Aurora B kinase activity–dependent and –independent functions of the chromosomal passenger complex in regulating sister chromatid cohesion

The chromosomal passenger complex (CPC) is a master regulator of mitosis. CPC consists of inner centromere protein (INCENP), Survivin, Borealin, and the kinase Aurora B and plays key roles in regulating kinetochore–microtubule attachments and spindle assembly checkpoint signaling. However, the role of CPC in sister chromatid cohesion, mediated by the cohesin complex, remains incompletely understood. Here, we show that Aurora B kinase activity contributes to centromeric cohesion protection partly through promoting kinetochore localization of the kinase Bub1. Interestingly, disrupting the interaction of INCENP with heterochromatin protein 1 (HP1) in HeLa cells selectively weakens cohesion at mitotic centromeres without detectably reducing the kinase activity of Aurora B. Thus, through this INCENP–HP1 interaction, the CPC also protects centromeric cohesion independently of Aurora B kinase activity. Moreover, the requirement for the INCENP–HP1 interaction in centromeric cohesion protection can be bypassed by tethering HP1 to centromeres or by depleting the cohesin release factor Wapl. We provide further evidence suggesting that the INCENP–HP1 interaction protects centromeric cohesion by promoting the centromere localization of Haspin, a protein kinase that antagonizes Wapl activity at centromeres. Taken together, this study identifies Aurora B kinase activity–dependent and –independent roles for the CPC in regulating centromeric cohesion during mitosis in human cells.


Edited by Xiao-Fan Wang
The chromosomal passenger complex (CPC) is a master regulator of mitosis. CPC consists of inner centromere protein (INCENP), Survivin, Borealin, and the kinase Aurora B and plays key roles in regulating kinetochore-microtubule attachments and spindle assembly checkpoint signaling. However, the role of CPC in sister chromatid cohesion, mediated by the cohesin complex, remains incompletely understood. Here, we show that Aurora B kinase activity contributes to centromeric cohesion protection partly through promoting kinetochore localization of the kinase Bub1. Interestingly, disrupting the interaction of INCENP with heterochromatin protein 1 (HP1) in HeLa cells selectively weakens cohesion at mitotic centromeres without detectably reducing the kinase activity of Aurora B. Thus, through this INCENP-HP1 interaction, the CPC also protects centromeric cohesion independently of Aurora B kinase activity. Moreover, the requirement for the INCENP-HP1 interaction in centromeric cohesion protection can be bypassed by tethering HP1 to centromeres or by depleting the cohesin release factor Wapl. We provide further evidence suggesting that the INCENP-HP1 interaction protects centromeric cohesion by promoting the centromere localization of Haspin, a protein kinase that antagonizes Wapl activity at centromeres. Taken together, this study identifies Aurora B kinase activitydependent and -independent roles for the CPC in regulating centromeric cohesion during mitosis in human cells.
Chromosomal instability resulting from chromosome missegregation during mitosis is a hallmark of cancer cells and contributes to tumorigenesis (1,2). The fidelity of chromosome segregation is guaranteed by a sophisticated mecha-nism that ensures timely resolution of sister chromatid cohesion, correct attachment of kinetochores to microtubules, and proper response of spindle assembly checkpoint (SAC) 3 monitoring the status of kinetochore-microtubule (KT-MT) attachments, which allows chromosome segregation only when all chromosomes have completed biorientation on the metaphase plate (3).
The chromosomal passenger complex (CPC) is a master regulator of mitosis (4). The CPC consists of the kinase subunit Aurora B, the scaffold subunit inner centromere protein (INCENP), and the two regulatory subunits Survivin and Borealin. These proteins play specific roles in controlling the localization and function of the CPC. During early mitosis, Survivin and Borealin associate with the N-terminal CEN domain of INCENP and mediate the centromeric localization of CPC by directly binding to phosphorylated histone tails (5)(6)(7). The C terminus of INCENP binds to Aurora B through an IN-box domain, leading to allosteric activation of Aurora B (8 -11). Heterochromatin protein 1 (HP1), which binds to INCENP or Borealin and is distributed along with the CPC to various locations throughout mitosis, can be considered the fifth subunit of the CPC. However, the functional significance of HP1 in the CPC remains incompletely understood.
Aurora B kinase activity plays a key role in the correction of erroneousKT-MTattachments.AuroraB-mediatedphosphorylation of multiple kinetochore substrates in the KMN network, which consists of the KNL1, Mis12, and Ndc80 complexes, has been implicated in releasing incorrect attachments (12)(13)(14)(15). Aurora B kinase is also required for SAC activation. This is achieved both through releasing improperly attached microtubules to generate unattached kinetochore and through phosphorylating substrates in the kinetochore to directly or indirectly recruit spindle checkpoint proteins (16). Compared with these well-established functions, the exact role of the CPC in the regulation of sister chromatid cohesion is unclear.
Sister chromatid cohesion is mediated by a multiple-subunit cohesin complex composed of Smc1, Smc3, Scc1, SA2 (or SA1), and the accessory subunit Pds5B (or Pds5A) (17). Sororin and Wapl competitively interact with Pds5A/B to positively and negatively regulate the association of cohesin with chromatin, respectively (18 -22). Through antagonizing Wapl activity in cohesin release, Sororin ensures DNA replication-dependent sister chromatid cohesion and its maintenance in the subsequent G 2 phase (22)(23)(24). During early mitosis, although cohesin at centromeres is protected by a complex mechanism involving the Wapl antagonists Sgo1, Sororin, and Haspin until the proteolytic cleavage of Scc1 by the protease Separase at anaphase onset (25), most cohesin is removed by Wapl from chromosome arms in a cleavage-independent manner (18, 19, 26 -28). This prophase pathway of cohesin removal requires phosphorylation of SA2 (29 -31) and Sororin (22,32). Phosphorylation of Sororin by Cyclin-dependent kinase 1 and Aurora B destabilizes its interaction with Pds5A/B and causes Wapl activation and cohesin release (33), enabling the resolution of chromosome arms in prophase and prometaphase. Therefore, Aurora B kinase activity negatively regulates sister chromatid cohesion along the chromosome arms in early mitosis.
In this study, we report that Aurora B kinase activity positively regulates sister chromatid cohesion at mitotic centromeres at least partly through promoting the kinetochore localization of Bub1 in human cells. Importantly, through the interaction of its INCENP subunit with HP1, the CPC also plays an Aurora B kinase activity-independent role in the protection of centromeric cohesion.

