Three steps to the immortality of cancer cells: senescence, polyploidy and self-renewal

Ērenpreisa, Jekaterina; Cragg, Mark S.

doi:10.1186/1475-2867-13-92

Cited by 151 publications

(177 citation statements)

References 138 publications

(260 reference statements)

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“…Neosis is considered as occurring in multinucleated postsenescent cells and as being characterized by karyokinesis via nuclear budding and asymmetric cytokinesis, producing aneuploid mononuclear cells with extended lifespans and transient stem cell features. It is believed that polyploid mother cells die after these events (Rajaraman et al, 2006;Erenpreisa and Cragg, 2013). Consequently, genotoxic resistance seems to be closely associated with reversible senescence, polyploidization, and stemness.…”

Section: Introductionmentioning

confidence: 99%

Atypical Cell Populations Associated with Acquired Resistance to Cytostatics and Cancer Stem Cell Features: The Role of Mitochondria in Nuclear Encapsulation

Díaz-Carballo

Gustmann

Jastrow

et al. 2014

DNA and Cell Biology

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Until recently, acquired resistance to cytostatics had mostly been attributed to biochemical mechanisms such as decreased intake and/or increased efflux of therapeutics, enhanced DNA repair, and altered activity or deregulation of target proteins. Although these mechanisms have been widely investigated, little is known about membrane barriers responsible for the chemical imperviousness of cell compartments and cellular segregation in cytostatic-treated tumors. In highly heterogeneous cross-resistant and radiorefractory cell populations selected by exposure to anticancer agents, we found a number of atypical recurrent cell types in (1) tumor cell cultures of different embryonic origins, (2) mouse xenografts, and (3) paraffin sections from patient tumors. Alongside morphologic peculiarities, these populations presented cancer stem cell markers, aberrant signaling pathways, and a set of deregulated miRNAs known to confer both stem-cell phenotypes and highly aggressive tumor behavior. The first type, named spiral cells, is marked by a spiral arrangement of nuclei. The second type, monastery cells, is characterized by prominent walls inside which daughter cells can be seen maturing amid a rich mitochondrial environment. The third type, called pregnant cells, is a giant cell with a syncytium-like morphology, a main nucleus, and many endoreplicative functional progeny cells. A rare fourth cell type identified in leukemia was christened shepherd cells, as it was always associated with clusters of smaller cells. Furthermore, a portion of resistant tumor cells displayed nuclear encapsulation via mitochondrial aggregation in the nuclear perimeter in response to cytostatic insults, probably conferring imperviousness to drugs and long periods of dormancy until nuclear eclosion takes place. This phenomenon was correlated with an increase in both intracellular and intercellular mitochondrial traffic as well as with the uptake of free extracellular mitochondria. All these cellular disorders could, in fact, be found in untreated tumor cells but were more pronounced in resistant entities, suggesting a natural mechanism of cell survival triggered by chemical injury, or a primitive strategy to ensure stemming, self-renewal, and differentiation under adverse conditions, a fact that may play a significant role in chemotherapy outcomes.

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Section: Introductionmentioning

confidence: 99%

Atypical Cell Populations Associated with Acquired Resistance to Cytostatics and Cancer Stem Cell Features: The Role of Mitochondria in Nuclear Encapsulation

Díaz-Carballo

Gustmann

Jastrow

et al. 2014

DNA and Cell Biology

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“…Indeed, it is reasonable to suggest that the unique mechanism of acquired resistance to metformin has opposing roles in growth and metastatic dissemination, while refractoriness to metformin limits breast cancer cell growth, likely due to an aberrant mitotic/cytokinetic machinery and accelerated autophagy, it notably increases the potential of metastatic dissemination by amplifying the number of pro-migratory and stemness inputs via the activation of a significant number of proteases and EMT regulators. Future studies should unambiguously elucidate whether our findings using supra-physiological concentrations of metformin mechanistically recapitulate the processes through which the induction of a migratory-stemness cellular state paradoxically occurs in a polyploid, senescent-autophagic scenario [102][103][104][105] that is triggered by the chronic metabolic stresses that commonly occur during cancer development and after treatment with cancer drugs.…”

Section: P Value Ratiomentioning

confidence: 99%

Acquired resistance to metformin in breast cancer cells triggers transcriptome reprogramming toward a degradome-related metastatic stem-like profile

et al. 2014

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“…This is no surprise given the range of evolutionary trajectories that characterize diverse cancer types and the difficulty of obtaining a truly representative picture of the evolutionary paths that cell lineages follow within a single tumor (Gerlinger et al 2014b;Walther et al 2015). Beyond the unresolved population genetic considerations of the effects of variation in a polyploid context (e.g., see Otto and Whitton 2000;Gerstein and Otto 2009), on the phenotypic side, recent work suggested that polyploidy may indeed promote rampant aneuploidy and genetic and phenotypic diversity (Lagadec et al 2012;Erenpreisa and Cragg 2013;Zhang et al 2013). Furthermore, polyploid giant cells, which are often found in human solid tumors, are highly resistant to low oxygen conditions, cycle slowly (Zhang et al 2013), and have been proposed to also contribute to lineage expansion and heterogeneity upon induction by chemotherapy or radiation treatment (Lagadec et al 2012;Zhang et al 2013).…”

Section: Mammalsmentioning

confidence: 99%

Genome management and mismanagement—cell-level opportunities and challenges of whole-genome duplication

Yant

Bomblies

2015

Genes Dev.

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Whole-genome duplication (WGD) doubles the DNA content in the nucleus and leads to polyploidy. In whole-organism polyploids, WGD has been implicated in adaptability and the evolution of increased genome complexity, but polyploidy can also arise in somatic cells of otherwise diploid plants and animals, where it plays important roles in development and likely environmental responses. As with whole organisms, WGD can also promote adaptability and diversity in proliferating cell lineages, although whether WGD is beneficial is clearly context-dependent. WGD is also sometimes associated with aging and disease and may be a facilitator of dangerous genetic and karyotypic diversity in tumorigenesis. Scaling changes can affect cell physiology, but problems associated with WGD in large part seem to arise from problems with chromosome segregation in polyploid cells. Here we discuss both the adaptive potential and problems associated with WGD, focusing primarily on cellular effects. We see value in recognizing polyploidy as a key player in generating diversity in development and cell lineage evolution, with intriguing parallels across kingdoms.

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Three steps to the immortality of cancer cells: senescence, polyploidy and self-renewal

Cited by 151 publications

References 138 publications

Atypical Cell Populations Associated with Acquired Resistance to Cytostatics and Cancer Stem Cell Features: The Role of Mitochondria in Nuclear Encapsulation

Atypical Cell Populations Associated with Acquired Resistance to Cytostatics and Cancer Stem Cell Features: The Role of Mitochondria in Nuclear Encapsulation

Acquired resistance to metformin in breast cancer cells triggers transcriptome reprogramming toward a degradome-related metastatic stem-like profile

Genome management and mismanagement—cell-level opportunities and challenges of whole-genome duplication

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