Dissecting the role of molecular motors in the mitotic spindle

Accurate segregation of genetic material during both mitosis and meiosis is essential for the viability of future cellular generations. Genetic material is packaged in the form of chromosomes during cell division, and chromosomes are segregated equally into two daughter cells by a dynamic, microtubule-based structure known as the spindle. Molecular motor proteins of the kinesin and dynein superfamilies are essential players in the functional microanatomy of cell division. They power various aspects of spindle assembly and function, including establishing spindle bipolarity, spindle pole organization, chromosome alignment and segregation, regulating microtubule dynamics, and cytokinesis. This review highlights the roles that various members of the kinesin and dynein motor superfamilies play during mitosis and meiosis. Understanding how microtubule motors function during cell division will unravel how the spindle precisely segregates chromosomes, and may offer insights into the molecular basis of disease states that arise from spindle malfunctions. For example, chromosome non-disjunction during meiosis causes such disorders as Klinefelter, Turner, and Down Syndromes. Chromosome non-disjunction during mitosis is an important contributing mechanism for tumor progression. In addition, since motor proteins are essential for spindle assembly and function, they provide obvious targets for intervention into the cell division cycle, and compounds that specifically block motor functions during mitosis may prove to be valuable chemotherapeutic agents. Anat Rec (New Anat) 261:14-24, 2000.     

C. elegans condensin promotes mitotic chromosome architecture, centromere organization, and sister chromatid segregation during mitosis and meiosis

Chromosome segregation and X-chromosome gene regulation in Caenorhabditis elegans share the component MIX-1, a mitotic protein that also represses X-linked genes during dosage compensation. MIX-1 achieves its dual roles through interactions with different protein partners. To repress gene expression, MIX-1 acts in an X-chromosome complex that resembles the mitotic condensin complex yet lacks chromosome segregation function. Here we show that MIX-1 interacts with a mitotic condensin subunit, SMC-4, to achieve chromosome segregation. The SMC-4/MIX-1 complex positively supercoils DNA in vitro and is required for mitotic chromosome structure and segregation in vivo. Thus, C. elegans has two condensin complexes, one conserved for mitosis and another specialized for gene regulation. SMC-4 and MIX-1 colocalize with centromere proteins on condensed mitotic chromosomes and are required for the restricted orientation of centromeres toward spindle poles. This cell cycle-dependent localization requires AIR-2/AuroraB kinase. Depletion of SMC-4/MIX-1 causes aberrant mitotic chromosome structure and segregation, but not dramatic decondensation at metaphase. Moreover, SMC-4/MIX-1 depletion disrupts sister chromatid segregation during meiosis II but not homologous chromosome segregation during meiosis I, although both processes require chromosome condensation. These results imply that condensin is not simply required for compaction, but plays a more complex role in chromosome architecture that is essential for mitotic and meiotic sister chromatid segregation.     

NOR activity and centromere suppression related in a de novo fusion tdic(9;13)(p22;p13) chromosome in a child with del(9p) syndrome

A female infant with del(9p) syndrome was found to have the karyotype 45,XX,tdic(9;13)(p22;p13) de novo. In the translocation chromosome, various combinations of AgNOR activity and inactivity were found with suppression of either the 9 or neither centromere. These phenomena of discontinuous centromeric suppression and variation in NOR activity in the one chromosome were scored on AgNOR, GTG, and a combination of AgNOR- and GTG-banded preparations. With AgNOR staining, 15.8% tdic chromosomes were AgNOR-positive, and this coincided (in preparations with GTG banding only) with 16% tdic chromosomes with a nonstaining gap present at the NOR site. This suggested that when the NOR-nonstaining gap was present the AgNOR staining would be positive; this was confirmed by the absence of gaps in combination AgNOR-GTG-banded preparations. In cells with tdic-NOR-negative chromosomes, equal proportions of cells with the 13 or both centromeres constricted were observed, but in cells with tdic-AgNOR-positive chromosomes there was only half the proportion of tdic chromosomes with both centromeres constricted; ie, there was a (significant) tendency towards inactivity of the NOR when both centromeres were constricted in the tdic chromosome. Therefore, the 2 phenomena, variation in NOR activity and centromeric suppression, are interrelated in this case.     