Inhibiting Aurora B kinase activity causes centromeric cohesion defects, which can be rescued by centromere-tethered Bub1
To dissect the role of CPC in the regulation of sister chromatid cohesion, we depleted its scaffold subunit INCENP by small interfering RNA (siRNA) and analyzed chromosomes prepared from HeLa cells that were arrested in mitosis with the microtubule destabilizer nocodazole. Immunofluorescence microscopy showed that the average interkinetochore (inter-KT) distance on chromosomes prepared from INCENP-depleted cells was 23% further apart than the control (Fig. 1, A and B), which is indicative of weakened centromeric cohesion. Similarly, inhibition of Aurora B kinase activity by the small-molecule inhibitor Hesperadin (34), as evidenced by loss of H3 serine 10 phosphorylation (H3-pS10) on chromatin (35), significantly increased the inter-KT distance (Fig. S1, A and B). As previously shown (28), we also noticed that Aurora B inhibition impaired the resolution of chromosome arms in nocodazole-arrested mitotic cells (Fig. S1A). These results indicate that, in contrast to its role in releasing cohesin from chromosome arms, Aurora B kinase activity is required to protect proper strength of sister chromatid cohesion at mitotic centromeres.
We also found that inhibition of Aurora B kinase activity by Hesperadin and ZM447439 (Fig. S1C), another small-molecule inhibitor of Aurora B kinase (36), significantly reduced the centromeric localization of Sgo1 (Fig. 1, C and D). Consistently, Aurora B inhibition caused a strong reduction in the kinetochore localization of Bub1 kinase (Fig. 1, E and F) as well as Bub1-mediated phosphorylation of histone H2A at threonine 120 (H2A-pT120) (Fig. 1, G and H) (37), which is a direct binding site for Sgo1 at mitotic centromeres (38,39). We therefore speculated that Aurora B kinase activity ensures full enrichment of Sgo1 at mitotic centromeres at least partly through promoting the kinetochore localization of Bub1 kinase. To test this hypothesis, we expressed a CENP-B (CB) fusion protein, CB-Bub1-K-GFP, in which Bub1 kinase domain is fused to the centromeric targeting domain of CENP-B (40,41), which binds a 17-bp CENP-B-box motif within the ␣-satellite repeats of human centromeres (42)(43)(44). As expected, treatment of cells stably expressing CB-GFP with Hesperadin caused strong delocalization of Sgo1 from mitotic centromeres (Fig. 1, I and J). Interestingly, centromeric localization of Sgo1 was largely retained when cells stably expressing CB-Bub1-K-GFP were treated with Hesperadin, consistent with the role of Bub1-mediated H2A-pT120 in recruiting Sgo1 to centromeres. Moreover, the inter-KT distance in cells expressing CB-Bub1-K-GFP was not sensitive to Aurora B inhibition by Hesperadin (Fig. 1, K and L). Thus, the need for Aurora B kinase activity in maintaining proper inter-KT distance can be bypassed by tethering Bub1 to centromeres. These results are also consistent with the role of Sgo1 in protecting centromeric cohesion (30,(45)(46)(47). Previous studies reported that Aurora B kinase activity is required for efficient localization and activation of Mps1 at kinetochores (48 -53) and that Mps1-mediated phosphorylation of KNL1 recruits Bub1 to kinetochores (54 -57). In line with this, we found that treatment of cells with reversine and AZ3146, smallmolecule inhibitors of Mps1 that strongly reduce the centromeric accumulation of Bub1 and Sgo1 (37, 51, 58), significantly increased the inter-KT distance (Fig. S1, D and E). Moreover, Mps1 inhibition significantly increased the inter-KT distance in cells stably expressing CB-GFP but not CB-Bub1-K-GFP, indicating that the requirement for Mps1 kinase activity in maintaining proper centromeric cohesion can be bypassed by centromere-tethered Bub1 (Fig. S1, F and G). Taken together, these results indicate that Aurora B kinase activity protects centromeric cohesion at least partly through promoting the localization of Bub1 kinase at kinetochores.

