Genomic in situ hybridization to identify alien chromosomes and chromosome segments in wheat

Summary Genomic in situ hybridization was used to identify alien chromatin in chromosome spreads of wheat, Triticum aestivum L., lines incorporating chromosomes from Leymus multicaulis (Kar. and Kir.) Tzvelev and Thinopyrum bessarabicum (Savul. and Rayss) Löve, and chromosome arms from Hordeum chilense Roem. and Schult, H. vulgare L. and Secale cereale L. Total genomic DNA from the introgressed alien species was used as a probe, together with excess amounts of unlabelled blocking DNA from wheat, for DNA:DNA in-situ hybridization. The method labelled the alien chromatin yellow-green, while the wheat chromosomes showed only the orange-red fluorescence of the DNA counterstain. Nuclei were screened from seedling root-tips (including those from half-grains) and anther wall tissue. The genomic probing method identified alien chromosomes and chromosome arms and allowed counting in nuclei at all stages of the cell cycle, so complete metaphases were not needed. At prophase or interphase, two labelled domains were visible in most nuclei from disomic lines, while only one labelled domain was visible in monosomic lines. At metaphase, direct visualization of the morphology of the alien chromosome or chromosome segment was possible and allowed identification of the relationship of the alien chromatin to the wheat chromosomes. The genomic in-situ hybridization method is fast, sensitive, accurate and informative. Hence it is likely to be of great value for both cytogenetic analysis and in plant breeding programmes.     

Chromosome fibers studied by a spreading technique

Chromosomes and interphase nuclei can be spread on the surface of water in a simplified Langmuir trough. Interphase nuclei of Triturus erythrocytes display fibers with a diameter of about 250–300 Å. Very similar fibers are seen in metaphase chromosomes of cultured human cells. Fibers from grasshopper spermatocyte chromosomes (prophase) are more variable in diameter, and many fibers thinner than 200 Å extend laterally from the chromosome. In the grasshopper spermatocyte, fibers align in parallel to form plates. It is suggested that the 250–300 Å fibers may represent an inactive state of the chromosome material, and that only the thinner fibers are involved in RNA synthesis. The 250–300 Å fibers may result from the folding or coiling of a thinner fiber having the approximate dimensions of the nucleohistone molecule.     

朱顶红生殖细胞分裂过程中微管超微结构的变化

用透射电镜的方法,对朱顶红（Ａｍ ａｒｙｌｌｉｓｖｉｔｔａｔａ Ａｉｔ．）花粉管中生殖细胞的分裂过程中微管分布和结构形态变化进行了观察,获得如下主要的结果：有丝分裂前期,微管的数量较分裂前减少并变短,靠近细胞核分布。分裂前中期,微管出现于原来的核区并与染色体发生联系,形成着丝点微管。分裂中期,染色体排列于赤道面上形成赤道板,微管构成纺锤体。分裂后期,染色体分成两群,被缩短的着丝点微管拉向两极。在纺锤体两极的微管汇聚。后期的晚期,当极的微管尚未消失时,在赤道区域出现丰富的成膜体微管,在成膜体中央,细胞板前体物聚集。分裂末期,极微管和着丝点微管消失,成膜体微管在新形成的核膜和细胞板间扩展并穿过细胞板     

Ultrastructural Changes of the Microtubule in the Generative Cell of Amaryllis vittata Ait. During Mitosis

Structural changes of microtubules (MTs) in the generative cell (GC) of Amaryllis vittara Alt. during mitosis in pollen tube have been investigated with electron microscopy. The division cycle was completed approximately within 12 h. During prophase, the MTs bundles distributed in the cortex of the GC, they were less and shorter than that before mitosis, some of which beginning to be near the nucleus. When the chromatin condensed and the GC entered metaphase, the MTs increased in number and distributed among the chromosomes (CHs) in the original nuclear zone, but they were not arranged in distinct bundlesed. Some of them connected with the CHs to form kinetochore MTs (KMTs), where as the cortical MTs in prophase still remained there. During metaphase, the CHs were arranged on the equartor forming a metaphase plate, and all the MTs formed a diffuse spindle. When the GC entered anaphase, the KMTs were shortened and they were involved in the segregation of the CHs into two groups. The MTs were much more and focused in the two polar regions. In late anaphase, while the MTs still existed at the poles, rich phragmoplast MTs appeared in the equator zone and the precusors of cell plate (CP) aggregated in the middle of the phragmoplast. When the GC entered telophase, the CHs diffused as chromatin, and phragmoplast MTs extended between the two newly formed nuclear envelops and even through the CP While the polar MTs and KMTs disappeared, the MTs in the newly formed sperm cells were different from that of the GC.     

