蛋白抗体呈阳性显色反应的抗原。以抗肌动蛋白的抗体作一抗、金颗粒标记的蛋白A作二抗的间接免疫电镜实验结果表明,在实验组间期细胞核的核仁、集缩染色质和核基质以及中期染色体上都有很多金颗粒分布。上述结果证明,肌动蛋白是多头绒泡菌细胞核和染色体及其骨架的组成成分。     

肌动蛋白存在于蚕豆细胞核和染色体中

以兔抗肌动蛋白抗体为一抗,FTTC偶联的羊抗兔IgG抗体为二抗进行间接免疫荧光实验,观察到蚕豆(Vicia faba L.)根端分生组织中完整的细胞核和染色体均有明亮荧光。用抗肌动蛋白抗体和蛋白A-胶体金进行标记的免疫电镜实验结果表明,金颗粒分布在蚕豆细胞核中,集缩染色质和核仁中金颗粒较多。经DNaseI消化和2 mol/L NaCl处理得到去除DNA和组蛋白的细胞核和染色体。免疫荧光实验结果指出,去除DNA和组蛋白的细胞核和染色体与抗肌动蛋白抗体呈阳性反应。上述结果说明,肌动蛋白不仅存在于完整的蚕豆细胞核和染色体中,而且存在于去除DNA和组蛋白的蚕豆细胞核和染色体中。另外,用抗原肌球蛋白抗体所做的免疫荧光标记结果表明,原肌球蛋白也存在于蚕豆细胞核和染色体中。对高等植物细胞核和染色体以及核骨架和染色体骨架是否含有肌动蛋白等问题进行了讨论。     

植物细胞中NuMA类似蛋白的分布及其在细胞周期中的变化

免疫荧光染色结果说明植物细胞核内含有与抗动物ＮｕＭＡ多抗呈阳性交叉反应的多肽。选择性抽提并结合免疫荧光染色结果说明这种多肽位于核基质纤维蛋白网络上。免疫印迹反应显示胡萝卜（ＤａｕｃｕｓｃａｒｏｔａＬ．）悬浮培养细胞核基质蛋白与抗动物ＮｕＭＡ蛋白多抗的阳性反应条带为７４ｋＤ和７６ｋＤ。有丝分裂各期免疫荧光染色的结果表明植物细胞中的ＮｕＭＡ类似蛋白在有丝分裂过程中呈现有规律的变化。结合选择性抽提的有丝分裂各期的免疫荧光染色的结果表明核基质在此过程中也发生明显变化。应用选择性抽提并结合ＤＧＤ包埋去包埋电镜技术对植物细胞间期及有丝分裂期核基质的形态结构进行了观察。结果显示胡萝卜悬浮培养细胞间期核内存在一个非染色质性的纤维蛋白网络体系,而在正处于分裂的细胞中则未观察到。以上结果说明ＮｕＭＡ类似蛋白是核基质的组分之一并与有丝分裂密切相关。     

四膜虫（Tetrahymena thermophila）核纤层的研究

采用非树脂包埋去包埋超薄切片电镜技术,并结合选择性生化抽提方法以及间接免疫荧光染色方法显示,在四膜虫细胞内存在典型的核纤层结构。蛋白分离纯化与免疫印迹法分析结果说明四膜虫细胞核纤层可能主要由分子量为６６ＫＤ的多肽构成。蛋白分离纯化结果表明四膜虫细胞的核纤层蛋白可能不如高等动物细胞的丰富。     

多头绒泡菌间期细胞核和中期染色体中的银染蛋白分析*

电镜原位观察结合图象分析研究了多头绒泡菌Physarum polycephalum Schw间期细胞核和中期染色体中银染蛋白的形状、大小和分布。结果看到,银染蛋白主要呈颗粒状存在于间期细胞核和中期染色体中。银粒的大小不一,分布不均匀。间期细胞核中存在众多直径在5~15nm的银粒,其中10nm以上的较大银粒主要分布于核仁,集缩染色质和核基质部分10nm以上银粒不多。中期细胞核内10nm以上的较大银粒主要分布于染色体中。染色体中除含有一些较大银粒外,多数银粒的直径为5~10nm。本文结果提示,构成染色体骨架的嗜银蛋白可能来自间期细胞核的染色质、核基质和核仁。     

