Cancer recurrence and lethality are enabled by enhanced survival and reversible cell cycle arrest of polyaneuploid cells

Pienta, Kenneth J.; Hammarlund, Emma U.; Brown, Joel S.; Amend, Sarah R.; Axelrod, Robert

doi:10.1073/pnas.2020838118

Cited by 80 publications

(106 citation statements)

References 143 publications

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“…Under stress PACCs are the majority of the population and enter into a quiescent state to survive. In this quiescent state PACCs contain high levels of lipids (Sirois et al, 2019), they do not reproduce (Pienta et al, 2021), and they are physically enlarged, similar to the enlarged S. cerevisiae. When stress is released, PACCs are able to undergo division (i.e., restart reproductive efforts) in the form of neosis (cell budding) to produce new, smaller progeny that are the same size as the original cell population (Figure 2C) (Sundaram et al, 2004;Zhang et al, 2013;Amend et al, 2019).…”

Section: Discussion: Understanding Different Types Of Dormancy Provides Insight Into Dormant Pacc Metabolismmentioning

confidence: 99%

“…These cells, defined as PACCs, exhibit temporary polyploidization of their aneuploid genome while simultaneously altering their metabolism to survive environmental stress (Pienta et al, 2020a,c). Following polyploidization, PACCs halt cell proliferation, entering a dormant state (Pienta et al, 2021). Eventually, when stress is removed, PACCs exit the dormant state and generate progeny to establish a recurrence (Puig, 2008;Zhang et al, 2013;Amend et al, 2019).…”

Section: Discussion: Understanding Different Types Of Dormancy Provides Insight Into Dormant Pacc Metabolismmentioning

confidence: 99%

“…active, and eventually reinitiate proliferation enables cancer cell survival and results in observed therapy resistant recurrence (Pienta et al, 2020c(Pienta et al, , 2021.…”

mentioning

confidence: 99%

“…New evidence suggests that the dormant cancer cell capable of surviving stress by entering a quiescent state is the polyaneuploid cancer cell (PACC) (Lopez-Sánchez et al, 2014;Pienta et al, 2021). PACCs [also referred to as polyploid giant cancer cells (PGCCs), multinucleated cancer cells, blastomere-like cancer cells, and osteoclast-like cancer cells] are enlarged cancer cells that have undergone whole-genome multiplication of their aneuploid genome (Erenpreisa et al, 2000(Erenpreisa et al, , 2008Mosieniak and Sikora, 2010;Zhang et al, 2014Zhang et al, , 2015Fei et al, 2015;Chen et al, 2019;Pienta et al, 2020c).…”

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confidence: 99%

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Polyaneuploid Cancer Cell Dormancy: Lessons From Evolutionary Phyla

2021

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Dormancy is a key survival strategy in many organisms across the tree of life. Organisms that utilize some type of dormancy (hibernation, aestivation, brumation, diapause, and quiescence) are able to survive in habitats that would otherwise be uninhabitable. Induction into dormant states is typically caused by environmental stress. While organisms are dormant, their physical activity is minimal, and their metabolic rates are severely depressed (hypometabolism). These metabolic reductions allow for the conservation and distribution of energy while conditions in the environment are poor. When conditions are more favorable, the organisms are then able to come out of dormancy and reengage in their environment. Polyaneuploid cancer cells (PACCs), proposed mediators of cancer metastasis and resistance, access evolutionary programs and employ dormancy as a survival mechanism in response to stress. Quiescence, the type of dormancy observed in PACCs, allows these cells the ability to survive stressful conditions (e.g., hypoxia in the microenvironment, transiting the bloodstream during metastasis, and exposure to chemotherapy) by downregulating and altering metabolic function, but then increasing metabolic activities again once stress has passed. We can gain insights regarding the mechanisms underlying PACC dormancy by looking to the evolution of dormancy in different organisms.

