Kohta Takahashi

Mis16 and Mis18 Are Required for CENP-A Loading and Histone Deacetylation at Centromeres

Centromeres contain specialized chromatin that includes the centromere-specific histone H3 variant, spCENP-A/Cnp1. Here we report identification of five fission yeast centromere proteins, Mis14-18. Mis14 is recruited to kinetochores independently of CENP-A, and, conversely, CENP-A does not require Mis14 to associate with centromeres. In contrast, Mis15, Mis16 (strong similarity with human RbAp48 and RbAp46), Mis17, and Mis18 are all part of the CENP-A recruitment pathway. Mis15 and Mis17 form an evolutionarily conserved complex that also includes Mis6. Mis16 and Mis18 form a complex and maintain the deacetylated state of histones specifically in the central core of centromeres. Mis16 and Mis18 are the most upstream factors in kinetochore assembly as they can associate with kinetochores in all kinetochore mutants except for mis18 and mis16, respectively. RNAi knockdown in human cells shows that Mis16 function is conserved as RbAp48 and RbAp46 are both required for localization of human CENP-A.

Mis6, a fission yeast inner centromere protein, acts during G1/S and forms specialized chromatin required for equal segregation.

Disorder in sister chromatid separation can lead to genome instability and cancer. A temperature-sensitive S. pombe mis6-302 frequently loses a minichromosome at 26 degrees C and abolishes equal segregation of regular chromosomes at 36 degrees C. The mis6+ gene is essential for viability, and its deletion results in missegregation identical to mis6-302. Mis6 acts before or at the onset of S phase, and mitotic missegregation defects are produced only after the passage of G1/S at 36 degrees C. Mis6 locates at the centromeres throughout the cell cycle. In the mutant, positioning of the centromeres becomes abnormal, and specialized chromatin in the inner centromeres, which give the smear micrococcal nuclease pattern in wild type, is disrupted. The ability to establish correct biorientation of sister centromeres in metaphase cells requires the Mis6-containing chromatin and originates during the passage of G1/S.

Heterochromatin integrity affects chromosome reorganization after centromere dysfunction.

The centromere is essential for the inheritance of genetic information on eukaryotic chromosomes. Epigenetic regulation of centromere identity has been implicated in genome stability, karyotype evolution, and speciation. However, little is known regarding the manner in which centromere dysfunction affects the chromosomal architectures. Here we show that in the fission yeast Schizosaccharomyces pombe, the conditional deletion of the centromere produces survivors that carry either a neocentromere-acquired chromosome at the subtelomeric region or an acentric chromosome rescued by intertelomere fusion with either of the remaining chromosomes. The ratio of neocentromere formation to telomere fusion is considerably decreased by the inactivation of genes involved in RNA interference–dependent heterochromatin formation. By affecting the modes of chromosomal reorganization, the genomic distribution of heterochromatin may influence the fate of karyotype evolution.

A Cell Cycle-Regulated GATA Factor Promotes Centromeric Localization of CENP-A in Fission Yeast

CENP-A, the centromere-specific histone H3 variant, plays a crucial role in organizing kinetochore chromatin for precise chromosome segregation. We have isolated Ams2, a Daxx-like motif-containing GATA factor, and histone H4, as multicopy suppressors of cnp1-1, an S. pombe CENP-A mutant. While depletion of Ams2 results in the reduction of CENP-A binding to the centromere and chromosome missegregation, increasing its dosage restores association of a CENP-A mutant protein with centromeres. Conversely, overexpression of CENP-A or histone H4 suppresses an ams2 disruptant. The intracellular amount of Ams2 thus affects centromeric nucleosomal constituents. Ams2 is abundant in S phase and associates with chromatin, including the central centromeres through binding to GATA-core sequences. Ams2 is thus a cell cycle-regulated GATA factor that is required for centromere function.

Requirement of Chromatid Cohesion Proteins Rad21/Scc1 and Mis4/Scc2 for Normal Spindle-Kinetochore Interaction in Fission Yeast

BACKGROUNDnProteins conserved from yeast to human hold two sister chromatids together. The failure to form cohesion in the S phase results in premature separation of chromatids in G2/M. Mitotic kinetochores free from microtubules or the lack of tension are known to activate spindle checkpoint.nnnRESULTSnThe loss of chromatid cohesion in fission yeast mutants (mis4-242 and rad21-K1) leads to the activation of Mad2- and Bub1-dependent checkpoint, possibly due to a diminished microtubule-kinetochore interaction. Bub1, a checkpoint kinase, localizes briefly at early mitotic kinetochores in wild-type, whereas the cohesion mutation greatly increases the duration of kinetochore localization. Bub1 is bound to the central centromere region of mitotic cells. These cohesion mutants are hypersensitive to a tubulin poison and are synthetic lethal with dis1 and bir1/cut17, which are defective in microtubule-kinetochore interaction. The formation of specialized centromere chromatin containing CENP-A does not require cohesion. Dominant-negative noncleavable Rad21 fails to activate checkpoint but blocks sister chromatid separation and full spindle elongation in anaphase.nnnCONCLUSIONSnMis4 and Rad21 (budding yeast Scc2 and Scc1 homologs, respectively) act in establishing the normal spindle-kinetochore interaction in early mitosis and inhibit sister chromatid separation until the cleavage of Rad21 in anaphase. Checkpoint directly or indirectly monitors the states of cohesion in early mitosis. Full spindle extension occurs with unequal nuclear division in cohesion mutants in the absence of Mad2.

