Regulation Of Aurora Research Articles

ALKBH3-dependent m1A demethylation of Aurora A mRNA inhibits ciliogenesis

Primary cilia are antenna-like subcellular structures to act as signaling platforms to regulate many cellular processes and embryonic development. m1A RNA modification plays key roles in RNA metabolism and gene expression; however, the physiological function of m1A modification remains largely unknown. Here we find that the m1A demethylase ALKBH3 significantly inhibits ciliogenesis in mammalian cells by its demethylation activity. Mechanistically, ALKBH3 removes m1A sites on mRNA of Aurora A, a master suppressor of ciliogenesis. Depletion of ALKBH3 enhances Aurora A mRNA decay and inhibits its translation. Moreover, alkbh3 morphants exhibit ciliary defects, including curved body, pericardial edema, abnormal otoliths, and dilation in pronephric ducts in zebrafish embryos, which are significantly rescued by wild-type alkbh3, but not by its catalytically inactive mutant. The ciliary defects caused by ALKBH3 depletion in both vertebrate cells and embryos are also significantly reversed by ectopic expression of Aurora A mRNA. Together, our data indicate that ALKBH3-dependent m1A demethylation has a crucial role in the regulation of Aurora A mRNA, which is essential for ciliogenesis and cilia-associated developmental events in vertebrates.

KIF14 controls ciliogenesis via regulation of Aurora A and is important for Hedgehog signaling.

Primary cilia play critical roles in development and disease. Their assembly and disassembly are tightly coupled to cell cycle progression. Here, we present data identifying KIF14 as a regulator of cilia formation and Hedgehog (HH) signaling. We show that RNAi depletion of KIF14 specifically leads to defects in ciliogenesis and basal body (BB) biogenesis, as its absence hampers the efficiency of primary cilium formation and the dynamics of primary cilium elongation, and disrupts the localization of the distal appendage proteins SCLT1 and FBF1 and components of the IFT-B complex. We identify deregulated Aurora A activity as a mechanism contributing to the primary cilium and BB formation defects seen after KIF14 depletion. In addition, we show that primary cilia in KIF14-depleted cells are defective in response to HH pathway activation, independently of the effects of Aurora A. In sum, our data point to KIF14 as a critical node connecting cell cycle machinery, effective ciliogenesis, and HH signaling.

Aurora A inhibition disrupts chromosome condensation and spindle assembly during the first embryonic division in pigs.

As common overexpression of Aurora A in various tumours, much attention has focused on its function in inducing cancer, and its value in cancer therapeutics, considerably less is known regarding its role in the first cleavage division of mammalian embryos. Here, we highlight an indispensable role of Aurora A during the first mitotic division progression of pig embryos just after meiosis. The expression and spatiotemporal localization of Aurora A were initially assessed in pig embryos during the first mitotic division by Western blot analysis and indirect immunofluorescent staining. Then, the potential role of Aurora A was further evaluated using a highly selective Aurora A inhibitor, MLN8054, during this mitotic progression in pig embryos. Aurora A was found to express and exhibit a specific dynamic intracellular localization pattern during the first mitotic division in pig embryos. Aurora A was diffused in the cytoplasm at the prophase stage, and then exhibited a dynamic intracellular localization which was tightly associated with the chromosome and spindle dynamics throughout subsequent mitotic phases. Inhibition of Aurora A by MLN8054 treatment led to the failure of the first cleavage, with the majority of embryos being arrested in prophase of the mitotic division. Further subcellular structure examination showed that Aurora A inhibition not only led to the failure of spindle microtubule assembly, but also resulted in severe defects in chromosome condensation, accompanied by an obvious decrease in p-TACC3(S558) expression during the prophase of the first mitosis. Together, these results illustrated that Aurora A is crucial for both spindle assembly and chromosome condensation during the first mitotic division in pig embryos, and that the regulation of Aurora A may be associated with its effects on p-TACC3(S558) expression.

