蚕豆染色体集缩和解集缩过程中的螺旋结构

运用常规电镜技术观察到,在有丝分裂前期的集缩过程中,蚕豆(Vicia faba)染色体横切面为直径约0.5μm的染色质纤维形成的环状结构;染色体纵切面上存在着平行排列的0.5μm染色质纤维,它们与染色体长轴所成的角度近似直角。通过立体电镜观察可清晰辨认出这些纤维盘绕成的螺旋结构。在有丝分裂末期至间期的解集缩过程中,染色体横切面由环形变为“C”形。这种“C”形构造显示了染色体螺旋结构的解螺旋过程。在染色体集缩和解集缩过程中均可观察到0.5μm染色质纤维和直径约0.2μm的染色质纤维。本文讨论了放射环模型和多级螺旋模型。     

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。     

多头绒泡菌染色体构建过程的形态学研究

以同步核内有丝分裂的多头绒泡菌(Physarum polycephalum)原质团为材料,在有丝分裂周期中连续取材,按常规方法制备超薄切片,在电镜下研究了染色体形态构建的整个过程。有丝分裂前期,首先是G_2期凝集的染色质块逐渐解集缩成为松散状,染色质在松散的同时逐渐改组成直径为80～150nm的松散染色线结构。接着是在松散的染色线上形成一些电子密度高的集缩区,随着集缩区的增多和扩展,染色线缩短变粗,最后形成直径300～350nm的染色体。上述两个过程各需30min左右。与上述过程同时发生的是,核仁由中央位置逐渐移向边缘,前期50min左右时在近核膜处呈团块状解体。染色体形态构建的整个过程约需1h,可分为染色质的松散改组和集缩两个连续的步骤,25～30nm染色质纤维是这一过程中能分辨的最细的形态单位。     

小麦间期集缩染色质的超微结构研究

本文以普通小麦(Triticum aestivum L.)根端分生组织为材料,在透射电镜下对间期细胞核内的集缩染色质的高层次结构进行了研究。在其中观察到直径约为20—25nm、50nm及110—120nm 的不同等级染色线,并且发现直径110—120nm 的染色线是由50nm 的染色线组成的,而直径约50nm 的染色线是由20—25nm 的染色线组成的。对这三个层次染色质结构之间的集缩方式进行了讨论。     

豌豆细胞核仁中rDNA的超微定位和排布构型

利用细胞化学DNA特异染色法——NAMA-Ur特异染色法对豌豆细胞核仁中rDNA的位置及其排布构型进行了原位观察。结果表明,核仁中的rDNA位于纤维中心(FC)以及FC与致密纤维组分的交界处,以环绕FC的形式排布。不同位置的rDNA成分都具有集缩和解集缩两种形态结构,核仁外的核仁伴随染色质经过核仁通道进入核仁,沿FC周边排列,与其中的DNA相连。     

豌豆细胞核仁中rDNA的超微定位和排布构型

利用细胞化学DNA特异染色法——NAMA-Ur特异染色法对豌豆细胞核仁中rDNA的位置及其排布构型进行了原位观察。结果表明,核仁中的rDNA位于纤维中心(FC)以及FC与致密纤维组分的交界处,以环绕FC的形式排布。不同位置的rDNA成分都具有集缩和解集缩两种形态结构,核仁外的核仁伴随染色质经过核仁通道进入核仁,沿FC周边排列,与其中的DNA相连。     

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。     

蚕豆细胞核仁和核质中剪接因子SC35的定位研究

本文以蚕豆(Vicia faba L.)根端分生组织细胞为材料,以抗SC35抗体为探针,在电镜下对SC35在高等植物细胞中的存在与否和分布特点进行了研究,发现经抗SC35抗体标记后,标明SC35位置的胶体金颗粒主要分布于核仁的致密纤维组分(DFC)、核质的染色质间颗粒(IGs)和染色质周边纤维处(PFs),而核仁的纤维中心(FC)、核仁液泡和集缩染色质团块中央部位的金颗粒很少。DFC, IGs和PFs处的金颗粒平均密度分别为65.89个/μm~2和36.28个/μm~2,远远高于集缩染色质团块中央部位以及FC和核仁液泡处的金颗粒平均密度(分别为5.90个/μm~2和6.26个/μm~2)。说明蚕豆细胞核仁的DFC,核质的IGs和PFs处富含剪接因子SC35。本文研究结果表明,SC35或SC35类蛋白在蚕豆细胞核质中的分布与其在哺乳动物细胞核质中的分布规律相似。同时本文首次报道了SC35或SC35类蛋白存在于核仁中。     

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     

果蝇多线染色体β异染色质区的螺旋结构

从1973年发现核小体至今,研究者们对染色质纤维结构和这种纤维组织成染色体的方式进行了广泛而深入的研究.由DNA到核小体到30nm染色质纤维几乎公认是按螺旋方式集缩的,但是有关30nm 左右染色质纤维如何压缩形成染色体的高层次结构还没有统一的意见.     

