Biochemical effects of 12-O-tetradecanoylphorbol-13-acetate, retinoic acid, phenobarbital, and 5-azacytidine on a normal rat liver epithelial cell line

Compound 48/80 (poly-p-methoxyphenethylmethylamine), an agent commonly used to trigger degranulation of mast cells, at concentrations of 5-20 micrograms/ml suppresses the proliferation of L1210 and Friend leukemic cells in vitro, inducing the formation of giant cells, which are polykaryons. Both the proportion of polykaryons in cultures and their size (which reflects the number of nuclei per polykaryon) increase during growth in the presence of 48/80 up to 48 hr; thereafter, the cells lose viability. A predominant number of nuclei in these polykaryons contain a 4C, or higher DNA content. The data indicate that compound 48/80 impairs the cleavage (cytokinesis) and perhaps mitotic processes. Mechanisms by which compound 48/80 induces the described effects are unknown but may be related to the polycationic nature of the polymer and its interaction with the cell membrane. Certain attributes of compound 48/80 suggest that this or similar polymers may have value as research tools for the study of regulatory mechanisms involved in cell division.     

Stathmin Prevents the Transition from a Normal to an Endomitotic Cell Cycle during Megakaryocytic Differentiation

Physiological polyploidy is a characteristic of several cell types including themegakaryocytes (MK) that give rise to circulating blood platelets. MK achieve polyploidy byswitching from a normal to an endomitotic cell cycle characterized by the absence of late mitoticstages. During an endomitotic cycle, the cells enter into mitosis and proceed normally throughmetaphase and early anaphase. However, late anaphase, telophase and cytokinesis are aborted. Thisabortive mitosis is associated with atypical multipolar mitotic spindles and limited chromosomesegregation. Stathmin is a microtubule-depolymerizing protein that is important for the regulation ofthe mitotic spindle and interfering with its expression disrupts the normal mitotic spindle and leadsto aberrant mitotic exit. As cells enter mitosis, the microtubule depolymerizing-activity of stathminis switched-off, allowing microtubules to polymerize and assemble into a mitotic spindle.Reactivation of stathmin in the later stages of mitosis is necessary for the disassembly of the mitoticspindle and the exit from mitosis. Previous studies had shown that stathmin expression isdownregulated as MK become polyploid and inhibition of its expression in K562 cells increasestheir propensity to become polyploid. In this report, we describe our studies of the mechanism bywhich stathmin plays its role in MK polyploidization. We show that stathmin overexpressionprevents the transition from a mitotic cycle to an endomitotic cycle as determined by a decrease inthe number of multipolar mitotic spindles. These observations support a model in whichdownregulation of stathmin expression in megakaryocytes and other polyploid cells may be acritically important factor in endomitosis and polyploidy.     

Calcium- and integrin-binding protein 1 regulates endomitosis and its interaction with Polo-like kinase 3 is enhanced in endomitotic Dami cells

Endomitosis is a form of mitosis in which both karyokinesis and cytokinesis are interrupted and is a hallmark of megakaryocyte differentiation. Very little is known about how such a dramatic alteration of the cell cycle in a physiological setting is achieved. Thrombopoietin-induced signaling is essential for induction of endomitosis. Here we show that calcium- and integrin-binding protein 1 (CIB1), a known regulator of platelet integrin α(IIb)β(3) outside-in signaling, regulates endomitosis. We observed that CIB1 expression is increased in primary mouse megakaryocytes compared to mononuclear bone marrow cells as determined by Western blot analysis. Following PMA treatment of Dami cells, a megakaryoblastic cell line, we found that CIB1 protein expression increased concomitant with cell ploidy. Overexpression of CIB1 in Dami cells resulted in multilobated nuclei and led to increased time for a cell to complete cytokinesis as well as increased incidence of furrow regression as observed by time-lapse microscopy. Additionally, we found that surface expression of integrin α(IIb)β(3,) an important megakaryocyte marker, was enhanced in CIB1 overexpressing cells as determined by flow cytometry. Furthermore, PMA treatment of CIB1 overexpressing cells led to increased ploidy compared to PMA treated control cells. Interestingly, expression of Polo-like kinase 3 (Plk3), an established CIB1-interacting protein and a key regulator of the mitotic process, decreased upon PMA treatment of Dami cells. Furthermore, PMA treatment augmented the interaction between CIB1 and Plk3, which depended on the duration of treatment. These data suggest that CIB1 is involved in regulating endomitosis, perhaps through its interaction with Plk3.     

