Cell-scale biophysical determinants of cell competition in epithelia

Gradeci, Daniel; Bove, Anna; Vallardi, Giulia; Lowe, Alan R.; Banerjee, Shiladitya; Charras, Guillaume

doi:10.7554/elife.61011

Cited by 29 publications

(29 citation statements)

References 44 publications

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“…More sophisticated agent-based multi-scale models can be used to simulate more specific cell and tissue morphologies, such as competition during the transition to congruence. An example of such models was used in (Gradeci et al, 2021) using automatic annotation of movies of co-cultured wild-type and polarity deficient MDCK cells lasting up to 4 days, providing extensive input on the behaviour of wild-type and mutant cells. Their modelling identified that cell density and stiffness is sufficient to account for the apoptotic elimination of loser cells during mechanical competition.…”

Section: Discussionmentioning

confidence: 99%

Levels of p53 expression determine the competitive ability of embryonic stem cells during the onset of differentiation

Montero

Bowling

Pérez-Carrasco

et al. 2022

Preprint

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During development, the rate of tissue growth is determined by the relative balance of cell division and cell death. Cell competition is a fitness quality control mechanism that contributes to this balance by eliminating viable cells that are less-fit than their neighbours. What mutations confer cells with a competitive advantage or the dynamics of the interactions between winner and loser cells are not well understood. Here, we show that embryonic cells lacking the tumour suppressor p53 are super-competitors that eliminate their wild-type neighbours through the direct induction of apoptosis. This elimination is context dependant, as does not occur when cells are pluripotent and is triggered by the onset of differentiation. Furthermore, by combining mathematical modelling and cell-based assays we show that the elimination of wild-type cells is not through a competition for space or nutrients, but instead is mediated by short range interactions that are dependent on the local cell neighbourhood. This highlights the importance of the local cell neighbourhood and the competitive interactions within this neighbourhood for the regulation of proliferation during early embryonic development.

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Section: Discussionmentioning

confidence: 99%

Levels of p53 expression determine the competitive ability of embryonic stem cells during the onset of differentiation

Montero

Bowling

Pérez-Carrasco

et al. 2022

Preprint

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“…Given that ECM stiffness increases in certain pathologies including fibrotic diseases, cancer and inflammatory bowel diseases (IBD) ( Lampi and Reinhart-King, 2018 ; Onfroy-Roy et al, 2020 ), it remains still an open question whether varying ECM stiffness would promote or limit infected cell extrusion and, if so, what would be the physical and molecular mechanisms involved. Interestingly, Gradeci et al, showed that changes in the ratio of winner-to-loser cell stiffness altered the kinetics of cell competition between wild-type MDCK cells and cells depleted for the polarity protein scribble, although ECM stiffness was not addressed in this study ( Gradeci et al, 2021 ). Another study on competition between wild-type cells and oncogenically-transformed ones did show that increasing ECM stiffness attenuates extrusion of transformed cells by tuning the dynamic localization of filamin, an important F-actin crosslinking protein ( Pothapragada et al, 2022 ).…”

Section: Introductionmentioning

confidence: 72%

“…Cell competition refers to the process whereby less fit cells, often denoted “losers”, are sensed and eliminated by more fit neighboring cells, accordingly referred to as “winners” ( Gradeci et al, 2021 ). This competition between losers and winners is essential for tissue homeostasis but it also emerges during tissue development and can play a role in various pathologies including tumor development ( Meyer et al, 2014 ; Moreno et al, 2019 ).…”

Section: Introductionmentioning

confidence: 99%

A Stiff Extracellular Matrix Favors the Mechanical Cell Competition that Leads to Extrusion of Bacterially-Infected Epithelial Cells

Aparicio-Yuste

Muenkel

Clark

et al. 2022

Front. Cell Dev. Biol.