Yeast Cohesin complex requires a conserved protein, Eco1p(Ctf7), to establish cohesion between sister chromatids during DNA replication

Sister chromatid cohesion is crucial for chromosome segregation during mitosis. Loss of cohesion very possibly triggers sister separation at the metaphase→anaphase transition. This process depends on the destruction of anaphase inhibitory proteins like Pds1p (Cut2p), which is thought to liberate a sister-separating protein Esp1p (Cut1p). By looking for mutants that separate sister centromeres in the presence of Pds1p, this and a previous study have identified six proteins essential for establishing or maintaining sister chromatid cohesion. Four of these proteins, Scc1p, Scc3p, Smc1p, and Smc3p, are subunits of a ‘Cohesin’ complex that binds chromosomes from late G₁ until the onset of anaphase. The fifth protein, Scc2p, is not a stoichiometric Cohesin subunit but it is required for Cohesin’s association with chromosomes. The sixth protein, Eco1p(Ctf7p), is not a Cohesin subunit. It is necessary for the establishment of cohesion during DNA replication but not for its maintenance during G₂ and M phases.     

人类染色体动粒蛋白研究进展

动粒是染色体着丝粒区域一个4层结构的特化部位,是一个复杂的多层蛋白质结构。动粒蛋白在装配有功能的动粒、保证染色体的正确分离、维持染色体倍体性等方面具有重要功能。本文主要探讨了几种与动粒结构和功能密切相关的动粒蛋白。     

Histone H3 phosphorylation of mammalian chromosomes

Inferences about the role and location of phosphorylated histone H3 are derived primarily from biochemical studies. A few direct observations at chromosome level have shown that phosphorylation begins at the site of heterochromatin and spreads throughout the chromosome. However, a comparative study of chromosomes of mouse (L929 cells), Chinese hamster (CHO 9 cells) and the Indian muntjac (male cells) reveals some distinguishable details among mammalian species. Whereas the L929 cells exhibit the typical pattern of phosphorylation at the region of centromeric heterochromatin associated with the active centromere, the heterochromatin blocks associated with the inactive centromeres also show label of about equivalent intensity. Throughout the cell cycle, heterochromatin exhibits sharper (denser) and better defined label than does euchromatin which expresses somewhat diffuse label. The centromere constriction on biarmed chromosomes, originating in Robertsonian translocations, appears phosphorylated in some, if not all chromosomes. A similar situation was found for the CHO 9 cells indicating that phosphorylation does include the region in which H3 is supposedly replaced by CENP-A. An interesting feature of the CHO cell line was the dense label at and near the telomeres; this feature was not observed in either the mouse or the Indian muntjac. The centromere regions of the Indian muntjac chromosomes showed three sites of label in the multicentric X chromosome and two each on chromosome pair number 1 and Y₂; the sites coinciding with the reaction sites of antikinetochore antibodies. Also, the X and Y₁ chromosomes of Indian muntjac show intense phosphorylation at the sites of secondary constrictions.The chromosomes of all three species were phosphorylated throughout the cell cycle. As the chromosomes started to decondense during anaphase, heavy phosphorylation was observed in the form of discontinuous beaded structures indicating partial despiralization of the chromosome. Interestingly, when cells had completed karyokinesis and resolved into two independent nuclei, the phosphorylation was observed at the midbody. At this stage, the cytoplasm appeared to be again phosphorylated.     

Karyotyping chromosomes by electron microscopy. Condensation-inhibition of G bands in human and Chinese hamster chromosomes by a BrdU-Hoechst 33258 treatment

A BrdU-Hoechst 33258 treatment of living cells, which selectively induced condensation-inhibition of G-band chromatin in human and Chinese hamster chromosomes, is presented. As a consequence mitotic chromosomes showed high resolution R-banding patterns when examined by light and electron microscopy. Besides each whole chromosome identification, this procedure also permitted the electron microscopic study of specific structures, such as satellites, secondary constrictions, telomeres, centromeres, as well as G and R bands, some of them not visible by light microscopy. We have also observed that the chromatin of G and R bands behave as blocks of chromatin condensation and that G-band chromatin develops condensation along G₂. Under the BrdU-Hoechst 33258 treatment, chromatin fibers seem to invert their spontaneous pattern of condensation within the chromosomes.     