Expression of a nondegradable cyclin B1 affects plant development and leads to endomitosis by inhibiting the formation of a phragmoplast

In plants after the disassembly of mitotic spindle, a specific cytokinetic structure called the phragmoplast is built, and after cytokinesis, microtubules populate the cell cortex in an organized orientation that determines cell elongation and shape. Here, we show that impaired cyclin B1 degradation, resulting from a mutation within its destruction box, leads to an isodiametric shape of epidermal cells in leaves, stems, and roots and retarded growth of seedlings. Microtubules in these misshaped cells are grossly disorganized, focused around the nucleus, whereas they were entirely missing or abnormally organized along the cell cortex. A high percentage of cells expressing nondestructible cyclin B1 had doubled DNA content as a result of undergoing endomitosis. During anaphase the cytokinesis-specific syntaxin KNOLLE could still localize to the midplane of cell division, whereas NPK1-activating kinesin-like protein 1, a cytokinetic kinesin-related protein, was unable to do so, and instead of the formation of a phragmoplast, the midzone microtubules persisted between the separated nuclei, which eventually fused. In summary, our results show that the timely degradation of mitotic cyclins in plants is required for the reorganization of mitotic microtubules to the phragmoplast and for proper cytokinesis. Subsequently, the presence of nondegradable cyclin B1 leads to a failure in organizing properly the cortical microtubules that determine cell elongation and shape.     

Endomitotic Megakaryocytes form a Midzone in Anaphase but Have a Deficiency in Cleavage Furrow Formation

Megakaryocyte differentiation is marked by development of progressive polyploidy and accumulation of large nuclear mass and cytoplasmic volume. During differentiation, megakaryocytes undergo repeated incomplete cell cycles in which mitosis is aborted in late anaphase with failure of cytokinesis, termed endomitosis. Recent studies have postulated that failure of Aurora-B kinase to localize to the spindle midzone is responsible for endomitosis in megakaryocytes. In diploid cells, the translocation of Aurora-B kinase is critical for positioning of the cleavage furrow, in part through its phosphorylation of the Rho family GTPase activating protein MgcRacGAP which in turn alters activity of RhoA. However, we have previously demonstrated that Aurora-B kinase localizes to centromeres and is functional in endomitotic megakaryocytes. Here, we show that endomitotic megakaryocytes form midzone structures that recruit Aurora-B kinase and its substrate MgcRacGAP. Although many cells with polyploid anaphases showed cortical localization of Aurora-B kinase, we did not observe accumulation of RhoA in furrows or formation of an actin ring. When mitotic exit was induced by inhibition of cdk1, diploid control cells formed furrows exhibiting cortical RhoA but megakaryocytes exited endomitosis without evidence of furrowing. Therefore, localization of Aurora-B kinase to the midzone is normal in endomitotic megakaryocytes but furrowing is abnormal. These data suggest that endomitotic MKs fail to complete cytokinesis due to aberrant regulation of furrowing at a step subsequent to the localization of Aurora-B kinase, possibly involving the activation or localization of RhoA. This work explores the mechanism of a normally occurring furrowing defect in a non-malignant primary cell.     