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Cell competition refers to the mechanism whereby less fit cells (“losers”) are sensed and eliminated by more fit neighboring cells (“winners”) and arises during many processes including intracellular bacterial infection. Extracellular matrix (ECM) stiffness can regulate important cellular functions, such as motility, by modulating the physical forces that cells transduce and could thus modulate the output of cellular competitions. Herein, we employ a computational model to investigate the previously overlooked role of ECM stiffness in modulating the forceful extrusion of infected “loser” cells by uninfected “winner” cells. We find that increasing ECM stiffness promotes the collective squeezing and subsequent extrusion of infected cells due to differential cell displacements and cellular force generation. Moreover, we discover that an increase in the ratio of uninfected to infected cell stiffness as well as a smaller infection focus size, independently promote squeezing of infected cells, and this phenomenon is more prominent on stiffer compared to softer matrices. Our experimental findings validate the computational predictions by demonstrating increased collective cell extrusion on stiff matrices and glass as opposed to softer matrices, which is associated with decreased bacterial spread in the basal cell monolayer in vitro. Collectively, our results suggest that ECM stiffness plays a major role in modulating the competition between infected and uninfected cells, with stiffer matrices promoting this battle through differential modulation of cell mechanics between the two cell populations.

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“…Evidence for homeostatic cell density as a predictor of fitness can be found in both experiments and simulations [1,16,38,39] and indeed homeostatic density has already been suggested as a competition driver, but only in a very limited sense: one that attributes fitness to a species-dependent threshold density above which apoptosis is triggered [40][41][42]. The quite intuitive reasoning for the homeostatic density driving the competition in that specific case is that the 'loser' species can be above the threshold and diminishes while the 'winner' species is still below its own apoptosis threshold and prospers.…”

Section: Discussionmentioning

confidence: 95%

“…Here, on the other hand, we allow for a more general relationship between the death and division rates that still supports homeostasis. Another distinction is that, in [40][41][42], division and death rates were considered to depend directly on the density of growing cells, while here we consider these to depend on pressure as seen experimentally in many systems including in epithelia [31], tumours [43,44], morphogenesis [2], yeast [30] and bacteria [45]. When proliferation and/or removal rates depend on pressure, they are affected by the production of all load-bearing matter in the confined system, and not just by the active growing cells.…”

Section: Discussionmentioning

confidence: 99%

A competitive advantage through fast dead matter elimination in confined cellular aggregates

2022

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Competition of different species or cell types for limited space is relevant in a variety of biological processes such as biofilm development, tissue morphogenesis and tumor growth. Predicting the outcome for non-adversarial competition of such growing active matter is non-trivial, as it depends on how processes like growth, proliferation and the degradation of cellular matter are regulated in confinement; regulation that happens even in the absence of competition to achieve the dynamic steady state known as homeostasis. Here, we show that passive by-products of the processes maintaining homeostasis can significantly alter fitness. Even for purely pressure-regulated growth and exclusively mechanical interactions, this enables cell types with lower homeostatic pressure to outcompete those with higher homeostatic pressure. We reveal that interfaces play a critical role for this specific kind of competition: There, growing matter with a higher proportion of active cells can better exploit local growth opportunities that continuously arise as the active processes keep the system out of mechanical equilibrium. We elucidate this effect in a theoretical toy model and test it in an agent-based computational model that includes finite-time mechanical persistence of dead cells and thereby decouples the density of growing cells from the homeostatic pressure. Our results suggest that self-organization of cellular aggregates into active and passive matter can be decisive for competition outcomes and that optimizing the proportion of growing (active) cells can be as important to survival as sensitivity to mechanical cues.

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Cell-scale biophysical determinants of cell competition in epithelia

Cited by 29 publications

References 44 publications

Levels of p53 expression determine the competitive ability of embryonic stem cells during the onset of differentiation

Levels of p53 expression determine the competitive ability of embryonic stem cells during the onset of differentiation

A Stiff Extracellular Matrix Favors the Mechanical Cell Competition that Leads to Extrusion of Bacterially-Infected Epithelial Cells

A competitive advantage through fast dead matter elimination in confined cellular aggregates

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