Evolution of a kinase allosteric site

Enzyme Regulation Enzyme activity is often regulated by conformational changes coupled to binding of an effector at an allosteric site, a feature especially important for enzymes involved in signaling cascades. Hadzipasic et al. studied the origins of allosteric regulation of Aurora A, a kinase involved in progression of the eukaryotic cell cycle. Aurora A is allosterically regulated through the binding of an effector protein named TPX2, which also targets the kinase to spindle microtubules. By reconstructing ancestor kinase sequences, they found that TPX2 bound to an early Aurora A but had very weak activation that was gradually strengthened by evolution of an allosteric network within the kinase. An evolutionary advantage from localizing the active protein at the mitotic spindle may have driven the development of this regulatory mechanism. Science , this issue p. [912][1] [1]: /lookup/doi/10.1126/science.aay9959

The Deubiquitinating Enzyme USP14 Regulates Leukemic Chemotherapy Drugs-Induced Cell Apoptosis by Suppressing Ubiquitination of Aurora Kinase B

Background/Aims: Aurora kinase B is a mitotic checkpoint kinase that plays a pivotal role in mitosis by ensuring correct chromosome segregation and normal progression through mitosis. Aurora B has been found to be amplified and overexpressed in several types of leukemia. The deubiquitinating enzyme USP14 is one of three proteasome-associated deubiquitinating enzymes and plays critical roles in diverse biological processes including cancer. However, whether USP14 has a role in leukemia cells remains elusive. Methods: Leukemic U937, NB4 and Jurkat cells were treated with diverse apoptosis-inducing drugs. The interaction between USP14 and Aurora B were determined by Western blot. The effect of USP14 in the regulation of Aurora B was detected by cycloheximide (CHX) and deubiquitination assays. FACS assay was used to determine the apoptosis ratio of cells after treatments. Results: We found that Aurora B was ubiquitinated and degraded during leukemic chemotherapy drugs-induced cell apoptosis. FBXW7 mediated Aurora B ubiquitination and degradation during chemotherapeutic drugs-induced apoptosis. USP14 associated with Aurora B and prevented Aurora B degradation. Functionally, overexpression of USP14 inhibits chemotherapeutic drugs-induced apoptosis in leukemia cells. On the contrary, administration of b-AP15, a specific inhibitor of USP14, significantly increased leukemia cells apoptosis in a dose-dependent manner. Conclusion: Thus, our data suggest that USP14 plays a novel critical role of in leukemia cells apoptosis through Aurora B stabilization and USP14 could be a potential therapeutic target for leukemia.

Abstract 522: Role and regulation of Aurora A in radiation resistance mechanisms in glioblastoma

Abstract Glioblastoma (GBM) is the most aggressive tumor of the human brain, which inevitably escapes the standard treatment modalities that include surgery, radiotherapy and chemotherapy. Consequently, the median survival of GBM patients remains 12-15 months despite these aggressive treatments. Therefore, to develop effective therapies, it is important to understand how GBM cells develop therapeutic resistance. Aurora A is a ubiquitously expressed serine/threonine kinase, which plays essential roles in mitotic regulation. This protein kinase, which phosphorylates p53, PP1, CEBP, and histone H3 among other regulators of cell division, is overexpressed in various neoplasms including GBM and invariably associated with poor prognosis. Recent studies have demonstrated that Aurora A contributes to radio-resistance in various solid neoplasm including GBM. Importantly, Aurora A inhibitors are currently in phase I/II clinical trials for solid cancer. Notably, Aurora A inhibitor MLN8237 that crosses the blood brain barrier specifically inhibits Aurora A at concentrations ≤ maximally tolerated dose in animal models and in phase I clinical trials. We found that Aurora A protein level is upregulated by ionizing radiation in GBM cells. This was, in part, mediated by radiation-induced inhibition of 26S-proteosomal degradation of Aurora A. Aurora A was silenced using both lentiviral mediated shRNA expression and a specific Aurora A inhibitor in three different established cell lines, and were treated with 6 gy radiation. We found that pharmacological inhibition and RNAi-mediated knockdown of Aurora A sensitized the GBM cells to radiation therapy resulting in reduced cell proliferation and increased apoptosis. Interestingly, we observed that RNAi-mediated down-regulation of Aurora A was associated with a decrease in X-linked inhibitor of apoptosis (XIAP) expression in GBM cells. We also found that Aurora A and XIAP were co-localized in GBM cells. Taken, together our results reveal a mechanism by which Aurora A confers radio-resistance in GBM cells and further rationalize the use of Aurora A inhibitors as radio-sensitizer in solid neoplasms including GBM. Funding sources: This work was supported by R01CA108633 (To AC), 1RC2CA148190 (To AC) U10CA180850-01 (To AC), 1R01CA169368 (To AC) from the National Cancer Institute (NCI), Brain Tumor Funders Collaborative Grant (To AC), Ohio State University Comprehensive Cancer Center Award (To AC) Citation Format: Brinda Ramasubramanian, Kamalakannan Palanichamy, Disha Patel, Saikh Jaharul Haque, Arnab Chakravarti. Role and regulation of Aurora A in radiation resistance mechanisms in glioblastoma. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 522.

