TY - JOUR
T1 - Metabolic coordination and phase transitions in spatially distributed multi-cellular systems
AU - Narayanankutty, Krishnadev
AU - Pereiro-Morejon, José Antonio
AU - Ferrero-Fernández, Arián
AU - Onesto, Valentina
AU - Forciniti, Stefania
AU - del Mercato, Loretta L
AU - Mulet, Roberto
AU - De Martino, Andrea
AU - Tourigny, David
AU - De Martino, Daniele
N1 - K.N. and D.D.M. thank the FBB (Fundación Biofísica Bizkaia) for support. D.D.M. acknowledges financial support from the grants PIBA_2024_1_0016 (Basque Government) and Project PID2023-146408NB-I00 funded by MICIU/AEI/10.13039/501100011033 and by FEDER, UE. J.A.P.M., R.M., and A.D.M. acknowledge financial support from the European REA, Marie Skłodowska-Curie Actions, grant agreement no. 101131463 (SIMBAD). DST thanks Biofisika Institute for hosting him while part of this work was carried out. L.L.D.M. thanks the Associazione Italiana per la Ricerca contro il Cancro (AIRC) (MFAG-2019, n. 22902), the PRIN 2022 (2022CRFNCP) funded by the Italian Ministry of Research (MUR) European Union - Next Generation EU and the Italian Ministry of Research, under the complementary actions to the NRRP ‘Fit4MedRob - Fit for Medical Robotics’ Grant (#PNC0000007). A.F.F. acknowledges support from the Predoctoral Training Program for Non-Doctoral Research Personnel of the Basque Government's Department of Education.
PY - 2025/5/19
Y1 - 2025/5/19
N2 - 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.
AB - 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.
U2 - 10.1038/s42005-025-02133-x
DO - 10.1038/s42005-025-02133-x
M3 - Article
SN - 2399-3650
VL - 8
JO - Communications Physics
JF - Communications Physics
M1 - 205
ER -