INCENP interacts with the chromo shadow domain (CSD) of HP1␣ and HP1␥
Previous studies showed that INCENP interacts with HP1 (59 -62) and that loss of HP1␣ and/or HP1␥ weakens centromeric cohesion (63)(64)(65). We were thus prompted to examine whether the INCENP-HP1 interaction might contribute to the role of CPC in regulating sister chromatid cohesion.

Role of the CPC in protecting sister chromatid cohesion
Moreover, INCENP-GFP (WT or the mutants) and endogenous Aurora B localized normally to centromeres in prometaphase and metaphase and subsequently to the anaphase spindle midzone (Figs. 3, B and D, and S2, B and C).
In addition, we further noticed that the mutant forms of INCENP-GFP were defective in localizing to the heterochromatic loci in interphase cells (Fig. 3E). Similar defects were observed when the INCENP mutant proteins were transiently expressed in mouse NIH 3T3 cells (Fig. S2D). These results indicate that although the INCENP-HP1 interaction is dispensable for the centromeric localization of CPC during mitosis it is required for CPC localization to heterochromatin in interphase.
Moreover, we found that the frequency of anaphases with lagging chromosomes was obviously higher in cells expressing the mutant forms of INCENP-GFP than in control cells (Fig. 3, F and G). An increased rate of chromosome missegregation was also observed when cells were released from transient mitotic arrest with S-trityl-L-cysteine (STLC) (Fig. S2E), an Eg5 inhibitor that reversibly blocks cells in prometaphase with monopolar spindles.
Taken together, these results indicate that INCENP targets HP1 to mitotic centromeres, but not vice versa, and that the INCENP-HP1 interaction is required to prevent chromosome missegregation during mitosis. In line with this, HP1␤, which is defective in binding INCENP (Fig. 2, D and E), is not enriched at centromeres in mitosis (63).

