何氏奥库线虫在生长过程中肠细胞核内DNA含量变化的细胞光度法分析

1.何氏奥库线虫生长过程中,肠细胞核平均数目逐渐增多,但未观察到有丝分裂,只出现近似无丝分裂的图象。该线虫肠细胞核数目和核体积形成相反的变化。2.为了阐明线虫肠细胞的遗传信息含量的变化,应用细胞光度法测定核内DNA 含量。结果表明,在相近体长的雌虫中,肠细胞核数目和每核平均DNA 含量成相反关系。凡细胞核较多的肠道,每核平均DNA 含量较低;反之亦然。如果选取肠细胞核数目相近的雌虫进行比较,随着虫体的长大,每核平均DNA 含量有所增高。3.这种线虫肠细胞核为多倍体,每核平均甚至高达3000C,但各核DNA 含量的分布曲线的高峰并不严格形成2~n 比例,显示这是由部分的双倍体DNA 不完全复制而成。4.尽管各线虫的肠细胞核数目和核体积相差悬殊,但是在相近长度的雌虫中,整个肠道的DNA 总量经常保持在一定数值范围内。随着虫体的增大,肠道DNA总量逐渐提高。5.这种雌虫的生殖过程连续交叉,不分成明显阶段,肠道DNA 总量反映虫体维持全身营养代谢的需要。显示代谢DMA 和仆基因的存在和变化,为深入阐明细胞分化原则提供依据。     

贻贝雄性生殖系统的组织学和超微结构

贻贝雄性生殖系统中精巢由树枝状的生殖管,输精管民。生殖管反复分枝成生精小管而末端膨大的泡囊,二者皆由位于基膜上的生殖上皮和管壁上皮构成,生殖上皮是由圆形或卵圆形的精原细胞组成,精原细胞最大,核内染色质稀疏,靠核膜内侧分布,核仁一个,明显。初级精母细胞上,染色质开始集成小团块,线粒体向细胞的一侧集中,次级精母细胞与表母细胞结构相似,染色质浓缩成数大块,核膜或散布于核内,精细胞内开始出现顶体颗粒并逐渐     

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。     

东方蝾螈早期发育过程中细胞核超微结构的观察

东方蝾螈胚胎发育过程中,从原肠早期到原肠末期无论外胚层或中胚层细胞核内都含有大量的异染色质团块,而到神经板形成后所有细胞核内染色质均呈分散状态。异染色质向常染色质的转变过程发生在原肠末期到神经板形成这段时间里,在原口闭合后4.5小时之前完成,此时期似乎是形态发生的转折点。到发育的后期,细胞核内有一些染色质又会由分散状态转变为凝聚的异染色质团块。预定神经上皮向神经组织分化的决定是个逐渐的过程,这一过程在原肠口闭合时已经开始,到神经板期完成。染色质的分散似乎发生在细胞有了初步决定之后。本文就染色质超微结构变化的意义以及染色质超微结构变化与细胞分化的关系等问题进行了讨论。     

小麦类根瘤胞间根瘤菌对分生细胞核的影响

在小麦类根瘤中,分生细胞核很大,而且较圆整,一般为一个核仁,有的核仁还有核仁泡,但通常一个核仁只有一个核仁泡,染色质较少,呈团块状分布。若胞间根瘤菌离分生细胞核较远,分生细胞核变化不大,只是染色质开始由团块状变为长条形,但仍有核仁。当胞间根瘤菌靠近分生细胞核时,细胞核变小,染色质密度增加并形成网状,而且无核仁出现。在上述这些无核仁的分生细胞核内有一种特殊的管状内含体,它们位于网状染色质附近的核基质中。本文还讨论了分生细胞核的变化规律及其与胞间根瘤菌存在的关系。     