Endoreplication

Developmentally programmed polyploidy occurs by at least four different mechanisms, two of which (endoreduplication and endomitosis) involve switching from mitotic cell cycles to endocycles by the selective loss of mitotic cyclin-dependent kinase (CDK) activity and bypassing many of the processes of mitosis. Here we review the mechanisms of endoreplication, focusing on recent results from Drosophila and mice.Eukaryotic cells proliferate by undergoing a sequence of events termed the “mitotic cell cycle” in which the genome is duplicated once and only once between cell divisions. The result is a population of cells with two copies of each chromosome (diploid, or 2C). Agents that interfere with the mechanisms that govern genome duplication frequently induce reinitiation of nuclear DNA replication during S phase. This phenomenon, termed “DNA rereplication,” is an aberrant event that produces a population of cells with a heterogeneous DNA content that reflects incomplete chromosome duplication, stalled replication forks, and DNA damage. In most cells, these events can lead to inducing the cell’s DNA damage response and can lead to apoptosis (Lee et al. 2010).Remarkably, some cells are developmentally programmed to exit their mitotic cell cycle in response either to environmental signals or to injury or stress, and then differentiate into nonproliferating, viable, polyploid cells. This phenomenon, termed “developmentally programmed polyploidy,” is a normal part of animal and plant development that occurs frequently in ferns, flowering plants, mollusks, arthropods, amphibians, and fish, although rarely in mammals. In contrast to DNA rereplication, developmentally programmed polyploidy produces cells with a DNA content of >4C, but in integral multiples of 4C (e.g., 8C, 16C, 32C, etc.), consistent with multiple S phases in the absence of cytokinesis. These cells typically stop proliferating but remain viable in a terminally differentiated state that may serve to regulate tissue size or organization, to trigger cell differentiation or morphogenesis, to increase the number of genes dedicated to tissue-specific functions without increasing the number of cells, or to adapt to environmental conditions. Mitotic divisions of polyploid cells are common for plant species, but they are rarely found in animals. Although known for decades, polyploid mitosis in insects remained mostly unstudied until it was recently shown that the cells of the rectal papilla in Drosophila undergo mitosis after executing two or more endocycles (Fox et al. 2010). Thus, polyploidy is not an irreversible process, although the benefit of this cell cycle variant remains to be elucidated.Developmentally programmed polyploidy occurs by at least four different mechanisms (Ullah et al. 2009). Proliferating cells in the syncytial blastoderm of Drosophila embryos and some hepatocytes in the postnatal liver of mammals become multinucleated and therefore polyploid by failing to undergo cytokinesis after mitosis (“acytokinetic mitosis”). Differentiation of skeletal muscle myoblasts into myotubes, monocytes into osteoclasts, and formation of placental syncytiotrophoblasts involves “cell fusion” to produce multinucleated, terminally differentiated cells that are similarly polyploid. Alternatively, cells may exit their mitotic cell cycle by arresting mitosis during anaphase and failing to undergo cytokinesis. This phenomenon, termed “endomitosis,” produces cells with a single giant nucleus that may subsequently fragment into a multinuclear appearance. Endomitosis occurs in mammals when megakaryoblasts differentiate into megakaryocytes (Bluteau et al. 2009), and in some plant cells (Weingartner et al. 2004). However, the primary mechanism for developmentally programmed polyploidy in arthropods (Smith and Orr-Weaver 1991; Edgar and Orr-Weaver 2001), plants (de la Paz Sanchez et al. 2012), and possibly mammals (Ullah et al. 2009) is “endoreplication” (also referred to as “endoreduplication”). Endoreplication occurs when a cell exits the mitotic cell cycle in G₂ phase and undergoes multiple S phases without entering mitosis and undergoing cytokinesis. The result is a giant cell with a single, enlarged, polyploid nucleus.     

Mitotic catastrophe and endomitosis in tumour cells: an evolutionary key to a molecular solution

Following genotoxic insult, p53 mutated tumour cells undergo mitotic catastrophe. This is characterised by a switch from mitosis to the endocycle. The essential difference between mitosis and the endocycle is that in the latter, DNA synthesis is uncoupled from cell division, which leads to the formation of endopolyploid cells. Recent data suggests that a return from the endocycle into mitosis is also possible. Furthermore, our observations indicate that a particular type of endocycle known as endomitosis may be involved in this return. Here we review the role of endomitosis in the somatic reduction of polyploidy during development and its postulated role in the evolution of meiosis. Finally, we incorporate these evolutionary data to help interpret our most recent observations in the tumour cell system, which indicate a role for endomitosis and meiotic regulators, in particular p39mos in the segregation of genomes (somatic reduction) of these endopolyploid cells.     

Patterns of DNA and chromosome variation during in vitro growth in various genotypes of potato

Patterns of variation in nuclear DNA content and chromosome number were analysed in a temporal sequence, during in vitro growth of calli and cell suspensions in two monohaploids, a dihaploid and a tetraploid of potato (Solanum tuberosum). The results showed that both polyploidization and aneuploidy occurred during the initial stages of callus induction in all the genotypes. With further growth of callus, the frequency and extent of polyploidy and aneuploidy increased. In addition, the patterns of DNA and chromosome variation in cell suspension cultures revealed continued mitotic activity and transmission of cells with higher ploidy levels and aneuploidy. The results suggest that endoreduplication as well as endomitosis are important mechanisms of polyploidization, and that chromosome lagging and non-disjunction contribute to the production of aneuploidy.The various genotypes cultured under the same in vitro growth conditions differed in genetic instability, as assessed from the rate and degree of polyploidization and aneuploidy. Monohaploids showed more rapid rate of polyploidization than the dihaploid and tetraploid potatoes. It was concluded that the differences in genetic stability were due to different ploidy levels and genetic make-up of the genotypes.     

