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。     

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。     

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。     

百合花粉母细胞核骨架的超微结构观察

参照动物细胞核骨架的研究方法,用整装电镜技术和DGD包埋-去包埋技术研究了选择性抽提的和完整的百合(Lilium davidii var. willmottiae (Wilson) Roffill)花粉母细胞。结果表明,住减数分裂前期Ⅰ,百合花粉母细胞核内存在一个精细的非染色质纤维——核骨架。该网络由5～15nm的纤维交织而成,广泛地分布于细胞核内。这些核骨架有的分布于染色体间,有的分布于染色体周围,并与染色体和核仁相连。随着减数分裂时间的推移,染色体(质)间核骨架纤维逐渐减少,染色体(质)周围的核骨架纤维逐渐增多,并与染色体内部的纤维结构相连,表明核骨架一方面为染色体拓扑变化提供一个空间支架,另一方面也可能参与了染色体骨架的构建。     

大麦细胞核及染色体肌球蛋白免疫细胞化学定位

对去除DNA、组蛋白和大部分非组蛋白的大麦(Hordeum vulgare)细胞核和染色体间接免疫荧光标记实验结果表明:抗肌球蛋白抗体的荧光标记弥散分布在整个细胞核和染色体上;进一步应用免疫胶体金技术分析肌球蛋白在细胞核和染色体的分布情况,发现在染色体中散布着大量的胶体金颗粒;间期细胞核中胶体金颗粒主要分布在核仁和染色质中。上述实验结果表明:肌球蛋白是细胞核及染色体非组蛋白组成成分。本文还对肌球蛋白在细胞核和染色体中的分布规律进行了讨论。     

玉米rRNA基因的组织和表达模式

玉米（Zea mays）只有1对45S rDNA位点并在分裂期染色体形成次缢痕,是研究植物细胞rRNA基因组织和表达模式的简单模型。采用荧光原位杂交（fluorescence in situ hybridization,FISH）、CPD（PI与DAPI组合）染色和银染技术,分析了玉米根尖分生细胞rRNA基因的组织和表达模式。45S rDNA探针在所有间期细胞核中显示2种杂交信号：荧光强烈地位于核仁周边的纽,而相对较弱地分布于核仁内的点。在部分细胞中可观察到点与纽相连或从纽发出;点的数目越多,纽变得越小;点的数目多少与细胞的活性呈正相关。研究结果表明,纽代表了处于凝缩状态的非活性的rDNA染色质,纽解凝缩形成的点是rRNA基因活跃转录的细胞学表现;不同阶段间期核的点的数目变化反映了被活化的rRNA基因数目不同。间期和前期细胞的CPD染色和相继的银染结果显示,大部分rDNA染色质没有参与核仁的形成。rDNA FISH显示,同一间期细胞的2个同源rDNA位点的表达水平存在差异,同源染色体次缢痕的长度差异以及Ag-NOR和银染核仁的异态性进一步证实了这种差异的存在。FISH结果显示,早中期细胞的rDNA染色质相对解凝缩,银染在所有早中期细胞和部分中期细胞显示了明显的核仁,表明玉米的rRNA基因在有丝分裂早中期有较活跃的转录,其转录在晚中期才停止。     

玉米rRNA基因的组织和表达模式

玉米(Zea mays)只有1对45S rDNA位点并在分裂期染色体形成次缢痕, 是研究植物细胞rRNA基因组织和表达模式的简单模型。采用荧光原位杂交(fluorescence in situ hybridization, FISH)、CPD(PI与DAPI组合)染色和银染技术, 分析了玉米根尖分生细胞rRNA基因的组织和表达模式。45S rDNA探针在所有间期细胞核中显示2种杂交信号: 荧光强烈地位于核仁周边的纽, 而相对较弱地分布于核仁内的点。在部分细胞中可观察到点与纽相连或从纽发出; 点的数目越多, 纽变得越小; 点的数目多少与细胞的活性呈正相关。研究结果表明, 纽代表了处于凝缩状态的非活性的rDNA染色质, 纽解凝缩形成的点是rRNA基因活跃转录的细胞学表现; 不同阶段间期核的点的数目变化反映了被活化的rRNA基因数目不同。间期和前期细胞的CPD染色和相继的银染结果显示, 大部分rDNA染色质没有参与核仁的形成。rDNA FISH显示, 同一间期细胞的2个同源rDNA位点的表达水平存在差异, 同源染色体次缢痕的长度差异以及Ag-NOR和银染核仁的异态性进一步证实了这种差异的存在。FISH结果显示, 早中期细胞的rDNA染色质相对解凝缩, 银染在所有早中期细胞和部分中期细胞显示了明显的核仁, 表明玉米的rRNA基因在有丝分裂早中期有较活跃的转录, 其转录在晚中期才停止。     