高等动物细胞核膜和核纤层结构、功能及动态变化调控机制

细胞核是真核细胞中最大的细胞器．高等动物细胞核主要由双层核膜、核孔复合体、核纤层、染色质和核仁等组成．在细胞有丝分裂期,细胞核呈现去装配和再装配等动态变化．在细胞分裂间期,核膜、核孔复合体和核纤层构成细胞核的外周结构,为遗传物质在染色质和核仁中的代谢提供了一个相对稳定的环境,同时调控细胞核内外的物质转运,在细胞增殖、分化、个体发育和细胞衰老等许多方面发挥着重要作用．本文主要对高等动物细胞核膜和核纤层结构、功能及动态变化调控机制等方面的研究进展进行简要综述．     

四膜虫(Tetrahymena shanghaiensis)大核核仁与去膜大核能诱导非细胞体系核重建

外源DNA或染色质在非洲爪蟾卵提取物中可以诱导细胞核样结构的重建。重建核除不具有核仁样结构外,在其它形态结构上与真核细胞核十分相似。前人的工作表明在重建核中具有核仁前体结构。但可能是由于缺少活性核仁组织者的缘故,这些核仁前体不能相互融合形成新生核仁。那么活性核仁组织者在重建核中是否能发挥其功能呢?为了研究这一问题,我们提取纯化了四膜虫的大核与大核的周边核仁。进一步去除大核的核被膜,并将去除核被膜的大核与大核核仁分别加入非洲爪赡卵非细胞体系中。通过电镜超薄切片观察,我们发现无论是与大核染色质相连的周边核仁还是分离纯化的核仁结构在非洲爪赡卵非细胞体系中都不能保持其原有结构特征,而是发生了典型核重建变化,并且在诱导形成的重建核中也看不到核仁样结构。这些结果说明具有活性的核仁组织者在加入非洲爪蟾卵提取物后既不能继续保持其原有的RNA转录功能也不能诱导新的核仁的出现。     

沙打旺组织培养中脱分化细胞的超微结构及细胞核的动态变化

对沙打旺的下胚轴、子叶、幼叶组织培养中脱分化细胞进行了超微结构观察,并着重讨论了细胞核的动态变化。脱分化细胞的细胞质中线粒体墙加,嵴明显;多聚核糖体增多;高尔基体增加;质体中积累淀粉。核仁与核内异染色质之间有一个动态过程。此过程暂称“核仁物质喷射“现象。在致有以下：１．核体出现,半嵌在增大的核仁上,核内异染色质沿核膜凝聚;２．异染色质移向核仁,并与核仁接触,核体消失,部分异质进入核仁;３．核仁物质     

多头绒泡菌细胞核周期的电镜研究

多头绒泡菌Ｐｈｙｓａｒｕｍ ｐｏｌｙｃｅｐｈａｌｕｍ Ｓｃｈｗ的营养生长 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,核仁解体后的物质呈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     

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。     

Quantitative investigation of reproduction of condensed chromatin of sex chromosomes during trophoblast cell polyploidization and endoreduplication in the East European field vole Microtus rossiaemeridionalis

