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© The Rockefeller University Press,
0021-9525/2001//669 $5.00
The Journal of Cell Biology, Volume 152, Number 4,
, 2001 669-682
Original Article |
Drosophila Aurora B Kinase Is Required for Histone H3 Phosphorylation and Condensin Recruitment during Chromosome Condensation and to Organize the Central Spindle during Cytokinesis
dmg25{at}mole.bio.cam.ac.uk
Aurora/Ipl1-related kinases are a conserved family of enzymes that have multiple functions during mitotic progression. Although it has been possible to use conventional genetic analysis to dissect the function of aurora, the founding family member in Drosophila (Glover, D.M., M.H. Leibowitz, D.A. McLean, and H. Parry. 1995. Cell. 81:95–105), the lack of mutations in a second aurora-like kinase gene, aurora B, precluded this approach. We now show that depleting Aurora B kinase using double-stranded RNA interference in cultured Drosophila cells results in polyploidy. aurora B encodes a passenger protein that associates first with condensing chromatin, concentrates at centromeres, and then relocates onto the central spindle at anaphase. Cells depleted of the Aurora B kinase show only partial chromosome condensation at mitosis. This is associated with a reduction in levels of the serine 10 phosphorylated form of histone H3 and a failure to recruit the Barren condensin protein onto chromosomes. These defects are associated with abnormal segregation resulting from lagging chromatids and extensive chromatin bridging at anaphase, similar to the phenotype of barren mutants (Bhat, M.A., A.V. Philp, D.M. Glover, and H.J. Bellen. 1996. Cell. 87:1103–1114.). The majority of treated cells also fail to undertake cytokinesis and show a reduced density of microtubules in the central region of the spindle. This is accompanied by a failure to correctly localize the Pavarotti kinesin-like protein, essential for this process. We discuss these conserved functions of Aurora B kinase in chromosome transmission and cytokinesis.
Key Words: Aurora B kinase • chromosome condensation • phospho-histone H3 • barren • cytokinesis
© 2001 The Rockefeller University Press
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Introduction |
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The Aurora- and Ipl1-like protein kinases form a conserved family of enzymes, the founding members of which are encoded by the S. cerevisiae and Drosophila genes, IPL1 and aurora, respectively (Francisco and Chan 1994; Glover et al. 1995; for review see Giet and Prigent 1999). While the yeast genome encodes only one such kinase required for accurate chromosome segregation, metazoan genomes have at least two subfamilies of aurora-like kinases. One is associated with centrosomes and is activated in early mitosis, and a second is associated with chromosomes and the spindle midbody and is activated later. We will refer to these families as Aurora-like kinases A and B, respectively, as recently suggested by Nigg 2001. The precise effects of loss of function of either of these enzymes varies a little between different organisms and cell types. Broadly speaking, however, the A-type enzymes are required to maintain the separation of centrosomes to give normal bipolar spindle structure. This is shown, for example, in Drosophila from the phenotype of aurora mutants (which we now propose to call aurora A; Glover et al. 1995); or in Xenopus, where the corresponding pEg2 kinase can be eliminated using antibodies or inactive mutants (Roghi et al. 1998; Giet and Prigent 2000). The B-type Aurora-like kinases, on the other hand, appear to be required for cytokinesis, as shown, for example, by transfection of an inactive kinase mutant into cultured mammalian cells (Tatsuka et al. 1998; Terada et al. 1998). An affect on cytokinesis has also been reported in mutants of the gene for the C. elegans B-type enzyme, Air-2, or after RNA interference (RNAi)1 (Schumacher et al. 1998; Kaitna et al. 2000; Severson et al. 2000). The air-2 encoded kinase is required for the positioning of Zen-4, a kinesin-like protein required at the midzone of the late central spindle for cytokinesis. Abnormal chromosome segregation is also observed after reduction of air-2 function.
The dynamics of the localization of the Aurora B class of enzymes can be partially explained by recent findings showing they exist in a complex with an inner centromere protein (INCENP) (Adams et al. 2000; Kaitna et al. 2000). INCENPs are one example of so-called "passenger proteins" that localize to the centromeric regions of chromosomes at metaphase and are then redistributed to the central spindle during cytokinesis. Defects in INCENP function lead to failure of chromosome congression and cytokinesis defects (Mackay et al. 1998). These findings, and the fact that B-type Aurora kinase becomes incorrectly localized in human cells expressing mutant INCENPs that fail to localize, has led to the idea that INCENP functions to target the B-type kinases, first to chromosomes and then to the spindle midzone (Adams et al. 2000). A physical interaction is also seen between the Air-2 kinase and the counterpart of INCENP in C. elegans, ICP-1. Moreover, the disruption of icp-1 function by RNAi leads to the same phenotype as air-2 RNAi (Kaitna et al. 2000). This direct functional interaction between the Aurora-like kinases and INCENP occurs not only in metazoan cells, but also in budding yeast where the counterpart of INCENP, Sli15p, was identified through a screen for genes that interact with Ipl1 (Kim et al. 1999).
