Lactate controls cancer stemness and plasticity through epigenetic regulation

Nguyen T B Nguyen; Sira Gevers; Rutger N U Kok; Lotte M Burgering; Hannah Neikes; Ninouk Akkerman; Max A Betjes; Marlies C Ludikhuize; Can Gulersonmez; Edwin C A Stigter; Yvonne Vercoulen; Jarno Drost; Hans Clevers; Michiel Vermeulen; Jeroen S van Zon; Sander J Tans; Boudewijn M T Burgering; Maria J Rodríguez Colman

doi:10.1016/j.cmet.2025.01.002

Lactate controls cancer stemness and plasticity through epigenetic regulation

Nguyen T B Nguyen, Sira Gevers, Rutger N U Kok, Lotte M Burgering, Hannah Neikes, Ninouk Akkerman, Max A Betjes, Marlies C Ludikhuize, Can Gulersonmez, Edwin C A Stigter, Yvonne Vercoulen, Jarno Drost, Hans Clevers, Michiel Vermeulen, Jeroen S van Zon, Sander J Tans, Boudewijn M T Burgering, Maria J Rodríguez Colman

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Tumors arise from uncontrolled cell proliferation driven by mutations in genes that regulate stem cell renewal and differentiation. Intestinal tumors, however, retain some hierarchical organization, maintaining both cancer stem cells (CSCs) and cancer differentiated cells (CDCs). This heterogeneity, coupled with cellular plasticity enabling CDCs to revert to CSCs, contributes to therapy resistance and relapse. Using genetically encoded fluorescent reporters in human tumor organoids, combined with our machine-learning-based cell tracker, CellPhenTracker, we simultaneously traced cell-type specification, metabolic changes, and reconstructed cell lineage trajectories during tumor organoid development. Our findings reveal distinctive metabolic phenotypes in CSCs and CDCs. We find that lactate regulates tumor dynamics, suppressing CSC differentiation and inducing dedifferentiation into a proliferative CSC state. Mechanistically, lactate increases histone acetylation, epigenetically activating MYC. Given that lactate's regulation of MYC depends on the bromodomain-containing protein 4 (BRD4), targeting cancer metabolism and BRD4 inhibitors emerge as a promising strategy to prevent tumor relapse.

Originele taal-2	Engels
Tijdschrift	Cell Metabolism
Vroegere onlinedatum	4 feb. 2025
DOI's	https://doi.org/10.1016/j.cmet.2025.01.002
Status	Gepubliceerd - 2025

Trefwoorden

cancer metabolism
cell plasticity
cell types
cell-cell interactions
differentiation
heterogeneity
live imaging
organoids
single-cell tracking
stem cells

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10.1016/j.cmet.2025.01.002

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Nguyen, N. T. B., Gevers, S., Kok, R. N. U., Burgering, L. M., Neikes, H., Akkerman, N., Betjes, M. A., Ludikhuize, M. C., Gulersonmez, C., Stigter, E. C. A., Vercoulen, Y., Drost, J., Clevers, H., Vermeulen, M., van Zon, J. S., Tans, S. J., Burgering, B. M. T., & Rodríguez Colman, M. J. (2025). Lactate controls cancer stemness and plasticity through epigenetic regulation. Cell Metabolism. https://doi.org/10.1016/j.cmet.2025.01.002

@article{1c7a0f6287a64937be8c51c7b541f0a7,

title = "Lactate controls cancer stemness and plasticity through epigenetic regulation",

abstract = "Tumors arise from uncontrolled cell proliferation driven by mutations in genes that regulate stem cell renewal and differentiation. Intestinal tumors, however, retain some hierarchical organization, maintaining both cancer stem cells (CSCs) and cancer differentiated cells (CDCs). This heterogeneity, coupled with cellular plasticity enabling CDCs to revert to CSCs, contributes to therapy resistance and relapse. Using genetically encoded fluorescent reporters in human tumor organoids, combined with our machine-learning-based cell tracker, CellPhenTracker, we simultaneously traced cell-type specification, metabolic changes, and reconstructed cell lineage trajectories during tumor organoid development. Our findings reveal distinctive metabolic phenotypes in CSCs and CDCs. We find that lactate regulates tumor dynamics, suppressing CSC differentiation and inducing dedifferentiation into a proliferative CSC state. Mechanistically, lactate increases histone acetylation, epigenetically activating MYC. Given that lactate's regulation of MYC depends on the bromodomain-containing protein 4 (BRD4), targeting cancer metabolism and BRD4 inhibitors emerge as a promising strategy to prevent tumor relapse.",

keywords = "cancer metabolism, cell plasticity, cell types, cell-cell interactions, differentiation, heterogeneity, live imaging, organoids, single-cell tracking, stem cells",