Radiation-induced cytogenetic damage in relation to changes in interphase chromosome conformation

The premature chromosome condensation (PCC) technique was used to study several factors that determine the yield of chromosome fragments as observed in interphase cells after irradiation. In addition to absorbed dose and the extent of chromosome condensation at the time of irradiation, changes in chromosome conformation as cells progressed through the cell cycle after irradiation affected dramatically the yield of chromosome fragments observed. As a test of the effect of chromosome decondensation, irradiated metaphase Chinese hamster ovary (CHO) cells were allowed to divide, and the prematurely condensed chromosomes in the daughter cells were analyzed in their G1 phase. The yield of chromosome fragments increased as the daughter cells progressed toward S phase and chromosome decondensation occurred. When early G1 CHO cells were irradiated and analyzed at later times in G1 phase, an increase in chromosome fragmentation again followed the gradual increase in chromosome decondensation. As a test of the effect of chromosome condensation, G0 human lymphocytes were irradiated and analyzed at various times after fusion with mitotic CHO cells, i.e., as condensation proceeded. The yield of fragments observed was directly related to the amount of chromosome condensation allowed to take place after irradiation and inversely related to the extent of chromosome condensation at the time of irradiation. It can be concluded that changes in chromosome conformation interfered with rejoining processes. In contrast, resting chromosomes (as in G0 lymphocytes irradiated before fusion) showed efficient rejoining. These results support the hypothesis that cytogenetic lesions become observable chromosome breaks when chromosome condensation or decondensation occurs during the cell cycle.     

An indirect role for cyclin B-Cdc2 in inducing chromosome condensation in Xenopus egg extracts

We have studied the cytoplasmic mechanism that induces metaphase chromosome condensation in cell-free Xenopus egg extracts. To analyze the mechanism responsible for inducing chromosome condensation separately from those responsible for sperm chromatin remodeling and nuclear envelope disassembly, we used Xenopus sperm chromatin that had already been remodeled to nucleosomal chromatin by incubating demembranated sperm with egg extracts added with lysolecithin. We found that inhibition of cyclin B-Cdc2 with butyrolactone I abolished chromosome condensation of the remodeled sperm chromatin by M-phase egg extracts, but incubation of the chromatin with active cyclin B-Cdc2 alone did not induce chromosome condensation, indicating a requirement for cytoplasmic factor(s) in addition to cyclin B-Cdc2 for the induction of chromosome condensation. We further demonstrated that if the cyclin B-Cdc2-dependent phosphorylation state was protected against dephosphorylation by a preincubation of M-phase extracts with ATP-γ-S, chromosome condensation and phosphorylation of chromosomal histone H1 occurred even when extracts were depleted of cyclin B-Cdc2 activity. The chromosome condensation seen in the absence of cyclin B-Cdc2 was completely inhibited with another protein kinase inhibitor, 6-dimethylaminopurine, implying that a protein kinase other than cyclin B-Cdc2 was involved in the induction of chromosome condensation. These results strongly suggest that a cyclin B-Cdc2-dependent protein kinase cascade is involved in inducing chromosome condensation and the phosphorylation of chromosomal histone H1.     

Analysis of proteins associated with chromosome condensation in baby hamster kidney cells

To identify proteins concerned with chromosome condensation processes, we used a temperature-sensitive mutant, tsBN2 derived from BHK21, in which premature chromosome condensation occurred at high temperature. When the proteins synthesized in tsBN2 during the induction of premature chromosome condensation were analyzed by two-dimensional gel electrophoresis, we found that an acidic protein with a molecular weight of 35,000 was specifically associated with chromosome condensation. In the normal cell cycle, this protein was synthesized from the G2 through the M phase. The protein was located mainly in the chromosome fraction and was phosphorylated.     

Chromosome condensation in the absence of the non-SMC subunits of MukBEF

MukBEF is a bacterial SMC (structural maintenance of chromosome) complex required for chromosome partitioning in Escherichia coli. We report that overproduction of MukBEF results in marked chromosome condensation. This condensation is rapid and precedes the effects of overproduction on macromolecular synthesis. Condensed nucleoids are often mispositioned; however, cell viability is only mildly affected. The overproduction of MukB leads to a similar chromosome condensation, even in the absence of MukE and MukF. Thus, the non-SMC subunits of MukBEF play only an auxiliary role in chromosome condensation. MukBEF, however, was often a better condensin than MukB. Furthermore, the chromosome condensation by MukB did not rescue the temperature sensitivity of MukEF-deficient cells, nor did it suppress the high frequency of anucleate cell formation. We infer that the role of MukBEF in stabilizing chromatin architecture is more versatile than its role in controlling chromosome size. We further propose that MukBEF could be directly involved in chromosome segregation.     

