Simulation of Somatic Evolution Through the Introduction of Random Mutation to the Rules of Conway’s Game of Life
Michael R. King

TL;DR
This paper uses a modified version of Conway’s Game of Life to simulate somatic evolution and tumor-like growth through random mutations in cellular rules.
Contribution
A novel CA model introduces random mutations to GOL rules, simulating somatic evolution and tumor growth dynamics.
Findings
Accumulated mutations in GOL rules lead to unregulated growth resembling tumor tissues.
The overcrowding threshold is the most critical mutated rule for tumor-like transitions.
Fitter subclones outcompete and replace wildtype cells in the simulation.
Abstract
Conway’s Game of Life (GOL), and related cellular automata (CA) models, have served as interesting simulations of complex behaviors resulting from simple rules of interactions between neighboring cells, that sometime resemble the growth and reproduction of living things. Thus, CA has been applied towards understanding the interaction and reproduction of single-cell organisms, and the growth of larger, disorganized tissues such as tumors. Surprisingly, however, there have been few attempts to adapt simple CA models to recreate the evolution of either new species, or subclones within a multicellular, tumor-like tissue. In this article, I present a modified form of the classic Conway’s GOL simulation, in which the three integer thresholds that define GOL (number of neighboring cells, below which a cell will “die of loneliness”; number of neighboring cells, above which a cell will die of…
Genes, proteins, chemicals, diseases, species, mutations and cell lines named across the full text — each resolved to its canonical identifier and authoritative record.
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Taxonomy
TopicsMathematical Biology Tumor Growth · Evolution and Genetic Dynamics · Cancer Genomics and Diagnostics
