Bir1/Cut17 moving from chromosome to spindle upon the loss of cohesion is required for condensation, spindle elongation and repair.

BACKGROUND: In mammals, proteins containing BIR domains (IAPs and survivin) are implicated in inhibiting apoptosis and sister chromatid separation. In the nematode, Bir1 is required for a proper localization of aurora kinase, which moves from the mitotic chromosome in metaphase to the spindle midzone in anaphase as a passenger. Fission yeast Bir1/Pbh1 is essential for normal mitosis. RESULTS: A temperature sensitive mutant cut17-275 exhibits the defect in condensation and spindle elongation at 36 degrees C, while securin is degraded. Gene cloning shows that the cut17+ gene is identical to bir1+/pbh1+. At 26 degrees C, cut17-275 is UV sensitive as the repair of DNA damage is severely compromised. Bir1/Cut17 is a nuclear protein in interphase, which is then required for recruiting condensin to the mitotic nucleus, and concentrates to form a discrete number of dots from prometaphase to metaphase. Once the chromatids are separated, Bir1/Cut17 no longer binds to kinetochores and instead moves to the middle of spindle. Chromatin immunoprecipitation suggested that Bir1/Cut17 associates with the outer repetitious centromere region in metaphase. Following the initiation of anaphase the protein switches from being a chromosomal protein to a spindle protein. This transit is stringently regulated by the state of sister chromatid cohesion proteins Mis4 and Rad21. Ark1, is an aurora kinase homologue whose mitotic distribution is identical to, and under the control of Bir1/Cut17. CONCLUSIONS: Bir1/Cut17 and Ark1 act as "passengers" but they may play a main role as a recruitment factor, essential for condensation, spindle elongation and DNA repair. Bir1/Cut17 should have roles both in mitotic and in interphase chromosome. The proper location of Ark1 requires Bir1/Cut17, and the mitotic localization of Bir1/Cut17 requires sister cohesion.

Time course analysis of precocious separation of sister centromeres in budding yeast: continuously separated or frequently reassociated?

BACKGROUND: Sister kinetochores are bioriented toward the spindle poles in eukaryotic metaphase before chromosome segregation. In the budding yeast Saccharomyces cerevisiae, sister centromeres/kinetochores are separated in the early spindle, while the sister arms remain associated. Biorientation is thought to be established in this organism with precocious separation of sister centromeres in early stages of the cell cycle. It is not, however, settled whether this pre-anaphase separation is continuous or only transient and whether the transient separation has any physiological significance. RESULTS: Time-lapse observation of the behaviour of budding yeast centromeres in living cells was performed using GFP alone or in combination with CFP marking. Sixty-three per cent of the cell population showed permanent separation of centromeres for a long period of time from the small-budded stage to the onset of anaphase in the single-colour GFP-CEN construct. The remaining cell population (6 of 16) showed brief apparent reassociation of centromere signals before anaphase, but the frequency of the association was very low. In a time-lapse observation of the double-colour marked cells by GFP-CEN and CFP-SPB (the spindle pole body), the continuous separation of sister centromeres in the short medial spindle was firmly established. CONCLUSIONS: In the budding yeast, once sister centromeres separate, they rarely reassociate in pre-anaphase. Sister centromere cohesion at this stage appears to be irrelevant for normal chromosome segregation. Whether abundant cohesin in the centromere regions has any role in anaphase remains to be determined.

M phase-specific kinetochore proteins in fission yeast: microtubule-associating Dis1 and Mtc1 display rapid separation and segregation during anaphase.

