Centromere Pairing Research Articles

Attachment of kinetochores to spindle microtubules during meiosis I of Lilium microsporocytes.

Kinetochores and microtubules were visualized simultaneously during spindle formation at the first meiotic division in microsporocytes of Lilium longiflorum (2n = 24) under a confocal laser-scanning microscope, after immunofluorescence staining with centromere-recognizing antiserum and tubulin-specific antibody. During early prometaphase I, each kinetochore of bivalent chromosomes appeared to be an amorphous flat structure upon its initial attachment to microtubules. It became compact and spherical with the development of the spindle. From late prometaphase I, when the bipolar spindle was nearly complete, each kinetochore resembled a double disk that was suggestive of a pair of sister kinetochores and the homologous kinetochores were oriented towards opposite poles. Thus, the bipolar spindle at metaphase I included 12 bivalent chromosomes with a total of four kinetochores each. At anaphase I, the sister kinetochores moved to the same spindle pole as a paired unit. In microsporocytes arrested at prometaphase I by colchicine treatment, the sister kinetochores also came to be distinguishable. These results suggest that the change of kinetochore structure during meiosis I may be under chromosomal control but be somewhat associated with its attachment to spindle microtubules.

Maize meiotic spindles assemble around chromatin and do not require paired chromosomes.

To understand how the meiotic spindle is formed and maintained in higher plants, we studied the organization of microtubule arrays in wild-type maize meiocytes and three maize meiotic mutants, desynaptic1 (dsy1), desynaptic2 (dsy2), and absence of first division (afd). All three meiotic mutations have abnormal chromosome pairing and produce univalents by diakinesis. Using these three mutants, we investigated how the absence of paired homologous chromosomes affects the assembly and maintenance of the meiotic spindle. Before nuclear envelope breakdown, in wild-type meiocytes, there were no bipolar microtubule arrays. Instead, these structures formed after nuclear envelope breakdown and were associated with the chromosomes. The presence of univalent chromosomes in dsy1, dsy2, and afd meiocytes and of unpaired sister chromatids in the afd meiocytes did not affect the formation of bipolar spindles. However, alignment of chromosomes on the metaphase plate and subsequent anaphase chromosome segregation were perturbed. We propose a model for spindle formation in maize meiocytes in which microtubules initially appear around the chromosomes during prometaphase and then the microtubules self-organize. However, this process does not require paired kinetochores to establish spindle bipolarity.

Unusual pattern of mitosis in the free-living flagellateDimastigella mimosa (Kinetoplastida)

The three-dimensional ultrastructural organization of the mitotic apparatus ofDimastigella mimosa was studied by computer-aided, serial-section reconstruction. The nuclear envelope remains intact during nuclear division. During mitosis, chromosomes do not condense, whereas intranuclear microtubules are found in close association with six pairs of kinetochores. No discrete microtubule-organizing centers, except kinetochore pairs, could be found within the nucleus. The intranuclear microtubules form six separate bundles oriented at different angles to each other. Each bundle contains up to 8 tightly packed microtubules which push the daughter kinetochores apart. At late anaphase only, midzones of these bundles align along an extended interzonal spindle within the narrow isthmus between segregating progeny nuclei. The nuclear division inD. mimosa can be described as closed intranuclear mitosis with acentric and separate microtubular bundles and weakly condensed chromosomes.

The physical and genomic organization of microsatellites in sugar beet.

Microsatellites, tandem arrays of short (2-5 bp) nucleotide motifs, are present in high numbers in most eukaryotic genomes. We have characterized the physical distribution of microsatellites on chromosomes of sugar beet (Beta vulgaris L.). Each microsatellite sequence shows a characteristic genomic distribution and motif-dependent dispersion, with site-specific amplification on one to seven pairs of centromeres or intercalary chromosomal regions and weaker, dispersed hybridization along chromosomes. Exclusion of some microsatellites from 18S-5.8S-25S rRNA gene sites, centromeres, and intercalary sites was observed. In-gel and in situ hybridization patterns are correlated, with highly repeated restriction fragments indicating major centromeric sites of microsatellite arrays. The results have implications for genome evolution and the suitability of particular microsatellite markers for genetic mapping and genome analysis.