Intranuclear DNA density affects chromosome condensation in metazoans

Chromosome condensation is critical for accurate inheritance of genetic information. The degree of condensation, which is reflected in the size of the condensed chromosomes during mitosis, is not constant. It is differentially regulated in embryonic and somatic cells. In addition to the developmentally programmed regulation of chromosome condensation, there may be adaptive regulation based on spatial parameters such as genomic length or cell size. We propose that chromosome condensation is affected by a spatial parameter called the chromosome amount per nuclear space, or “intranuclear DNA density.” Using Caenorhabditis elegans embryos, we show that condensed chromosome sizes vary during early embryogenesis. Of importance, changing DNA content to haploid or polyploid changes the condensed chromosome size, even at the same developmental stage. Condensed chromosome size correlates with interphase nuclear size. Finally, a reduction in nuclear size in a cell-free system from Xenopus laevis eggs resulted in reduced condensed chromosome sizes. These data support the hypothesis that intranuclear DNA density regulates chromosome condensation. This suggests an adaptive mode of chromosome condensation regulation in metazoans.     

Control of chromosome behavior in amphibian oocytes. II. The effect of inhibitors of RNA and protein synthesis on the induction of chromosome condensation in transplanted brain nuclei by oocyte cytoplasm

We studied the effects of actinomycin D, alpha-amanitin, puromycin, and cycloheximide on the cytoplasmic activity of maturing Rana pipiens oocytes that induces chromosome condensation in transplanted brain nuclei. Treatment of oocytes with each inhibitor suppressed the chromosome condensation induced by metaphase oocytes to varying degrees depending upon the dose of inhibitor, despite the fact that untreated metaphase I oocytes already possessed chromosome condensation activity (CCA). Treatment of brain nuclei before injection completely suppressed condensation at all doses used. Chromosome condensation induced by metaphase II oocyte cytoplasm, however, was insensitive to all the inhibitors, even when the brain nuclei were pretreated. Oocytes treated with alpha-amanitin throughout maturation induced chromosome condensation when tested at metaphase II. Removal of the oocyte chromosomes after the germinal vesicle (GV) broke down did not prevent the development of CCA, whereas removal of the entire GV before initiation of maturation deprived oocytes of CCA. The results suggest that metaphase I oocyte cytoplasm stimulates synthesis of brain nuclear RNAs that are translated into proteins necessary for chromosome condensation, whereas metaphase II oocytes possess all the factors for chromosome condensation. In both cases, GV nucleoplasm appears indispensable for the development of CCA, whereas immediate activity of the oocyte genome is not required.     

Mitotic chromosome structure and condensation

Mitotic chromosome structure has been the cell biology equivalent of a 'riddle, wrapped in a mystery, inside an enigma'. Observations that genetic knockout or knockdown of condensin subunits or topoisomerase II cause only minimal perturbation in overall chromosome condensation, together with analysis of early stages of chromosome condensation and effects produced by histone H1 depletion, suggest a need to reconsider textbook models of mitotic chromosome condensation and organization.     

Chromosome condensation may enhance X-ray-related cell lethality in a temperature-sensitive mutant (tsBN2) of baby hamster kidney cells (BHK21)

In the tsBN2 cell line, which has a temperature-sensitive defect in the regulatory mechanism for chromosome condensation, the lethal effect of X rays was enhanced by incubating the cells at a nonpermissive temperature (40 degrees C) following X irradiation. This enhancement was suppressed in the presence of cycloheximide, which inhibits induction of premature chromosome condensation. The findings obtained in the case of delayed incubation at 40 degrees C and in synchronized cells indicate that X-ray-related potentially lethal damage, which can be expressed by chromosome condensation, is produced in the cells at any stage of the cell cycle, but it is repairable for all cells except those at around the late G2-M phase, where chromosome condensation occurs at a permissive temperature (33.5 degrees C). These observations suggest that the high sensitivity of late G2-M cells to X rays is caused by the events associated with chromosome condensation.     

In vivo analysis of chromosome condensation in Saccharomyces cerevisiae

Although chromosome condensation in the yeast Saccharomyces cerevisiae has been widely studied, visualization of this process in vivo has not been achieved. Using Lac operator sequences integrated at two loci on the right arm of chromosome IV and a Lac repressor-GFP fusion protein, we were able to visualize linear condensation of this chromosome arm during G2/M phase. As previously determined in fixed cells, condensation in yeast required the condensin complex. Not seen after fixation of cells, we found that topoisomerase II is required for linear condensation. Further analysis of perturbed mitoses unexpectedly revealed that condensation is a transient state that occurs before anaphase in budding yeast. Blocking anaphase progression by activation of the spindle assembly checkpoint caused a loss of condensation that was dependent on Mad2, followed by a delayed loss of cohesion between sister chromatids. Release of cells from spindle checkpoint arrest resulted in recondensation before anaphase onset. The loss of condensation in preanaphase-arrested cells was abrogated by overproduction of the aurora B kinase, Ipl1, whereas in ipl1-321 mutant cells condensation was prematurely lost in anaphase/telophase. In vivo analysis of chromosome condensation has therefore revealed unsuspected relationships between higher order chromatin structure and cell cycle control.