Flow cytometric analyses of intraplant nuclear DNA content variation induced by sticky chromosomes

BACKGROUND: In several plant species, sticky chromosomes are a consequence of genetic mutations or environmental effects on mitosis and meiosis. Sticky chromosomes result in an unequal distribution of genetic material in daughter cells. This unequal distribution is hypothesized to result in an increase in the coefficient of variation (CV) of the G1 peak of dividing cells. METHODS: The st1 mutant and a nonmutant line in the same genetic background of maize (Zea mays L.) were planted in a soilless mix. A wheat (Triticum aestivum L. em thell.) line was grown in both low and high aluminum-saturated soil. Both plant species were assessed for sticky chromosomes by Feulgen-stained mitotic analysis and flow cytometric analysis of propidium iodide (PI)-stained G1 nuclei. RESULTS: In the st1 mutant, a significant increase in the number of abnormal anaphase figures was observed. An increase in abnormal mitotic figures was observed in wheat plants grown in aluminum soil. Using flow cytometry, an increase in the CV of the G1/G0 peak was seen in the maize mutant and in wheat grown at high levels of aluminum saturation. This increase correlated with the number of abnormal anaphase cells observed. CONCLUSIONS: Flow cytometry was sensitive enough to detect the intraplant nuclear DNA variation associated with sticky chromosomes within a plant.     

Effects of ethidium bromide on mitosis and chromosomes: a possible material basis for chromosome stickiness

When two types of mammalian cells were treated with ethidium bromide for several hours, the mitotic figures showed no chromatid breaks or exchanges but a high incidence of sticky chromosomes. Electron microscopic examinations revealed that many chromosomes are connected by submicroscopic chromatin strands of various widths. Chromosome stickiness, therefore, is interpreted as entanglement of chromatin fibers between unrelated chromosomes, probably caused by abnormal condensation behaviors prior to mitosis. Presumably, chromatin breaks would occur when sticky chromosomes separate during anaphase. Such microscopically undetectable breaks expressed as various kinds of chromosomal aberrations in the next mitosis when the damaged cells were permitted to recover in the absence of ethidium bromide.     

Involvement of knob heterochromatin in mitotic abnormalities in germinating aged seeds of maize.

Seeds of three inbred lines of maize, with contrasting numbers of heterochromatic knobs and stored under two different ageing treatments, were analyzed for the occurrence of abnormalities at mitotic anaphase in root meristems 3, 7, 21,42, and 56 days after germination, and in root meristems of their freshly harvested selfed progeny. The largest category of detectable aberrations involved breakage of knobbed chromosome arms. We have obtained evidence that knob heterochromatin plays a central role in the origin of primary chromosome bridges. The initial event responsible for the occurrence of breakages and lagging chromosomes was characterized by the nondisjunction of newly replicated sister chromatids, which was observed to occur preferentially at the knob level. Such configurations, and all the other types of abnormalities (as for example, lagging chromosomes, typical chromosome bridges, fragments, and micronuclei), were observed at decreasing frequencies throughout root growth. Nevertheless, we have detected the occurrence of breakage-fusion-bridge cycles that were initiated by broken chromosomes. The relationship between late-replicating DNA in maize knob heterochromatin and the vulnerability of such regions to breakage is discussed. Our observations suggest a similarity between the mechanisms involved or associated with the origin of the described abnormalities and those reported to occur in cultured maize cells.     

Meiotic drive of chromosomal knobs reshaped the maize genome.

Meiotic drive is the subversion of meiosis so that particular genes are preferentially transmitted to the progeny. Meiotic drive generally causes the preferential segregation of small regions of the genome; however, in maize we propose that meiotic drive is responsible for the evolution of large repetitive DNA arrays on all chromosomes. A maize meiotic drive locus found on an uncommon form of chromosome 10 [abnormal 10 (Ab10)] may be largely responsible for the evolution of heterochromatic chromosomal knobs, which can confer meiotic drive potential to every maize chromosome. Simulations were used to illustrate the dynamics of this meiotic drive model and suggest knobs might be deleterious in the absence of Ab10. Chromosomal knob data from maize's wild relatives (Zea mays ssp. parviglumis and mexicana) and phylogenetic comparisons demonstrated that the evolution of knob size, frequency, and chromosomal position agreed with the meiotic drive hypothesis. Knob chromosomal position was incompatible with the hypothesis that knob repetitive DNA is neutral or slightly deleterious to the genome. We also show that environmental factors and transposition may play a role in the evolution of knobs. Because knobs occur at multiple locations on all maize chromosomes, the combined effects of meiotic drive and genetic linkage may have reshaped genetic diversity throughout the maize genome in response to the presence of Ab10. Meiotic drive may be a major force of genome evolution, allowing revolutionary changes in genome structure and diversity over short evolutionary periods.     