BACKGROUND: Kinetochore microtubules are made early in mitosis and link chromosomal kinetochores to the spindle poles. They are required later to move the separated sister chromatids toward the opposite poles upon the onset of anaphase. Very little is known about proteins that are responsible for the connection between kinetochores and mitotic microtubules. RESULTS: We here show that fission yeast Dis1 and the related protein Mtc1/Alp14 are both able to bind microtubules in vitro and share an essential function for viability in vivo. The deletion of mtc1+ results in an instability of cytoplasmic microtubules that can be suppressed by the ectopic expression of dis1+. Dis1 and Mtc1 are localized along interphase cytoplasmic microtubules and are mobilized onto the spindle upon mitotic commitment. In chromatin immunoprecipitation (CHIP) experiments Dis1 coprecipitated with the central centromeric DNA in an M phase-specific manner. Consistently, observations of both living cells in which the native, genomic copy of dis1+ tagged with GFP and cells fixed by immunostaining established that Dis1 behaves as a kinetochore protein during the progression from metaphase to anaphase. The central and C-terminal regions of Dis1 are sufficient for interactions with microtubules and the kinetochore, respectively. In anaphase, the GFP signals of both Dis1 and Mtc1 suddenly separate and move quickly toward opposite spindle poles. CONCLUSIONS: Fission yeast Dis1 and Mtc1 are members of an evolutionarily conserved microtubule binding protein family that includes frog XMAP215. Dis1 and Mtc1 are implicated in stabilizing kinetochore microtubules in metaphase and so counteract the action of microtubule destabilizing factors that dominate in anaphase. Dis1 may play a dual role by becoming a part of the kinetochores in an M phase-specific manner, and it may possibly generate connections between kinetochores and microtubules.

Fission yeast living mitosis visualized by GFP-tagged gene products.

The fission yeast Schizosaccharomyces pombe has been used as a model organism to study cell cycle control and dynamic chromosome behavior during anaphase segregation as genetic and cytological approaches are easily amenable. To understand the role of gene products involved in these cellular events, it is important to determine intracellular localization of each gene product during the cell cycle. In this article, visualization in living cells of several gene products involved in cell cycle control and sister chromatid separation is described. The genes tagged with jellyfish green fluorescent protein (GFP) include sad1(+) (encoding a spindle pole body (SPB) protein), atb2(+) (alpha-tubulin), mis6(+) (a kinetochore protein), eat1(+) (a novel actin-like protein localized in the nucleus) and cdc13(+) (a mitotic cyclin). In addition, LacI which is bound to a DNA segment containing LacO repeat sequences integrated near the centromere (cen1) is visualized. These are useful to monitor cell cycle events in living cells.

Establishing biorientation occurs with precocious separation of the sister kinetochores, but not the arms, in the early spindle of budding yeast.

Sister kinetochores are bioriented toward the spindle poles in higher eukaryotic prometaphase before chromosome segregation. We show that, in budding yeast, the sister kinetochores are separated in the very early spindle, while the sister arms remain associated. Biorientation of the separated kinetochores is achieved already after replication. Mtw1p, a homolog of fission yeast Mis12 required for biorientation, locates at the centromeres in an Ndc10p-dependent manner. Mtw1p and the sequences 1.8 and 3.8 kb from CEN3 and CEN15, respectively, behave like the precociously separated kinetochores, whereas the sequences 23 and 35 kb distant from CEN3 and CEN5 previously used as the centromere markers behave like a part of the arm. Mtw1p and Ndc10p are identically located except for additional spindle localization of Ndc10p. A model explaining small centromeres and early spindle formation in budding yeast is proposed.

Proper metaphase spindle length is determined by centromere proteins Mis12 and Mis6 required for faithful chromosome segregation.

High-fidelity chromosome transmission is fundamental in controlling the quality of the cell division cycle. The spindle pole-to-pole distance remains constant from metaphase to anaphase A. We show that fission yeast sister centromere-connecting proteins, Mis6 and Mis12, are required for correct spindle morphogenesis, determining metaphase spindle length. Thirty-five to sixty percent extension of metaphase spindle length takes place in mis6 and mis12 mutants. This may be due to incorrect spindle morphogenesis containing impaired sister centromeres or force unbalance between pulling by the linked sister kinetochores and kinetochore-independent pushing. The mutant spindle fully extends in anaphase, although it is accompanied by drastic missegregation by aberrant sister centromere separation. Hence, metaphase spindle length may be crucial for segregation fidelity. Suppressors of mis12 partly restore normal metaphase spindle length. In mis4 that is defective in sister chromatid cohesion, metaphase spindle length is also long, but anaphase spindle extension is blocked, probably due to the activated spindle checkpoint. Extensive missegregation is caused in mis12 only when Mis12 is inactivated from the previous M through to the following M, an effective way to avoid missegregation in the cell cycle. Mis12 has conserved homologs in budding yeast and filamentous fungi.