Early and late G2 arrest of cells undergoing radiation‐induced apoptosis or micronucleation

Conventional flow cytometric DNA measurements combined with the microscopic detection of cells in the late G2 phase of the cell cycle (characterized by the occurrence of paired kinetochores) enabled us to differentiate and to quantify early and late G2 cells 0-40 h after irradiation using a radioresistant (L929) and a radiosensitive (HL-60) cell line. This approach provided us with (1) a new kind of G2 arrest characteristic revealing changes in the G2 phase which can not be detected by flow cytometric DNA measurements, (2) cell line dependent differences in the radiation-induced transition through G2, accompanied by the occurrence of micronucleation and apoptosis, and (3) the characterization of apoptotic cells occurring probably during early G2 and bearing a rapidly reduced number of kinetochores in contrast to mitotic cells, suggesting processes different from those that operate in mitosis.

Proliferation enhancement by spontaneous multiplication of chromosome 7 in rheumatic synovial cells in vitro.

Mosaic trisomy of chromosome 7 is known to occur in a variety of non-neoplastic hyperproliferative disorders. In long-term cell cultures established from rheumatic synovium with mosaic trisomy 7, we observed a continuous increase in the proportion of cells with trisomy 7 to over 50% by the 10th in vitro passage. Simultaneous in situ hybridization with a repetitive chromosome-7-specific DNA probe and fluorescent Ki-67 labelling showed a strong correlation between trisomy 7 and an elevated proliferation index in cultured rheumatic synovial cells. Moreover, we observed a fraction of rapidly proliferating cells with up to eight copies of chromosome 7 as the sole cytogenetic change. Frequent somatic pairing of centromeres of two chromosomes 7 in interphase nuclei suggests either atypical non-disjunction with a persisting centromere or selective endoreduplication of chromosome 7.

The Experimental Homologous and Heterologous Separation Distance Histograms for the Centromeres of Chromosomes 7, 11, and 17 in Interphase Human T-Lymphocytes

The simultaneous 3D arrangement of the interphase centromeres of chromosomes 7, 11, and 17 in unstimulated human T-lymphocytes is analyzed. Using triple in situ hybridization in combination with optical sectioning and image processing, the identification of three pairs of centromeres in each nucleus and the assignment of 3D coordinates to each centromere are made. The homologous and heterologous centromere separation distance histograms are determined and compared to the hypothesized histograms for randomly distributed centromeres. The experimental nuclei are truncated spheres in shape with a principal radius of 3.7 ± 0.3 μm and a truncated hemispherical height of 2.6 μm. None of the separation distance distributions appears to be statistically significantly different from a random model distribution.

Simplified and optimized kinetochore detection: cytogenetic marker for late-G 2 cells

Cytogenetic detection of kinetochore proteins using the CREST antibody coupled with secondary antibodies labeled with different fluorescent probes has been optimized for several in vitro mammalian cell lines. This study investigated selected parameters including the influence of common fixatives (methanol, ethanol, methanol: acetic acid (3:1)), detergents (Tritron-X100, Tween), fluorescent probes (CY3, BODIPY, FITC), washing protocols, and an antifading agent (paraphenylenediamine) on the detection of kinetochore proteins in control and X-ray (240 kVp)-irradiated cells. Utilizing an optimized fixation and staining protocol, a brilliant visualization of kinetochores in interphase cells was obtained in control as well as X-ray-irradiated interhase cells. Application of this improved kinetochore staining methodology readily permits discriminating cells containing either single or paired kinetochores, the latter of which are characteristic of late-G 2 phase and prophase cells.

Immunocytology of chiasmata and chromosomal disjunction at mouse meiosis.

Immunocytological and in situ hybridization evidence supports the hypothesis that at meiosis of chiasmate organisms, chromosomal disjunction and reductional segregation of sister centromeres are integrated with synaptonemal complex functions. The Mr 125,000 synaptic protein, Syn1, present between cores of paired homologous chromosomes during pachytene of meiotic prophase, is lost from synaptonemal complexes coordinately with homolog separation at diplotene. Separation is constrained by exchanges between non-sister chromatids, the chiasmata. We show that the Mr 30,000 chromosomal core protein, Cor1, associated with sister chromatid pairs, remains an axial component of post-pachytene chromosomes until metaphase I. We demonstrate that at this time the chromatin loops are still attached to their cores. A reciprocal exchange event between two homologous non-sister chromatids is therefore immobilized by anchorage of sister chromatids to their respective cores. Cores thus contribute to the sister chromatid cohesiveness required for maintenance of chiasmata and proper chromosomal disjunction. Cor1 protein accumulates in juxtaposition to pairs of sister centromeres during metaphase I. Presumably, independent movement of sister centromeres at anaphase I is restricted by Cor1 anchorage. That reductional separation of sister centromeres is mediated by Cor1, is supported by the dissociation of Cor1 from separating sister centromeres at anaphase II and by its absence from mitotic anaphases.