Behaviour of chromosomes in anaphase cells in embryogenic callus cultures of maize (Zea mays L.)

Mitotic anaphase cells of highly friable and embryogenic calluses which had been induced from immature embryos of two inbred lines of maize that have contrasting levels of heterochromatic knobs were analysed for the presence of abnormalities 3, 6, 9 and 12 months after the initiation of culture. A total of 500 typical anaphases was scored at each time point, and various aberrations, such as delay in the separation of sister chromatides, chromosome bridges (single, double and multiple) and chromosome fragments, were revealed to occur extensively in the cultures of both genotypes. Preparations after C-banding revealed that primary breakages often occurred inside knobs or at junction regions between the euchromatin and the heterochromatin of the knobs. Figures characterized by the delayed separation of sister chromatids, which originated preferentially at the knob level and was considered to be an initial event in the development of breakages, were observed at constant frequencies throughout the experiment. Increasing numbers of aberrant cells were detected with time, mainly due to the accumulation of cells with chromosome bridges and fragments. Several mitotic figures suggested the occurrence of breakagefusion-bridge cycles that were initiated by broken chromosomes. The overall frequencies of aberrant cells were similar for both genotypes, despite the differences in knob composition. However, callus cultures induced from the genotype having the higher level of knobs had more aberrant cells with abnormalities that involved several chromosomes, such as multiple bridges and multiple fragments.     

Genome reversion process of endopolyploidy confers chromosome instability on the descendent diploid cells

Endotetraploidy with 4-chromatid chromosomes divides by a bipolar, 2-step meiotic-like division back to diploidy (subcells), which is chiefly achieved by co-segregation of whole genomes uncoupled from spindle participation. This study shows diploid subcell inheritance of endopolyploid-division traits: perpendicular division relative to the cytoskeleton axis, dysfunctional centromere/kinetochore regions and whole genomic separations from co-segregation. The assimilation of these traits into the innate mitotic machinery of the subcells resulted in diploid mitotic divisions that tolerated mild disturbances in cycling progression and in chromosomal distributions. The data were interpreted as demonstrating a blending together of endopolyploid and mitotic division traits with result of an endo-modified mitosis in subcell propagation. Additionally, chromosomal stickiness caused breakage in anaphase/telophase. The observations are discussed in regard to a potential for slowly developing aneuploidy with increasing genomic complexity, which is widely accepted to be the basic route in tumorigenesis.     

Complex structure of knobs and centromeric regions in maize chromosomes

The recovery of maize (Zea mays L.) chromosome addition lines of oat (Avena sativa L.) from oat x maize crosses enables us to analyze the structure and composition of individual maize chromosomes via the isolation and characterization of chromosome-specific cosmid clones. Restriction fragment fingerprinting, sequencing, and in situ hybridization were applied to discover a new family of knob associated tandem repeats, the TR1, which are capable of forming fold-back DNA segments, as well as a new family of centromeric tandem repeats, CentC. Analysis of knob and centromeric DNA segments revealed a complex organization in which blocks of tandemly arranged repeating units are interrupted by insertions of other repeated DNA sequences, mostly represented by individual full size copies of retrotransposable elements. There is an obvious preference for the integration/association of certain retrotransposable elements into knobs or centromere regions as well as for integration of retrotransposable elements into certain sites (hot spots) of the 180-bp repeat. DNA hybridization to a blot panel of eight individual maize chromosome addition lines revealed that CentC, TR1, and 180-bp tandem repeats are found in each of these maize chromosomes, but the copy number of each can vary significantly from about 100 to 25,000. In situ hybridization revealed variation among the maize chromosomes in the size of centromeric tandem repeats as well as in the size and composition of knob regions. It was found that knobs may be composed of either 180-bp or TR1, or both repeats, and in addition to large knobs these repeated elements may form micro clusters which are detectable only with the help of in situ hybridization. The association of the fold-back elements with knobs, knob polymorphism and complex structure suggest that maize knob may be consider as megatransposable elements. The discovery of the interspersion of retrotransposable elements among blocks of tandem repeats in maize and some other organisms suggests that this pattern may be basic to heterochromatin organization for eukaryotes.     