Disrupting the INCENP-HP1 interaction does not compromise Aurora B kinase activity
We next examined whether Aurora B kinase activity is compromised in cells expressing the HP1 binding-deficient mutants of INCENP-GFP. Aurora B phosphorylates multiple substrates, including histone H3 serine 10 on chromatin (35) and CENP-A at serine 7 at centromeres (70) (Fig. S1C) and KMN network proteins at kinetochores (12)(13)(14)(15). Immunofluorescence staining showed that the levels of H3-pS10 were comparable in cells expressing the WT or mutant forms of INCENP-GFP (Figs. 4, A and B, and S3, A and B). This indicates that global Aurora B kinase activity is not compromised in the absence of INCENP-HP1 interaction. We further found that phosphorylationofCENP-Aatserine7(CENP-A-pS7)andphosphorylation of Hec1 at serine 44 (Hec1-pS44), the readout of Aurora B kinase activity at centromeres and outer kinetochores, respectively, were insensitive to the loss of INCENP-HP1 interaction (Figs. 4, C-F, and S3, C and D).
To test whether loss of INCENP-HP1 interaction influences Aurora B activation, we used conditions in which Aurora B is initially inhibited in mitotic cells, but reactivation is then allowed upon removal of Aurora B inhibitor (Fig. S3E). After treatment with Hesperadin, Hec1-pS44 signal at kinetochores was abolished as expected. After removal of Hesperadin, Hec1-pS44 at kinetochores was largely recovered within 60 -90 min in cells expressing WT INCENP-GFP. When we repeated these experiments in cells expressing the mutant forms of INCENP-GFP, the kinetics of Hec1-pS44 recovery was not delayed (Fig. S3, F and G). These findings suggest that, in these experimental circumstances, the INCENP-HP1 interaction does not contribute to activation of Aurora B and phosphorylation of substrates at kinetochores. Moreover, in cells expressing either the wildtype or mutant forms of INCENP-GFP, we did not find obvious differences in centromeric enrichment of Sgo1 and H2A-pT120 as well as the kinetochore localization of Bub1 (Figs. 4, G-L, and S3, H-K). Taken together, these results indicate that loss of the

Role of the CPC in protecting sister chromatid cohesion
INCENP-HP1 interaction does not detectably compromise Aurora B kinase activity in mitotic cells.

Disrupting the INCENP-HP1 interaction weakens centromeric cohesion
Inspection of chromosome spreads prepared from nocodazole-arrested mitotic cells showed that, upon depletion of endogenous INCENP by siRNA, cells expressing the mutant forms of INCENP-GFP did not have obvious loss of sister chromatid cohesion (Fig. S4, A and B). Similar results were obtained when cells were arrested in mitosis with STLC (Fig. S4C).
Next, we treated cells with STLC to accumulate monopolar mitoses and then released them into MG132, a proteasome inhibitor that arrests cells in metaphase, to allow bipolar spindle formation and chromosome alignment (71). Examination of fixed cells showed that cells expressing the mutant forms of INCENP-GFP were largely impaired in maintaining the alignment of chromosomes on the metaphase plate (Fig. 5A). Similar results were observed when these cells were directly subjected to MG132-induced metaphase arrest (Fig. 5B). Time-lapse livecell imaging further showed that, upon MG132-induced metaphase arrest, cells expressing the mutant forms of INCENP-GFP began to exhibit irreversible chromosome scattering from the metaphase plate much earlier than control cells (Fig. 5, C  and D).
These results prompted us to investigate whether sister chromatid cohesion was compromised in cells expressing the mutant forms of INCENP-GFP. Inspection of chromosome spreads prepared from cells arrested in metaphase with MG132 revealed a strong increase in premature chromatid separation (Figs. 5E and S4D). We also found that the inter-KT distance of mitotic chromosomes was around 20% further apart in mutant

