Integrating Genetic and Nongenetic Drivers of Somatic Evolution During Carcinogenesis: The Biplane Model

Overview

Journal Evol Appl

Specialty Biology

Date 2020 Sep 21

PMID 32952610

Citations 9

Authors

Robert A Gatenby

Stanislav Avdieiev

Kenneth Y Tsai

Joel S Brown

Affiliations

Soon will be listed here.

Abstract

The multistep transition from a normal to a malignant cellular phenotype is often termed "somatic evolution" caused by accumulating random mutations. Here, we propose an alternative model in which the initial genetic state of a cancer cell is the result of mutations that occurred throughout the lifetime of the host. However, these mutations are not carcinogenic because normal cells in multicellular organism cannot ordinarily evolve. That is, proliferation and death of normal cells are controlled by local tissue constraints typically governed by nongenomic information dynamics in the cell membrane. As a result, the cells of a multicellular organism have a fitness that is identical to the host, which is then the unit of natural selection. Somatic evolution of a cell can occur only when its fate becomes independent of host constraints. Now, survival, proliferation, and death of individual cells are dependent on Darwinian dynamics. This cellular transition from host-defined fitness to self-defined fitness may, consistent with the conventional view of carcinogenesis, result from mutations that render the cell insensitive to host controls. However, an identical state will result when surrounding tissue cannot exert control because of injury, inflammation, aging, or infection. Here, all surviving cells within the site of tissue damage default to self-defined fitness functions allowing them to evolve so that the mutations accumulated over the lifetime of the host now serve as the genetic heritage of an evolutionary unit of selection. Furthermore, tissue injury generates a new ecology cytokines and growth factors that might promote proliferation in cells with prior receptor mutations. This model integrates genetic and nongenetic dynamics into cancer development and is consistent with both clinical observations and prior experiments that divided carcinogenesis to initiation, promotion, and progression steps.

Citing Articles

Lung adenocarcinomas without driver genes converge to common adaptive strategies through diverse genetic, epigenetic, and niche construction evolutionary pathways.

Gatenby R, Luddy K, Teer J, Berglund A, Freischel A, Carr R Med Oncol. 2024; 41(6):135.

PMID: 38704802 PMC: 11070398. DOI: 10.1007/s12032-024-02344-2.

The paradox of cooperation among selfish cancer cells.

Capp J, Thomas F, Marusyk A, Dujon A, Tissot S, Gatenby R Evol Appl. 2023; 16(7):1239-1256.

PMID: 37492150 PMC: 10363833. DOI: 10.1111/eva.13571.

Updating the Definition of Cancer.

Brown J, Amend S, Austin R, Gatenby R, Hammarlund E, Pienta K Mol Cancer Res. 2023; 21(11):1142-1147.

PMID: 37409952 PMC: 10618731. DOI: 10.1158/1541-7786.MCR-23-0411.

Mutation or not, what directly establishes a neoplastic state, namely cellular immortality and autonomy, still remains unknown and should be prioritized in our research.

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Identifying key questions in the ecology and evolution of cancer.

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