CIN and Aneuploidy: Different Concepts, Different Consequences

Schukken, Klaske M.; Foijer, Floris

doi:10.1002/bies.201700147

Cited by 44 publications

(38 citation statements)

References 116 publications

(169 reference statements)

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“…We, therefore, reasoned that targeting RNA or protein processing, transcriptional regulation, apoptosis, or DNA repair might be particularly toxic to aneuploid cells and cells exhibiting a CIN phenotype. As CIN and aneuploidy are different concepts (Schukken & Foijer, 2018) and have different consequences for cells (Stingele et al, 2012;Andriani et al, 2016;Schukken & Foijer, 2018) aneuploidy and CIN might impose different therapeutic vulnerabilities. To test this, we performed two small-scale drug screens, one to identify compounds that selectively prevent the propagation of aneuploid cells and another to identify small molecules that selectively targets CIN cells.…”

Section: Resultsmentioning

confidence: 99%

“…Although CIN and aneuploidy are intimately related, CIN has additional effects on cell physiology and growth in addition to those imposed by the resulting aneuploidy (Schukken and Foijer, 2018). Because CIN drives karyotype heterogeneity, thus increasing the rate of evolution that cancer cells use to acquire new features and adapt (McGranahan et al, 2012;Giam & Rancati, 2015), targeting CIN would provide an even more powerful means to kill cancer cells than aneuploidy alone.…”

Section: Introductionmentioning

confidence: 99%

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Altering microtubule dynamics is synergistically toxic with spindle assembly checkpoint inhibition

et al. 2020

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Chromosomal instability (CIN) and aneuploidy are hallmarks of cancer. As most cancers are aneuploid, targeting aneuploidy or CIN may be an effective way to target a broad spectrum of cancers. Here, we perform two small molecule compound screens to identify drugs that selectively target cells that are aneuploid or exhibit a CIN phenotype. We find that aneuploid cells are much more sensitive to the energy metabolism regulating drug ZLN005 than their euploid counterparts. Furthermore, cells with an ongoing CIN phenotype, induced by spindle assembly checkpoint (SAC) alleviation, are significantly more sensitive to the Src kinase inhibitor SKI606. We show that inhibiting Src kinase increases microtubule polymerization rates and, more generally, that deregulating microtubule polymerization rates is particularly toxic to cells with a defective SAC. Our findings, therefore, suggest that tumors with a dysfunctional SAC are particularly sensitive to microtubule poisons and, vice versa, that compounds alleviating the SAC provide a powerful means to treat tumors with deregulated microtubule dynamics.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Altering microtubule dynamics is synergistically toxic with spindle assembly checkpoint inhibition

et al. 2020

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“…CS defects such as those observed in our CIC KO lines, including the presence of micronuclei and lagging chromosomes, have been linked to copy number alterations in daughter cells [30][31][32] . To determine whether evidence of copy number defects could be observed in CICdeficient cells, we performed single-cell genome sequencing (DLP+ 33 ) on DNA libraries from the parental CIC WT NHA line and NHA-derived CIC KO lines (A2 and H9 described above, and additional lines B6 and H10).…”

Section: Loss Of Cic In Nha Cells Is Associated With Copy Number Altementioning

confidence: 72%

Multi-omic analysis of CIC’s functional networks reveals novel interaction partners and a potential role in mitotic fidelity

Chittaranjan

Song

Chan

et al. 2019

Preprint

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Background: CIC is a transcriptional repressor inactivated by loss-of-function mutations in several cancer types, including gliomas, lung cancers, and gastric adenocarcinomas. CIC alterations and/or loss of CIC activity have been associated with poorer outcomes and more aggressive phenotypes across cancer types, which is consistent with the notion that CIC functions as a tumour suppressor across a wide range of contexts.Results: Using mammalian cells lacking functional CIC, we found that CIC deficiency was associated with chromosome segregation (CS) defects, resulting in chromosomal instability and aneuploidy. These CS defects were associated with transcriptional dysregulation of spindle assembly checkpoint and cell cycle regulators. We also identified novel CIC interacting proteins, including core members of the SWI/SNF complex, and showed that they cooperatively regulated the expression of genes involved in cell cycle regulation. Finally, we showed that loss of CIC and ARID1A cooperatively increased CS defects and reduced cell viability. Conclusions:Our study ascribes a novel role to CIC as an important regulator of the cell cycle and demonstrates that loss of CIC can lead to chromosomal instability and aneuploidy in human and murine cells through defects in CS, providing insight into the underlying mechanisms of CIC's increasingly apparent role as a "pan-cancer" tumour suppressor.

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“…We therefore reasoned that targeting RNA or protein processing, transcriptional regulation, apoptosis, or DNA repair might be particularly toxic to aneuploid cells and cells exhibiting a CIN phenotype. As CIN and aneuploidy are different concepts (Schukken & Foijer, 2017) and have different consequences for cells (Schukken & Foijer, 2017; Stingele et al , 2012; Andriani et al , 2016), aneuploidy and CIN might impose different therapeutic vulnerabilities. To test this, we performed two small-scale drug screens, one to identify compounds that selectively kill aneuploid cells and another to identify small molecules that selectively kill CIN cells.…”

Section: Resultsmentioning

confidence: 99%

“…While CIN and aneuploidy are intimately related, CIN has additional effects on cell physiology and growth in addition to those imposed by the resulting aneuploidy (Schukken & Foijer, 2017). Since CIN drives karyotype heterogeneity thus increasing the rate of evolution that cancer cells use to acquire new features and adapt (Giam & Rancati, 2015; McGranahan et al , 2012), targeting CIN would provide an even more powerful means to kill cancer cells than aneuploidy alone.…”

Section: Introductionmentioning

confidence: 99%

Altering microtubule dynamics is synergistically toxic with inhibition of the spindle checkpoint

Schukken

Lin

Schubert

et al. 2019

Preprint

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Chromosome instability (CIN) and aneuploidy are hallmarks of cancer. As the majority of cancers are aneuploid, targeting aneuploidy or CIN may be an effective way to target a broad spectrum of cancers. Here, we perform two small molecule compound screens to identify drugs that selectively target cells that are aneuploid or exhibit a CIN phenotype. We find that aneuploid cells are much more sensitive to the energy metabolism regulating drug ZLN005 than their euploid counterparts. Furthermore, cells with an ongoing CIN phenotype, induced by spindle assembly checkpoint (SAC) alleviation, are significantly more sensitive to the Src kinase inhibitor SKI606. We show that inhibiting Src kinase increases microtubule polymerization rates and, more generally, that deregulating microtubule polymerization rates is particularly toxic to cells with a defective SAC. Our findings therefore suggest that tumors with a dysfunctional SAC are particularly sensitive to microtubule poisons and, vice versa, that compounds alleviating the SAC provide a powerful means to treat tumors with deregulated microtubule dynamics.

show abstract

CIN and Aneuploidy: Different Concepts, Different Consequences

Cited by 44 publications

References 116 publications

Altering microtubule dynamics is synergistically toxic with spindle assembly checkpoint inhibition

Altering microtubule dynamics is synergistically toxic with spindle assembly checkpoint inhibition

Multi-omic analysis of CIC’s functional networks reveals novel interaction partners and a potential role in mitotic fidelity

Altering microtubule dynamics is synergistically toxic with inhibition of the spindle checkpoint

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