Propagation of centromeric chromatin requires exit from mitosis

Centromeres direct chromosomal inheritance by nucleating assembly of the kinetochore, a large multiprotein complex required for microtubule attachment during mitosis. Centromere identity in humans is epigenetically determined, with no DNA sequence either necessary or sufficient. A prime candidate for the epigenetic mark is assembly into centromeric chromatin of centromere protein A (CENP-A), a histone H3 variant found only at functional centromeres. A new covalent fluorescent pulse-chase labeling approach using SNAP tagging has now been developed and is used to demonstrate that CENP-A bound to a mature centromere is quantitatively and equally partitioned to sister centromeres generated during S phase, thereby remaining stably associated through multiple cell divisions. Loading of nascent CENP-A on the megabase domains of replicated centromere DNA is shown to require passage through mitosis but not microtubule attachment. Very surprisingly, assembly and stabilization of new CENP-A-containing nucleosomes is restricted exclusively to the subsequent G1 phase, demonstrating direct coupling between progression through mitosis and assembly/maturation of the next generation of centromeres.     

Assembly of Drosophila centromeric nucleosomes requires CID dimerization

Centromeres are essential chromosomal regions required for kinetochore assembly and chromosome segregation. The composition and organization of centromeric nucleosomes containing the essential histone H3 variant CENP-A (CID in Drosophila) is a fundamental, unresolved issue. Using immunoprecipitation of CID mononucleosomes and cysteine crosslinking, we demonstrate that centromeric nucleosomes contain CID dimers in vivo. Furthermore, CID dimerization and centromeric targeting require a residue implicated in formation of the four-helix bundle, which mediates intranucleosomal H3 dimerization and nucleosome integrity. Taken together, our findings suggest that CID nucleosomes are octameric in vivo and that CID dimerization is essential for correct centromere assembly.     

Drosophila cohesins DSA1 and Drad21 persist and colocalize along the centromeric heterochromatin during mitosis

Sister chromatid cohesion in eukaryotes is maintained mainly by a conserved multiprotein complex termed cohesin. Drad21 and DSA1 are the Drosophila homologues of the yeast Scc1 and Scc3 cohesin subunits, respectively. We recently identified a Drosophila mitotic cohesin complex composed of Drad21/DSA1/DSMC1/DSMC3. Here we study the contribution of this complex to sister chromatid cohesion using immunofluorescence microscopy to analyze cell cycle chromosomal localization of DSA1 and Drad21 in S2 cells. We observed that DSA1 and Drad21 colocalize during all cell cycle stages in cultured cells. Both proteins remain in the centromere until metaphase, colocalizing at the centromere pairing domain that extends along the entire heterochromatin; the centromeric cohesion protein MEI-S332 is nonetheless reported in a distinct centromere domain. These results provide strong evidence that DSA1 and Drad21 are partners in a cohesin complex involved in the maintenance of sister chromatid arm and centromeric cohesion during mitosis in Drosophila.     

Trichomonas vaginalis: chromatin and mitotic spindle during mitosis

The mitotic phases and the changes that the chromatin and mitotic microtubules undergo during mitosis in the sexually transmitted parasite Trichomonas vaginalis are described. Parasites arrested in the gap 2 phase of the cell cycle by nutrient starvation were induced to mitosis by addition of fresh whole medium. [(3)H] Thymidine labeling of trichomonad parasites for 24 h showed that parasites have at least four synchronic duplications after mitosis induction. Fixed or live and acridine orange (AO)-stained trichomonads analyzed at different times during mitosis by epifluorescence microscopy showed that mitosis took about 45 min and is divided into five stages: prophase, metaphase, early and late anaphase, early and late telophase, and cytokinesis. The AO-stained nucleus of live trichomonads showed green (DNA) and orange (RNA) fluorescence, and the nucleic acid nature was confirmed by DNase and RNase treatment, respectively. The chromatin appeared partially condensed during interphase. At metaphase, it appeared as six condensed chromosomes, as recently reported, which decondensed at anaphase and migrated to the nuclear poles at telophase. In addition, small bundles of microtubules (as hemispindles) were detected only in metaphase with the polyclonal antibody anti-Entamoeba histolytica alpha-tubulin. This antibody showed that the hemispindle and an atractophore-like structure seem to duplicate and polarize during metaphase. In conclusion, T. vaginalis mitosis involves five mitotic phases in which the chromatin undergoes different degrees of condensation, from chromosomes to decondensed chromatin, and two hemispindles that are observed only in the metaphase stage.     