Abstract 5097: Tissue stiffness regulates multinucleation in mammary epithelial cells

Abstract This study investigates how increased stiffness of the tumor microenvironment (TME) can facilitate cellular multinucleation. Multinucleation is an easily observable marker for polyploidy, facilitating the quantification of this phenotype. Polyploidy is commonly an intermediate to aneuploidy, defined as an abnormal number of chromosomes, a phenotype found in 85% of solid cancers that can drive tumorigenesis. Up to 37% percent of tumors exhibit whole-genome doubling, which typically precedes other somatic copy number alterations. Additionally, induction of tetraploidy in human cells promoted increased tolerance for mutation, resistance to chemotherapeutic drugs, and transformation in culture. Tumors are inherently stiffer than normal tissue, and this property has been shown to affect cell growth and proliferation. Similarly, cell cycle errors have long been linked to chromosomal abnormalities. Here, we used engineered two-dimensional substrata that mimic tumor and normal microenvironments to investigate how matrix stiffness regulates multinucleation in mammary epithelial cells. Cells cultured on “stiff” substrata, representing tumor tissue, showed a nearly 14-fold increase in multinucleation compared to cells cultured on “soft” substrata, representing normal tissue. We found that multinucleation was regulated in part by signaling downstream of MMP3, a protease commonly upregulated in cancer. This signaling depended on expression of the Rac1 splice variant, Rac1b, production of reactive oxygen species (ROS), and expression of Snail. Under all conditions, cells cultured on soft substrata maintained a low frequency of multinucleation. We also investigated biochemical effectors downstream of Snail. Aurora A kinase (Aurora A) is a mitotic regulator commonly elevated in cancer that has been shown to induce multinucleation in mammary epithelial cells and increase tumor incidence in mice. We found using microarray analysis that MMP3 increases the levels of Aurora A in mammary epithelial cells. We further discovered that upregulation of Aurora A in response to MMP3 signaling was limited to one transcript variant. These data suggest that an increase in multinucleation is driven by the stiffening of the tissue during tumorigenesis, in part by MMP3-induced signaling and regulation of Aurora A splicing. More broadly, these data suggest a key role for the mechanical properties of the tumor microenvironment in cancer progression. Citation Format: Allison K. Simi, Derek C. Radisky, Celeste M. Nelson. Tissue stiffness regulates multinucleation in mammary epithelial cells. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 5097.

MicroRNA let-7b regulates genomic balance by targeting Aurora B kinase

The let-7 microRNA (miRNA) family has been implicated in the regulation of diverse cellular processes and disease pathogenesis. In cancer, loss-of-function of let-7 miRNAs has been linked to tumorigenesis via increased expression of target oncogenes. Excessive proliferation rate of tumor cells is often associated with deregulation of mitotic proteins. Here, we show that let-7b contributes to the maintenance of genomic balance via targeting Aurora B kinase, a key regulator of the spindle assembly checkpoint (SAC). Our results indicate that let-7b binds to Aurora B kinase 3′UTR reducing mRNA and protein expression of the kinase. In cells, excess let-7b induced mitotic defects characteristic to Aurora B perturbation including increased rate of polyploidy and multipolarity, and premature SAC inactivation that leads to forced exit from chemically induced mitotic arrest. Moreover, the frequency of aneuploid HCT-116 cells was significantly increased upon let-7b overexpression compared to controls. Interestingly, together with a chemical Aurora B inhibitor, let-7b had an additive effect on polyploidy induction in HeLa cells. In breast cancer patients, reduced let-7b expression was found to be associated with increased Aurora B expression in grade 3 tumors. Furthermore, let-7b was found downregulated in the most aggressive forms of breast cancer determined by clinicopathological parameters. Together, our findings suggest that let-7b contributes to the fidelity of cell division via regulation of Aurora B. Moreover, the loss of let-7b in aggressive tumors may drive tumorigenesis by up-regulation of Aurora B and other targets of the miRNA, which further supports the role of let-7b in tumor suppression.