Although a B-type Aurora kinase gene has been identified in Drosophila, the lack of mutants at this locus has prevented any analysis of its potential mitotic function (Reich et al. 1999). In this paper we report that levels of the Aurora B kinase can be reduced by RNAi in cultured Drosophila S2 cells. This leads to cytokinesis failure, together with chromosome condensation and segregation defects strikingly similar to those we have described previously for mutations in the condensin gene barren (Bhat et al. 1996). The segregation defects are accompanied by aberrant chromatin condensation, a reduction in the phosphorylated form of histone H3, and a failure to recruit the Barren protein onto condensed chromosomes.
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Materials and Methods |
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Double-stranded RNA Synthesis
The aurora B cDNA was amplified by PCR from a testis cDNA library (Hazelrigg and Tu 1994) using the primers 5'-CAGAATTCCGCCATGACGCTTTCCCGCGCG-3' containing the EcoRI site, and 5'-CAAAAGCTTCCTGGCCGTGTTCTCCTTGCC-3' containing the HindIII site. The PCR amplification product was cloned into pGEMt easy vector (Promega). The clones containing the opposite orientations were selected, mixed in equal proportions, and digested by SpeI. The digested plasmids were used to produce double-stranded RNA (dsRNA) using Megascript T7 transcription kit (Ambion). The RNA was purified according to the manufacturer's instructions, denaturated for 5 min at 94°C, and annealed overnight by a slow cooling. dsRNA was analyzed by 1% electrophoresis in agarose gel to ensure that the RNA migrated as a single band (
1 kb).
Condition for RNAi in S2 Cultured Cells
RNAi was carried out using a modification of the method of Clemens (2000). Cells were inoculated the day before transfection into 6-well plates. For RNAi, the cells were washed three times with medium without serum and antibiotics and transfected with Transfast lipid reagent (Promega) according to the manufacturer's instructions. 3.3 µg was used to transfect each well plate. Cells were incubated for 3 d to allow the turnover of the aurora B protein kinase. Using these conditions, effects on cell cycle progression could first be seen 2 d after transfection. Samples were taken at various times after transfection and analyzed by FACS®, Western blot, or immunofluorescence.
Antibodies and Western Blotting
The rat antitubulin antibody (clone YL1/2) was obtained from Sigma-Aldrich and the antiphospho-histone H3 from Upstate Biotechnology. Rabbit anticyclin B (Rb271), antibarren, and antipavarotti (Rb3301) have been described previously (Whitfield et al. 1990; Bhat et al. 1996; Adams et al. 1998). Anti-Prod antibody (Torok et al. 1997) was given to us by Peter Bryant (University of California at Irvine, Irvine, CA). FITC- or Texas red–conjugated goat anti–rat, or anti–rabbit, secondary antibodies used in immunofluorescence were obtained from Jackson ImmunoResearch Laboratories. Alkaline phosphatase–conjugated goat anti–rabbit or anti–rat antibodies used in Western blotting were from Sigma-Aldrich. To produce antibodies against Aurora B, the 15 COOH-terminal amino acids of the aurora B protein kinase (QLKQKRDRGKENTARN) were coupled to keyhole limpit hemocyanin and injected into rabbits. After three boosts, the serum was purified by affinity chromatography using a recombinant histidine-tagged protein blotted on a nitrocellulose membrane as described previously (Giet et al. 1999). Recombinant AurB-his6 was produced by first cloning PCR product into pGEM, and then subcloning it into pET23b. Protein was isolated from inclusion bodies of bacteria expressing the kinase from pET23b by resuspension in 8 M urea, followed by dialysis in PBS. The antibody was used at a concentration of 100 ng/ml. In peptide competition experiments, the peptide concentration was 10 µg/ml.
Immunofluorescence Analysis
S2 cells grown on glass coverslips were fixed in PHEM buffer (60 mM Pipes, 25 mM Hepes, pH 6.8, 10 mM EGTA, 4 mM MgCl2). The cells were permeabilized using PBST (PBS containing 0.1% Triton X-100). All incubations were performed in PBST containing 1% BSA. DNA was stained by TOTO3-iodide (Molecular Probes) or propidium iodide. Vectashield mounting medium H-1000 was purchased from Vector Laboratories. Images were acquired using a confocal scanning head (model 1024; Bio-Rad Laboratories) mounted on an Optiphot microscope (Nikon) and prepared for publication using Adobe Photoshop®.
