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Metabolic coordination and phase transitions in spatially distributed multi-cellular systems

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arxiv 2405.13424 v2 pith:LQKHJO4U submitted 2024-05-22 cond-mat.stat-mech physics.bio-phq-bio.CB

Metabolic coordination and phase transitions in spatially distributed multi-cellular systems

classification cond-mat.stat-mech physics.bio-phq-bio.CB
keywords metabolicoverflowmetabolismmulti-cellularsingle-cellcoordinationdataexchanges
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During overflow metabolism, cells excrete glycolytic byproducts when growing under aerobic conditions in a seemingly wasteful fashion. While potentially advantageous for microbes with finite oxidative capacity, its role in higher organisms is harder to assess. Recent single-cell experiments suggest overflow metabolism arises due to imbalances in inter-cellular exchange networks. We quantitatively characterize this scenario by integrating spatial metabolic modeling with tools from statistical physics and experimental single-cell flux data. Our results provide a theoretical demonstration of how diffusion-limited exchanges shape the space of accessible multi-cellular metabolic states. Specifically, a phase transition from a balanced network of exchanges to an unbalanced, overflow regime occurs as mean glucose and oxygen uptake rates vary. Heterogeneous single-cell metabolic phenotypes occur near this transition. Time-resolved tumor-stroma co-culture data support the idea that overflow metabolism stems from failure of inter-cellular metabolic coordination. In summary, environmental control is an emergent multi-cellular property, rather than a cell-autonomous effect.

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