The ARF tumor suppressor prevents chromosomal instability and ensures mitotic checkpoint fidelity through regulation of Aurora B.

The ARF tumor suppressor is part of the CDKN2A locus and is mutated or undetectable in numerous cancers. The best-characterized role for ARF is in stabilizing p53 in response to cellular stress. However, ARF has tumor suppressive functions outside this pathway that have not been fully defined. Primary mouse embryonic fibroblasts (MEFs) lacking the ARF tumor suppressor contain abnormal numbers of chromosomes. However, no role for ARF in cell division has previously been proposed. Here we demonstrate a novel, p53-independent role for ARF in the mitotic checkpoint. Consistent with this, loss of ARF results in aneuploidy in vitro and in vivo. ARF(-/-) MEFs exhibit mitotic defects including misaligned and lagging chromosomes, multipolar spindles, and increased tetraploidy. ARF(-/-) cells exhibit overexpression of Mad2, BubR1, and Aurora B, but only overexpression of Aurora B phenocopies mitotic defects observed in ARF(-/-) MEFs. Restoring Aurora B to near-normal levels rescues mitotic phenotypes in cells lacking ARF. Our results define an unexpected role for ARF in chromosome segregation and mitotic checkpoint function. They further establish maintenance of chromosomal stability as one of the additional tumor-suppressive functions of ARF and offer a molecular explanation for the common up-regulation of Aurora B in human cancers.

Phosphorylation Regulates Kinase and Microtubule Binding Activities of the Budding Yeast Chromosomal Passenger Complex in Vitro

The chromosomal passenger complex (CPC) is a key regulator of mitosis in eukaryotes. It comprises four essential and conserved proteins known in mammals/yeasts as Aurora B/Ipl1, INCENP/Sli15, Survivin/Bir1, and Borealin/Nbl1. These subunits act together in a highly controlled fashion. Regulation of Aurora B/Ipl1 kinase activity and localization is critical for CPC function. Although regulation of CPC localization and kinase activity in vivo has been investigated elsewhere, studies on the complete, four-subunit CPC and its basic biochemical properties are only beginning. Here we describe the biochemical characterization of purified and complete Saccharomyces cerevisiae four-subunit CPC. We determined the affinity of the CPC for microtubules and demonstrated that the binding of CPC to microtubules is primarily electrostatic in nature and depends on the acidic C-terminal tail (E-hook) of tubulin. Moreover, phosphorylation of INCENP/Sli15 on its microtubule binding region also negatively regulates CPC affinity for microtubules. Furthermore, we show that phosphorylation of INCENP/Sli15 is required for activation of the kinase Aurora B/Ipl1 and can occur in trans. Although phosphorylation of INCENP/Sli15 is essential for activation, we determined that a version of the CPC lacking the INCENP/Sli15 microtubule binding region (residues Glu-91 to Ile-631) is able to form an intact complex that retains microtubule binding activity. Thus, we conclude that this INCENP/Sli15 linker domain plays a largely regulatory function and is not essential for complex formation or microtubule binding.

