Helen Dodson

Centrosome amplification induced by DNA damage occurs during a prolonged G2 phase and involves ATM

Centrosomes are the principal microtubule organising centres in somatic cells. Abnormal centrosome number is common in tumours and occurs after γ‐irradiation and in cells with mutations in DNA repair genes. To investigate how DNA damage causes centrosome amplification, we examined cells that conditionally lack the Rad51 recombinase and thereby incur high levels of spontaneous DNA damage. Rad51‐deficient cells arrested in G2 phase and formed supernumerary functional centrosomes, as assessed by light and serial section electron microscopy. This centrosome amplification occurred without an additional DNA replication round and was not the result of cytokinesis failure. G2‐to‐M checkpoint over‐ride by caffeine or wortmannin treatment strongly reduced DNA damage‐induced centrosome amplification. Radiation‐induced centrosome amplification was potentiated by Rad54 disruption. Gene targeting of ATM reduced, but did not abrogate, centrosome amplification induced by DNA damage in both the Rad51 and Rad54 knockout models, demonstrating ATM‐dependent and ‐independent components of DNA damage‐inducible G2‐phase centrosome amplification. Our data suggest DNA damage‐induced centrosome amplification as a mechanism for ensuring death of cells that evade the DNA damage or spindle assembly checkpoints.

CENP-I is essential for centromere function in vertebrate cells.

We identified a novel essential centromere protein, CENP-I, which shows sequence similarity with fission yeast Mis6 protein, and we showed that CENP-I is a constitutive component of the centromere that colocalizes with CENP-A, -C, and -H throughout the cell cycle in vertebrate cells. To determine the precise function of CENP-I, we examined its role in centromere function by generating a conditional loss-of-function mutant in the chicken DT40 cell line. In the absence of CENP-I, cells arrested at prometaphase with misaligned chromosomes for long periods of time. Eventually, cells exited mitosis without undergoing cytokinesis. Immunocytochemical analysis of CENP-I-deficient cells demonstrated that both CENP-I and CENP-H are necessary for localization of CENP-C but not CENP-A to the centromere.

Aurora-B Phosphorylation in Vitro Identifies a Residue of Survivin That Is Essential for Its Localization and Binding to Inner Centromere Protein (INCENP) in Vivo

The chromosomal passengers, aurora-B kinase, inner centromere protein (INCENP), and survivin, are essential proteins that have been implicated in the regulation of metaphase chromosome alignment, spindle checkpoint function, and cytokinesis. All three share a common pattern of localization, and it was recently demonstrated that aurora-B, INCENP, and survivin are present in a complex in Xenopus eggs and Saccharomyces cerevisiae. The presence of aurora-B kinase in the complex and its ability to bind the other components directly suggest that INCENP and survivin could potentially be aurora-B substrates. This hypothesis was recently proven for INCENP in vitro. Here we report that human survivin is specifically phosphorylated in vitro by aurora-B kinase at threonine 117 in its carboxyl α-helical coil. Mutation of threonine 117 to alanine prevents survivin phosphorylation by aurora-B in vitro but does not alter its localization in HeLa cells. By contrast, a phospho-mimic, in which threonine 117 was mutated to glutamic acid, was unable to localize correctly at any stage in mitosis. Mutation at threonine 117 also prevented immunoprecipitation of INCENP with survivin in vivo. These data suggest that phosphorylation of survivin at threonine 117 by aurora-B may regulate targeting of survivin, and possibly the entire passenger complex, in mammals.

DNA damage induces Chk1-dependent centrosome amplification

Centrosomal abnormalities are frequently observed in cancers and in cells with defective DNA repair. Here, we used light and electron microscopy to show that DNA damage induces centrosome amplification, not fragmentation, in human cells. Caffeine abrogated this amplification in both ATM (ataxia telangiectasia, mutated)‐ and ATR (ATM and Rad3‐related)‐defective cells, indicating a complementary role for these DNA‐damage‐responsive kinases in promoting centrosome amplification. Inhibition of checkpoint kinase 1 (Chk1) by RNA‐mediated interference or drug treatment suppressed DNA‐damage‐induced centrosome amplification. Radiation‐induced centrosome amplification was abrogated in Chk1−/− DT40 cells, but occurred at normal levels in Chk1−/− cells transgenically expressing Chk1. Expression of kinase‐dead Chk1, or Chk1S345A, through which the phosphatidylinositol‐3‐kinase cannot signal, failed to restore centrosome amplification, showing that signalling to Chk1 and Chk1 catalytic activity are necessary to promote centrosome overduplication after DNA damage.

Analysis of Scc1-deficient cells defines a key metaphase role of vertebrate cohesin in linking sister kinetochores.