Armadillo levels are reduced during mitosis in Drosophila

The Armadillo protein of Drosophila melanogaster is both a structural component of adherens junctions at apical cell membranes and also a key cytoplasmic transducer of the Wingless signalling pathway. We have used the Gal4-UAS system to over-express Armadillo in the Drosophila wing: this hyperactivates the Wingless pathway and leads to the formation of ectopic, supernumerary wing bristles. Here, we report that this adult phenotype is dominantly enhanced by mutations in cdc25(string) and, conversely, is suppressed by co-expression of Cdc25(String). Furthermore, we show that the steady state levels of Armadillo protein produced from the UAS transgene are also sensitive to cdc25(string) dosage in the cells of the larval imaginal wing disc. Consistent with the role of Cdc25(String) in promoting mitosis and with our genetic interaction data, we find a strong correlation between progression through mitosis and a reduction in Armadillo levels. Significantly, this is true whether Armadillo is over-expressed or not, and both cytoplasmic (signalling) and membrane-associated (junctional) Armadillo appears to be affected. We conclude that this phenomenon may reduce the efficacy of Wingless signalling and/or intercellular adhesion during cell division.     

The unique centromeric chromatin structure of Schizosaccharomyces pombe is maintained during meiosis

In meiosis I sister centromeres are unified in their polarity on the spindle, and this unique behavior is known to require the function of meiosis-specific factors that set some intrinsic property of the centromeres. The fission yeast, Schizosaccharomyces pombe, possesses complex centromeres consisting of repetitive DNA elements, making it an excellent model in which to study the behavior of complex centromeres. In mitosis, during which sister centromeres mediate chromosome segregation by establishing bipolar chromosome attachments to the spindle, the central core of the S. pombe centromere chromatin has a unique irregular nucleosome pattern. Deletion of repeats flanking this core structure have no effect on mitotic chromosome segregation, but have profound effects during meiosis. While this demonstrates that the outer repeats are critical for normal meiotic sister centromere behavior, exactly how they function and how monopolarity is established remains unclear. In this study we provide the first analysis of the chromatin structure of a complex centromere during meiosis. We show that the nature and extent of the unique central core chromatin structure is maintained with no measurable expansion. This demonstrates that monopolarity of sister centromeres, and subsequent reversion to bipolarity, does not involve a global change to the centromeric chromatin structure.     

Spindle mechanics and dynamics during mitosis in Drosophila

Drosophila melanogaster is an excellent model for studying mitosis. Syncytial embryos are amenable to time-lapse imaging of hundreds of synchronously dividing spindles, allowing the quantitation of spindle and chromosome dynamics with unprecedented fidelity. Other Drosophila cell types, including neuroblasts, cultured cells, spermatocytes and oocytes, contain spindles that differ in their design, providing cells amenable to different types of experiments and allowing identification of common core mechanisms. The function of mitotic proteins can be studied using mutants, inhibitor microinjection and RNA interference (RNAi) to identify the full inventory of mitotic proteins encoded by the genome. Here, we review recent advances in understanding how ensembles of mitotic proteins coordinate spindle assembly and chromosome motion in this system.     

Histone variants in mouse centromeric chromatin

Summary Highly purified centromeric heterochromatin was isolated from mouse liver nuclei and the pattern of core histone variants was analyzed. In comparison with total chromatin, the centromeric heterochromatin of young animals was characterized by (1) enrichment in the replication-dependent variants H2A₁, H2B₂ and H3₂, (2) reduced amount of the minor variant H2A_z and (3) absence of ubiquitinated molecules of H2A. This specific variant pattern changed upon ageing as a result of accumulation of replacement variants so that in adult animals both chromatin preparations exhibited similar pattern for H2A and H2B, while the difference in the profile of H3 variants was preserved.     

Changes in non-histone chromatin proteins during the storage of chromatin

We have described here the changes in stored chicken reticulocyte chromatin which take place among non-histone protein fractions based on SDS-polyacylamide gel electrophoresis and hybridization of globin cDNA with RNAs transcribed on native and reconstitited chromatin templates.     

Assembly of an active chromatin structure during replication.

MSB cells were pulse labeled with 3H-thymidine and the isolated nuclei digested with either staphylococcal nuclease (to about 40% acid solubility) or DNase I (to 15% acid solubility). The purified, nuclease resistant single-copy DNA was then hybridized to nuclear RNA (nRNA). The results of these experiments show that actively transcribed genes are assembled into nucleosome-like structures within 5-10 nucleosomes of the replication fork and that they also acquire a conformation characteristic of actively transcribed nucleosomes (ie, a DNase I sensitive structure) within 20 nucleosomes of the fork. Assuming DNA sequence specific interactions are required for establishing a DNase I sensitive conformation on active genes during each round of replication, our results indicate that a specific recognition event can occur very rapidly and very specifically in eukaryotic cells. The results are discussed in terms of the possible mechanisms responsible for propagating active, chromosomal conformations from mother cells to daughter cells.     