FBXW7 is involved in Aurora B degradation

FBXW7, a component of E3 ubiquitin ligase, plays an important role in mitotic checkpoint, but its role remains unclear. Aurora B is a mitotic checkpoint kinase that plays a pivotal role in mitosis by ensuring correct chromosome segregation and normal progression through mitosis. Whether Aurora B and FBXW7 are coordinately regulated during mitosis is not known. Here, we show that FBXW7 is a negative regulator for Aurora B. Ectopic expression of FBXW7 can suppress the expression of Aurora B. Accordingly, FBXW7 deficiency leads to Aurora B elevation. Mechanistic studies show that all FBXW7 isoforms are negative regulators of Aurora B expression through ubiquitination-mediated protein degradation. Aurora B interacts with R465 and R505 residues of WD 40 domain of FBXW7. Significantly, inverse correlation between FBXW7 and Aurora B elevation is translated into the deregulation of mitosis. FBWX7 expression mitigates Aurora B-mediated cell growth and mitotic deregulation. In addition, FBXW7 reduces the percentage of multinucleated cells caused by Aurora B overexpression. These data suggest that FBXW7 is an important negative regulator of Aurora B, and that the loss or mutation of FBXW7 as seen in many types of cancer could lead to an abnormal elevation of Aurora B and result in deregulated mitosis, which accelerates cancer cell growth.

Abstract 2038: Aurora A and BRCA1 cooperate to control cytokinesis failure leading to aneuploidy in ovarian cystadenoma cells

Abstract Aneuploidy, defined by a chromosome number that is not a multiple of the haploid number, is a hallmark of cancer. In order to study the mechanism of aneuploidy development in ovarian cancer, we used cell strains derived from benign ovarian cystadenomas, the benign counterparts of the type of ovarian cancer that develops in BRCA1 mutation carriers. The cells were transfected with SV40 Large T Antigen, conferring the equivalent of a p53 mutation, which is present in nearly all cancers that develop in BRCA1 mutation carriers. These cells are not immortal and invariably reach crisis after up to 50 population doublings in vitro. We previously showed that this crisis event, which is not triggered by telomere attrition, is associated with a cell cycle arrest at the M phase, and that decreased BRCA1 expression allows cells to overcome this crisis event, resulting in tetraploidy and subsequent aneuploidy. The finding that cells recovering from crisis undergo sudden changes in their ploidy status strongly suggests that such recovery is characterized by initiation of a new cell cycle without first completing cytokinesis. We used time-lapse photography to test this hypothesis. Such studies revealed that a significant proportion of cells treated with siRNA against BRCA1 recovered from a cell cycle arrest during the mitotic phase without undergoing cytokinesis, resulting in bi-nucleation. We further hypothesized that Aurora A plays a role in regulating this process, in part, by acting as an upstream regulator of BRCA1 expression. Here we show that Aurora A protein and kinase activity are both up-regulated while levels of BRCA1 expression are down-regulated in cells as they age in culture. Levels of BRCA1 expression increased upon knockdown of Aurora A kinase, further suggesting an inverse relationship between expression levels of these proteins. Inhibition of Aurora A prevented recovery from mitotic arrest as evidenced by an increase in BubR1 and Mad2, two components of the mitotic checkpoint complex and a decrease in Cdc27, a component of the anaphase promoting complex. Genomic DNA profiles of cells treated with siRNA against Aurora A showed decreased tetraploidy and microscopic examination showed decreased multinucleation. Time-lapse photography of cells approaching crisis, treated with siRNA against Aurora A showed that the M phase arrest was prolonged compared to controls and invariably led to apoptosis in contrast to cells treated with siRNA against BRCA1. Down regulation of Aurora A in a younger cells, not approaching crisis, did not induce a mitotic arrest. We conclude that decreased BRCA1 expression in cells approaching crisis leads to recovery from a mitotic arrest without completion of cytokinesis, leading to tetraploidy and subsequent aneuploidy. Although decreased Aurora A expression does not induce a mitotic arrest, it prevents recovery from such arrest, resulting in cell death from apoptosis. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr 2038. doi:1538-7445.AM2012-2038

Abstract LB-287: TPX2 acts as a scaffold and co-activator protein for the oncogenic kinase Aurora B