Simultaneous measurement of DNA content in cell nuclei and condensed chromatin bodies formed by heterochromatized regions of sex chromosomes (gonosomal chromatin bodies, GCB) has been performed in two trophoblast cell populations of the East-european field vole Microtus rossiaemeridionalis, namely in the proliferative population of trophoblast cells of the junctional zone of placenta and in the secondary giant trophoblast cells. One or two gonosomal chromatin bodies have been observed in trophoblast cell nuclei of all embryos studied (perhaps both male and female), In the proliferative trophoblast cell population, characterized by low ploidy levels (2c-16c), and in the highly polyploid population of secondary giant trophoblast cells (16c-256c), the total DNA content in GCB increased proportionally to the ploidy level. In separate bodies, the DNA content rose also in direct proportion with the ploidy level seen in the nuclei with both one and two GCBs in the two trophoblast cell populations. A certain increase in percentage of the nuclei with 2-3 GCBs was shown in the nuclei of the junctional zone of placenta; this may be accounted for by genome multiplication via uncompleted mitoses. In the secondary giant trophoblast cell nuclei (16c-256c), the number of GCBs did not exceed 2, and the share of nuclei with two GCBs did not increase, thus suggesting the polytene nature of sex chromosome in these cells. At different poloidy levels, the ratio of DNA content in the nucleus to the total DNA content in GCB did not change significantly giving evidence of a regular replication of sex chromosomes in each cycle of genome reproduction. In all classes of ploidy, the mean total DNA content in trophoblast cell nuclei with single heterochromatic body was less than in the nuclei with two and more GCBs. This may indicate that a single GCB in many cases does not derive from the fusion of two GCBs. To put it another way, in the nuclei with one GCB and in those with two or more GCBs, different chromosome regions may undergo heterochromatization. The regularities observed here are, most probably, associated with the peculiarities in the structure of X- and Y-chromosomes in a range of species of Microtus (M. agrestis, M. rossiaemeridionalis, M. transcaspicus). As a result, gonosomal chromatin bodies may include large blocks of both constitutive heterochromatin of X- and Y-chromosomes (in male and female embryos) and inactivated euchromatin of "lyonized" X-chromosome in female embryos. Therefore the presence of two or more GCBs in trophoblast cells of M. rossiaemeridionalis may be accounted for by both polyploidy and functional state of the nucleus, in which gonosomal constitutive heterochromatin and inactivated euchromatin form two large chromocenters rather than one. The differences in DNA content in GCBs in the nuclei with one and two GCBs seem to be an indirect indication that the two chromocenters may be formed by two different gonosomes, with the extent of their heterochromatization being higher than that in the nuclei with one GCB. GCBs in the trophoblast cells of M. rossiaemeridionalis are observed not only at the early developmental stages, as it was observed in rat at the first half of pregnancy (Zybina and Mosjan, 1967), but also at the later stages, up to the 17th day of gestation. At these stages, the nuclei with non-classical polytene chromosomes rearrange to those with a great number of endochromosomes, probably because of disintegration of chromosomes into oligotene fibrils. However, it does not seem unlikely that this process may involve heterochromatized gonosomal bodies, since only one or two large GCBs can be seen in the nuclei as before. The presence of prominent blocks of constitutive heterochromatin seems to favor a closer association of sister chromatids in polytene chromosomes, which prevents their dissociation into endochromosomes with the result that polyteny of sex chromosomes in the field vole trophoblast is probably retained during a longer period of embryonic development.     

Transformations of sperm nuclei incorporated into sea urchin (Arbacia punctulata) embryos at different stages of the cell cycle

In order to test the hypothesis that regulators of male pronuclear development may have a more general role, sharing some relation to factors involved with the cell cycle, Arbacia zygotes and 2- to 8-cell stage embryos were inseminated during different phases of the cell cycle and examined by light and electron microscopy. Differences in the development and morphology of fertilization cones and sperm asters were observed in embryos inseminated during different stages of the cell cycle. Extremely large fertilization cones, approximately four times the length of those found in fertilized eggs, formed in embryos inseminated during metaphase to telophase. Sperm asters developed only in embryos inseminated during prophase to anaphase. These variations are believed to reflect changes in the status of the cortex and cytoskeletal system of the embryo. Although sperm nuclei underwent morphological changes subsequent to incorporation, in general, they failed to develop into male pronuclei. There was a consistent correlation in sperm nuclear transformations and the cell cycle which was expressed in two patterns of morphogenesis: (1) sperm nuclei incorporated into embryos just prior to prophase and at telophase failed, for the most part, to disperse and transformed into aggregations of chromatin granules approximately 40 nm in diameter; and (2) sperm nuclei incorporated into prometaphase-anaphase embryos dispersed and then condensed into chromatin masses, morphologically similar to chromosomes of the embryo. Evidence is discussed which indicates that following the normal period of fertilization changes occur in the zygote, rendering it unable to fully support the transformation of sperm nuclei into male pronuclei.     