Exchange of proteins during immunofractionation of chromatin

The migration and rearrangement of chromosomal proteins during immunofractionation of chromatin has been investigated. Oligonucleosomes from two different chromatins, chicken erythrocyte or rat liver, were mixed with oligonucleosomes from the other species which had been depleted of histones H1/H5 and high mobility group proteins (HMGs). The mixture was treated with buffers of various ionic strengths and immunofractionated on an anti-H1 degrees/H5 or anti-HMG-17 IgG-Sepharose column. The type of DNA, which was retained as the bound fraction on the column, was determined by slot blot analysis using nick-translated repetitive DNA probes from either chicken or rat. The results indicate that in low ionic strength buffers (i.e., below 40 mM NaCl), there is very little exchange of either histone H5 or HMG-17 among nucleosomes and therefore we suggest that it is possible to fractionate nucleosomes according to their antigenic content.     

Assembly of nucleolus-derived foci in various cultured mammalian cells during mitosis

During mitosis, rebuilding of the nucleolus is a step-wise process that, above all, includes an assembly of nucleolus-derived foci (NDF) in the cytoplasm of telophase cells. In this study, we performed a comparative analysis of NDF formation in mitotic cells of various mammalian cell cultures, such as green monkey CV1 cells, human HeLa cells, mouse 3T3 cells, and pig PK cells, both in control and following inhibition of rRNA synthesis by actinomycin D or by an adenosine analogue, DRB. The results obtained show that in all examined cell types NDF are formed shortly after or simultaneously with the onset of chromosome segregation to the poles of the mitotic spindle. However, an efficiency of NDF assembly, i.e. the number of NDF per anaphase or telophase cell, and the portion of anaphase and telophase cells containing NDF vary in different cell cultures, being most prominent in CVI and HeLa cells. In these cells, the vast majority of NDF accumulate several proteins of the mature nucleolus, such as B23/nucleophopmin, C23/nucleotin, fibrillarin, and, to a lesser extent, Nop52. The rRNA harbored by NDF is synthesized several hours prior mitosis, and plays an essential role the maintenance of NDF structural integrity. Starting from early stages of the assembly onwards, the NDF are predominantly located in the area occupied by aster microtubules of the mitotic spindle.     

Structure, assembly and reading of centromeric chromatin

Centromeres are epigenetically defined chromatin domains marked by the presence of the histone H3 variant CENP-A. Here we review recent structural and biochemical work on CENP-A, and advances in understanding the mechanisms that propagate and read centromeric chromatin domains.     

Isolation of chromosome-associated proteins from Drosophila melanogaster that bind a human centromeric DNA sequence

The molecular mechanism involved in packaging centromeric heterochromatin is still poorly understood. CENP-B, a centromeric protein present in human cells, is though to be involved in this process. This is a DNA-binding protein that localizes to the central domain of the centromere of human and mouse chromosomes due to its association with the 17-bp CENP-B box sequence. We have designed a biochemical approach to search for functional homologues of CENP-B in Drosophila melanogaster. This strategy relies upon the use of DNA fragments containing the CENP-B box to identify proteins that specifically bind this sequence. Three polypeptides were isolated by nuclear protein extraction, followed by sequential ion exchange columns and DNA affinity chromatography. All three proteins are present in the complex formed after gel retardation with the human alphoid satellite DNA that contains the CENP-B box. Footprinting analysis reveals that the complex occupies both strands of the CENP-B box, although it is still unclear which of the polypeptides actually makes contact with the DNA. Localization of fluorescein-labeled proteins after microinjection into early Drosophila embryos shows that they associate with condensed chromosomes. Immunostaining of embryos with a polyclonal serum made against all three polypeptides also shows chromosomal localization throughout mitosis. During metaphase and anaphase the antigens appear to localize preferentially to centromeric heterochromatin. Immunostaining of neuroblasts chromosome spreads confirmed these results, though some staining of chromosomal arms is also observed. The data strongly suggests that the polypeptides we have identified are chromosomal binding proteins that accumulate mainly at the centromeric heterochromatin. Furthermore, DNA binding assays clearly indicate that they have a high specific affinity for the human CENP-B box. This would suggest that at least one of the three proteins isolated might be a functional homologue of the human CENP-B.