DNA damage-induced cell death is enhanced by progression through mitosis

Progression through the G₂/M transition following DNA damage is linked to cytokinesis failure and mitotic death. In four different transformed cell lines and two human embryonic stem cell lines, we find that DNA damage triggers mitotic chromatin decondensation and global phosphorylation of histone H2AX, which has been associated with apoptosis. However, extended time-lapse studies in HCT116 colorectal cancer cells indicate that death does not take place during mitosis, but 72% of cells die within 3 days of mitotic exit. By contrast, only 11% of cells in the same cultures that remained in interphase died, suggesting that progression through mitosis enhances cell death following DNA damage. These time-lapse studies also confirmed that DNA damage leads to high rates of cytokinesis failure, but showed that cells that completed cytokinesis following damage died at higher rates than cells that failed to complete division. Therefore, post-mitotic cell death is not a response to cytokinesis failure or polyploidy. We also show that post-mitotic cell death is largely independent of p53 and is only partially suppressed by the apical caspase inhibitor Z-VAD-FMK. These findings suggest that progression through mitosis following DNA damage initiates a p53- and caspase-independent cell death response that prevents propagation of genetic lesions.     

Polyploid megakaryocytes can complete cytokinesis

Megakaryocytes (MK) undergo polyploidization through endomitosis, a mitotic process that ends prematurely due to aborted cytokinesis. To better understand this and other events associated with MK differentiation, we performed long-term and large-field live cell imaging of human MKs derived in cord blood (CB) and bone marrow (BM) CD34+ cell cultures. Polyploid level of imaged cells was evaluated using three complementary approaches; cell history, cell size and ploidy correlation and nuclei staining. This system and strategy enabled the direct observation of the development of a large number of MKs (n=4865) and to quantify their fates. The most significant finding of this study is that a considerable proportion of polyploid MKs could complete cytokinesis. This unexpected process gave rise to polyploid daughter cell(s) with normal fates and contributed significantly to the expansion of polyploid MKs. Further analyses revealed that the proliferation rate amongst polyploid MKs was inversely correlated to their ploidy level, and that this phenomenon was much more frequent in CB- than BM-derived MKs. Accordingly, endomitosis was identified as the dominant fate of polyploid BM-MKs, while this was less accentuated for polyploid CB-MKs. These findings explain partially why CB-derived MKs remain in lower ploidy class. In conclusion, this study demonstrates that the development of polyploid MK results from the failure and/or success of cytokinesis and brings a new paradigm to the field of megakaryopoiesis.     

The characteristics of the course of mitosis in polykaryons formed during cell fusion]

A new method of cell fusion is proposed utilizing treatment with 15% solution of DMSO in serum before and after PEG treatment. With such treatments in SPEV cell culture a higher rate of cell fusion was obtained than that with other known methods of cell fusion. In the first wave of mitoses (0.5-4 h) mainly asynchronous division of nuclei, premature chromosome condensation and formation of telophase-like nuclei were observed in polykaryons. In the period of the second wave (14-20 h), mitoses were mainly synchronous and completed with cytokinesis. Micronuclei were formed frequently as a result of such mitoses. After the first wave of mitoses the number of polykaryons with pycnotic chromosomes sharply increased, and after the second wave of mitoses the number of polykaryons with pycnotic nuclei increased. The results obtained allow to conclude that heterophasic condition of the fused cells is one of the causes of pathological mitosis of polykaryons and of their death.     

Individual nuclei in polykaryons can control cyclin distribution and DNA synthesis.

Nuclear patterns of cyclin (PCNA) distribution that subdivide S-phase (determined using PCNA autoantibodies specific for this protein) as well as [3H]thymidine incorporation followed by autoradiography have been used to determine the S-phase synchrony of homophasic polykaryons produced by polyethylene glycol (PEG)-induced fusion of populations of mitotic transformed human amnion cells (AMA) exhibiting the following average distribution of phases: prophase, 9%, metaphase, 60% (including early and late prometaphase), anaphase, 3.8%, telophase, 26.2% and interphase, 1%. Both synchronous and asynchronous polykaryons were generated from these fusions; the latter being frequently observed only amongst populations of multinucleated cells having three or more nuclei. These results are taken to imply that individual nuclei in these polykaryons can control cyclin distribution and DNA synthesis in spite of the fact that they share a common cytoplasm.     