Cleavage of the cohesin subunit Scc1p/Mcd1p/Rad21 permits sister chromatid separation and is considered to trigger anaphase onset. It has also been suggested that the cohesin complex is essential for chromosome condensation and for assembling fully functional kinetochores. Here, we used vertebrate cells conditionally deficient in Scc1 to probe cohesin function in mitosis. Cells lacking cohesin arrest in prometaphase, with many chromosomes failing to align at a metaphase plate and high levels of the spindle assembly checkpoint protein, BubR1, at all kinetochores. We show that the structural integrity of chromosomes is normal in the absence of Scc1. Furthermore, specific inhibition of topoisomerase II, which is required for decatenation of replicated chromosomes, can bypass the cohesin requirement for metaphase chromosome alignment and spindle checkpoint silencing. Since the kinetochore effects of Scc1 deficiency can be compensated for by topoisomerase II inhibition, we conclude that Scc1 is not absolutely required for kinetochore assembly or function, and that its principal role in allowing the onset of anaphase is the establishment of sufficient inter‐sister tension to allow biorientation.

Involvement of centrosome amplification in radiation-induced mitotic catastrophe.

Cells exposed to ionising radiation die via different mechanisms, including apoptosis and mitotic catastrophe. To determine the frequency of mitotic catastrophe in tumour cells after irradiation, we used timelapse imaging to track centrin-1 and histone H2B in U2OS osteosarcoma cells. We observed a dose-dependent increase in the frequency of mitotic catastrophe after irradiation, although a consistent 30% of cell death occurred through mitotic failure at doses from 2- 10 Gy. One potential cause of mitotic catastrophe is centrosome amplification, which is induced by irradiation, and which can result in the formation of multipolar mitotic spindles. Up to 60% of mitotic catastrophes occurred in cells with >2 centrosomes after irradiation. We observed multipolar mitoses in p53+ and p53- tumour cells after irradiation and found that the spindle assembly checkpoint is active in multipolar mitotic cells. However, we did not detect active caspase-3 in multipolar mitoses. These data demonstrate that a significant proportion of cell death induced by ionising irradiation is through an apoptosis-independent mechanism involving centrosome amplification and mitotic catastrophe.

A Centrosome-autonomous Signal That Involves Centriole Disengagement Permits Centrosome Duplication in G2 Phase after DNA Damage

How centrosomes amplify after DNA damage is unclear. Cell fusions demonstrated that only irradiated centrosomes duplicate when fused with untreated partners, suggesting a licensing signal that does not move from one centrosome to another. Our data indicate that centriole disengagement occurs after irradiation, suggesting this as the signal.

Roles of vertebrate Smc5 in sister chromatid cohesion and homologous recombinational repair.

ABSTRACT The structural maintenance of chromosomes (Smc) family members Smc5 and Smc6 are both essential in budding and fission yeasts. Yeast smc5/6 mutants are hypersensitive to DNA damage, and Smc5/6 is recruited to HO-induced double-strand breaks (DSBs), facilitating intersister chromatid recombinational repair. To determine the role of the vertebrate Smc5/6 complex during the normal cell cycle, we generated an Smc5-deficient chicken DT40 cell line using gene targeting. Surprisingly, Smc5− cells were viable, although they proliferated more slowly than controls and showed mitotic abnormalities. Smc5-deficient cells were sensitive to methyl methanesulfonate and ionizing radiation (IR) and showed increased chromosome aberration levels upon irradiation. Formation and resolution of Rad51 and gamma-H2AX foci after irradiation were altered in Smc5 mutants, suggesting defects in homologous recombinational (HR) repair of DNA damage. Ku70−/− Smc5− cells were more sensitive to IR than either single mutant, with Rad54−/− Smc5− cells being no more sensitive than Rad54−/− cells, consistent with an HR function for the vertebrate Smc5/6 complex. Although gene targeting occurred at wild-type levels, recombinational repair of induced double-strand breaks was reduced in Smc5− cells. Smc5 loss increased sister chromatid exchanges and sister chromatid separation distances in mitotic chromosomes. We conclude that Smc5/6 regulates recombinational repair by ensuring appropriate sister chromatid cohesion.

Increased sister chromatid cohesion and DNA damage response factor localization at an enzyme-induced DNA double-strand break in vertebrate cells

The response to DNA damage in vertebrate cells involves successive recruitment of DNA signalling and repair factors. We used light microscopy to monitor the genetic dependencies of such localization to a single, induced DNA double strand break (DSB) in vertebrate cells. We used an inducible version of the rare-cutting I-SceI endonuclease to cut a chromosomally integrated I-SceI site beside a Tet operator array that was visualized by binding a Tet repressor-GFP fusion. Formation of γ-H2AX foci at a single DSB was independent of ATM or Ku70. ATM-deficient cells showed normal kinetics of 53Bp1 recruitment to DSBs, but Rad51 localization was retarded. 53Bp1 and Rad51 foci formation at a single DSB was greatly reduced in H2AX-null DT40 cells. We also observed decreased inter-sister chromatid distances after DSB induction, suggesting that cohesin loading at DSBs causes elevated sister chromatid cohesion. Loss of ATM reduced DSB-induced cohesion, consistent with cohesin being an ATM target in the DSB response. These data show that the same genetic pathways control how cells respond to single DSBs and to multiple lesions induced by whole-cell DNA damage.