Behaviour of a ‘sticky-desynaptic’ mutant in pearl millet

In the progeny after selfing of a normally open pollinated variety (L.S. 326-3) of pearl millet (Pennisetum americanum (L.) Leeke, n=7) one plant exhibited desynapsis, chromosome stickiness and high sterility. Meiosis was normal until diplotene. Thereafter, it was characterized by dissociation of bivalents into univalents and formation of nonspecific congregations of chromosomes at diakinesis, shrinkage of cytoplasm and occurrence of unoriented sticky chromatin masses at metaphase I, relaxation of stickiness, unbalanced chromosome numbers at the poles and laggards at anaphase I, and presence of other irregularities in subsequent stages. Meiosis was completed. Male and female sterility was high. This meiotic mutant thus has multiple effects and is inherited as a monogenic recessive and designated as st.     

秤锤树的核型研究及其减数分裂过程的观察

观察研究了秤锤树有丝分裂和减数分裂的细胞学特征。秤锤树核型为2n=2x=24=4m 7sm(2SAT) 1st,属于较为原始的2A型。有丝分裂间期核为复杂染色中心型,前期出现B染色体,中期染色体中等大小。减数分裂中期具12对正常的二价体,但后期I和后期Ⅱ均有染色体异常现象发生。统计断片、落后染色体和染色体桥出现的比例与花粉粒败育性比例比较一致,表明秤锤树的小孢子在发生和发育过程中较高频率的败育现象可能存存一常的细胞学原因．     

Chromosome instabilities and programmed cell death in tapetal cells of maize with B chromosomes and effects on pollen viability

B chromosomes (B's), knobbed chromosomes, and chromosome 6 (NOR) of maize undergo nondisjunction and micronucleus formation in binucleate tapetal cells. These chromosome instabilities are regular events in the program of tapetal cell death, but the B's strongly increase A chromosome instability. We studied 1B and 0B plants belonging to selected lines for high or low B transmission rate and their F1 hybrids. These lines are characterized by meiotic conservation or loss of B chromosomes, respectively. The female B transmission (fBtl) allele(s) for low B transmission is dominant, inducing micronucleus formation and B nondisjunction. We hypothesize that the fBtl allele(s) induces knob instability. This instability would be sufficient to produce B loss in both meiocytes and binucleate tapetal cells. B instability could, in turn, produce instabilities in all chromosomes of maize complement. To establish whether the chromosomal instabilities are related to the tapetal programmed cell death (PCD) process, we applied the TUNEL technique. PCD, estimated as the frequency of binucleate tapetal cells with TUNEL label, was significantly correlated with the formation of micronuclei and the frequency of pollen abortion. It can be concluded that the observed chromosome instabilities are important to the PCD process and to the development of microspores to form viable pollen grains.     

木立芦荟小孢子母细胞减数分裂与花粉育性关系的初步研究

文章从减数分裂过程、小孢子发育两方面,探讨了木立芦荟（Aloe arboresens Mill.）花粉败育的原因。木立芦荟花粉母细胞染色体数目为2n=14,由四对长染色体和三对短染色体组成,属二型性核型。其减数分裂异常,发现存在单价体和多价体、染色体桥、落后染色体、不均等分离、微核等。同时观察到木立芦荟染色体具有极度的粘质性,使减数分裂各阶段的染色体不易散开。统计各种异常现象出现的频率并分析了这些异常现象形成的可能机制及对正常小孢子形成的影响,推测染色体间的丝状粘连可能是木立芦荟小孢子母细胞减数分裂异常并导致败育花粉产生的主要因素。成熟花粉粒中90%以上为败育花粉,属碘败型。     

Studies of mitotic and centromeric abnormalities in Roberts syndrome: Implications for a defect in the mitotic mechanism

Roberts syndrome is an inherited human condition that is of particular interest because separation of centromeres and constitutive heterochromatin is observed in metaphase chromosomes. In this study we investigated the frequency of other cytological abnormalities in three Roberts syndrome patients. Our findings when taken with previous cytological reports emphasize that there are other features that are equally characteristic of Roberts syndrome: (1) aneuploidy with random chromosome loss and (2) micronuclei and/or nuclear lobulations of 8%–24% of interphase cells. We observed abnormal chromosome movement involving one or all the chromosomes during anaphase. Evidence is presented suggesting that aneuploidy, micronuclei and abnormal nuclear morphology are a direct result of lagging chromosomes. The cytological features documented for Roberts syndrome indicate that this is a human mitotic mutant.by T.C. Hsu     

Spo76p is a conserved chromosome morphogenesis protein that links the mitotic and meiotic programs.