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Section: Discussion: Understanding Different Types Of Dormancy Provides Insight Into Dormant Pacc Metabolismmentioning

confidence: 99%

Section: Discussion: Understanding Different Types Of Dormancy Provides Insight Into Dormant Pacc Metabolismmentioning

confidence: 99%

“…active, and eventually reinitiate proliferation enables cancer cell survival and results in observed therapy resistant recurrence (Pienta et al, 2020c(Pienta et al, , 2021.…”

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confidence: 99%

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confidence: 99%

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Polyaneuploid Cancer Cell Dormancy: Lessons From Evolutionary Phyla

2021

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“…Polyaneuploid cancer cells (PACCs) are a recently discovered form of collusion in cancer. During times of microenvironmental stress, aneuploid cancer cells can fuse together to form PACCs, entering a state of quiescence or reversible therapy-induced senescence to protect their genome and avoid apoptosis (Pienta et al, 2021). Due to their high levels of genomic content, PACCs that enter the cell cycle and divide into non-polyploid cells can produce new phenotypic variants of cancer cells that contribute to cancer heterogeneity and lethality (Bukkuri et al, under review; Bukkuri et al, under preparation).…”

Section: Cousins Of Corruptionmentioning

confidence: 99%

Viewing Cancer Through the Lens of Corruption: Using Behavioral Ecology to Understand Cancer

Bukkuri

Adler

2021

Front. Ecol. Evol.

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All biological systems depend on signals for coordination: signals which pass information among agents that run the gamut from cells to organisms. However, their very importance makes signals vulnerable to subversion. How can a receiver know whether a signal is honest or deceptive? In other words, are signals necessarily a reliable indicator of agent quality or need? By drawing parallels to ecological phenomena ranging from begging by nestlings to social insects, we investigate the role of signal degradation in cancer. We thus think of cancer as a form of corruption, in which cells command huge resource investment through relatively cheap signals, just as relatively small bribes can leverage large profits. We discuss various mechanisms which prevent deceptive signaling in the natural world and within tissues. We show how cancers evolve ways to escape these controls and relate these back to evasion mechanisms in ecology. We next introduce two related concepts, co-option and collusion, and show how they play critical roles in ecology and cancer. Drawing on public policy, we propose new approaches to view treatment based on taxation, changing the incentive structure, and the recognition of corrupted signaling networks.

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Surviving the Storm: The Role of Poly‐ and Depolyploidization in Tissues and Tumors

Zhao,

He,

Zhao

et al. 2024

Advanced Science

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Polyploidization and depolyploidization are critical processes in the normal development and tissue homeostasis of diploid organisms. Recent investigations have revealed that polyaneuploid cancer cells (PACCs) exploit this ploidy variation as a survival strategy against anticancer treatment and for the repopulation of tumors. Unscheduled polyploidization and chromosomal instability in PACCs enhance malignancy and treatment resistance. However, their inability to undergo mitosis causes catastrophic cellular death in most PACCs. Adaptive ploid reversal mechanisms, such as multipolar mitosis, centrosome clustering, meiosis‐like division, and amitosis, counteract this lethal outcome and drive cancer relapse. The purpose of this work is to focus on PACCs induced by cytotoxic therapy, highlighting the latest discoveries in ploidy dynamics in physiological and pathological contexts. Specifically, by emphasizing the role of “poly‐depolyploidization” in tumor progression, the aim is to identify novel therapeutic targets or paradigms for combating diseases associated with aberrant ploidies.

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Cancer recurrence and lethality are enabled by enhanced survival and reversible cell cycle arrest of polyaneuploid cells

Cited by 80 publications

References 143 publications

Polyaneuploid Cancer Cell Dormancy: Lessons From Evolutionary Phyla

Polyaneuploid Cancer Cell Dormancy: Lessons From Evolutionary Phyla

Viewing Cancer Through the Lens of Corruption: Using Behavioral Ecology to Understand Cancer

Surviving the Storm: The Role of Poly‐ and Depolyploidization in Tissues and Tumors

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