THE STRANDEDNESS OF MEIOTIC CHROMOSOMES FROM ONCOPELTUS

Meiotic chromosomes were isolated from male Oncopeltus fasciatus by dissecting the testes under insect Ringer's solution and spreading the living cells on the Langmuir trough. After being dried by the critical point method, preparations were examined under the electron microscope. Chromosomes at all stages of prophase prove to be multistranded. A significant increase in the number of parallel 250 A fibers in the chromosomes occurs between zygotene and diakinesis. Parallel folding, rather than true multistrandedness, is interpreted as the mechanism responsible for this observed increase in multistrandedness. It has not been possible to determine whether the multistrandedness observed at leptotene represents true multistrandedness or is the result of parallel folding. Apparent multistrandedness is lost at metaphase when the 250 A fibers of the chromosomes become coiled more tightly. In preparations isolated by these methods, no structures other than the 250 A chromosome fibers are visible in the chromomeres, which appear as regionally coiled or folded areas of the fibers along the arm of the chromosome.     

Differential expression of a phosphoepitope at the kinetochores of moving chromosomes

A phosphorylated epitope is differentially expressed at the kinetochores of chromosomes in mitotic cells and may be involved in regulating chromosome movement and cell cycle progression. During prophase and early prometaphase, the phosphoepitope is expressed equally among all the kinetochores. In mid-prometaphase, some chromosomes show strong labeling on both kinetochores; others exhibit weak or no labeling; while in other chromosomes, one kinetochore is intensely labeled while its sister kinetochore is unlabeled. Chromosomes moving toward the metaphase plate express the phosphoepitope strongly on the leading kinetochore but weakly on the trailing kinetochore. This is the first demonstration of a biochemical difference between the two kinetochores of a single chromosome. During metaphase and anaphase, the kinetochores are unlabeled. At metaphase, a single misaligned chromosome can inhibit further progression into anaphase. Misaligned chromosomes express the phosphoepitope strongly on both kinetochores, even when all the other chromosomes of a cell are assembled at the metaphase plate and lack expression. This phosphoepitope may be involved in regulating chromosome movement to the metaphase plate during prometaphase and may be part of a cell cycle checkpoint by which the onset of anaphase is inhibited until complete metaphase alignment is achieved.     

Do individual allocyclic chromosomes in metaphase reflect their interphase domains?

Summary Individual S phase allocyclic chromosomes have been analyzed in Bloom syndrome lymphocytes, in cells with an r(9), and in hypotetraploid Ehrlich mouse ascites cells treated with 1-methyl-2-benzyl hydrazine. On the basis of the following observations, we conclude that such chromosomes more or less reflect their domains in interphase: (1) The S phase allocyclic chromosomes have the same structure as S phase prematurely condensed chromatin (PCC) in fused cells; in other words they form limited areas of chromatin dots; (2) the allocyclic chromosome is the only chromosome in a metaphase plate which synthesizes DNA simultanneously with interphase nuclei; (3) the size of the allocyclic chromosomes is related to the size of the corresponding metaphase chromosome; and (4) the S phase allocyclic chromosomes resemble closely the chromosome domains in interphase made visible with biotinylated human DNA. A variety of evidence shows that most allocyclic chromosomes are simply left behind in their cycle, which presumably is caused by a deletion or inactivation of a hypothetical coiling center situated on each chromosome arm.     

Stage-specific damage to synaptonemal complexes and metaphase chromosomes induced by X rays in male mouse germ cells

Synaptonemal complexes reveal mutagen-induced effects in germ cell meiotic chromosomes. This study was aimed at characterizing relationships between damage to synaptonemal complexes and metaphase I chromosomes following radiation exposure at various stages of spermatogenesis. Male mice were irradiated with doses of 0, 2, or 4 Gy, and spermatocytes were harvested at times consistent with earlier exposures as spermatogonial stem cells, preleptotene cells (premeiotic DNA synthesis), or meiotic prophase cells. After stem-cell exposure, twice as many rearrangements were observed in synaptonemal complexes as in metaphase I chromosomes. Irradiation during premeiotic DNA synthesis resulted in dose-related increases in synaptonemal complex breakage and rearrangements (including novel forms) and in metaphase chromosomal aberrations. Following prophase exposure, various types and levels of damage to synaptonemal complexes and metaphase chromosomes were observed. Irradiation of zygotene cells led to high frequencies of chromosome multivalents in metaphase I without a correspondingly high level of damage in preceding prophase synaptonemal complexes. Thus irradiation of premeiotic and meiotic cells results in variable relationships between damage to synaptonemal complexes and metaphase chromosomes. Interpretations of these relationships are based upon what is known about both radiation clastogenesis and the structural/temporal relationships between synaptonemal complexes at prophase and chromosomes at metaphase I of meiosis.     