Morphological and cytofluorometric study of the giant cells of the trophoblast of the common vole]

The primary and secondary giant cells of trophoblast in placenta Microtus arvalis were studied. The giant polyploid nuclei are formed in result of series of successively proceeding endomitotic polyploidization of chromosomes. Two stages of endomitosis are described: endointerphase with the uniform net of thin chromatin threads and the stage when small round or rod-shaped paired chromosomes gather mostly under the nuclear membrane. Great number of round, oval, and complex-shaped nucleoli may be seen in nuclei during both stages of endomitosis, the number growing during polyploidization. The morphology of the chromosome-nucleolar apparatus involves peculiarities of the polyploidization mechanism in placenta Microtus arvalis trophoblast. Endomitosis occurs both in low and high-polyploid nuclei. Cytofluorometric determination of the DNA amount in nuclei polyploid nature. The degree of polyploidy of the trophoblast giant cells nuclei during terminal differentiation of placenta corresponds to 128c-512c, and some nuclei contain the DNA amount corresponding to 1024 and 2048 chromosomal sets. The cause of origin of the polyploid cells in trophoblast of rodents placenta is discussed.     

Temperature-sensitive cell cycle mutants: a chinese hamster cell line with a reversible block in cytokinesis.

A thermosensitive line (TS 111) was isolated from a suspension culture of Chinese hamster fibroblasts, using a BUdR suicide selection technique. In this line, cytokinesis is blocked at 39 degrees C. DNA and protein synthesis are not arrested but keep on at a steady rate. Giant cells are produced which accumulate either numerous nuclei or one big nucleus with several nucleoli and more than a hundred chromosomes. At each nuclear cycle, all the chromosomes in the cell appear to condense in a synchronous manner, although it is possible that not all the sets of chromosomes duplicate. When the culture is returned to the permissive temperature (34 degrees C) after a prolonged arrest at the restrictive temperature, cytokinesis resumes with early extrusion of karyoplasts from multinucleated cells. The division block is independent of cell density in suspension culture and is not prevented by cell contact when cells grow attached to Petri dishes. At 34 degrees C, a residual expression of the mutation is indicated by the presence of binucleate and up to 30% anucleate cells. A remarkable similarity and some synergism exists between the mutation and cytochalasin B effects.     

Presence of a defect in karyokinesis during megakaryocyte endomitosis

Megakaryocyte is the naturally polyploid cell that gives rise to platelets. Polyploidization occurs by endomitosis, a process corresponding to a late failure of cytokinesis with a backward movement of the daughter cells. Generally, a pure defect in cytokinesis produces a multinucleated cell, but megakaryocytes are characterized by a single polylobulated nucleus with a 2^N ploidy. Here, we show the existence of a defect in karyokinesis during the endomitotic process. From late telophase until the reversal of cytokinesis, some dipolar mitosis/endomitosis and most multipolar endomitosis present a thin DNA link between the segregated chromosomes surrounded by an incomplete nuclear membrane formation, which implies that sister chromatid separation is not complete. This observation may explain why polyploid megakaryocytes display a single polylobulated nucleus along with an increase in ploidy.     

The induction of polyploidy or apoptosis by the Aurora A kinase inhibitor MK8745 is p53-dependent