Abstract Aurora B kinase is a master regulator of mitosis and is over-expressed in a variety of malignancies including astrocytomas, seminomas, ependymomas, prostate cancer and non small-cell lung cancer. Several Aurora B inhibitors are currently being evaluated for their efficacy in cancer therapy. Therefore, it is critical to understand the regulation of Aurora B activity by other proteins. Aurora B forms the enzymatic core of the Chromosomal Passenger Complex (CPC). The CPC consists of three other proteins besides Aurora B: INCENP, Survivin and Borealin. All these proteins have been known to promote Aurora B activation. The mitotic protein Targeting Protein for Xenopus kinesin-like protein 2 (TPX2) co-localizes with Aurora B at several stages of mitosis, hinting at the existence of a signaling cross-talk between Aurora B and TPX2. The main purpose of our study is to determine whether Aurora B and TPX2 can cross-talk with each other during mitosis, and if found so, to decode the mechanism by which this signaling cross-talk occurs. We hypothesize that TPX2 can transmit signals to regulate Aurora B activity during mitosis. To test our hypothesis, we have performed experiments utilizing M-phase Xenopus egg extracts (XEE) which possess an abundance of mitotic proteins, and human cell lines as model systems. By performing immunoprecipitation assays (IPs) in M-phase XEE, we detected an interaction between TPX2 and the CPC proteins - Aurora B, INCENP and Survivin. This validates the existence of a signaling cross-talk between TPX2 and the CPC proteins. Moreover, IPs and microtubule pelleting assays utilizing XEE revealed that, as is typical of scaffold proteins, either too much or too little TPX2 alters Aurora B activity. Significantly, immunodepletion of endogenous TPX2 from XEE decreases the association between Aurora B and its activators- Survivin and INCENP, leading to a consequent reduction in Aurora B activity. Additionally, in vitro binding assays demonstrate that, residues 138 to 328 of Xenopus TPX2 (TPX2 B) are sufficient to enhance the interaction between Aurora B and its activator, Survivin. Further, TPX2 B also increases Aurora B kinase activity in an in vitro kinase assay. These data suggest that under endogenous conditions, TPX2 functions as a co-activator of Aurora B by increasing Aurora B-Survivin and Aurora B-INCENP interactions. Importantly, IPs with Panc-1 and CFPAC-1 pancreatic cancer cell lines suggest that this mechanism of Aurora B activation by TPX2 is likely to be conserved in human cancer cell lines. Based upon our results, we conclude that TPX2 enhances Aurora B activity by serving as a scaffold protein for assembly of the CPC. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 103rd Annual Meeting of the American Association for Cancer Research; 2012 Mar 31-Apr 4; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2012;72(8 Suppl):Abstract nr LB-287. doi:1538-7445.AM2012-LB-287

Regulation of Aurora B Kinase by the Lipid Raft Protein Flotillin-1

The lipid raft protein Flotillin-1 was previously shown to be required for cell proliferation. Here we show that it is critical for the maintenance of the levels of the mitotic regulator Aurora B. Knockdown of Flotillin-1 induced aberrant mitotic events similar to those produced by Aurora B depletion and led to a marked decline in Aurora B levels and activity. Transfection of wild-type full-length Flotillin-1 or forms directed to the nucleus increased Aurora B levels and activity. Flotillin-1 interacted with Aurora B directly through its SPFH domain in a complex distinct from the chromosomal passenger protein complex, and the two proteins co-purified in nuclear, non-raft fractions. These observations are the first evidence for a function of Flotillin-1 outside of lipid rafts and suggest its critical role in the maintenance of a pool of active Aurora B.

Aurora A is differentially expressed and regulated in chromosomal and microsatellite instable sporadic colorectal cancers