Spo76p is conserved and related to the fungal proteins Pds5p and BIMD and the human AS3 prostate proliferative shutoff-associated protein. Spo76p localizes to mitotic and meiotic chromosomes, except at metaphase(s) and anaphase(s). During meiotic prophase, Spo76p assembles into strong lines in correlation with axial element formation. As inferred from spo76-1 mutant phenotypes, Spo76p is required for sister chromatid cohesiveness, chromosome axis morphogenesis, and chromatin condensation during critical transitions at mitotic prometaphase and meiotic midprophase. Spo76p is also required for meiotic interhomolog recombination, likely at postinitiation stage(s). We propose that a disruptive force coordinately promotes chromosomal axial compaction and destabilization of sister connections and that Spo76p restrains and channels the effects of this force into appropriate morphogenetic mitotic and meiotic outcomes.     

Karyotype of maize (Zea mays L.) mitotic metaphase chromosomes as revealed by fluorescencein situ hybridization (FISH) with cytogenetic DNA markers

Here we demonstrate fluorescencein situ hybridization (FISH) of chromosome-specific cytogenetic DNA markers for chromosome identification in maize using repetitive and single copy probes. The fluorescently labeled probes, CentC and pZm4–21, were shown to be reliable cytogenetic markers in the maize inbred line KYS for identification of mitotic metaphase chromosomes. The fluorescent strength of CentC signal, relative position, knob presence, size and location were used for the karyotyping. Based on direct visual analysis of chromosome length and position of FISH signals, a metaphase karyotype was constructed for maize inbred line KYS. All chromosomes could be identified unambiguously. The knob positions in the karyotype agreed well with those derived from traditional cytological analyses except chromosomes 3, 4 and 8. One chromosome with a telomeric knob on the short arm was assigned to 3. A chromosome with a knob in the middle of the long arm was assigned number 4 by simultaneous hybridization with a knob-specific probe pZm4–21 and a chromosome 4-specific probe Cent 4. On chromosome 8, we found an additional small telomeric knob on the short arm. In addition, chromosome-specific probes were employed to identify chromosome 6 (45S rDNA) and chromosome 9 (single-copy probeumc105a cosmid).     

玉米和类玉米种间杂交后代细胞学鉴定

利用组成玉米异染色质钮的180-bp重复序列和TR-1元件以及45S rDNA对玉米自交系F107、GB57、二倍体多年生类玉米及其远缘杂交后代的染色体进行荧光原位杂交,确定了3种重复序列在亲本染色体上的分布;同时对远缘杂交后代进行了细胞学鉴定,通过荧光信号在染色体上的位置,证实远缘杂交后代中异源种质的染色体来源;讨论了异染色质钮重复序列对玉米和其野生种杂交后代外源染色体整合和染色体行为等方面研究的应用。     

Biochemical heterogeneity and developmental varieties in T-cell leukemia

During mitosis, chromosomes undergo dynamic structural changes that include condensation of chromosomes – the formation of individual compact chromosomes necessary for faithful segregation of sister chromatids in anaphase. Polo-like kinase 1 (Plk1) regulates multiple mitotic events by binding to targeting factors at different mitotic structures in a phosphorylation dependent manner. In this study, we report the identification of a putative ATPase that targets Plk1 to chromosome arms during mitosis. PICH (Plk1-interacting checkpoint “helicase”) displays a temporal localization on chromosome arms and kinetochores during early mitosis. Interaction with PICH recruits Plk1 to chromosome arms and disruption of this interaction abolishes Plk1 localization on chromosome arms. Moreover, depletion of PICH or overexpression of PICH mutant that is defective in Plk1 binding or ATP binding causes defects in mitotic chromosome compaction, formation of anaphase bridge and cytokinesis failure. We provide data to show that both PICH phosphorylation and its ATPase activity are required for mitotic chromosome compaction. Our study provides a mechanism for targeting Plk1 to chromosome arms and suggests that the PICH ATPase activity is important for the regulation of mitotic chromosome architecture.     