Visualization of chromatin substructure: upsilon bodies

Spread chromatin fibers, from isolated eucaryotic nuclei, reveal linear arrays of spherical particles (upsilon bodies), about 70 A in diameter, connected by thin filaments about 15 A wide. These particles have been observed in freshly isolated nuclei from rat thymus, rat liver, and chicken erythrocytes. In addition, upsilon bodies can be visualized in preparations of isolated sheared chromatin, and in chromatin reconstructed from dissociating solvent conditions (i.e., high urea-NaCl concentration). As a criterion for perturbation of native chromatin structure low-angle X-ray diffraction patterns were obtained from nuclear pellets at different stages in the preparation of nuclei fro electron microscopy. These results suggest that the particulate (upsilon body) structures observed by electron microscopy may be closely related to the native configuration of chromatin.     

Chromosome-like bodies of dysentery ameba Entamoeba histolytica

Intact and surface stretched amembraneous nuclei of Entamoeba histolytica (Rhizopoda, Lobosea, Entamoebidae) trophozoites were studied by light and electron microscopy. A moderately dense karyosome about 1.5 microns in diameter, localized in the central part of the interphase nucleus, contains the bulk of nuclear DNA. Within the karyosome, beaded and ribbon-like chromatin bodies surrounding a loose fibrillar core are commonly recognized. The peripheral domain of both interphase and several mitotic nuclei is filled with a heterogeneous material similar in its ultrastructure to the nucleolar substance. A wide fibrogranular domain lies between this unusual nucleolus and the karyosome. Rosette-like intranuclear inclusions 0.2-0.4 micron in diameter are often seen in both the fibrogranular and nucleolar domains. At the prophase-metaphase, nearly 50 linear chromosome-like bodies are detected as being in close association with several large beaded and ribbon-like chromatin bodies. At the anaphase-telophase, the chromatin bodies per surface-stretched daughter nucleus of live entamoebae, and in each amembraneous daughter nuclear preparation number nearly 14 and 6, respectively. Besides, in each amembraneous DAPI-stained nucleus a set of 50 or so linear chromosome-like bodies are clearly identified. We infer that the nucleus of E. histolytica contains more than 50 linear chromosomes which at different stages of the cell cycle can unite into several beaded and ribbon-like associations. These form a single moderately dense chromatin karyosome in the central part of the interphase nucleus.     

Coordinates,DNA content and heterogeneity of cell nuclei and segments of the <Emphasis Type="Italic">Caenorhabditis elegans</Emphasis> intestine

A specific protocol allowed to selectively stain and image the cell nuclei of the intestine of the nematode Caenorhabditis elegans. Digital processing of these images yielded quantitative information on the coordinates and the relative DNA content of these cell nuclei. With this technique, the exact locations (in relation to the length of worm or intestine) of the 20 intestinal cell nuclei of larval stage L1 and of the 34 intestinal cell nuclei of larval stages L2–4 and adults were determined. Tracking the DNA content of an individual intestinal cell nuclei allowed to study nuclear DNA endoreduplications during larval growth. The evaluation of the DNA content of all intestinal cell nuclei revealed a strong heterogeneity between the cell nuclei and intestinal segments with a maximum in segments int4–int5 in the L1 stage and int5–int6 in the L2–L4 stages. Minimum values were detected in the segments int2 and int8–int9 of all larval stages. Heterogeneity between the intestinal segments of C. elegans does not only concern the DNA content of cell nuclei, but also other cellular features like the quantity of intracellular vesicles or the absorption of particles out of the intestinal lumen.     

Spermatogenesis and chromatin condensation in male germ cells of sea cucumber Holothuria leucospilota (Clark, 1920)