The centrosome-associated kinase aurora A has been shown to be involved in genetic instability and to be (over)expressed in several human carcinomas. This study investigated aurora A gene copy numbers, mRNA and protein expression as well as tumour cell proliferation and aneuploidy in chromosomal and microsatellite instable sporadic colorectal cancers. Case-matched tissues of normal (n=71) and dysplastic (n=49) colorectal epithelium and invasive carcinomas (n=71) were included in this study. PCR-based microsatellite analysis classified 14/71 (20%) of carcinomas as microsatellite instable. A stepwise increase of aurora A mRNA expression (P<0.0001; quantitative RT-PCR) and aurora A protein expressing tumour cells (P=0.0141; immunohistochemistry) occurred in the adenoma-carcinoma sequence. Within invasive carcinomas, aurora A mRNA levels (P=0.0259) and aurora A positive tumour cells (P<0.0001) were closely associated with tumour cell proliferation (Ki-67 specific immunohistochemistry). Compared with chromosomal instable carcinomas, microsatellite instable carcinomas had significantly more aurora A positive tumour cells (P=0.0043) and a higher tumour cell proliferation (P=0.0335). In contrast, only chromosomal instable carcinomas exhibited marked tumour cell aneuploidy (P=0.0004, fluorescence in situ hybridization) and significantly higher aurora A gene copy numbers (P=0.0206) as compared with microsatellite instable carcinomas. This study further supports a role of aurora A in the carcinogenesis of sporadic colorectal cancers. Moreover, it demonstrates that in a minority of predominantly microsatellite instable carcinomas the presence of aurora A positive tumour cells is merely reflecting tumour cell proliferation. In contrast, the large majority of chromosomal instable carcinomas shows additional (de)regulation of aurora A by gene amplification and concomitant tumour cell aneuploidy. Thus, sporadic colorectal cancers exhibit different mechanisms of aurora A regulation and this may impact the efficacy of aurora-targeted therapies.

An Afg2/Spaf-Related Cdc48-like AAA ATPase Regulates the Stability and Activity of the C. elegans Aurora B Kinase AIR-2

The Aurora B kinase is the enzymatic core of the chromosomal passenger complex, which is a critical regulator of mitosis. To identify novel regulators of Aurora B, we performed a genome-wide screen for suppressors of a temperature-sensitive lethal allele of the C. elegans Aurora B kinase AIR-2. This screen uncovered a member of the Afg2/Spaf subfamily of Cdc48-like AAA ATPases as an essential inhibitor of AIR-2 stability and activity. Depletion of CDC-48.3 restores viability to air-2 mutant embryos and leads to abnormally high AIR-2 levels at the late telophase/G1 transition. Furthermore, CDC-48.3 binds directly to AIR-2 and inhibits its kinase activity from metaphase through telophase. While canonical p97/Cdc48 proteins have been assigned contradictory roles in the regulation of Aurora B, our results identify a member of the Afg2/Spaf AAA ATPases as a critical in vivo inhibitor of this kinase during embryonic development.

A Novel Mechanism for Activation of the Protein Kinase Aurora A

Segregation of chromosomes during mitosis requires interplay between several classes of protein on the spindle, including protein kinases, protein phosphatases, and microtubule binding motor proteins [1–4]. Aurora A is an oncogenic cell cycle-regulated protein kinase that is subject to phosphorylation-dependent activation [5–11]. Aurora A localization to the mitotic spindle depends on the motor binding protein TPX2 (Targeting Protein for Xenopus kinesin-like protein 2), but the protein(s) involved in Aurora A activation are unknown [11–13]. Here, we purify an activator of Aurora A from Xenopus eggs and identify it as TPX2. Remarkably, Aurora A that has been fully deactivated by Protein Phosphatase 2A (PP2A) becomes phosphorylated and reactivated by recombinant TPX2 in an ATP-dependent manner. Increased phosphorylation and activation of Aurora A requires its own kinase activity, suggesting that TPX2 stimulates autophosphorylation and autoactivation of the enzyme. Consistently, wild-type Aurora A, but not a kinase inactive mutant, becomes autophosphorylated on the regulatory T loop residue (Thr 295) after TPX2 treatment. Active Aurora A from bacteria is further activated at least 7-fold by recombinant TPX2, and TPX2 also impairs the ability of protein phosphatases to inactivate Aurora A in vitro. This concerted mechanism of stimulation of activation and inhibition of deactivation implies that TPX2 is the likely regulator of Aurora A activity at the mitotic spindle and may explain why loss of TPX2 in model systems perturbs spindle assembly [14–16]. Our finding that a known binding protein, and not a conventional protein kinase, is the relevant activator for Aurora A suggests a biochemical model in which the dynamic localization of TPX2 on mitotic structures directly modulates the activity of Aurora A for spindle assembly.