Synaptonemal complex proteins: occurrence, epitope mapping and chromosome disjunction

We have used polyclonal antibodies against fusion proteins produced from cDNA fragments of a meiotic chromosome core protein, Cor1, and a protein present only in the synapsed portions of the cores, Syn1, to detect the occurrence and the locations of these proteins in rodent meiotic prophase chromosomes. The 234 amino acid Cor1 protein is present in early unpaired cores, in the lateral domains of the synaptonemal complex and in the chromosome cores when they separate at diplotene. A novel observation showed the presence of Cor1 axial to the metaphase I chromosomes and substantial amounts of Cor1 in association with pairs of sister centromeres. The centromere-associated Cor1 protein becomes dissociated from the centromeres at anaphase II and it is not found in mitotic metaphase centromeres. The extended presence of Cor1 suggests that it may have a role in chromosome disjunction by fastening chiasmata at metaphase I and by joining sister kinetochores, which ensures co-segregation at anaphase I. Two-colour immunofluorescence of Cor1 and Syn1 demonstrates that synapsis between homologous cores is initiated at few sites but advances rapidly relative to the establishment of new initiation sites. If the rapid advance of synapsis deters additional initiation sites between pairs of homologues, it may provide a mechanism for positive recombination interference. Immunogold epitope mapping of antibodies to four Syn1 fusion proteins places the amino terminus of Syn1 towards the centre of the synaptonemal complex while the carboxyl terminus extends well into the lateral domain of the synaptonemal complex. The Syn1 fusion proteins have a non-specific DNA binding capacity. Immunogold labelling of Cor1 antigens indicates that the lateral domain of the synaptonemal complex is about twice as wide as the apparent width of lateral elements when stained with electron-dense metal ions. Electron microscopy of shadow-cast surface-spread SCs confirms the greater width of the lateral domain. The implication of these dimensions is that the proteins that comprise the synaptic domain overlap with the protein constituents of the lateral domains of the synaptonemal complex more than was apparent from earlier observations. This arrangement suggests that direct interactions might be expected between some of the synaptonemal complex proteins.

The spatial arrangement of Allium triquetrum chain quadrivalents at metaphase I as reviewed by confocal microscopy.

We examined the three-dimensional arrangement of bivalents and, in particular, a chain of four chromosomes (chain quadrivalent) in the metaphase I spindle of pollen mother cells of Allium triquetrum by confocal microscopy. Firstly, we show by optical sectioning and three-dimensional image reconstruction that the cooriented pairs of centromeres of all seven bivalents lie virtually parallel to each other in the metaphase I spindle, parallel to the long axis of the spindle. Secondly, we likewise show that the four centromeres of the chain quadrivalent are aligned in the metaphase I spindle in, essentially, a two-dimensional array, not in a three-dimensional array, as proposed by some other authors. This two-dimensionality has its basis, we argue, in the principle that poleward directed spindle forces minimise centromere-to-pole distances and therefore align pairs of centromeres connected to opposite poles most axially (vertically) in the spindle. These distances are minimised for the quadrivalent as a whole only when it lies in two dimensions, i.e. in a plane parallel to the spindle axis.

Somatic pairing of centromeres and short arms of chromosome 15 in the hematopoietic and lymphoid system

Normal human bone marrow and peripheral blood leukocytes as well as malignant cells from a variety of leukemias and lymphomas, demonstrate somatic pairing of centromeres and p arms of chromosome 15 during interphase. This phenomenon, effected by sequences on the p arm and requiring the intranuclear transport of spatial domains for at least one of the homologs, was not seen in amniotic fluid cells, uterine cervical tissue or in tissue fibroblasts. These studies contribute to the recent evidence of somatic pairing of homologous chromosomes in man and provide support for mobile chromosomal domains in interphase. It appears that sequences on the p arm of chromosome 15, possibly the nucleolar organizing genes, are uniquely important in the maturation of benign and malignant cells of hemato-lymphopoietic origin.