author = "Nguyen, {Nguyen T B} and Sira Gevers and Kok, {Rutger N U} and Burgering, {Lotte M} and Hannah Neikes and Ninouk Akkerman and Betjes, {Max A} and Ludikhuize, {Marlies C} and Can Gulersonmez and Stigter, {Edwin C A} and Yvonne Vercoulen and Jarno Drost and Hans Clevers and Michiel Vermeulen and {van Zon}, {Jeroen S} and Tans, {Sander J} and Burgering, {Boudewijn M T} and {Rodr{\'i}guez Colman}, {Maria J}",

year = "2025",

doi = "10.1016/j.cmet.2025.01.002",

language = "English",

journal = "Cell Metabolism",

issn = "1550-4131",

publisher = "Cell Press",

}

Nguyen, NTB, Gevers, S, Kok, RNU, Burgering, LM, Neikes, H, Akkerman, N, Betjes, MA, Ludikhuize, MC, Gulersonmez, C, Stigter, ECA, Vercoulen, Y, Drost, J , Clevers, H, Vermeulen, M, van Zon, JS, Tans, SJ, Burgering, BMT & Rodríguez Colman, MJ 2025, 'Lactate controls cancer stemness and plasticity through epigenetic regulation', Cell Metabolism. https://doi.org/10.1016/j.cmet.2025.01.002

TY - JOUR

T1 - Lactate controls cancer stemness and plasticity through epigenetic regulation

AU - Nguyen, Nguyen T B

AU - Gevers, Sira

AU - Kok, Rutger N U

AU - Burgering, Lotte M

AU - Neikes, Hannah

AU - Akkerman, Ninouk

AU - Betjes, Max A

AU - Ludikhuize, Marlies C

AU - Gulersonmez, Can

AU - Stigter, Edwin C A

AU - Vercoulen, Yvonne

AU - Drost, Jarno

AU - Clevers, Hans

AU - Vermeulen, Michiel

AU - van Zon, Jeroen S

AU - Tans, Sander J

AU - Burgering, Boudewijn M T

AU - Rodríguez Colman, Maria J

PY - 2025

Y1 - 2025

N2 - Tumors arise from uncontrolled cell proliferation driven by mutations in genes that regulate stem cell renewal and differentiation. Intestinal tumors, however, retain some hierarchical organization, maintaining both cancer stem cells (CSCs) and cancer differentiated cells (CDCs). This heterogeneity, coupled with cellular plasticity enabling CDCs to revert to CSCs, contributes to therapy resistance and relapse. Using genetically encoded fluorescent reporters in human tumor organoids, combined with our machine-learning-based cell tracker, CellPhenTracker, we simultaneously traced cell-type specification, metabolic changes, and reconstructed cell lineage trajectories during tumor organoid development. Our findings reveal distinctive metabolic phenotypes in CSCs and CDCs. We find that lactate regulates tumor dynamics, suppressing CSC differentiation and inducing dedifferentiation into a proliferative CSC state. Mechanistically, lactate increases histone acetylation, epigenetically activating MYC. Given that lactate's regulation of MYC depends on the bromodomain-containing protein 4 (BRD4), targeting cancer metabolism and BRD4 inhibitors emerge as a promising strategy to prevent tumor relapse.

AB - Tumors arise from uncontrolled cell proliferation driven by mutations in genes that regulate stem cell renewal and differentiation. Intestinal tumors, however, retain some hierarchical organization, maintaining both cancer stem cells (CSCs) and cancer differentiated cells (CDCs). This heterogeneity, coupled with cellular plasticity enabling CDCs to revert to CSCs, contributes to therapy resistance and relapse. Using genetically encoded fluorescent reporters in human tumor organoids, combined with our machine-learning-based cell tracker, CellPhenTracker, we simultaneously traced cell-type specification, metabolic changes, and reconstructed cell lineage trajectories during tumor organoid development. Our findings reveal distinctive metabolic phenotypes in CSCs and CDCs. We find that lactate regulates tumor dynamics, suppressing CSC differentiation and inducing dedifferentiation into a proliferative CSC state. Mechanistically, lactate increases histone acetylation, epigenetically activating MYC. Given that lactate's regulation of MYC depends on the bromodomain-containing protein 4 (BRD4), targeting cancer metabolism and BRD4 inhibitors emerge as a promising strategy to prevent tumor relapse.

KW - cancer metabolism

KW - cell plasticity

KW - cell types

KW - cell-cell interactions

KW - differentiation

KW - heterogeneity

KW - live imaging

KW - organoids

KW - single-cell tracking

KW - stem cells

UR - https://www.mendeley.com/catalogue/29ce1979-b61e-3097-ab4c-5b1be89ad7a3/

U2 - 10.1016/j.cmet.2025.01.002

DO - 10.1016/j.cmet.2025.01.002

M3 - Article

C2 - 39933514

SN - 1550-4131

JO - Cell Metabolism

JF - Cell Metabolism

ER -

Lactate controls cancer stemness and plasticity through epigenetic regulation

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