Human autoimmune sera recognize a conserved 26 kD protein associated with mammalian heterochromatin that is homologous to heterochromatin protein 1 ofDrosophila

Immunofluorescence indicated that autoimmune sera from certain scleroderma/CREST patients, in addition to binding to the primary constrictions or centromeres, also labelled pericentromeric heterochromatin in mouse and human metaphase chromosomes. Immunoblotting has revealed that two conserved nuclear antigens are recognized by this CREST subgroup, one of mol. wt 26 kD (p26), and the other of mol. wt 23 kD (p23).In situ immunolabelling with affinity purified antibodies demonstrated that p26, but not p23, is concentrated in pericentromeric heterochromatin. Further studies have shown that both p26 and p23 are immunologically related to theDrosophila heterochromatin-associated protein HP1, and to other chromodomain proteins.     

Chromosome size and origin as determinants of the level of CENP-A incorporation into human centromeres

We have expressed an EGFP-CENP-A fusion protein in human cells in order to quantitate the level of CENP-A incorporated into normal and variant human centromeres. The results revealed a 3.2-fold difference in the level of CENP-A incorporation into α-satellite repeat DNA-based centromeres, with the Y centromere showing the lowest level of all normal human chromosomes. Identification of individual chromosomes revealed a statistically significant, though not absolute, correlation between chromosome size and CENP-A incorporation. Analysis of three independent neocentromeres revealed a significantly reduced level of CENP-A compared to normal centromeres. Truncation of a neocentric marker chromosome to produce a minichromosome further reduced CENP-A levels, indicating a remodelling of centromeric chromatin. These results suggest a role for increased CENP-A incorporation in the faithful segregation of larger chromosomes and support a model of centromere evolution in which neocentromeres represent ancestral centromeres that, through adaptive evolution, acquire satellite repeats to facilitate the incorporation of higher numbers of CENP-A containing nucleosomes, thereby facilitating the assembly of larger kinetochore structures.     

Centromeres and kinetochores of Brassicaceae

The centromere—the primary constriction of monocentric chromosomes—is essential for correct segregation of chromosomes during mitosis and meiosis. Centromeric DNA varies between different organisms in sequence composition and extension. The main components of centromeric and pericentromeric DNA of Brassicaceae species are centromeric satellite repeats. Centromeric DNA initiates assembly of the kinetochore, the large protein complex where the spindle fibers attach during nuclear division to pull sister chromatids apart. Kinetochore assembly is initiated by incorporation of the centromeric histone H3 cenH3 into centromeric nucleosomes. The spindle assembly checkpoint acts during mitosis and meiosis at centromeres and maintains genome stability by preventing chromosome segregation before all kinetochores are correctly attached to microtubules. The function of the spindle assembly checkpoint in plants is still poorly understood. Here, we review recent advances of studies on structure and functional importance of centromeric DNA of Brassicaceae, assembly and function of cenH3 in Arabidopsis thaliana and characterization of core SAC proteins of A. thaliana in comparison with non-plant homologues.     

The mouse A/HeJ Y chromosome: Another good Y gone bad

In both humans and mice there are numerous reports of Y chromosome abnormalities that interfere with sex determination. Recent studies in the mouse of one such mutation have identified Y chromosome nondisjunction during preimplantation development as the cause of abnormal testis determination that results in a high frequency of true hermaphroditism. We report here that the mouse Y chromosome from the A/HeJ inbred strain induces similar aberrations in sex determination. Our analyses provide evidence, however, that the mechanism underlying these aberrations is not Y chromosome nondisjunction. On the basis of our findings, we postulate that a mutation at or near the centromere affects both the segregation and sex-determining properties of the A/HeJ Y chromosome. This Y chromosome adds to the growing list of Y chromosome aberrations in humans and mice. In both species, the centromere of the Y is structurally and morphologically distinct from the centromeres of all other chromosomes. We conclude that these centromeric features make the human and mouse Y chromosomes extremely sensitive to minor structural alterations, and that our studies provide yet another example of a good Y chromosome gone 'bad.'     