多头绒泡菌间期细胞核和中期染色体中的银染蛋白分析

电镜原位观察结合图象分析研究了多头绒泡菌Physarum polycephalum Schw间期细胞核和中期染色体中银染蛋白的形状,大小和分布。结果看到,银染蛋白扩要呈颗粒状存在于间期细胞核和中期染色体中。银粒的大小不一,分布不均匀。间期细胞核中存在侈多直径在5－15nm的银粒,其中10nm以上的较大银粒主要分布于核仁,集缩染色质和核基质部分10nm以上银粒不多,中期细胞核内10nm以上的较大银粒主要分布于染色体中。染色体中除含有一些较大银粒外,多数银粒的直径为5－10nm。本文结果提示,构成染色体骨架的嗜银蛋白可能来自间期细胞核的染色质,核基质和核仁。     

A major 62-kD intranuclear matrix polypeptide is a component of metaphase chromosomes

We have isolated and partially characterized a major intranuclear matrix polypeptide from rat liver. This polypeptide, which is reversibly stabilized into the intranuclear matrix under conditions which promote intermolecular disulfide bond formation, has a Mr of 62,000 and pI of 6.8-7.2 as determined by two-dimensional IEF/SDS-PAGE. A chicken polyclonal antiserum was raised against the polypeptide purified from two-dimensional polyacrylamide gels. Affinity-purified anti-62-kD IgG was prepared and used to immunolocalize this polypeptide in rat liver tissue hepatocytes. In interphase hepatocytes the 62-kD antigen is localized in small, discrete patches within the nucleus consistent with the distribution of chromatin. The staining is most prominent at the nuclear periphery and somewhat less dense in the nuclear interior. Nucleoli and cytoplasm are devoid of staining. During mitosis the 62-kD antigen localizes to the condensed chromosomes with no apparent staining of cytoplasmic areas. The chromosomal staining during mitosis is uniform with no suggestion of the patching seen in interphase nuclei. Fractionation and immunoblotting studies using rat hepatoma tissue culture cells blocked in metaphase with colcemid confirm the chromosomal localization of this 62-kD intranuclear protein during mitosis. The 62-kD polypeptide fractionates completely with metaphase chromosome scaffolds generated by sequential treatment of isolated chromosomes with DNAse I and 1.6 M NaCl, suggesting that this major 62-kD intranuclear protein may be involved in maintaining metaphase chromosomal architecture.     

Nuclear matrix proteins (with molecular masses of 38 and 50 kDa) are transported by chromosomes in mitosis

Using the immunofluorescence method, sera M-68 and K-43 from patients with autoimmune diseases were shown to stain interphase nuclei and the periphery of mitotic chromosomes of pig embryo kidney cells. Western blotting revealed a polypeptide with a molecular mass of 50 kDa in M-68 serum and polypeptide with a molecular mass 38 kDa in K-43 serum. In the nuclear protein matrix, the antibodies to protein with a molecular mass of 38 kDa stained only the nucleolar periphery, while the antibodies to protein with a molecular mass of 50 kDa stained not only the nucleolar periphery, but also all interphase nuclei. It was shown that, among all components of the nuclear protein matrix (lamina, internuclear network, residual nucleoli), only the nucleolar periphery contained the 38-kDa protein, while the 50-kDa protein was part of the residual nucleolar periphery and participated in the formation of a nuclear-protein network. Both proteins in interphase cell in situ were located in nuclei, but one of them with a molecular mass of 50 kDa was in the form of small, clearly outlined granules, while the other protein (38 kDa) was in the form of small, bright granules on a background of a diffusely stained nucleus. Both proteins also were revealed as a continuous rim around the nucleolar periphery. During all mitotic stages, the 50-kDa protein was seen over the whole chromosomal periphery as a sheath, while the 38-kDa protein formed individual fragments and granules around them. After the decondensation of the nucleus and chromosomes induced by hypotonic treatment, both antibodies stained interphase nuclei diffusely, whereas, in mitotic cells, they stained the surfaces of swollen chromosomes. Polypeptide with a molecular mass of 50 kDa maintained a strong connection with the periphery of the chromosome in the norm during decondensation induced by hypotonic treatment and during subsequent recondensation in isotonic medium, while, during recondensation, protein with a molecular mass of 38 kDa partially lost contact with the chromosome and, at the same time, appeared in the form of granules in the cytoplasm. The obtained data allow one to conclude that nuclear matrix proteins can be transferred with peripheral chromosomal material; similar to the main nucleolar proteins (fibrillarin, B-23, nucleolin, et al.) and some non-nucleolar components of the nuclear protein matrix, they can also have connections of different stabilities with chromosomal periphery.     