多头绒泡菌有丝分裂后细胞核重建过程的形态学研究

以进行自然同步核内有丝分裂的多头绒泡菌(Physarum polycephalum)原生质团为材料,应用常规制片和整体银染后制片的电镜技术研究了有丝分裂后细胞核的形态构建过程。形成新核仁的前体物质在有丝分裂中期时散在染色体区域的周围,末期时与染色体组一起到达两极。子细胞核刚形成时核仁物质与染色质混合,以后核仁物质相互汇合并同染色质逐渐分开,最后形成一个大核仁。染色质在有丝分裂后期开始解集缩,到两极后在新形成的子核中进一步松解。染色质在充分松解后又开始集缩活动,形成一些集缩比较紧密的染色质小块。随着细胞核的进一步发育在核膜和核仁之间形成许多大小不等,形状不规则的染色质团块。     

小麦核仁的超微结构在细胞周期中的变化

应用整体银染技术在电镜下对小麦（Ｔｒｉｔｉｃｕｍ ａｅｓｔｉｖｕｍ Ｌ．）根端分生细胞核仁在细胞周期中的超微结构变化进行了研究。结果显示,间期核仁染色很深,能够区分出纤维中心、密集纤维成分、颗粒成分和核仁液泡等结构;染色质上也布满大量染色浅的细小银粒。前期,随着核仁的解体和染色质的集缩,染色质的边缘逐渐出现深染的大颗粒;到前期末时,大量的核仁物质向染色体周围扩散并附着到其表面。中期染色体的周边分布着来自解体核仁的银染大颗粒,形成一个不大均匀也不完全连续的“鞘”状结构。后期仍可见这种“鞘”状结构的存在。进入末期,这些银染核仁物质逐渐由“鞘”脱离,彼此融合形成前核仁体,最后参与新核仁的形成。这些结果表明,核仁解体后的物质直接转移到了染色体的表面,并形成一个不连续的表层,没有进入染色体内部;染色体内部的银染颗粒与核仁及其解体物质无关     

多头绒泡菌细胞核周期的电镜研究

多头绒泡菌PhysarumpolycophalumSchw的营养生长阶段为没有细胞壁的原生质团（合胞体）,内部众多的细胞核进行着同步的核内有丝分裂,本文电镜下研究了细胞核在有丝分裂周期中的结构变化。有丝分裂前期,染色质经松散改组和集缩形成染色体,核仁由中央移向边缘,并在近核膜处解体;中期核膜不消失,在核内形成纺锤体,核仁解体后的物质是不规则状散在于核内;有丝分裂后核膜的破裂处重新愈合,染色体解集缩成染色质,分散的核仁物质逐渐合并形成新的核仁。     

小麦中期染色体银染蛋白的分析

对小麦中期染色体中银染蛋白的大小、形状和分布频率进行图像分析,看到：染色体顺的银染蛋白以颗粒状的形式存在,其大小不同,分布不均匀,数量差异也较大;从形状来看,大的银粒为点状,小的银粒有的为点状,有的实际为短纤维状,结果表明：染色体骨架在小麦中是真实存在的,骨架蛋白以颗粒和纤维状的形式分布于整个染色体中。     

Ultrastructural Changes of the Nucleolus During Cell Cycle in Triticum aestivum

The ultrastructural changes of the nticleolus during cell cycle in common wheat (Triticum aestivum L. ) were studied by an "en bloc" silver-staining method. It was observed that in interphase, the nucleolus was heavily stained, within which fibrillar centres, dense fibrillar component, granular component and nucleolar vacuoles could be identified. A large quantity of argentine fine granules were distributed in the condensed chromatin. Dur-ing prophase, along with the disintegration of the nucleolus and condensation of the chromatin, the larger heavily-stained granules gradually appeared at the periphery of the chromatin. At late prophase, the materials derived from the nucleolus were spread and deposited on the surface of the chromosomes. The silver-stained, larger granules, deriving from the disintegrated nucleolus, accumulated at the periphery of the metaphase chromosomes and formed an uneven and discontinuous "sheath"-like structure. This "sheath"-like structure was also observed at anaphase. In telophase, the silver-stained nucleolar materials were progressively separated from the "sheath' and fused with each other to form prenucleolar bodies, and at last, participating in the formation of new nucleoli. The results showed that the nucleolar materials were transferred directly to the surface of the chromosomes and formed a discontinuous coat, but not incorporated into the interior of the chromosomes. The silverstained granules inside the chromosomes were neither related to the nucleolus nor to the materials from the disintegrated nucleolus.     