mSin3-associated protein, mSds3, is essential for pericentric heterochromatin formation and chromosome segregation in mammalian cells

The histone code guides many aspects of chromosome biology including the equal distribution of chromosomes during cell division. In the chromatin domains surrounding the centromere, known as pericentric heterochromatin, histone modifications, particularly deacetylation and methylation, appear to be essential for proper chromosome segregation. However, the specific factors and their precise roles in this highly orchestrated process remain under active investigation. Here, we report that germ-line or somatic deletion of mSds3, an essential component of the functional mSin3/HDAC corepressor complex, generates a cell-lethal condition associated with rampant aneuploidy, defective karyokinesis, and consequently, a failure of cytokinesis. mSds3-deficient cells fail to deacetylate and methylate pericentric heterochromatin histones and to recruit essential heterochromatin-associated proteins, resulting in aberrant associations among heterologous chromosomes via centromeric regions and consequent failure to properly segregate chromosomes. Mutant mSds3 molecules that are defective in mSin3 binding fail to rescue the mSds3 null phenotypes. On the basis of these findings, we propose that mSds3 and its associated mSin3/HDAC components play a central role in initiating the cascade of pericentric heterochromatin-specific modifications necessary for the proper distribution of chromosomes during cell division in mammalian cells.     

Cohesion proteins are present in centromere protein bodies associated with avian lampbrush chromosomes

Proteins of sister chromatid cohesion are important for maintenance of meiotic chromosome structure and retention of homologous chromosomes in bivalents during diplotene. Localization of the cohesion proteins within nuclei of growing oocytes merits special attention, particularly in avian oocytes, in which diplotene chromosomes assume the form of lampbrush chromosomes (LBCs). We performed indirect immunostaining using antibodies against cohesins SMC1α, SMC1β, SMC3, Rad21, and the SA/STAG family on chaffinch, pigeon and duck LBCs spreads, and frozen ovary sections. On LBCs spreads, antibodies to the majority of cohesins showed punctate staining on chromosome axes. LBC lateral loops, where sister chromatids are separated, did not show cohesin components. The spherical entities attached to the LBCs centromeres in avian germinal vesicles, the so-called protein bodies (PBs), were enriched in SMC1α, SMC3, Rad21, STAG1 and STAG2. The synaptonemal complex component SYCP3, which also participates in cohesion, was detected in the axes of avian lampbrush bivalents and, to a greater degree, in the PBs. In vitellogenic oocytes, cohesion proteins persist in the PBs associated with condensing bivalents when they concentrate into the karyosphere. These results indicate that cohesion proteins accumulate in centromere PBs in avian oocytes and are involved into structural maintenance of lampbrush chromosome axes.     

An identical chromosome abnormality: der(6)t(6;7)(q13;p13) in two patients with peripheral T-cell lymphoma

Centromeres of all chromosomes in normal cells exhibit kinetochore proteins detectable by antikinetochore antibodies. The present communication reports that some chromosomes in a transformed cell line of rat cerebral origin fail to deposit kinetochore proteins at their centromeres. These chromosomes may not undergo normal anaphase segregation and may be either lost or enter one or the other daughter cell. The observation that some chromosomes may be without detectable kinetochore proteins suggests a noval mechanism for origin of aneuploidy in transformed and neoplastic cells.     

Sequence of centromere separation: Occurrence,possible significance,and control

This review describes the existence of a phenomenon, sequential separation of centromeres, in mitotic cells of various species including both animals and plants. Critical observations at metaanaphase show that the centromeres of chromosomes in a given genome do not separate into two sister units randomly, but that there is a genetically controlled, nonrandom, species-specific sequence which is independent of the length of the chromosome or the position of the centromere. A stricter control appears to exist for late-separating than for early-separating chromosomes. At early stages of metaanaphase several chromosomes initiate onset of separation simultaneously or in rapid succession, but late-separating chromosomes are better defined in their sequential position. The effect of Colcemid on the sequence of separation is minimal. It is proposed that aneuploidy in humans and other organisms may result from out-of-phase separation of a given chromosome. With the exception of chromosome No. 16, it appears that very early- or very late-separating centromeres are involved in human trisomies more often than those in between.Perhaps one function of centromeric heterochromatin is the control of centromere separation. The amount of such chromatin shows a positive correlation with the timing of separation of the centromeres. Superimposed upon this quantitative influence is the qualitative aspect, as discussed for various genomes. This suggestion explains a lack of extremely large quantities of heterochromatin near the centromere. Its existence in the form of homogeneously staining regions distal to the centromere, as in some cancer cells or in sex chromosomes, seemingly has no influence on the separation of centromeres.A brief discussion of centromere separation errors in human disease is provided, and suggestions for further studies are made.     