Role of the CPC in protecting sister chromatid cohesion
INCENP-GFP-expressing cells than that in the control cells (Fig. 5F), which is indicative of compromised cohesion at mitotic centromeres.
To rule out the possibility that these cohesion defects were only observed upon treatment with MG132, we treated cells with GSK 923295, a small-molecule inhibitor of the mitotic kinesin CENP-E (73). As expected, upon treatment with GSK 923295 for 2 h, control HeLa cells were arrested in a metaphaselike state (Type I) in which most chromosomes were aligned on the metaphase plate with only a few chromosomes scattered to the spindle pole-proximal area (Fig. 5, G and H). Over time, more chromosomes that had completed the alignment started to scatter from the metaphase plate (Type II). Inspection of chromosome spreads showed that these "Type II" cells were largely impaired in maintaining sister chromatid cohesion (Fig.  5, I and J). This indicates that cohesion loss largely accounts for the increased misalignment of chromosomes during the sustained inhibition of CENP-E. Importantly, we found that the defects in maintaining metaphase chromosome alignment (Fig.  5, G and H) and sister chromatid cohesion were much stronger in cells expressing the INCENP-⌬PVVEI-GFP mutant than in the control (Fig. 5, I and J).
We recently reported that double knockout of HP1␣ and HP1␥ weakens sister chromatid cohesion at mitotic centromeres (63). In contrast, when HP1␣ and HP1␤ or HP1␤ and HP1␥ were knocked out in combination (Fig. S4, I-K), cells were capable of maintaining metaphase chromosome alignment and sister chromatid cohesion (Fig. S4, L-N). Thus, HP1␤, which is defective in binding INCENP and localizing at mitotic centromeres, is dispensable for centromeric cohesion protection. In sum, these results indicate that the INCENP-HP1 interaction is required to sustain proper strength of

Role of the CPC in protecting sister chromatid cohesion
centromeric cohesion, which is particularly important for the maintenance of cohesion between sister chromatids on the metaphase plate.

Centromere-tethered HP1 and Wapl depletion bypass the requirement for INCENP-HP1 interaction in centromeric cohesion protection
Given the requirement for INCENP in HP1 localization at mitotic centromeres, we next examined whether INCENP promotes centromeric cohesion at least partly through targeting HP1 to centromeres. We expressed the CSD of HP1␣ as a CENP-B fusion protein (CB-CSD-Myc). Immunofluorescence microscopy showed that expression of CB-CSD-Myc in Haspin-knockout (clone D2) cells was unable to shorten the inter-KT distance, which is in line with the requirement for Haspin in centromeric cohesion protection by HP1 (63). Importantly, expression of CB-CSD-Myc, but not CB-Myc, efficiently shortened the inter-KT distance in cells expressing either WT or the mutant form of INCENP-GFP (Fig. 6, A-C). Thus, targeting the CSD of HP1 to centromeres rescues sister  2). B, cells transfected as in A were exposed to MG132, then fixed at the indicated time points for DNA staining, and quantified in around 200 cells (n ϭ 2). C and D, the indicated INCENP-GFP cell lines stably expressing H2B-GFP were exposed to MG132 and subjected to live imaging. The time from the achievement of metaphase chromosome alignment to chromosome scattering was determined in at least 37 cells (C). Selected frames of the movies are shown (D). Time stated in hours:minutes. E, cells transfected as in A were exposed to MG132 for 7 h. Using mitotic chromosome spreads, the percentage of cells with cohesion loss was determined in 100 cells (n ϭ 2). Example images are shown in Fig. S4D.

Role of the CPC in protecting sister chromatid cohesion chromatid cohesion defects in cells lacking the INCENP-HP1
interaction. These results are in line with our previous observation that stable expression of the CSD of HP1␣ as a CENP-B fusion protein (CB-CSD-GFP) is sufficient to support proper centromeric cohesion in the absence of endogenous HP1␣ and HP1␥ (63). Moreover, we found that inhibition of Aurora B kinase activity by Hesperadin treatment was still capable of significantly increasing the inter-KT distance in HP1␣ and HP1␥ double-knockout cells stably expressing CB-CSD-GFP (Fig. S5,  A and B), suggesting that Aurora B kinase activity can protect centromeric cohesion in a way that is independent of the centromeric localization of HP1.
Whereas the majority of cohesin is released from chromosome arms by Wapl in early mitosis to allow sister-chromatid resolution (18,19), Wapl activity is normally inhibited at mitotic centromeres (25). We wondered whether aberrantly increased local Wapl activ-ity might account for the centromeric cohesion defects in cells lacking the INCENP-HP1 interaction. We found that Wapl depletion by siRNA effectively prevented metaphase chromosome misalignment in INCENP-⌬PVVEI-GFP-expressing cells during MG132-induced metaphase arrest (Fig. 6, D and E). Consistently, these mutant cells were capable of maintaining sister chromatid cohesion in the absence of Wapl (Fig. 6F). Moreover, proper inter-KT distance was restored by Wapl depletion in cells expressing the INCENP-⌬PVVEI-GFP mutant (Fig. 6G). Thus, Wapl depletion bypasses the requirement for INCENP-HP1 interaction in centromeric cohesion protection.

