The fate of extra centrosomes in newly formed tetraploid cells: should I stay, or should I go?

Bloomfield, Mathew; Cimini, Daniela

doi:10.3389/fcell.2023.1210983

Cited by 4 publications

(3 citation statements)

References 226 publications

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“…We have demonstrated using 1 day treatment with AZD2811 to produced tetraploid cells that these can form viable colonies and have long term proliferative potential as diploid and tetraploid colonies. This supports the detailed fate studies of enforced tetraploid cells demonstrating reduced long term proliferative potential but stable tetraploid progeny is a potential outcome [37,45], and the genomics data demonstrating that tetraploidy can be tolerated by tumour cells [9], and In contrast to tetraploid cells, cells that undergo >2 failed cytokinesis and accumulate >8n DNA content and a corresponding increase in centrosome number have lost colony forming ability and long term proliferative potential. Indeed, in many of these experiments, exposure to AURKBi for the initial 2-3 days was sufficient to drive continued endomitotic cycles of failed cytokinesis.…”

Section: Discussionsupporting

confidence: 73%

“…It also appears that once cells have failed cytokinesis twice, they will continue to undergo further endomitotic cycles with failed cytokinesis in the absence of AURKBi. The increased centrosomes numbers and their ability to form individual mitotic spindles at each mitosis, rather than cluster to form pseudo-bipolar spindles that have been shown to enable relatively normal mitosis although commonly leading to cell death in subsequent mitosis [36,43,45]. The loss requirement for continued AURKBi treatment after 2-3 days is likely to be due to an inability of the mitotic, multipolar (>8 poles), hyper-polyploid (>8n DNA) cells to satisfy the spindle assembly checkpoint and undergo mitotic slippage without cytokinesis.…”

Section: Discussionmentioning

confidence: 99%

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Aurora B inhibition promotes a hyper-polyploid state and continued endomitotic cycles in RB and p53 defective cells

Vora,

Andrew,

Kumar

et al. 2024

Preprint

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Aurora B kinase (AURKB) inhibitors have been trialed in a range of different tumour types but are not approved for any indication. Expression of the HPV oncogenes and loss of retinoblastoma (RB) protein function has been reported to increase sensitivity to AURKB inhibitors but the mechanism of their contribution to sensitivity is poorly understood. Two commonly reported outcomes of AURKB inhibition are polyploidy and senescence, although their relationship is unclear. Here we have investigated the major cellular targets of the HPV E6 and E7, p53 and RB, to determine their contribution to AURKB inhibitor induced polyploidy and senescence. We demonstrate that polyploidy is a universal feature of AURKB inhibitor treatment in all cell types including normal primary cells, but the subsequent outcomes are controlled by RB and p53. We demonstrate that p53 is required for an initial cell cycle arrest, but this arrest is only triggered after cells have undergone two failed mitosis and cytokinesis, but cells can enter senescence in the absence of p53. RB is essential AURKB inhibitor-induced senescence, and AURKB inhibitor induces hypophosphorylation of RB independent of inhibition of CDK2 or CDK4 kinases and p53. Hypophosphorylation is driven by enhanced dephosphorylation of RB. This work defines how p53 and RB interact to promote senescence by downregulating a suite of cell cycle regulators that are targets for E2F and DREAM repression.

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Section: Discussionsupporting

confidence: 73%

Section: Discussionmentioning

confidence: 99%

Aurora B inhibition promotes a hyper-polyploid state and continued endomitotic cycles in RB and p53 defective cells

Vora,

Andrew,

Kumar

et al. 2024

Preprint

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“…Cells with too many centrioles might divide abnormally and/or undergo cell cycle arrest, leading to reduced proliferation or even cell death. Thus, centriole numbers appear to be maintained at an equilibrium by a balance of centriole overproduction and negative selection acting on cells with extra centrioles 26,33 . However, most studies are limited to investigating short-term effects and transient centriole number alterations.…”

Section: Introductionmentioning

confidence: 99%

Adaptation of human cell populations to different levels of centriole amplification involves a two-step response

Dias Louro,

Peneda,

Bank

et al. 2024

Preprint

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Centrioles are the main components of cilia and centrosomes, which play a central role in cell proliferation and signalling. Their number is strictly regulated. Centriole amplification, or the presence of extra centrioles, often occurs in tumours and leads to aneuploidy and altered signalling and has been associated with cancer development and malignancy. Negative selection of cells with extra centrioles prevents numerical errors from expanding in the population, resulting in an overproduction-selection balance. However, how chronic perturbation of key centriolar regulators affect centriole number dynamics is poorly described. PLK4, a key regulator of centriole biogenesis, is often overexpressed in cancer and is associated with worse prognosis in breast cancer. Here we show that centriole amplification cannot be sustained in cultured MCF10A breast cells exposed to low and high levels of chronic PLK4 overexpression. We observed a short-term response in which negative selection and reduction in PLK4 mRNA limit centriole amplification. This was followed by long-term adaptation in which a rise in PLK4 mRNA levels was decoupled from accumulation of the protein at the centrosome. Furthermore, adaptation was dose-dependent. Populations evolved in low-overexpression conditions retained the ability to generate extra centrioles when PLK4 was further overexpressed, whereas centriole overproduction was irreversibly inhibited in populations evolved under high PLK4 overexpression. Taken together, our data reveal a two step mode of centriole number regulation and suggest that differences in the level of PLK4 overexpression may condition cancer evolution.

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Amplified centrosomes—more than just a threat

Kiermaier,

Stötzel,

Schapfl

et al. 2024

EMBO Rep

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Centrosomes are major organizing components of the tubulin-based cytoskeleton. In recent years, we have gained extensive knowledge about their structure, biogenesis, and function from single cells, cell–cell interactions to tissue homeostasis, including their role in human diseases. Centrosome abnormalities are linked to, among others primary microcephaly, birth defects, ciliopathies, and tumorigenesis. Centrosome amplification, a state where two or more centrosomes are present in the G1 phase of the cell cycle, correlates in cancer with karyotype alterations, clinical aggressiveness, and lymph node metastasis. However, amplified centrosomes also appear in healthy tissues and, independent of their established role, in multi-ciliation. One example is the liver where hepatocytes carry amplified centrosomes owing to whole-genome duplication events during organogenesis. More recently, amplified centrosomes have been found in neuronal progenitors and several cell types of hematopoietic origin in which they enhance cellular effector functions. These findings suggest that extra centrosomes do not necessarily pose a risk for genome integrity and are harnessed for physiological processes. Here, we compare established and emerging ‘non-canonical functions’ of amplified centrosomes in cancerous and somatic cells and discuss their role in cellular physiology.

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The fate of extra centrosomes in newly formed tetraploid cells: should I stay, or should I go?

Cited by 4 publications

References 226 publications

Aurora B inhibition promotes a hyper-polyploid state and continued endomitotic cycles in RB and p53 defective cells

Aurora B inhibition promotes a hyper-polyploid state and continued endomitotic cycles in RB and p53 defective cells

Adaptation of human cell populations to different levels of centriole amplification involves a two-step response

Amplified centrosomes—more than just a threat

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