Group phenotypic composition in cancer

Capp, Jean‐Pascal; DeGregori, James; Nedelcu, Aurora M.; Dujon, Antoine; Boutry, Justine; Pujol, Pascal; Alix‐Panabières, Catherine; Hamede, Rodrigo; Roche, Benjamín; Újvári, Beáta; Marusyk, Andriy; Gatenby, Robert A.; Thomas, Fréderic

doi:10.7554/elife.63518

Cited by 20 publications

(23 citation statements)

References 134 publications

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“…This prediction matches the increasingly acknowledged role of gene loss for evolutionary adaptation (115)(116)(117)(118)(119)(120)(121)(122). It also provides a plausible explanation for recurrent mutations in cancer cells (see below), recurring intratumoral phenotypic clusters (77,123,124), and the convergence towards the relatively few hallmarks of cancer (125). Importantly, most if not all the evidence presented above is commonly interpreted as, and may indeed be, the result of positive selection.…”

Section: The Use-it or Lose-it Model Of Adaptive Evolution Has Considerable Explanatory Power And Makes Testable Predictionssupporting

confidence: 70%

“…For example, it should help integrate ubiquitous and wellestablished phenomena such as pleiotropy, plasticity, and trade-offs (76). Also, it should be explicit about the relative contribution of evolutionary forces in the onset of adaptations as well as the interaction between these forces and the environment [e.g., surrounding tumor cells (77)]. Further, it should be able to integrate genetics and epigenetics, both of which play a central role in the emergence of cancer and cancer drug resistance [e.g., (13)].…”

Section: A Mechanism Of Adaptive Evolution Without Positive Selectionmentioning

confidence: 99%

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Bridging Tumorigenesis and Therapy Resistance With a Non-Darwinian and Non-Lamarckian Mechanism of Adaptive Evolution

et al. 2021

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Although neo-Darwinian (and less often Lamarckian) dynamics are regularly invoked to interpret cancer’s multifarious molecular profiles, they shine little light on how tumorigenesis unfolds and often fail to fully capture the frequency and breadth of resistance mechanisms. This uncertainty frames one of the most problematic gaps between science and practice in modern times. Here, we offer a theory of adaptive cancer evolution, which builds on a molecular mechanism that lies outside neo-Darwinian and Lamarckian schemes. This mechanism coherently integrates non-genetic and genetic changes, ecological and evolutionary time scales, and shifts the spotlight away from positive selection towards purifying selection, genetic drift, and the creative-disruptive power of environmental change. The surprisingly simple use-it or lose-it rationale of the proposed theory can help predict molecular dynamics during tumorigenesis. It also provides simple rules of thumb that should help improve therapeutic approaches in cancer.

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Section: The Use-it or Lose-it Model Of Adaptive Evolution Has Considerable Explanatory Power And Makes Testable Predictionssupporting

confidence: 70%

Section: A Mechanism Of Adaptive Evolution Without Positive Selectionmentioning

confidence: 99%

Bridging Tumorigenesis and Therapy Resistance With a Non-Darwinian and Non-Lamarckian Mechanism of Adaptive Evolution

et al. 2021

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“…Here we see teams in terms of intracellular regulatory networks, but this framework of identifying composition of two (or more) groups acting together to reinforce each other in scenarios of competing outcome can be applied more broadly. For instance different cells in a microenvironment can form groups with pro tumor and anti-tumor inflence (41). How and when are these teams of cells formed remains to be identified.…”

Section: Discussionmentioning

confidence: 99%

Landscape of Epithelial Mesenchymal Plasticity as an emergent property of coordinated teams in regulatory networks

Hari

Ullanat²,

Balasubramanian

et al. 2021

Preprint

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Elucidating the principles of cellular decision-making is of fundamental importance. These decisions are often orchestrated by underlying regulatory networks. While we understand the dynamics of simple network motifs, how do large networks lead to a limited number of phenotypes, despite their complexity, remains largely elusive. Here, we investigate five different networks governing epithelial-mesenchymal plasticity and identified a latent design principles in their topology that limits their phenotypic repertoire - the presence of two 'teams' of nodes engaging in a mutually inhibitory feedback loop, forming a toggle switch. These teams are specific to these networks and directly shape the phenotypic landscape and consequently the frequency and stability of terminal phenotypes vs. the intermediary ones. Our analysis reveals that network topology alone can contain information about phenotypic distributions it can lead to, thus obviating the need to simulate them. We unravel topological signatures that can drive canalization of cell-fates during diverse decision-making processes.

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“…More importantly, tumor cells that push the healthy tissue belong to different clones 17 . These subpopulations may cooperate 18 – 21 or compete 22 – 24 with each other during their way to invade the surrounding healthy tissue 25 . Despite huge literature on clonal diversity in tumors, it is not clear that how such interactions regulate invasion and how the intensity of environmental barriers restricts invasion.…”

Section: Introductionmentioning

confidence: 99%

Invasion front dynamics of interactive populations in environments with barriers

Azimzade

2022

Sci Rep

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Invading populations normally comprise different subpopulations that interact while trying to overcome existing barriers against their way to occupy new areas. However, the majority of studies so far only consider single or multiple population invasion into areas where there is no resistance against the invasion. Here, we developed a model to study how cooperative/competitive populations invade in the presence of a physical barrier that should be degraded during the invasion. For one dimensional (1D) environment, we found that a Langevin equation as $$dX/dt=V_ft+\sqrt{D_f}\eta (t)$$ d X / d t = V f t + D f η ( t ) describing invasion front position. We then obtained how $$V_f$$ V f and $$D_f$$ D f depend on population interactions and environmental barrier intensity. In two dimensional (2D) environment, for the average interface position movements we found a Langevin equation as $$dH/dt=V_Ht+\sqrt{D_H}\eta (t)$$ d H / d t = V H t + D H η ( t ) . Similar to the 1D case, we calculate how $$V_H$$ V H and $$D_H$$ D H respond to population interaction and environmental barrier intensity. Finally, the study of invasion front morphology through dynamic scaling analysis showed that growth exponent, $$\beta$$ β , depends on both population interaction and environmental barrier intensity. Saturated interface width, $$W_{sat}$$ W sat , versus width of the 2D environment (L) also exhibits scaling behavior. Our findings show revealed that competition among subpopulations leads to more rough invasion fronts. Considering the wide range of shreds of evidence for clonal diversity in cancer cell populations, our findings suggest that interactions between such diverse populations can potentially participate in the irregularities of tumor border.

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Group phenotypic composition in cancer

Cited by 20 publications

References 134 publications

Bridging Tumorigenesis and Therapy Resistance With a Non-Darwinian and Non-Lamarckian Mechanism of Adaptive Evolution

Bridging Tumorigenesis and Therapy Resistance With a Non-Darwinian and Non-Lamarckian Mechanism of Adaptive Evolution

Landscape of Epithelial Mesenchymal Plasticity as an emergent property of coordinated teams in regulatory networks

Invasion front dynamics of interactive populations in environments with barriers

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