A REC8-dependent plant Shugoshin is required for maintenance of centromeric cohesion during meiosis and has no mitotic functions

During meiosis, sequential release of sister chromatid cohesion (SSC) during two successive nuclear divisions allows the production of haploid gametes from diploid progenitor cells. Release of SSC along chromosome arms allows first a reductional segregation of homologs, and, subsequently, release of centromeric cohesion at anaphase II allows the segregation of chromatids. The Shugoshin (SGO) protein family plays a major role in the protection of centromeric cohesion in Drosophila and yeast. We have isolated a maize mutant that displays premature loss of centromeric cohesion at anaphase I. We showed that this phenotype is due to the absence of ZmSGO1 protein, a maize shugoshin homolog. We also show that ZmSGO1 is localized to the centromeres. The ZmSGO1 protein is not found on mitotic chromosomes and has no obvious mitotic function. On the basis of these results, we propose that ZmSGO1 specifically maintains centromeric cohesion during meiosis I and therefore suggest that SGO1 core functions during meiosis are conserved across kingdoms and in large-genome species. However, in contrast to other Shugoshins, we observed an early and REC8-dependent recruitment of ZmSGO1 in maize, suggesting that control of SGO1 recruitment to chromosomes is different in plants than in other model organisms.     

Functional and mutational variations of heterochromatic region in the maize nucleolus organizer (Variation of the NO heterochromatic region)

The following facts are considered in connection with the problem of population polymorphism at heterochromatic regions of maize chromosomes: (a) variation (1–3 μm) of the heterochromatic region of nucleolus organizer (NO knob) in pollen mother cell at the pachytene stage; (b) presumably function-dependent variation of the degree of its compaction (from a compact state in the majority of plants to a puff-like state); (c) the presence of rearrangements in the NO knob region (duplications and deletion); and (d) homozygous (in all cases) state of the NO knob. Deletion is combined with alterations in the structure of chromosomal NO and the overall karyotype. It is assumed that inbreeding and MGEs influence the mutability of the NO locus and activation of the gene set controlling cytokinesis, chemical reduplication, and, possibly, rDNA amplification. The mutation was classified as a systemic mutation. The mechanisms of NO knob homozygotization in meiosis (mitosis) and the mechanisms of maintenance of the polymorphism at functionally inactive chromosome knob regions in maize populations are compared.     

Detection of Klinefelter syndrome by G-banding analysis combined with primed in situ labeling technique

Primed in situ labeling (PRINS) technique is an alternative to in situ hybridization for rapid chromosome screening. We employed triple-color PRINS technique to detect chromosomal abnormalities in Klinefelter syndrome patients diagnosed by G-banding karyotype analysis. Among 1034 infertile male patients, 134 were found to be cytogenetically abnormal, including 70 with chromosomal number abnormalities and 64 with chromosomal structure abnormalities. Among these cytogenetically abnormal patients, 56 were diagnosed as having Klinefelter syndrome. PRINS technique was used on cultured lymphocyte metaphase cells of the Klinefelter syndrome patients; the same result was obtained with G-banding karyotype analysis. PRINS proved to be a rapid and reliable method to detect numerical chromosome abnormalities in peripheral blood lymphocytes in metaphase.     

Unpicking neurodegeneration in a dish with human pluripotent stem cells

Eukaryotic cell division is an orderly and timely process involving the error-free segregation of chromosomes and cytoplasmic components to give rise to two separate daughter cells. Defects in genome maintenance mechanisms such as cell cycle checkpoints and DNA repair can impact the segregation of the genome during mitosis leading to multiple chromosomal imbalances. In mammals, the DNA damage checkpoint effector Checkpoint Kinase 1 (Chk1) is essential for responses to DNA replication errors, external DNA damage, and chromatin breaks. We reported recently that Chk1 also was essential for chromosome segregation and completion of cytokinesis to prevent genomic instability. Our studies demonstrated that Chk1 deficiency in mitotic cells causes chromosome mis-alignment, lagging chromosomes, chromosome mis- segregation, cytokinetic regression, and binucleation. In addition, abrogation of Chk1 resulted in aberrant localization of mitotic Aurora B kinase at the metaphase plate, anaphase spindle midzone, and cytokinetic midbody as studied both in various cell lines and in a mouse model. Therefore, inappropriate regulation of Chk1 levels during cell cycle progression will result in failed cell division and enhanced genomic instability.