The nucleoli matrix proteins with molecular masses 40 and 27 kDa are transported as peripheral chromosomal material

Using immunofluoresence method, sera M-311 and K-30 obtained from patients with autoimmune disease were shown to stain interphase nuclei and the periphery of chromosomes. Western blotting revealed a polypeptide with mol. mass 27 kDa in serum K-30. Both proteins were localized in the karyoplasm. One of them (27 kDa) has a diffuse form and contains small granules, while the other (40 kDa) is in the form of small clearly outlined granules. Both proteins are also revealed around the nucleolar periphery, making a continental ring, while the main part of the nucleolus remains unstained. During pro- and metaphase, these proteins were associated with the chromosomal periphery: 27 kDa protein formed separate groups, and 40 kDa protein was seen over the whole chromosomal periphery. After nuclear and chromosomal decondensation, induced by hypotonic treatment (15% of culture medium solution), both antibodies stain diffusively interphase nuclei, but in mitotic cells they stained the surface of the swollen chromosomes. After chromatin recondensation in isotonic medium these proteins were localized similarly as in normal cells. Thus, both proteins maintained their association with the periphery of chromosomes. To reveal the nuclear protein matrix, cells were treated with 2M NaCl, DNAase and RNAase A. After this procedure, the antibodies stained only the nucleolar periphery, and no fluorescence in the karyoplasm was seen. It shows that of all the components of the nuclear protein matrix (lamina, internuclear network, residual nucleoli) only 27 and 40 kDa proteins are contained in the nucleolar rim. The data allow to suggest that the nucleolar matrix proteins may be transported to new cell nuclei as part of the peripheral chromosomal material likely as other nucleolar (fibrillarin, B-23, and others) or some non-nuclear components of the nuclear protein matrix are transported.     

Antibodies specific for mitotic human chromosomes

The induction of premature chromosome condensation in an interphase cell immediately following fusion with a mitotic cell suggests the presence of factors in the mitotic cell that are responsible for the transformation of an interphase nucleus into prematurely condensed chromosomes (PCC). Several lines of evidence suggest that these factors are proteins present in the cytoplasm of mitotic cells. The objective of this study was to raise antibodies to the factors responsible for PCC. Cytosol from synchronized mitotic HeLa cells was injected into rabbits in order to obtain antiserum. The IgG fraction from this antiserum reacted with 98% of mitotic HeLa cells when tested by indirect immunofluorescence. Most of the fluorescence was localized on the chromosomes. About 5% of the interphase nuclei also reacted with the antiserum, but 50% of these cells were in early G1. Antigenic reactivity was induced in the condensing interphase chromatin in 31% of the interphase nuclei found in mitotic-interphase fused cells. Rodent cells did not react with the antibody by indirect immunofluorescence. Mitotic HeLa cells were able to induce antigenic reactivity in 23 % of interphase Chinese hamster ovary (CHO) cell nuclei in fused binucleate cells, whereas the converse was not true of mitotic CHO cells. Enzyme digestion and incubation with denaturing agents suggested that antigenic reactivity depended on a DNA-non-histone protein complex.     

Nuclear matrix proteins are carried within peripheral material of mitotic chromosomes

Immunofluorescent analysis has shown that autoimmune sera M-222 and M-260 are bound to interphase nuclei and mitotic chromosomes of the pig embryo kidney cell culture. The fluorescent stain is diffuse in nuclei and forms a thin fluorescent area around each nucleolus, whereas the nucleolar cores are unstained. The periphery of each mitotic chromosome is stained distinctly. After removal of histones and DNA by the cell treatment with 2 M NaCl and DNase I, the Hoechst 33258 staining of nuclei and chromosomes disappears completely, whereas the pattern of staining with antibodies is not changed as compared with normal cells. Electron microscopy revealed in interphase nuclei after such treatment only lamina, residual nucleoli, and the intranuclear matrix network, and antibodies are bound just to these elements. Molecular mass of proteins bound to these antibodies was determined by immunoblotting. Serum M-260 contained antibodies to a single 65 kDa polypeptide, whereas antibodies to two polypeptides of 47 and 65 kDa were found in M-222. After chromatin removal and revealing nuclear protein matrix, M-222 binds only to 65 kDa polypeptides. Thus, peripheral chromosomal material is involved in transfer of the nuclear matrix polypeptide to daughter nuclei during mitosis.     