The INCENP-HP1 interaction promotes centromeric localization of Haspin to antagonize Wapl
During mitosis, Haspin localizes predominantly to centromeres and phosphorylates histone H3 at threonine 3, which is

Role of the CPC in protecting sister chromatid cohesion
particularly concentrated at centromeres (6,7,74). Given that INCENP targets HP1 to mitotic centromeres and that HP1 promotes the centromeric accumulation of Haspin (7, 63), we next examined whether Haspin localization at mitotic centromeres is compromised in cells lacking the INCENP-HP1 interaction. Immunofluorescence microscopy showed that the level of phosphorylation of histone H3 at threonine 3 (H3-pT3) at mitotic centromeres, the readout of Haspin activity, was significantly lower in INCENP-⌬PVVEI-GFP-expressing cells than in control cells (Fig. 7, A and B). Using HeLa cells stably expressing Haspin-GFP, we further found that depletion of INCENP by siRNA reduced the localization of Haspin-GFP at mitotic centromeres (Fig. 7, C and D). Thus, the INCENP-HP1 interaction is required for full enrichment of Haspin at centromeres in mitosis.
We previously showed that the Pds5-interacting motif (PIM) in the N terminus of Haspin competes with the PIM of Wapl for binding Pds5B and that centromeric targeting of the PIM-containing fragment of Haspin as a CENP-B fusion protein rescues the centromeric cohesion defect in cells lacking the Pds5B-Haspin interaction (75). We hypothesized that, if the INCENP-HP1 interaction protects centromeric cohesion through localizing Haspin, artificially targeting Haspin to centromeres might bypass the need for INCENP-HP1 interaction in cohesion protection. Indeed, expression of the N terminus (residues 1-50) of Haspin as a CENP-B fusion protein (CB-Haspin-N50-Myc), but

Role of the CPC in protecting sister chromatid cohesion
not CB-Myc, strongly shortened the inter-KT distance in cells expressing the INCENP-⌬PVVEI-GFP mutant (Fig. 7, E-G), indicative of the restoration of proper centromeric cohesion. Taken together, these results indicate that INCENP targets HP1 to mitotic centromeres, which promotes the centromeric localization of Haspin to antagonize Wapl activity in cohesin release.