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40 kD in Western blots of extracts of S2 cells that is greatly reduced when cells are treated with the aurora B dsRNA (see Fig. 2 C, middle). This staining, together with the immunostaining of mitotic cells (see below), can be competed out by the peptide used to raise the antibody (Fig. 1G and Fig. H). Aurora B cannot be detected by this antibody in interphase cells (Fig. 1 A), but it is readily apparent with a punctate distribution throughout all regions of condensing chromosomes in prophase cells (Fig. 1 B). By metaphase, the concentration of the protein has strongly increased in the centromeric regions (Fig. 1 C). Some of this centromeric staining persists in early anaphase, at which time the enzyme appears to become relocated on the central region of the spindle (Fig. 1 D). During anaphase B, when the poles start to move apart, labeling of the central spindle has become predominant (Fig. 1 E) and the enzyme is essentially confined to the midbody during cytokinesis (Fig. 1 F). Proteins showing this dynamic pattern of localization during mitosis have been termed "passengers"; they ride upon the chromosomes until metaphase, whereupon they alight to the platform of the central spindle.
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90% after aurB RNAi, amounts of total cellular protein appear unchanged, as do levels of 
-tubulin or the mitotically labile protein cyclin B (Fig. 2 C). This suggests that the cells are capable of progressing through S phase, but that defects occur in either or both chromosome segregation at mitosis or during cytokinesis.
Defects in Chromosome Segregation and Cytokinesis Occur in Multiple Cycles after aurora B RNAi
To assess the nature of the defects in cell cycle progression, we stained cells to reveal DNA and microtubules and quantified defects in the mitotic cells within the asynchronous population 3 d after treatment with aurB dsRNA. Whereas >90% of control interphase cells appear to have normal DNA content, as judged by the size of their nuclei, 70% of cells become polyploid after aurB RNAi, in agreement with the results reported above. Of these, 19% had a single abnormally large nucleus and 52% were multinucleate. The mitotic index of the population of aurB dsRNA–treated cells (5%) was not significantly different from control cells, indicating that in spite of the mitotic defects, cell cycle progression was not affected. Within the population of aurB RNAi cells a proportion of cells showed mitotic figures comparable to control cells (Fig. 3, A–D). However, the proportion of these cells undergoing apparently normal mitosis was greatly reduced (Table ). These apparently normal cells may not have taken up the dsRNA and their proportion relative to abnormal mitoses is comparable to the reduction in level of Aurora B kinase detected by Western blotting. Examples of the mitotic defects seen in the aurB RNAi cells are shown in Fig. 3E–N. The most striking feature is that incomplete chromosome condensation is seen in essentially all of these mitotic cells, albeit to varying extents. No obvious defects were detected at the spindle poles in prophase (Fig. 3E and Fig. J) and microtubules are well nucleated by the centrosomes at this and other mitotic stages. The prophase cell in Fig. 3 J has eight centrosomes, suggesting this is a 16N cell that has failed the two previous rounds of cytokinesis. There were also failures in the alignment of chromosomes on the metaphase plate. This feature is very clear in the cell in Fig. 3 F (arrows), but is also apparent in the cell in Fig. 3 K in which the majority of chromatin is on the metaphase plate. The extent to which chromatin can segregate to the spindle poles at anaphase varies dramatically, from situations in which there appear to be lagging chromatids, to cases in which massive chromatin bridges are formed (Fig. 3G and Fig. M). Such bridges fail to resolve at telophase (Fig. 3 I) and are presumably one means by which cells can arise that have a single polyploid nucleus. In other cases, lagging chromatids fail to resolve and will eventually form micronuclei, and cytokinesis appears to be blocked (Fig. 3 N). The proportion of binucleate cells at these late mitotic stages is elevated 15-fold over control cells. The density of microtubules in the central region of the mitotic spindle in these cells appears much lower than in control cells able to undergo cytokinesis (see below). Thus, defects in chromosome condensation after aurB RNAi are accompanied with abnormalities in chromosome segregation and failure of cytokinesis. Interestingly, the cells are not subject to checkpoint arrest and are able to undertake at least two to three rounds of polyploidization within the time frame of the experiment.