Aurora kinases are mitotic serine/threonine protein kinases and are attractive novel targets for anticancer therapy. Many small-molecule inhibitors of Aurora kinases are currently undergoing clinical trials. Aurora A kinase is essential for successful mitotic transition. MK8745 is a novel and selective small-molecule inhibitor of Aurora A kinase. MK8745 induced apoptotic cell death in a p53-dependent manner when tested in vitro in cell lines of multiple lineages. Cells expressing wild-type p53 showed a short delay in mitosis followed by cytokinesis, resulting in 2N cells along with apoptosis. However, cells lacking or with mutant p53 resulted in a prolonged arrest in mitosis followed by endoreduplication and polyploidy. Cytokinesis was completely inhibited in p53-deficient cells, as observed by the absence of 2N cell population. The induction of apoptosis in p53-proficient cells was associated with activation of caspase 3 and release of cytochrome c but was independent of p21. Exposure of p53 wild-type cells to MK8745 resulted in the induction of p53 phosphorylation (ser15) and an increase in p53 protein expression. p53-dependent apoptosis by MK8745 was further confirmed in HCT 116 p53^−/− cells transfected with wild-type p53. Transient knockdown of Aurora A by specific siRNA recapitulated these p53-dependent effects, with greater percent induction of apoptosis in p53 wild-type cells. In conclusion, our studies show p53 as a determining factor for induction of apoptosis vs. polyploidy upon inhibition of Aurora A.Key words: Aurora A kinase, polyploidy, apoptosis, p53, cell cycle     

CHRONOCRISIS: When Cell Cycle Asynchrony Generates DNA Damage in Polyploid Cells

Polyploid cells contain multiple copies of all chromosomes. Polyploidization can be developmentally programmed to sustain tissue barrier function or to increase metabolic potential and cell size. Programmed polyploidy is normally associated with terminal differentiation and poor proliferation capacity. Conversely, non-programmed polyploidy can give rise to cells that retain the ability to proliferate. This can fuel rapid genome rearrangements and lead to diseases like cancer. Here, the mechanisms that generate polyploidy are reviewed and the possible challenges upon polyploid cell division are discussed. The discussion is framed around a recent study showing that asynchronous cell cycle progression (an event that is named “chronocrisis”) of different nuclei from a polyploid cell can generate DNA damage at mitotic entry. The potential mechanisms explaining how mitosis in non-programmed polyploid cells can generate abnormal karyotypes and genetic instability are highlighted.     

Temporal and spatial regulation of phosphoinositide signaling mediates cytokinesis

Polarity is a prominent feature of both chemotaxis and cytokinesis. In chemotaxis, polarity is established by local accumulation of PI(3,4,5)P3 at the cell's leading edge, achieved through temporal and spatial regulation of PI3 kinases and the tumor suppressor, PTEN. We find that as migrating D. discoideum cells round up to enter cytokinesis, PI(3,4,5)P3 signaling is uniformly suppressed. Then, as the spindle and cell elongate, PI3 kinases and PTEN move to and function at the poles and furrow, respectively. Cell lines lacking both of these enzymatic activities fail to modulate PI(3,4,5)P3 levels, are defective in cytokinesis, and cannot divide in suspension. The cells continue to grow and duplicate their nuclei, generating large multinucleate cells. Furrows that fail to ingress between nuclei are unable to stably accumulate myosin filaments or suppress actin-filled ruffles. We propose that phosphoinositide-linked circuits, similar to those that bring about asymmetry during cell migration, also regulate polarity in cytokinesis.     

The induction of polyploidy or apoptosis by the Aurora A kinase inhibitor MK8745 is p53-dependent

Aurora kinases are mitotic serine/threonine protein kinases and are attractive novel targets for anticancer therapy. Many small-molecule inhibitors of Aurora kinases are currently undergoing clinical trials. Aurora A kinase is essential for successful mitotic transition. MK8745 is a novel and selective small-molecule inhibitor of Aurora A kinase. MK8745 induced apoptotic cell death in a p53-dependent manner when tested in vitro in cell lines of multiple lineages. Cells expressing wild-type p53 showed a short delay in mitosis followed by cytokinesis, resulting in 2N cells along with apoptosis. However, cells lacking or with mutant p53 resulted in a prolonged arrest in mitosis followed by endoreduplication and polyploidy. Cytokinesis was completely inhibited in p53-deficient cells, as observed by the absence of 2N cell population. The induction of apoptosis in p53-proficient cells was associated with activation of caspase 3 and release of cytochrome c but was independent of p21. Exposure of p53 wild-type cells to MK8745 resulted in the induction of p53 phosphorylation (ser15) and an increase in p53 protein expression. p53-dependent apoptosis by MK8745 was further confirmed in HCT 116 p53-/- cells transfected with wild-type p53. Transient knockdown of Aurora A by specific siRNA recapitulated these p53- dependent effects, with greater percent induction of apoptosis in p53 wild-type cells. In conclusion, our studies show p53 as a determining factor for induction of apoptosis vs. polyploidy upon inhibition of Aurora A.