Male germ cells in the testis of Holothuria leucospilota can be divided into 12 stages based on ultrastructure and patterns of chromatin condensation. The spermatogonium (Sg) is a spherical-shaped cell with a diameter of about 6.5-7microm. Its nucleus mostly contains euchromatin and small blocks of heterochromatin scattered throughout the nucleus. The nucleolus is prominent. Primary spermatocytes are divided into six stages, i.e., leptotene (LSc), zygotene (ZSc), pachytene (PSc), diplotene (DSc), diakinesis (DiSc) and metaphase (MSc). The early cells are round while in DiSc and in MSc cells are oval in shape. From LSc to MSc, the sizes of cells range from 3.5 to 4microm. LSc contains large blocks of heterochromatin as a result of increasingly condensed 17nm fibers. In ZSc, the nucleus contains prominent synaptonemal complexes but a nucleolus is absent. In PSc, heterochromatin blocks are tightly packed together by 26nm fibers and appeared as large patches in DSc. Heterochromatin patches were enlarged to form chromosomes in DiSc and MSc and then the chromosome are moved to be aligned along equatorial region. The secondary spermatocyte (SSc) is an oval cell about 4.5-5.5microm. Their nuclei contain large clumps of heterochromatin along the nuclear envelope and in the center nuclear region. Spermatids are divided into two stages, i.e., early spermatid (ESt) and late spermatid (LSt). The nuclei decrease in size by a half and become spherical; thus the chromatin fibers condensed into 20nm and are closely packed together leaving only small spaces in LSt. The spermatozoa (Sz), with chromatin tightly packed in the spherical nucleus with a diameter of 2microm and a small acrosome situated at the anterior of the nucleus. The tail consists of a pair of centrioles lying perpendicular to each other and surrounded by a mitochondrial ring, and an axonemal complex, surrounded by a plasma membrane.     

A comparison of the digestion of nuclei and chromatin by staphylococcal nuclease.

We have followed the kinetics of staphylococcal nuclease digestion of duck reticulocyte nuclei and chromatin from early stages to the digestion limit. We confirm that partial digestion of nuclei produces discrete DNA bands which are multiples of a monomer, 185 base pairs in length. The multimers are shown to be precursors of the monomer, which is next digested to a homogeneous, 140 base pair fragment. This fragment in turn gives rise to an array of nuclear limit digest DNA bands, which is almost identical with the limit digest pattern of isolated chromatin. As in the case of chromatin, half the DNA of nuclei is acid soluble at this limit. While the DNA limit digest patterns of nuclei and chromatin are similar, the large multimeric structures present as intermediates in nuclear digestion are absent in chromatin digestion. Alternate methods of chromatin gel preparation appear to leave more of the higher order structure intact, as measured by the production of these multimeric bands. Our results are consistent with the "beads on a string" model of chromatin proposed by others.     

Quantitative investigation of reproduction of gonosomal condensed chromatin during trophoblast cell polyploidization and endoreduplication in the east-european field vole <Emphasis Type="Italic">Microtus rossiaemeridionalis</Emphasis>

Simultaneous determinations of DNA content in cell nuclei and condensed chromatin bodies formed by heterochromatized regions of sex chromosomes (gonosomal chromatin bodies, GCB) have been performed in two trophoblast cell populations of the East-European field vole Microtus rossiaemeridionalis: in the proliferative population of trophoblast cells of the junctional zone of placenta and in the secondary giant trophoblast cells. One or two GCBs have been observed in trophoblast cell nuclei of all embryos studied (perhaps both male and female). In the proliferative trophoblast cell population characterized by low ploidy levels (2–16c) and in the highly polyploid population of secondary giant trophoblast cells (32–256c) the total DNA content in GCB increased proportionally to the ploidy level. In individual GCBs the DNA content also rose proportionally to the ploidy level in nuclei both with one and with two GCBs in both trophoblast cell populations. Some increase in percentage of nuclei with 2–3 GCBs was shown in nuclei of the placenta junctional zone; this may be accounted for by genome multiplication via uncompleted mitoses. In nuclei of the secondary giant trophoblast cells (16–256c) the number of GCBs did not exceed 2, and the fraction of nuclei with two GCBs did not increase, which suggests the polytene nature of sex chromosomes in these cells. In all classes of ploidy the DNA content in trophoblast cell nuclei with the single GCB was lower than in nuclei with two and more GCBs. This can indicate that the single GCB in many cases does not derive from fusion of two GCBs. The measurements in individual GCBs suggest that different heterochromatized regions of the X- and Y-chromosome may contribute in GCB formation.