Anaphase chromosome separation in dividing generative cells ofTradescantia

In dividing generative cells ofTradescantia, kinetochore pairs do not line up on a typical metaphase plate, but instead are distributed along the length and depth of the cell prior to anaphase onset. Kinetochore (K) fibers are linked to each other and to a system of axial microtubule (Mt) bundles in an arrangement that makes discrete half spindles, if present, not immediately obvious. Because such arrangements may have important implications for the conduct of the remainder of division, anaphase events were closely scrutinized using a combination of tubulin and kinetochore immunocytochemistry (the latter with CREST serum). Anaphase appears to consist of three principal processes. Around the time of anaphase onset, K-fibers and surrounding Mts become reorganized into two large superbundles. To each superbundle is attached a set of nonfilial kinetochores bound for one end of the cell. The K-fibers then appear to shorten to varying degrees; in many cases, kinetochores become linked directly to the superbundles. The superbundles then separate in an anaphase B-like process, further moving the kinetochores toward opposite ends of the cell. The superbundles themselves shorten, and distances within the bundles also decrease, such that the kinetochores cluster closer together. The results indicate that reorganization of Mts into superbundles (and the consequential manifestation of bipolarity) is important for orderly chromosome separation.

Ultrastructure of meiosis and the spindle pole body cycle in freeze-substituted basidia of the smut fungi Ustilago maydis and Ustilago avenae

Meiosis in the smut fungi Ustilago maydis and Ustilago avenae (Basidiomycota, Ustilaginales) was studied by electron microscopy of serial-sectioned freeze substituted basidia. At prophase I, a spindle pole body composed of two globular elements connected by a middle piece was attached to the extranuclear surface of each nucleus. Astral and spindle microtubules were initiated at each globular element at late prophase I to prometaphase I. During spindle initiation, the middle piece disappeared and interdigitating half-spindles entered the nucleoplasm, which was surrounded by discontinuous nuclear envelope together with perinuclear endoplasmic reticulum. Kinetochore pairs at metaphase I were analyzed to obtain a karyotype for each species. The meiotic spindle pole body replicational cycle is described. Key words: electron microscopy, freeze-substitution, meiosis, Ustilago, spindle pole body.

Kinetochore fiber formation in dividing generative cells of Tradescantia Kinetochore reorientation associated with the transition between lateral microtubule interactions and end-on kinetochore fibers

ABSTRACT Division of the generative cell of Tradescantia virginiana is unusual in that a typical bipolar spindle is not present Instead, the cell contains an axial system of microtubule (Mt) bundles, with kineto-chores distributed along the length and depth of the cell. Kinetochore fibers appear to be derived from and remain attached to the Mt bundles. Localizations with both anti-tubulin and CREST serum were performed in order to probe this relationship further. Pairs of CREST-positive, fluorescent dots presumed to be kinetochores are initially oriented transverse to the cell axis and appear to be associated with the Mt bundles via latéral interactions. Adjacent pairs are often joined to the same bundles, like rungs on a ladder. Lateral interactions are then converted intoor replaced by end-on kinetochore fibers similar in morphology to those seen in other cells. This conversion is accompanied by a realignment of the kinetochore pairs along the long axis of the cell. In addition, the center-to-center spacing between filial kinetochores doubles. Interconnections between kinetochore fibers and surrounding Mts appear to be maintained during the transition. These results may provide a general insight into the manner in which kinetochores interact with the division apparatus in eukaryotes.

Kinetochore behavior during generative cell division inTradescantia virginiana

Previous observations indicate that division of the generative cell inTradescantia virginiana is characterized by several unusual features, including persistence of surrounding microtubule (Mt) bundles during karyokinesis, lack of a distinct metaphase plate and direct contribution by mitotic Mts to the cytoskeleton of young sperm. We have further probed karyokinesis in these cells using additional antitubulin and chromosome staining, as well as kinetochore visualizations with CREST serum. The CREST antibodies reveal kinetochores as paired and single fluorescent dots similar to those seen in other species stained with this preparation. Double localizations show that the dots are located at the ends of Mt bundles previously identified as kinetochore fibers (Palevitz and Cresti 1989). Before anaphase, paired kinetochores are distributed along the length of the cell. They also tend to be located at the cell periphery or are directly connected to peripheral Mt bundles by their kinetochore (K)-fibers. Twelve pairs of dots can be counted per cell, equal to the expected number of chromosomes. During anaphase, kinetochore separation starts at various positions along the length of the cell, producing single, relatively uniformly distributed kinetochores in the crotches of forks formed by K-fiber trunks and elongating Mt branches attached to the base of the trunks. Eventually, K-fibers with attached kinetochores aggregate in stepwise fashion on thick Mt bundles at both ends of the cell. This pattern is reflected in the cytoskeleton of young sperm. These results further document the unusual distribution of chromosomes and kinetochores inTradescantia generative cells and the origin of the Mt cytoskeleton in sperm cells.