Discussion
Timely resolution of sister chromatid cohesion in a stepwise manner during mitosis is critical for precise chromosome segregation. Defects in this process lead to chromosomal instability in cancer cells (76). It has been known for a long time that Aurora B kinase activity promotes cohesin release from chromosome arms, thereby enabling the resolution of sister chromatids in prophase and prometaphase (27,28). Previous studies also found that depletion of Survivin or Aurora B or inhibition of Aurora B kinase activity impaired centromeric cohesion during mitosis (77,78). We confirmed these observations and further demonstrated that the requirement for Aurora B kinase activity in centromeric cohesion protection can be bypassed by centromere-tethered Bub1, whose kinase activity toward histone H2A is required to recruit Sgo1 to centromeres (38, 39, 41, 46, 79 -81). Thus, Aurora B kinase activity-dependent localization of the Mps1-pKNL1-Bub1 (p represents phosphorylation) signaling cascade to kinetochores not only plays an important role in SAC signaling through recruiting spindle checkpoint proteins (82) but also is required for centromeric cohesion through phosphorylating H2A and recruiting Sgo1 to centromeres (see the working model in Fig. 7H).
Previous studies have indicated that HP1 is a CPC-binding protein (59 -61, 83) and that the INCENP-HP1 interaction assists Aurora B kinase activity to prevent chromosome segregation errors, particularly in nontransformed cells (62). Our finding that the INCENP-HP1 interaction is required for CPC localization to heterochromatic loci in G 2 phase cells, together with a recent study (84), confirms the observation in a previous study (61). Interestingly, we found that loss of INCENP-HP1 interaction in HeLa cells does not seem to compromise Aurora B kinase activity at mitotic centromeres, likely because the amount of HP1 associated with CPC in cancer cells is below the threshold that is sufficient to cause an allosteric activation of Aurora B (62).
Importantly, we found that the INCENP-HP1 interaction is required to maintain sister chromatid cohesion at mitotic centromeres. This is in line with a recent study that infers that the CPC is localized at the inner centromere to sustain centromere cohesion on bioriented chromosomes with an unknown mechanism (85). At first glance, our results appear inconsistent with the previous observation that mitotic centromere targeting of HP1 is dispensable for sister chromatid cohesion in a HeLaderived Tet-On cell line (61). However, it should be noted that the status of sister chromatid cohesion in the absence of INCENP-HP1 interaction was measured by Kang et al. (61) using chromosome spreads prepared from nocodazole-arrested mitotic cells. Consistently, we did not observe obvious cohesion defects in cells arrested in mitosis with either nocodazole or STLC. Intriguingly, we found that the INCENP-HP1 interaction is particularly important to maintain cohesion between sister chromatids on the metaphase plate, a situation where the kinetochore is under the sustained spindle pulling forces. The cohesion defects observed in cells lacking the INCENP-HP1 interaction are reminiscent of the "cohesion fatigue" phenotype (86 -88). We demonstrated that Wapl depletion restores proper strength of centromeric cohesion in the absence of INCENP-HP1 interaction. In contrast, a recent study showed that Wapl-mediated opening of cohesin rings is not required after metaphase arrest to separate sister chromatid in cohesion fatigue (89). Thus, it seems that the sister chromatid cohesion defects in cells lacking INCENP-HP1 interaction are not simply an accelerated cohesion fatigue defect.
Although we cannot fully rule out the possibility that the INCENP-HP1 interaction protects centromeric cohesion through an additional unknown mechanism, we favor the idea that this interaction promotes the centromeric localization of Haspin, thereby antagonizing Wapl activity in cohesin release from mitotic centromeres (Fig. 7H) (63, 75, 90 -92). Because both INCENP and Haspin use the PXVXL motif to bind HP1 (61,63), it remains to be determined in the future how HP1 brought to centromeres by INCENP can also bind and recruit Haspin. This could be due to the dynamic nature of the interaction between the CSD dimer and PXVXL motif as well as the fact that INCENP is much more abundant than Haspin in somatic cells.
Moreover, we found that loss of the INCENP-HP1 interaction causes an elevated rate of chromosome missegregation. Then how might chromosome segregation errors occur in these cells with normal Aurora B kinase activity? It is possible that weakened cohesion at centromeres of metaphase chromosomes alters the kinetochore geometry and/or chromosome oscillation, thereby increasing errors in the KT-MT attachments.
Taken together, our results indicate that the CPC regulates sister chromatid cohesion at mitotic centromeres in ways that are both Aurora B kinase activity-dependent and -independent, thereby ensuring the maintenance of centromeric cohesion to the full extent in mitosis. This study provides important insight into the complex mechanism that ensures the fidelity of chromosome segregation during mitosis in human cells.

Role of the CPC in protecting sister chromatid cohesion
were subcloned into the BamHI site of pBos-CB-GFP. To make pBos-CB-Myc, GFP sequence in pBos-CB-GFP was digested with BamHI and NotI and replaced with the Myc tag. Then the PCR fragments encoding HP1 CSD (residues 121-179) and Haspin N terminus (residues 1-50) were subcloned into the BamHI site of pBos-CB-Myc, resulting in pBos-CB-CSD-Myc and pBos-CB-Haspin-N50-Myc, respectively. All point mutations were introduced with the QuikChange II XL site-directed mutagenesis kit (Agilent Technologies). All plasmids were sequenced to verify desired mutations and absence of unintended mutations.

