Selective advantage of trisomic human cells cultured in non-standard conditions

Rutledge, Samuel; Douglas, Temple A.; Nicholson, Joshua M.; Vila-Casadesús, María; Kantzler, Courtney L.; Wangsa, Darawalee; Barroso-Vilares, Monika; Kale, Shiv D.; Logarinho, Elsa; Cimini, Daniela

doi:10.1038/srep22828

Cited by 99 publications

(76 citation statements)

References 59 publications

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“…For example, trisomy of chromosome 21 predisposes individuals to leukemia (Seewald et al, 2012), and gain of chromosome 21 is a common occurrence in sporadic leukemia (Loncarevic et al, 1999; Ozery-Flato et al, 2011), but trisomy of chromosome 21 appears to protect against the development of many other cancer types, including breast, lung, and prostate cancers (Nižetić and Groet, 2012). Similarly, a recent report suggests that, while aneuploidy is typically detrimental to cell fitness, under certain conditions, such as hypoxia or chemotherapy treatment, aneuploid cells may proliferate better than euploid cells do (Rutledge et al, 2016). Thus, while the nine aneuploid lines that we examined hinder or are neutral with regard to tumor growth in every assay that we performed, it is conceivable that a wider survey of aneuploidies, oncogenes, or growth conditions would reveal unusual cases in which aneuploidy provides a fitness advantage.…”

Section: Discussionmentioning

confidence: 99%

Single-chromosome Gains Commonly Function as Tumor Suppressors

et al. 2017

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SUMMARY Aneuploidy is a hallmark of cancer, although its effects on tumorigenesis are unclear. Here, we investigated the relationship between aneuploidy and cancer development using cells engineered to harbor single extra chromosomes. We found that nearly all trisomic cell lines grew poorly in vitro and as xenografts, relative to genetically matched euploid cells. Moreover, the activation of several oncogenic pathways failed to alleviate the fitness defect induced by aneuploidy. However, following prolonged growth, trisomic cells acquired additional chromosomal alterations that were largely absent from their euploid counterparts and that correlated with improved fitness. Thus, while single-chromosome gains can suppress transformation, the genome-destabilizing effects of aneuploidy confer an evolutionary flexibility that may contribute to the aggressive growth of advanced malignancies with complex karyotypes.

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Section: Discussionmentioning

confidence: 99%

Single-chromosome Gains Commonly Function as Tumor Suppressors

et al. 2017

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“…Similarly, one study found aneuploidy and CIN in murine liver promote regeneration after hepatic injury (Duncan et al, 2012), although two subsequent studies using single cell sequencing did not identify aneuploidy in wild type hepatocytes (Choi et al, 2016; Knouse et al, 2014). Human cells with an extra chromosome 7 or 13 have a proliferative advantage over diploid cells under multiple stresses (Rutledge et al, 2016). Together, these data suggest that aneuploidy and CIN generate phenotypic variation, which allows for adaptation to environmental stresses and could explain their prevalence in aggressive human cancers.…”

Section: The Aneuploidy Paradoxmentioning

confidence: 99%

Living in CIN: Mitotic Infidelity and Its Consequences for Tumor Promotion and Suppression

2016

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Summary Errors in chromosome segregation during mitosis have been recognized as a hallmark of tumor cells since the late 1800s, resulting in the long-standing hypothesis that mitotic abnormalities drive tumorigenesis. Recent work has shown that mitotic defects can promote tumors, suppress them, or do neither, depending on the rate of chromosome missegregation. Here we discuss the causes of chromosome missegregation, their effects on tumor initiation and progression, and the evidence that increasing the rate of chromosome missegregation may be an effective chemotherapeutic strategy.

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“…This concept has been clearly demonstrated in single-celled organisms (Rancati et al 2008, Selmecki et al 2009, Pavelka et al 2010, Yona et al 2012, Chang et al 2013, however, demonstrating this in human cells has been more challenging. There is evidence that aneuploid human cells, although generally appearing less fit than their euploid counterparts under 'standard' conditions (Williams et al 2008, Thompson & Compton 2010 display advantages under selective conditions (Rutledge et al 2016) and that aneuploidy of pluripotent stem cells promotes their efficient adaptation to culture conditions (Barbaric et al 2014, Na et al 2014. Further, aneuploidy in murine liver cells promotes adaptation to chronic liver injury (Duncan et al 2012).…”

Section: Cin: a Clinical Problemmentioning

confidence: 99%

Role of chromosomal instability in cancer progression

McClelland

2017

Endocrine-Related Cancer

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Cancer cells often display chromosomal instability (CIN), a defect that involves loss or rearrangement of the cell's genetic material -chromosomes -during cell division. This process results in the generation of aneuploidy, a deviation from the haploid number of chromosomes, and structural alterations of chromosomes in over 90% of solid tumours and many haematological cancers. This trait is unique to cancer cells as normal cells in the body generally strictly maintain the correct number and structure of chromosomes. This key difference between cancer and normal cells has led to two important hypotheses: (i) cancer cells have had to overcome inherent barriers to changes in chromosomes that are not tolerated in non-cancer cells and (ii) CIN represents a cancer-specific target to allow the specific elimination of cancer cells from the body. To exploit these hypotheses and design novel approaches to treat cancer, a full understanding of the mechanisms driving CIN and how CIN contributes to cancer progression is required. Here, we will discuss the possible mechanisms driving chromosomal instability, how CIN may contribute to the progression at multiple stages of tumour evolution and possible future therapeutic directions based on targeting cancer chromosomal instability.

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Selective advantage of trisomic human cells cultured in non-standard conditions

Cited by 99 publications

References 59 publications

Single-chromosome Gains Commonly Function as Tumor Suppressors

Single-chromosome Gains Commonly Function as Tumor Suppressors

Living in CIN: Mitotic Infidelity and Its Consequences for Tumor Promotion and Suppression

Role of chromosomal instability in cancer progression

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