Cytotaxonomic differentiation of Wilhelmia equina (Linné, 1747) and Wilhelmia lineata (Meigen, 1804) (Diptera: Simuliidae)

In most cases the larvae of Wilhelmia equina and W. lineata cannot be distinguished by using classical morphological features. The morphological characteristics of the salivary gland polytene chromosomes allow one to differentiate clearly between the two species. Characteristic for W. equina are the extended region between the centromere, Ctr (transformed centromere), and the nucleolus organizer, NO, in IS, the definitive position of RB (ring of Balbiani) and bulge in IIS, and the fan-shaped IIIL telomere. The chromosomes of W. lineata are marked by complex chromosomal polymorphisms, the altered position of RB and bulge on IIS and by a strong ectopic pairing of centromeres. The comparison of banding patterns provides several intraspecific polymorphic inversions and interspecific fixed rearrangements for species diagnosis. Partial chromosome maps were established. The comparison of the chromosomal banding pattern of Wilhelmia with that of the Simulium standard reveals a whole-arm interchange between chromosomes I and II in Wilhelmia identical with that in Metomphalus, Prosimulium vernale, a form of P. mixtum, and Metacnephia.Key words: cytotaxonomy, Simuliidae, Wilhelmia equina, Wilhelmia lineata, larvae.

Ultrastructure of Mitosis in Entosiphon sulcatum (Euglenida)1

ABSTRACT The ultrastructural features of cell division in the biflagellate, phagotrophic euglenoid, Entosiphon sulcatum, have been examined. Prophase is marked by the appearance of daughter feeding apparatuses and the emergence of two additional flagella. Pairs of flagella begin to migrate laterally along the surface of the elongating nucleus and remain lateral to the developing spindle poles. As the nucleolus elongates, it becomes dumbbell‐shaped and the chromosomes move to the center of the nucleus, forming a loosely organized metaphase plate. Microtubules from opposing spindle poles attach to one of the pair of kinetochores found on each chromosome. The initial chromosome separation occurs during anaphase as the nucleus elongates. The length of the chromosomal microtubules does not decrease until late anaphase/early telophase. As the nucleus elongates, it forms a dumbbell‐shaped structure. Most of the remaining microtubules are positioned in the interzone between the forming daughter nuclei. The interzonal spindle becomes somewhat constricted but remains intact until it is broken by the impinging cleavage furrow. Replication of the pellicular strips is not completed until late in cytokinesis.

Arrangements of kinetochores in mouse cells during meiosis and spermiogenesis.

Antibodies from the serum of patients with the autoimmune disease scleroderma CREST were used to investigate the association and distribution of kinetochores in mouse cells during meiosis and spermiogenesis. The pattern of indirect immunofluorescent staining in pachytene nuclei indicated that each autosomal bivalent contains one fluorescent spot. Throughout pachytene, the kinetochores were arranged non-randomly into several clusters and distributed around the periphery of the nucleus. In subsequent stages of meiotic prophase I, distribution was random and the number of fluorescent spots increased from 21 to 40 corresponding to the diploid chromosome number and the number of halfbivalents oriented to the spindle poles at the metaphase I. Twenty pairs of kinetochores were observed at metaphase II. During spermiogenesis, the number of kinetochores correlated with the haploid chromosome number in early spermatids but tandem association of centromeres and clustering into a conspicuous chromocenter corresponded to a significant reduction in the number of fluorescent foci in mid-spermatid nuclei. The number of stained sites per nucleus continued to decrease during sperm maturation and total absence of staining was apparent in mature spermatozoa. Immunoblotting of proteins extracted from mature sperm however, indicated that a kinetochore antigen of Mr 80,000 was still present. Therefore, the absence of kinetochore staining in mature spermatozoa is probably due to the blockage of epitopes during chromatin condensation.

The Karyotype of Plasmodium falciparum Determined by Ultrastructural Serial Sectioning and 3D Reconstruction

The karyotype of the erythrocytic stages of Plasmodium falciparum was determined to be 14 by counting the number of kinetochores in the mitotic spindle of young schizonts. Fourteen pairs of kinetochores were identified in 3-dimensional reconstructions of the spindle derived from serial longitudinal and transverse sections. Kinetochores were ovoid (45 X 25 nm) in transverse sections, measured 100 nm in longitudinal section, and were heptalaminate in structure. A pair of spindle microtubules passed through each kinetochore. In schizonts at anaphase, each pole of the mitotic spindle consisted of paired kinetic centers inserted on the nuclear membrane. The kinetic centers resembled nuclear pores, but were more electron dense and were associated with spherical masses of an electron-dense cytoplasmic material.