CENP-A Reduction Induces a p53-Dependent Cellular Senescence Response To Protect Cells from Executing Defective Mitoses

ABSTRACT Cellular senescence is an irreversible growth arrest and is presumed to be a natural barrier to tumor development. Like telomere shortening, certain defects in chromosome integrity can trigger senescence; however, the roles of centromere proteins in regulating commitment to the senescent state remains to be established. We examined chromatin structure in senescent human primary fibroblasts and found that CENP-A protein levels are diminished in senescent cells. Senescence-associated reduction of CENP-A is caused by transcriptional and posttranslational control. Surprisingly, forced reduction of CENP-A by short-hairpin RNA was found to cause premature senescence in human primary fibroblasts. This premature senescence is dependent on a tumor suppressor, p53, but not on p16INK4a-Rb; the depletion of CENP-A in p53-deficient cells results in aberrant mitosis with chromosome missegregation. We propose that p53-dependent senescence that arises from CENP-A reduction acts as a “self-defense mechanism” to prevent centromere-defective cells from undergoing mitotic proliferation that potentially leads to massive generation of aneuploid cells.

Two distinct pathways responsible for the loading of CENP-A to centromeres in the fission yeast cell cycle

CENP-A is a centromere-specific histone H3 variant that is- essential for faithful chromosome segregation in all eukaryotes thus far investigated. We genetically identified two factors, Ams2 and Mis6, each of which is required for the correct centromere localization of SpCENP-A (Cnp1), the fission yeast homologue of CENP-A. Ams2 is a cell-cycle-regulated GATA factor that localizes on the nuclear chromatin, including on centromeres, during the S phase. Ams2 may be responsible for the replication-coupled loading of SpCENP-A by facilitating nucleosomal formation during the S phase. Consistently, overproduction of histone H4, but not that of H3, suppressed the defect of SpCENP-A localization in Ams2-deficient cells. We demonstrated the existence of at least two distinct phases for SpCENP-A loading during the cell cycle: the S phase and the late-G2 phase. Ectopically induced SpCENP-A was efficiently loaded onto the centromeres in G2-arrested cells, indicating that SpCENP-A probably undergoes replication-uncoupled loading after the completion of S phase. This G2 loading pathway of SpCENP-A may require Mis6, a constitutive centromere-binding protein that is also implicated in the Mad2-dependent spindle attachment checkpoint response. Here, we discuss the functional relationship between the flexible loading mechanism of CENP-A and the plasticity of centromere chromatin formation in fission yeast.

Epigenetic Inactivation and Subsequent Heterochromatinization of a Centromere Stabilize Dicentric Chromosomes

BACKGROUNDnThe kinetochore is a multiprotein complex that forms on a chromosomal locus designated as the centromere, which links the chromosome to the spindle during mitosis and meiosis. Most eukaryotes, with the exception of holocentric species, have a single distinct centromere per chromosome, and the presence of multiple centromeres on a single chromosome is predicted to cause breakage and/or loss of that chromosome. However, some stably maintained non-Robertsonian translocated chromosomes have been reported, suggesting that the excessive centromeres are inactivated by an as yet undetermined mechanism.nnnRESULTSnWe have developed systems to generate dicentric chromosomes containing two centromeres by fusing two chromosomes in fission yeast. Although the majority of cells harboring the artificial dicentric chromosome are arrested with elongated cell morphology in a manner dependent on the DNA structure checkpoint genes, a portion of the cells survive by converting the dicentric chromosome into a stable functional monocentric chromosome; either centromere was inactivated epigenetically or by DNA rearrangement. Mutations compromising kinetochore formation increased the frequency of epigenetic centromere inactivation. The inactivated centromere is occupied by heterochromatin and frequently reactivated in heterochromatin- or histone deacetylase-deficient mutants.nnnCONCLUSIONSnChromosomes with multiple centromeres are stabilized by epigenetic centromere inactivation, which is initiated by kinetochore disassembly. Consequent heterochromatinization and histone deacetylation expanding from pericentric repeats to the central domain prevent reactivation of the inactivated centromere.

A large number of tRNA genes are symmetrically located in fission yeast centromeres

We report here that the fission yeast centromere regions in the three chromosomes contain no less than 36 symmetrically arranged tRNA-coding sequences, and many of them are located within the inner inverted regions that are thought to be essential for the centromere function. There are 11 different species of tRNA-coding sequences, and four of them are identical to those previously known in this organism. This high-density distribution of tRNA genes in the centromere regions is surprising, as the fission yeast centromeres were thought to form transcriptionally inactive structures.

An interactive gene network for securin-separase, condensin, cohesin, Dis1/Mtc1 and histones constructed by mass transformation

The small genome of fission yeast Schizosaccharomyces pombe contains 4824 predicted genes and gene disruption suggests that ∼850 are essential for viability. To obtain information on interactions among genes required for chromosome segregation, an approach called Strategy B was taken using mass transformation of the 1015 temperature‐sensitive (ts) mutants that were made by random mutagenesis and transformed by plasmids carrying the genes for securin, separase, condensin, cohesin, kinetochore microtubule‐binding proteins Dis1/Mtc1 or histones. Mutant strains whose phenotypes were either suppressed or inhibited by plasmids were selected. Each plasmid interacted positively or negatively with the average 14 strains. Identification of the mutant gene products by cloning revealed many hitherto unknown interactions. The interactive networks of segregation therefore may consist of genes with a variety of functions. For example, separase/Cut1 interacts with Cdc48/p97/VCP, which stabilizes securin and separase. Surprisingly, S. pombe cdc48 mutants displayed the mitotic phenotype highly similar to separase/cut1 mutants. This approach also provides a novel way of mutant isolation, resulting in two histone H2B strains and a cohesion mutant with a new phenotype.