Genes occupy a fixed and symmetrical position on sister chromatids

A high-resolution fluorescence methodology for nonisotopic in situ hybridization was applied to determine the positions occupied by several single-copy genes, DNA sequences, and integrated viral genomes on sister chromatids. The lateral and longitudinal mapping of the probes was performed on prometaphase and metaphase chromosomes. A fixed lateral position, exterior or median in relation to the longitudinal axis of the chromatids, was observed for a given probe, with a symmetrical position of the double fluorescent spots. This position appears to be independent of chromosome condensation stage from prometaphase to metaphase. These observations suggest an opposite helical-handedness conformation of DNA on both chromatids with a mirror symmetry. They support the model of chromosome packaging recently proposed by Boy de la Tour and Laemmli. Moreover, our results indicate that the last stages of chromosome condensation occur by packing down the coils without further coiling.     

CELL DIVISION IN SPIROGYRA. I. MITOSIS

Dividing cells of Spirogyra sp. were examined with both the light and electron microscopes. By preprophase many of the typical transverse wall micro-tubules disappeared while others were seen in the thickened cytoplasmic strands. Microtubules appeared in the polar cytoplasm at prophase and by prometaphase they penetrated the nucleus. They were attached to chromosomes at metaphase and early anaphase, and formed a sheath surrounding the spindle during anaphase; they were seen in the interzonal strands and cytoplasmic strands at telophase. The interphase nucleolus, containing 2 distinct zones and chromatinlike material, fragmented at prophase; at metaphase and anaphase nucleolar material coated the chromosomes, obscuring them by late anaphase. The chromosomes condensed in the nucleoplasm at prophase, moving into the nucleolus at prometaphase. The nuclear envelope was finally disrupted at anaphase during spindle elongation; at telophase membrane profiles coated the reforming nuclei. During anaphase and early telophase the interzonal region contained vacuoles, a few micro-tubules, and sometimes eliminated n ucleolar material; most small organelles, including swollen endoplasmic reticulum and tubular membranes, were concentrated in the polar cytoplasm. Quantitative and qualitative cytological observations strongly suggest movement of intact wall rnicrotubules to the spindle at preprophase and then back again at telophase.     

Effects of kinetin on cell division,with special reference to initiation and duration of mitosis

Summary Kinetin, a substance recently isolated from DNA preparations, produced polyploidy and various forms of pycnosis in meristematic cells of growing onion roots.Non-toxic concentrations of the substance changed the mean durations of mitosis and interphase as well as the relative durations of prophase, metaphase, anaphase, and telophase in onion root tip cells. It was inferred that the time of the mitotic period was increased, while the duration of interphase was decreased by addition of kinetin to the medium.The phenomena observed are interpreted to be due to (a) a trigger action of kinetin some time during interphase, resulting in premature prophase initiation, and (b) effects of kinetin on the coiling cycle of the chromosomes.It is suggested that the activity of kinetin may in some way be associated with the RNA metabolism of the nucleus.     

A developmental study of constitutive heterochromatin in Microtus agrestis

In the vole, Microtus agrestis, the constitutive heterochromatin is largely restricted to the giant sex chromosomes but varies in its degree of condensation in various cell types. In the cleavage embryos and fibroblasts it formed one or two long and extended heterochromatic fibers, in hepatocytes it formed two large and diffuse masses and in neurons, spermatogonia and oogonia it formed two large and compact masses. The basic patterns of all differentiated cells were essentially unchanged throughout development.—At all stages of development and in cells of all types, mitotic nuclei displayed two large heteropycnotic chromosomes in prophase and persistent condensation in telophase. Apposition and delayed separation of chromatids of the giant chromosomes was also observed in metaphase and anaphase, respectively. During the first meiotic prophase of spermatocytes and oocytes, the giant chromosomes were also heteropycnotic.—The results strongly suggest that constitutive heterochromatin is localized in the same chromosomes throughout development and represents a specific entity.     