Distribution of nuclear matrix proteins in interphase CHO cells and rearrangements during the cell cycle. An ultrastructural study

The nuclear matrix contains a group of residual non-histone proteins which remain structurally organized after extensive extraction of isolated nuclei with a high salt buffer, nucleases and a non-ionic detergent. Electron microscopic examination shows that the nuclear matrix is composed of a pore-complex lamina, an intranuclear network and residual nucleoli. In CHO cells biochemical analyses performed by one-dimensional SDS-PAGE show three major nuclear matrix polypeptides with molecular weights between 60 and 70 kDa. Polyclonal antibodies produced against these polypeptides were used to determine their nuclear distribution. Using immunoblotting, these proteins were found in whole nuclei, nuclear matrix, and in the intranuclear network but not in the pore-complex lamina. In order to determine the relationship between these structural proteins and the organization of the nucleus, the proteins were localized in situ. Ultrastructural detection was carried out by immunogold staining of thin sections of Lowicryl K4M-embedded cells. In interphase nuclei all condensed chromatin clumps were labelled. The nucleolus and the interchromatin granules were never immunogold-stained. During mitosis, the label was found to be associated with the chromosomes. This study shows that unlike the lamins, these 60-70 kDa nuclear matrix proteins are associated with the condensed chromatin throughout the cell cycle.     

A cytochemical study of the nonhistone protein content of condensed and extended chromatin

Cytochemical techniques have been used to study the distribution of nonhistone proteins in sections of interphase nuclei and mitotic chromosomes. Condensed chromatin, including the heterochromatin of interphase nuclei from frog liver, and mitotic metaphase and anaphase chromosomes from bovine kidney, show little or no staining for nonhistone protein. Regions of frog liver nuclei which contain extended chromatin (euchromatin) stain intensely for nonhistone protein. These differences in nonhistone staining of condensed and extended chromatin support the suggestion that regions of condensed chromatin contain considerably less nonhistone protein than regions of extended chromatin. The results suggest further that there may be considerably less nonhistone protein associated with chromosomes and interphase heterochromatin than has been reported in most previous analyses of isolated chromatin and chromosome preparations.     

An electron microscopic study of mitosis in mouse duodenal crypt cells confirms that the prophasic condensation of chromatin begins during the DNA-synthesizing (S) stage of the cycle

The phases of mitosis were examined in the columnar cells at the base of duodenal crypts in adult male mice given an intravenous injection of 3H-thymidine and sacrificed 20 min later. The duodenum was fixed by immersion into glutaraldehyde-formaldehyde, and the cells were examined in the electron microscope, with or without processing for radioautography. Interphase nuclei are characterized by the distribution of chromatin; aside from the cortical chromatin spread along nuclear envelope and nucleolus, there are chromatin accumulations that belong mainly in two different classes: 1) numerous chromatin "specks" ranging in size from about 5 to 70 nm and averaging 47 nm; 2) a few roughly circular or elongated chromatin "packets" measuring from 70 to 230 nm. Early prophase nuclei differ mainly by a large increase in the number of chromatin packets to 20-30 or more per nuclear profile; their average diameter is 128 nm. During mid-prophase, the chromatin packets enlarge gradually to an average 221 nm diameter. Between mid- and late prophase, there is a further increase in diameter to 679 nm. At metaphase, the packets take on the appearance of mature chromosomes, and their diameter increases to 767 nm. At anaphase, daughter chromosomes migrate to each pole, where they fuse into a compact chromatin mass. At telophase, nucleoplasmic areas progressively enlarge within the chromatin mass and separate strands of chromatin, which gradually become segmented into chromatin clumps. Counts of mitotic cells show a high proportion of prophase and telophase nuclei. Calculation from the counts yields the duration of the phases, that is, 5.6, 0.2, 0.1, and 1.6 hr, respectively, for pro-, meta-, ana-, and telophase. Finally, radioautography 20 min after 3H-thymidine injection shows labeling in 54% of the interphase nuclei, 85% of early prophase nuclei, and 73% of mid-prophase nuclei, while there is no label in late prophase, metaphase, anaphase and telophase nuclei. In confirmation of previous light microscopic work, the S stage of the cycle begins when a cell is in interphase and continues through the early prophase and part of mid-prophase. Moreover, the main sites of DNA synthesis are the chromatin specks during interphase and the cortical chromatin during early and mid-prophase. The chromosome condensation taking place in the meantime may be separated into two main steps: 1) a slow, moderate condensation of the chromatin packets during early and mid-prophase and 2) a rapid, pronounced one during late prophase and prometaphase when the packets become chromosomes.     