Topoisomerase II is a structural component of mitotic chromosome scaffolds

We have obtained a polyclonal antibody that recognizes a major polypeptide component of chicken mitotic chromosome scaffolds. This polypeptide migrates in SDS PAGE with Mr 170,000. Indirect immunofluorescence and subcellular fractionation experiments confirm that it is present in both mitotic chromosomes and interphase nuclei. Two lines of evidence suggest that this protein is DNA topoisomerase II, an abundant nuclear enzyme that controls DNA topological states: anti-scaffold antibody inhibits the strand-passing activity of DNA topoisomerase II; and both anti-scaffold antibody and an independent antibody raised against purified bovine topoisomerase II recognize identical partial proteolysis fragments of the 170,000-mol-wt scaffold protein in immunoblots. Our results suggest that topoisomerase II may be an enzyme that is also a structural protein of interphase nuclei and mitotic chromosomes.     

Analysis of the internal nuclear matrix. Oligomers of a 38 kD nucleolar polypeptide stabilized by disulfide bonds

When rat liver nuclei are treated with the sulfhydryl cross-linking reagent sodium tetrathionate (NaTT) prior to nuclease treatment and extraction with 1.6 M NaCl, residual nucleoli and an extensive non-chromatin intranuclear network remain associated with the nuclear envelope. Subsequent treatment of this structure with 1 M NaCl containing 20 mM dithiothreitol (DTT) solubilizes the intranuclear material, while the nuclear envelope remains structurally intact. We have isolated and partially characterized a major polypeptide of the disulfide-stabilized internal nuclear matrix. The polypeptide, which has an apparent molecular mass 38 kD and isoelectric point 5.3, has been localized to the nucleolus of rat liver nuclei by indirect immunofluorescence using a specific polyclonal chicken antiserum. Based on its molecular mass, isoelectric point, intracellular localization and amino acid composition, the 38 kD polypeptide appears to be analogous to the nucleolar phosphoprotein B23 described by Prestayko et al. (Biochemistry 13 (1974) 1945) [20]. Immunologically related polypeptides have likewise been localized to the nucleoli of both hamster and human tissue culture cell lines as well as the cellular slime mold Physarum polycephalum. By immunoblotting, a single 38 kD polypeptide is recognized by the antiserum in rat, mouse, hamster and human cell lines. The antiserum has been utilized to investigate the oligomeric structure of the 38 kD polypeptide and the nature of its association with the rat liver nuclear matrix. By introducing varying numbers of disulfide bonds, we have found that the 38 kD polypeptide becomes incorporated into the internal nuclear matrix in a two-step process. Soluble disulfide-bonded homodimers of the polypeptide are first formed and then are rendered salt-insoluble by more extensive disulfide cross-linking.     

The protein composition of Friend cell nuclear matrix stabilized by various treatments. Different recovery of nucleolar proteins B23 and C23 and nuclear lamins

Summary— Using two-dimensional polyacrylamide gels stained with Coomassie blue we have studied the protein composition of the nuclear matrix obtained from mouse erythroleukemic nuclei kept at O°C throughout the isolation procedure to prepare the high ionic strength resistant fraction (control matrix) or stabilized in vitro or in vivo by different procedures prior to subfractionation (ie 37°C incubation of isolated nuclei; sodium tetrathionate exposure of purified nuclei; heat shock of intact cells). When the matrix obtained from 37°C incubated nuclei was compared with the control matrix, striking differences in the polypeptide pattern were seen if the protein was obtained in both cases from an equivalent number of nuclei. On the other hand, if the same amount of protein for both the samples was applied to the gels the differences were less evident. Sodium tetrathionate stabilization of isolated nuclei and heat shock of intact cells produced a matrix protein pattern that was very similar and differed from that of the in vitro heat-exposed matrix. Using specific polyclonal antisera, we demonstrate that nucleolar proteins B23/numatrin and C23/nucleolin were very abundant in the matrix obtained from chemically-treated nuclei or in vivo heat-stabilized nuclei but were recovered in very small amounts (B23) or completely absent (C23) in the matrix prepared from nuclei heated to 37°C in vitro. Differences were seen also in the recovery of nuclear lamins, and especially lamin B, that was poorly represented in the sodium tetrathionate-stabilized matrix. The results demonstrate that in mouse erythroleukemia cells the increased recovery of nuclear matrix protein that is seen after in vitro heating of isolated nuclei is predominantly due to an additional recovery of the same types of polypeptides that are detected also in the absence of such a treatment. The data also indicate that in vivo heat shock of intact cells produces a nuclear matrix protein pattern that is more similar to the pattern seen after stabilization of purified nuclei with sodium tetrathionate and differs significantly from that obtained by exposing nuclei to 37°C in vitro, unlike to that what previous reports have indicated.