Cell cycle function of a rice B2-type cyclin interacting with a B-type cyclin-dependent kinase

Cyclin-dependent kinases (CDKs) are involved in the control of cell cycle progression. Plant A-type CDKs are functional homologs of yeast Cdc2/Cdc28 and are expressed throughout the cell cycle. In contrast, B-type CDK (CDKB) is a family of mitotic CDKs expressed during the S/M phase, and its precise function remains unknown. Here, we identified two B2-type cyclins, CycB2;1 and CycB2;2, as a specific partner of rice CDKB2;1. The CDKB2;1-CycB2 complexes produced in insect cells showed a significant level of kinase activity in vitro, suggesting that CycB2 binds to and activates CDKB2. We then expressed green fluorescent protein (GFP)-fused CDKB2;1 and CycB2;2 in tobacco BY2 cells to investigate their subcellular localization during mitosis. Surprisingly, the fluorescence signal of CDKB2;1-GFP was tightly associated with chromosome alignment as well as with spindle structure during the metaphase. During the telophase, the signal was localized to the spindle midzone and the separating sister chromosomes, and then to the phragmoplast. On the other hand, the CycB2;2-GFP fluorescence signal was detected in nuclei during the interphase and prophase, moved to the metaphase chromosomes, and then disappeared completely after the cells passed through the metaphase. Co-localization of CDKB2;1-GFP and CycB2;2-GFP on chromosomes aligned at the center of the metaphase cells suggests that the CDKB2-CycB2 complex may function in retaining chromosomes at the metaphase plate. Overexpression of CycB2;2 in rice plants resulted in acceleration of root growth without any increase in cell size, indicating that CycB2;2 promoted cell division probably through association with CDKB2 in the root meristem.     

水稻中期染色体和DNA纤维的高效制备技术

水稻中期染色体和DNA纤维制备是水稻分子细胞遗传学研究中的关键技术。目前,这两个技术还有很多不足,该研究建立了高效制备水稻中期染色体和DNA纤维的方法。该方法制备的染色体,分裂相多、杂质少、背景清晰、染色体分散且形态好,水稻根尖分生组织细胞的分裂指数高达25％。植物细胞的细胞壁是制备DNA纤维的最大障碍,所以必须先提取细胞核,然后裂解细胞核释放出DNA纤维。在这个研究中,还建立了一个用刀切法分离细胞核,进而用SDS裂解核膜,用载玻片拖出DNA来制备水稻DNA纤维的方法。该方法制备的DNA纤维多呈平行的细线,背景清晰,伸展的程度均匀,适合于原位杂交。     

Immunocytochemical localization of chromatin regions UV-microirradiated in S phase or anaphase. Evidence for a territorial organization of chromosomes during cell cycle of cultured Chinese hamster cells

Chinese hamster cells (M3-1 line) in S phase were laser-UV-microirradiated (lambda, 257 nm) at a small site of the nucleus. Cells were fixed either immediately thereafter or in subsequent stages of the cell cycle, including prophase and metaphase. The microirradiated chromatin was visualized by indirect immunofluorescence microscopy using antibodies specific for UV-irradiated DNA. During the whole post-incubation period (4-15 h) immunofluorescent labelling was restricted to a small part of the nucleus (means, 4.5% of the total nuclear area). In mitotic cells segments of a few chromosomes only were labelled. Following microirradiation of chromosome segments in anaphase, immunofluorescent labelling was observed over a small part of the resulting interphase nucleus. A territorial organization of interphase chromosomes, i.e. interphase chromosomes occupying distinct domains, has previously been demonstrated by our group for the nucleus of Chinese hamster cells in G1. Our present findings provide evidence that this organization pattern is maintained during the entire cell cycle.     

Surface and shape changes during cell division

Summary Rat kangaroo cells (PtK₂) were studied with scanning and transmission electron microscopy in order to correlate shape changes during the cell cycle with the presence or absence of microvilli and stress fibers. During interphase, bundles of actin are prominent in the cytoplasm, and microvilli are localized over and around the centrally positioned nucleus. As mitosis begins, the interphase bundles of actin and the microvilli disappear, but the mitotic cells maintain a flattened shape. At metaphase the cell is still so flat that both the chromosomes and spindle apparatus are visible through the intact cell membrane. Microvilli reappear in late anaphase above the chromosomes and poles. Before cleavage begins, microvilli increase in number until they cover the apical surface of the cell. At the same time, the cell increases in height so that the chromosomes and mitotic apparatus can no longer be detected through the cell membrane. During cleavage, microvilli continue to cover the cell in a uniform manner but become greatly diminished in number after cytokinesis is completed and the cells flatten and enter interphase. It is suggested that the microvilli organize a network of actin filaments which interact with cortical myosin to produce the cell rounding prior to cleavage.     

Ultrastructural analysis of chromatin in meiosis I + II of rye (Secale cereale L.)