Family studies on nucleoside phosphorylase and the short arm of chromosome 14

A family with two nucleoside phosphorylase-deficient patients has been scored for the segregation of NP⁰ and the variable region 14p. The most likely 14p: NP recombination fraction is (M5 in males and 0–30 in females.
There is no family data to assign the Pi:Gm linkage group to chromosome 14, but as immunoglobulin heavy chain has been assigned to this chromosome by somatic cell methods the most likely gene order is 14p:NP: Pi:Gm with Pi in 14q2 and Gm in 14(q23 →q32), but the order 14p:NP:Gm:Pi with Pi in 14(q24 → qter) and Gm in 14(q22 → q24) is not excluded.
The available linkage data between biochemical markers on acrocentric chromosomes and their short arm markers suggest that there may be more recombination towards the ends of human chromosomes whether or not those ends carry centromeres.     

From equator to pole: splitting chromosomes in mitosis and meiosis

During eukaryotic cell division, chromosomes must be precisely partitioned to daughter cells. This relies on a mechanism to move chromosomes in defined directions within the parental cell. While sister chromatids are segregated from one another in mitosis and meiosis II, specific adaptations enable the segregation of homologous chromosomes during meiosis I to reduce ploidy for gamete production. Many of the factors that drive these directed chromosome movements are known, and their molecular mechanism has started to be uncovered. Here we review the mechanisms of eukaryotic chromosome segregation, with a particular emphasis on the modifications that ensure the segregation of homologous chromosomes during meiosis I.     

Effect of colchicine and telocentric chromosome conformation on centromere and telomere dynamics at meiotic prophase I in wheat–rye additions

Association of telomeres in a bouquet and clustering of centromere regions have been proposed to be involved in the search and recognition of homologous partners. We have analysed the role of these structures in meiotic chromosome pairing in wheat–rye addition lines by applying colchicine for disturbing presynaptic telomere movements and by modifying the centromere position from submetacentric to telocentric for studying centromere effects. Rye chromosomes, wheat and rye centromeres, and telomeres were identified by fluorescence in-situ hybridization. Presynaptic association of centromeres in pairs or in more complex structures involved mainly non-homologous chromosomes as deduced from the behaviour of rye centromeres. While centromere association was not affected by colchicine, colchicine inhibited bouquet formation, which caused failure of homologous synapsis. Homologous centromeres of rye telocentrics associated earlier than those of rye submetacentric chromosomes, indicating that migration of the telocentrics’ centromeres to the telomere pole during bouquet formation facilitated their association. Homologous chromosomes associated in premeiotic interphase can recognize each other and initiate synapsis at zygotene. However, telomere convergence is needed for bringing together the majority of homologous pairs that normally occupy separate territories in premeiotic nuclei.     

Centromeres of human chromosomes

The centromere, recognized cytologically as the primary constriction, is essential for chromosomal attachment to the spindle and for proper segregation of mitotic and meiotic chromosomes. Considerable progress has been made in identifying both DNA and protein components of the centromere and kinetochore complex in mammalian chromosomes, including definition of specific motor proteins with demonstrable functions in chromosome movement. Searches for possible environmental influences on chromosome disjunction might logically be based on known components of the segregation apparatus, both intrinsic and extrinsic to the chromosomes themselves. This article reviews available information on both DNA and protein components of the centromere of mammalian, particularly human, chromosomes and summarizes our current understanding of their role(s) in facilitating normal chromosome behavior in mitosis and meiosis. © 1996 Wiley-Liss, Inc.