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.     

Features of interactions of p68 anchorosomal protein with the nuclear envelope in the cell cycle

Chromatin associated with the nuclear envelope appears in the interphase nuclei as a layer of anchorosomes, granules 20-25 nm in diameter. The fraction of chromatin directly associated with the nuclear envelope is resistant to decondensation, shows a low level of DNA methylation, and contains specific acid-soluble proteins. However, mechanisms underlying the interaction of chromatin with the nuclear envelope are not fully understood. Specifically, it is not known whether anchorosomes are permanent structures or if they undergo reversible disassembly during mitosis, when contacts between chromatin and the nuclear envelope are destroyed. We obtained immune serum recognizing a 68 kDa protein from the nuclear envelopes fraction and studied the localization of this protein in interphase and mitotic cells. We show that this protein present in the NE/anchorosomal fraction does not remain bound with chromosomes during mitosis. It dissociates from chromosomes at the beginning of the prophase and then can be identified again at the periphery of the newly forming nuclei in the telophase.     

The translocation and specific binding of the pesticide fluometuron (cotoran) with the proteins of rat liver nuclei]

Intracellular distribution of labeled cotoran was studied. 3H-cotoran was shown to penetrate through the nuclear membrane to accumulate uneventfully in the intranuclear components. An insignificant amount of 3H-cotoran was associated with the nucleoplasm and the outer nuclear membrane. At the same time, essential radioactivity was observed in the proteins of the nuclear matrix (up to 30%) and in non-histone proteins of chromatin (up to 60%). Acception of 3H-cotoran on metaphase chromosomes of cultured cells as well as specificity of cotoran binding with non-histone proteins of chromatin in vivo and in vitro was studied by radioautography. It was revealed that cotoran was translocated into the interphase nuclei to be accepted by metaphase chromosomes of the HeLa line cells and fibroblasts in human embryo, and specifically, in receptor-like manner, bound to chromatin proteins.     

In situ factors affecting stability of the DNA helix in interphase nuclei and metaphase chromosomes

The data from earlier cytochemical studies, in which the metachromatic fluorochrome acridine orange (AO) was used to differentially stain single vs double-stranded DNA, suggested that DNA in situ in intact metaphase chromosomes or in condensed chromatin of G0 cells is more sensitive to denaturation, induced by heat or acid, than DNA in decondensed chromatin of interphase nuclei. Present studies show that, indeed, DNA in permeabilized metaphase cells, in contrast to cells in interphase, when exposed to buffers of low pH (1.5-2.8) becomes digestible with the single-strand-specific S1 or mung bean nucleases. A variety of extraction procedures and enzymatic treatments provided evidence that the presence of histones, HMG proteins, and S-S bonds in chromatin, as well as phosphorylation or poly(ADP)ribosylation of chromatin proteins, can be excluded as a factor responsible for the differential sensitivity of metaphase vs interphase DNA to denaturation. Cell treatment with NaCl at a concentration of 1.2 N and above abolished the difference between interphase and mitotic cells, rendering DNA in mitotic cells less sensitive to denaturation; such treatment also resulted in decondensation of chromatin visible by microscopy. The present data indicate that structural proteins extractable with greater than or equal to 1.2 N NaCl may be involved in anchoring DNA to the nuclear matrix or chromosome scaffold and may be responsible for maintaining a high degree of chromatin compaction in situ, such as that observed in metaphase chromosomes or in G0 cells. Following dissociation of histones, the high spatial density of the charged DNA polymer may induce topological strain on the double helix, thus decreasing its local stability; this can be detected by metachromatic staining of DNA with AO or digestion with single-strand-specific nucleases.