Scanning electron microscopy (SEM) proves to be an appropriate technique for imaging chromatin organization in meiosis I and II of rye (Secale cereale) down to a resolution of a few nanometers. It could be shown for the first time that organization of basic structural elements (coiled and parallel fibers, chromomeres) changes dramatically during the progression to metaphase I and II. Controlled loosening with proteinase K (after fixation with glutaraldehyde) provides an enhanced insight into chromosome architecture even of highly condensed stages of meiosis. By selective staining with platinum blue, DNA content and distribution can be visualized within compact chromosomes as well as in a complex arrangement of fibers. Chromatin interconnecting threads, which are typically observed in prophase I between homologous and non-homologous chromosomes, stain clearly for DNA. In zygotene transversion of chromatid strands to their homologous counterparts becomes evident. In pachytene segments of synapsed and non-synapsed homologs alternate. At synapsed regions pairing is so intimate that homologous chromosomes form one filament of structural entity. Chiasmata are characterized by chromatid strands which traverse from one homolog to its counterpart. Bivalents are characteristically fused at their telomeric regions. In metaphase I and II there is no structural evidence for primary and secondary constrictions.     

The Nucleolus and Parachromatin of the Ascites Tumor Cell

1. A method is described for distinguishing the ribonucleoproteins of the nucleolus and parachromatin of ascitic tumor cells of the mouse. 2. In these cells the transfer of ribonucleoprotein from the nucleus to the cytoplasm can occur in two ways. (a) At the end of prophase the nucleolus separates from the chromosomes and nucleolar fragments are released into the cytoplasm. (b) During prophase the parachromatin is aggregated to form parachromatin bodies which are discharged into the cytoplasm, where they can be detected during metaphase, anaphase, and telophase. 3. A metachromatic form of RNA is demonstrable, and may be synthesized, in close relation to the chromosomes during prophase, metaphase, and anaphase. During telophase the distribution of metachromatic RNA changes, the chromatin loses its metachromasia, and intranuclear metachromatic parachromatin becomes evident.     

A comparison of the distribution of actin and tubulin in the mammalian mitotic spindle as seen by indirect immunofluorescence

Rabbit antibodies against actin and tubulin were used in an indirect immunofluorescence study of the structure of the mitotic spindle of PtK1 cells after lysis under conditions that preserve anaphase chromosome movement. During early prophase there is no antiactin staining associated with the mitotic centers, but by late prophase, as the spindle is beginning to form, a small ball of actin antigenicity is found beside the nucleus; After nuclear envelope breakdown, the actiactin stains the region around each mitotic center, and becomes organized into fibers that run between the chromosomes and the poles. Colchicine blocks this organization, but does not disrupt the staining at the poles. At metaphase the antiactin reveals a halo of ill-defined radius around each spindle pole and fibers that run from the poles to the metaphase plate. Antitubulin shows astral rays, fibers running from chromosomes to poles, and some fibers that run across the metaphase plate. At anaphase, there is a shortening of the antiactin-stained fibers, leaving a zone which is essentially free of actin-staining fluorescence between the separating chromosomes. Antitubulin stains the region between chromosomes and poles, but also reveals substantial fibers running through the zone between separating chromosomes. Cells fixed during cytokinesis show actin in the region of the cleavage furrow, while antitubulin reveals the fibrous spindle remnant that runs between daughter cells. These results suggest that actin is a component of the mammalian mitotic spindle, that the distribution of actin differs from that of tubulin and that the distributions of these two fibrous proteins change in different ways during anaphase.     

Nuclear asynchrony in multinucleate rat kangaroo cells

Multinucleate (MN) cells were induced in PtK1 cells by colcemid treatment. A large percentage of cells developed nuclear asynchrony both in relation to DNA synthesis and mitosis within one cell cycle. Asynchrony could be traced even in metaphase and anaphase cells in which interphase nuclei, PCC of S-phase nuclei and less condensed prophase-like chromosomes could be observed along with normally condensed chromosomes. The occurrence of such abnormalities in these large MN cells may be explained on the basis of an uneven distribution of inducer molecules of DNA synthesis and mitosis due to cytoplasmic compartmentation. The less condensed form of all the chromosomes except chromosome 4 could be traced in asynchronous metaphase. The failure of the less condensed chromosomes to undergo complete condensation does not always appear to result from late entry of nuclei containing these chromosomes into G2 phase. It is likely that chromosome 4 carries gene(s) for chromosome condensation, as this chromosome itself never appears in a less condensed form. The inducers for chromosome condensation may not always be available at equal concentrations to all chromosomes located in separate nuclei, thus they may sometimes fail to undergo complete condensation before other nuclei reach the end of prophase, when the nuclear envelopes of all nuclei present in the cell break down simultaneously.