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The Aurora B enzyme becomes perfectly positioned to execute these processes as mitosis proceeds. It is distributed throughout the chromatin as it condenses at prophase, then becomes concentrated around the centromeric regions of the condensed chromosomes at metaphase, and finally leaves for the company of the central spindle region during anaphase. As such it behaves as a so-called passenger protein. It appears from recent studies to be in an intimate relationship with a travelling companion INCENP (Adams et al. 2000; Kaitna et al. 2000). The interaction of INCENP, or its yeast counterpart Sli5p, with Aurora-like kinases in yeast, C. elegans, and Xenopus suggests that this interaction is universal. The dynamic association of INCENP with chromosome arms at prometaphase, the centromeric region at metaphase, and then the spindle midzone at anaphase makes it an attractive candidate for targeting the Aurora B kinase to these regions. Indeed, dominant mutants of INCENP in human cells disrupt the localization of the Aurora B–like kinase AIL2 (Adams et al. 2000). The finding of abnormal chromosome segregation and cytokinesis after depletion of either the C. elegans INCENP, Icp-1, or its Aurora B–like kinase, Air-2, suggests the two passengers are about similar business (Schumacher et al. 1998; Woolard and Hodgekin 1999; Kaitna et al. 2000).
One striking effect of aurB RNAi is to permit progression through mitosis with improperly condensed chromosomes. We are able to account for these condensation defects by a diminution of the phosphorylation of serine 10 of histone H3 and a failure to localize condensin on the chromosomes. The former finding is consistent with several studies that now implicate a requirement for the phosphorylation of the NH2-terminal region of histone H3 at this residue for chromosome condensation. Not only does the formation of mitotic chromosomes in a Xenopus cell-free extract by a nucleosome-associated kinase correlate with histone H3 phosphorylation (de la Barre et al. 2000), but when the serine 10 residue is mutated to alanine it results in abnormal segregation and chromosome loss during mitosis and meiosis in Tetrahymena (Wei et al. 1999). One enzyme credited with the ability to phosphorylate histone H3 at mitosis is the NIMA kinase of Aspergillus (De Souza et al. 2000). However, our finding that levels of histone H3 phosphorylation are reduced after aurB RNAi in Drosophila cells is more in keeping with the report that the Aurora-like kinase homologues, Ipl1 of yeast and Air-2 (but not Air-1) of C. elegans, are required for histone H3 phosphorylation in these organisms (Hsu et al. 2000). The finding of some residual histone H3 phosphorylation either could reflect the incomplete elimination of Aurora B by RNAi, or could indicate that an alternative kinase has this capability, offering an explanation of the partial chromosome condensation seen in the RNAi-treated cells. Our current data are important in emphasizing the importance of histone H3 phosphorylation for chromosome transmission and as such are in line with the findings in Tetrahymena. This differs from the effects seen in budding yeast cells that continue through division cycles in the absence of histone H3 phosphorylation without showing defects in chromosome transmission. As an explanation, it has been suggested that other histones could be phosphorylated in addition to the histone H3 in the yeast cell and that such phosphorylation events could be sufficient to ensure normal chromosome dynamics. A major role of the yeast enzyme Ipl1p is to regulate the function of the kinetochore-associated protein Ndc10p through its phosphorylation (Biggins et al. 1999; Sassoon et al. 1999). Therefore, the increase in ploidy reported in ipl1 mutant cells has been attributed more to inappropriate kinetochore function, and consequently the effects of Air-2 depletion upon chromosome condensation in C. elegans have been a little overshadowed. It seems likely that the abnormal chromosome segregation in Drosophila cells after aurB RNAi is due to incomplete condensation, since a similar phenotype is seen in mutants of the condensin subunit Barren (Bhat et al. 1996). Of course, this does not exclude the possibility that defects in the organization of the centromeric regions and kinetochores arise directly as a result of aurB RNAi or as either a direct or indirect consequence of condensation defects. The increase in ploidy seen after aurora B RNAi is reminiscent of the Ipl1 phenotype in budding yeast, but differs in that it arises from both chromosome segregation and cytokinesis defects.
