A Similar Speciation Process Relying on Cellular Stochasticity in Microbial and Cancer Cell Populations

A Similar Speciation Process Relying on Cellular Stochasticity in Microbial and Cancer Cell Populations

Summary: Similarities between microbial and cancer cells were noticed in recent years and serve as a basis for an atavism theory of cancer. Cancer cells would rely on the reactivation of an ancestral “genetic program” that would have been repressed in metazoan cells. Here we argue that cancer cells...

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Main Authors: Jean-Pascal Capp, Frédéric Thomas
Format: Article
Language:English
Published: Elsevier 2020-09-01
Series:iScience
Subjects:
Ecology
Evolutionary Biology
Cancer
Online Access:http://www.sciencedirect.com/science/article/pii/S2589004220307239
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spelling doaj-a5e4d6135b314dde90cc431d5f5e9b0b2020-11-25T03:01:41ZengElsevieriScience2589-00422020-09-01239101531A Similar Speciation Process Relying on Cellular Stochasticity in Microbial and Cancer Cell PopulationsJean-Pascal Capp0Frédéric Thomas1Toulouse Biotechnology Institute, University of Toulouse, INSA, CNRS, INRAE, 31077 Toulouse, France; Corresponding authorCREEC, UMR IRD 224, CNRS 5290, University of Montpellier, 34394 Montpellier, FranceSummary: Similarities between microbial and cancer cells were noticed in recent years and serve as a basis for an atavism theory of cancer. Cancer cells would rely on the reactivation of an ancestral “genetic program” that would have been repressed in metazoan cells. Here we argue that cancer cells resemble unicellular organisms mainly in their similar way to exploit cellular stochasticity to produce cell specialization and maximize proliferation. Indeed, the relationship between low stochasticity, specialization, and quiescence found in normal differentiated metazoan cells is lost in cancer. On the contrary, low stochasticity and specialization are associated with high proliferation among cancer cells, as it is observed for the “specialist” cells in microbial populations that fully exploit nutritional resources to maximize proliferation. Thus, we propose a model where the appearance of cancer phenotypes can be solely due to an adaptation and a speciation process based on initial increase in cellular stochasticity.http://www.sciencedirect.com/science/article/pii/S2589004220307239EcologyEvolutionary BiologyCancer
collection DOAJ
language English
format Article
sources DOAJ
author Jean-Pascal Capp
Frédéric Thomas
spellingShingle Jean-Pascal Capp
Frédéric Thomas
A Similar Speciation Process Relying on Cellular Stochasticity in Microbial and Cancer Cell Populations
iScience
Ecology
Evolutionary Biology
Cancer
author_facet Jean-Pascal Capp
Frédéric Thomas
author_sort Jean-Pascal Capp
title A Similar Speciation Process Relying on Cellular Stochasticity in Microbial and Cancer Cell Populations
title_short A Similar Speciation Process Relying on Cellular Stochasticity in Microbial and Cancer Cell Populations
title_full A Similar Speciation Process Relying on Cellular Stochasticity in Microbial and Cancer Cell Populations
title_fullStr A Similar Speciation Process Relying on Cellular Stochasticity in Microbial and Cancer Cell Populations
title_full_unstemmed A Similar Speciation Process Relying on Cellular Stochasticity in Microbial and Cancer Cell Populations
title_sort similar speciation process relying on cellular stochasticity in microbial and cancer cell populations
publisher Elsevier
series iScience
issn 2589-0042
publishDate 2020-09-01
description Summary: Similarities between microbial and cancer cells were noticed in recent years and serve as a basis for an atavism theory of cancer. Cancer cells would rely on the reactivation of an ancestral “genetic program” that would have been repressed in metazoan cells. Here we argue that cancer cells resemble unicellular organisms mainly in their similar way to exploit cellular stochasticity to produce cell specialization and maximize proliferation. Indeed, the relationship between low stochasticity, specialization, and quiescence found in normal differentiated metazoan cells is lost in cancer. On the contrary, low stochasticity and specialization are associated with high proliferation among cancer cells, as it is observed for the “specialist” cells in microbial populations that fully exploit nutritional resources to maximize proliferation. Thus, we propose a model where the appearance of cancer phenotypes can be solely due to an adaptation and a speciation process based on initial increase in cellular stochasticity.
topic Ecology
Evolutionary Biology
Cancer
url http://www.sciencedirect.com/science/article/pii/S2589004220307239
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