Fluorescence microscopy, time-lapse live-cell imaging, and statistical analysis
Cells cultured on coverslips were fixed with 2% paraformaldehyde in PBS for 10 min followed by extraction with 0.5% Triton X-100 in PBS for 5 min. To stain Hec1-pS44, cells were extracted for 5 min in PHEM (60 mM Pipes, 25 mM Hepes, 10 mM EGTA, and 2 mM MgCl 2 , pH 6.9) plus 1% Triton X-100 and fixed at room temperature for 20 min in PHEM plus 4% formaldehyde. Mitotic cells collected by shake-off were spun on slides by Cytospin (Cytospin 4, Thermo Scientific) at 1500 rpm for 5 min. To produce chromosome spreads, mitotic cells obtained by selective detachment were incubated in 75 mM KCl for 10 min. After attachment to glass coverslips by Cytospin, chromosome spreads were fixed with 2% paraformaldehyde in PBS for 10 min followed by extraction with 0.5% Triton X-100 in PBS for 5 min. Fixed cells and chromosome spreads were stained with primary antibodies for 1-2 h and secondary antibodies for 1 h, all with 3% BSA in PBS with 0.5% Triton X-100 and at room temperature. DNA was stained for 10 min with DAPI. Fluorescence microscopy was carried out at room temperature using a Nikon ECLIPSE Ni microscope with a Plan Apo Fluor 60ϫ oil (numerical aperture, 1.4) objective lens and a Clara charge-coupled device (Andor Technology). The inter-KT distance was measured using the inner kinetochore marker CENP-C or centromere marker ACA on over 15 kinetochores per cell in at least 10 cells. Distance was determined by drawing a line from the outer kinetochore extending to the outer edge of its sister kinetochore. The length of the line was calculated using the imaging software of NIS-Elements BR (Nikon). Quantification of fluorescence intensity was carried out with NIH ImageJ using images obtained at identical illumination settings. Briefly, on chromosome spreads, the average pixel intensity of Sgo1, Bub1, H2A-pT120, CENP-A-pS7, Hec1-pS44, H3-pT3, Haspin-GFP, CENP-C, or ACA staining at centromeres, defined as circular regions including paired centromeres, or on chromosome arms, was determined using ImageJ.

Role of the CPC in protecting sister chromatid cohesion
After background correction, the ratio of kinetochore or centromeric staining intensity versus CENP-C or ACA or centromeric Sgo1/arm Sgo1 was calculated for each centromere.
Time-lapse live-cell imaging was carried out with the GE DV Elite Applied Precision DeltaVision system (GE Healthcare) equipped with Olympus oil objectives of 40ϫ (numerical aperture, 1.35) UApo/340, an API Custom Scientific complementary metal-oxide semiconductor camera, and Resolve3D soft-WoRx imaging software. Cells expressing H2B-GFP were plated in four-chamber glass-bottomed 35-mm dishes (Cellvis) coated with poly-D-lysine and filmed in a climate-controlled and humidified environment (37°C and 5% CO 2 ). Images were captured every 5 min. The acquired images were processed using Adobe Photoshop and Adobe Illustrator. Statistical analyses were performed with a two-tailed unpaired Student's t test in GraphPad Prism 6. A p value less than 0.05 was considered significant.
Plasmids expressing MBP-or GST-fused HP1 and INCENP proteins were constructed by subcloning PCR fragments into pGEX-MBP-10xHis or pGEX-4T1. The plasmids were transformed into BL21 competent cells (Stratagene). Cells were grown in LB broth under antibiotic selection at 37°C until reaching an A 600 of 0.6 -0.7, and protein expression was induced with 0.4 mM isopropyl 1-thio-␤-D-galactopyranoside at 16°C for 16 h. Cells were lysed by sonication in buffer A (50 mM Tris-HCl, pH 8.0, and 300 mM NaCl; for MBP fusion proteins) or buffer B (20 mM Tris-HCl, pH 8.0, 100 mM NaCl, 1 mM EDTA, and 1% Triton X-100; for GST fusion proteins). The lysate was clarified by centrifugation and incubated with amylose resin (BioLab) or GSH-Sepharose 4B (GE Healthcare) in lysis buffer. The resins were washed with lysis buffer or eluted with 150 mM maltose or 150 mM GSH. For pulldown of proteins from lysates (GST pulldown as the example), HeLa cells were first lysed in P150 buffer except that NaCl was used at 500 mM, and then the lysates were diluted to achieve the final concentration of NaCl at 150 mM. The lysates were precleared with GSH-Sepharose 4B beads and then incubated with GST fusion proteins immobilized to GSH-Sepharose 4B beads for 2 h.