The resemblance of the mitotic phenotype of cells after RNAi with aurB to that previously reported for Drosophila barren mutants (Bhat et al. 1996) can be further explained by the failure of Barren protein to be recruited to the mitotic chromosomes after aurB RNAi. Originally recognized through this mutant defect, it was later realized that Barren is the fly homologue of a member of the pentameric complex, condensin, first shown to be required for mitotic chromosome condensation in Xenopus (Hirano et al. 1997). It is possible that Barren or other members of the condensin complex could themselves be directly phosphorylated by Aurora B during chromosome condensation. However, the process seems likely to involve a plethora of phosphorylation events: the nuclear A-kinase anchoring protein (AKAP95) appears to target the human hCAP-D2 condensin to chromosomes (Collas et al. 1999; Steen et al. 2000) and phosphorylation of condensin subunits by cdk1 has been associated both with their nuclear accumulation and activation (Kimura et al. 1998; Sutani et al. 1999). It has been proposed that phosphorylation of the NH2 terminus of histone H3 leads to the recruitment or the activation of the condensin complex to the chromosome, where it can modify DNA topology. Our data indicate that phosphorylation of histone H3 by the Aurora B kinase and the localization of Barren onto chromosomes are associated events in mitosis. They support and extend a recent observation that human condensin proteins hCAP-E, hCAP-C, and hCAP-D2 colocalize with phosphorylated histone H3 in clusters in partially condensed regions of chromosomes in early prophase (Schmiesing et al. 2000). The similarity of the effects seen on chromosome condensation resulting from loss of either aurora B or barren function is striking and points to the value of studying these processes in a single model organism amenable to both genetic manipulation and RNAi. It is perhaps surprising that in both cases partial chromosome condensation is achieved and that there can be some degree of segregation of chromatin to the poles.
The second major mitotic abnormality that we observe after aurB RNAi in Drosophila cells is a failure of cytokinesis. Thus, like its mammalian and nematode counterparts AIM-1 and AIR-2, the enzyme encoded by aurora B appears essential for this process. Two proteins that play a role in cytokinesis have recently been shown to associate with the Aurora B–like kinases: INCENP, as discussed above (Adams et al. 2000; Kaitna et al. 2000), and the Zen-4 kinesin-like protein of C. elegans (Kaitna et al. 2000; Severson et al. 2000). The localization of the latter is disrupted after disruption of air-2 function using RNAi or conditional mutant alleles. Zen-4 is the C. elegans homologue of the Pavarotti KLP of Drosophila, which we now show likewise to be mislocalized on the central spindle from anaphase onwards after aurB RNAi. Pav-KLP also cooperates with Polo kinase to achieve its localization and function in Drosophila (Adams et al. 1998), suggesting that multiple mitotic kinases may be required to coordinate central spindle formation before cytokinesis, just as several kinases appear to be required for centrosome maturation and separation and chromosome condensation.
It is striking that aurB RNAi cells are not arrested by a mitotic checkpoint, given the abnormalities that they show in chromosome alignment at metaphase and the subsequent disorganization of the later mitotic spindle. However, the treated cells do undergo multiple cell cycles, as is clearly demonstrated in this cell culture system in which one can monitor the shift in ploidy by FACS® analysis and the increase in chromosome and centrosome complements by immunocytology. It is possible that these abnormalities arise too late in the mitotic cycle to trigger checkpoint arrest, although this seems unlikely for the chromosome segregation defect. Although it is possible that Aurora B is itself required for checkpoint functions, it could also be that the kinetochore regions of chromosomes are insufficiently well organized after aurB RNAi to promote the checkpoint activity of the complex of Bub/Mad proteins that associate with unaligned centromeres. It is noteworthy that the C. elegans baculovirus inhibitor of apoptosis (IAP)-related repeat protein Bir-1 appears to be required for the localization of Air-2. Bir-1 localizes to chromosomes and then the spindle midzone and Air-2 fails to localize to these same sites in the absence of Bir-1 (Speliotes et al. 2000). These IAP proteins, also known as survivin, are caspase inhibitors and as such counteract apoptosis (Li et al. 1998). Is it possible that B-type Aurora kinases might play a role alongside survivin in an apoptotic checkpoint to promote mitosis?
It is of considerable interest to know the multiple substrates of Aurora B kinase and to understand its mode of regulation in mitotic progression. It seems that subcellular localization of the enzyme could be one critical means of controlling access to its substrates. The enzyme localizes throughout condensing chromosomes when histone H3 is required to be phosphorylated. Its subsequent concentration at centromeres could direct enzyme activity towards specific chromosomal proteins at these sites, but may be instrumental in its movement onto the central spindle at anaphase, thereby providing an effective way of removing the enzyme from the chromatin to facilitate chromosome decondensation at telophase. Understanding the intricacies of these processes will be a future challenge.
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The work was supported by a Marie-Curie Research Fellowship from the European Commission to R. Giet and by a program grant from the Cancer Research Campaign.
Submitted: 1 November 2000
Revised: 22 December 2000
Accepted: 29 December 2000
1Abbreviations used in this paper: dsRNA, double-stranded RNA; INCENP, inner centromere protein; RNAi, RNA interference.
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