Metabolic adaptations of micrometastases alter EV production to generate invasive microenvironments

Michalis Gounis; America V. Campos; Engy Shokry; Louise Mitchell; Ruhi Deshmukh; Emmanuel Dornier; Nicholas Rooney; Sandeep Dhayade; Luis Pardo; Madeleine Moore; David Novo; Jenna Mowat; Craig Jamieson; Emily Kay; Sara Zanivan; Nikki R. Paul; Claire Mitchell; Colin Nixon; Iain Macpherson; Saverio Tardito; David Sumpton; Karen Blyth; Jim C. Norman; Cassie J. Clarke

doi:10.1083/jcb.202405061

Metabolic adaptations of micrometastases alter EV production to generate invasive microenvironments

Michalis Gounis, America V. Campos, Engy Shokry, Louise Mitchell, Ruhi Deshmukh, Emmanuel Dornier, Nicholas Rooney, Sandeep Dhayade, Luis Pardo, Madeleine Moore, David Novo, Jenna Mowat, Craig Jamieson, Emily Kay, Sara Zanivan, Nikki R. Paul, Claire Mitchell, Colin Nixon, Iain Macpherson, Saverio TarditoDavid Sumpton, Karen Blyth, Jim C. Norman, Cassie J. Clarke

Research output: Contribution to journal › Article › peer-review

Abstract

Altered cellular metabolism has been associated with the acquisition of invasive phenotypes during metastasis. To study this, we combined a genetically engineered mouse model of mammary carcinoma with syngeneic transplantation and primary tumor resection to generate isogenic cells from primary tumors and their corresponding lung micrometastases. Metabolic analyses indicated that micrometastatic cells increase proline production at the expense of glutathione synthesis, leading to a reduction in total glutathione levels. Micrometastatic cells also have altered sphingomyelin metabolism, leading to increased intracellular levels of specific ceramides. The combination of these metabolic adaptations alters extracellular vesicle (EV) production to render the microenvironment more permissive for invasion. Indeed, micrometastatic cells shut down Rab27-dependent production of EVs and, instead, switch on neutral sphingomyelinase-2 (nSM2)-dependent EV release. EVs released in an nSM2-dependent manner from micrometastatic cells, in turn, influence the ability of fibroblasts to deposit extracellular matrix, which promotes cancer cell invasiveness. These data provide evidence that metabolic rewiring drives invasive processes in metastasis by influencing EV release.

Original language	English
Article number	e202405061
Number of pages	29
Journal	Journal of Cell Biology
Volume	224
Issue number	8
DOIs	https://doi.org/10.1083/jcb.202405061
Publication status	Published - 9 Jun 2025

Keywords

cellular metabolism
mice
tumors
metastasis
metabolic adaptations

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Gounis, M., Campos, A. V., Shokry, E., Mitchell, L., Deshmukh, R., Dornier, E., Rooney, N., Dhayade, S., Pardo, L., Moore, M., Novo, D., Mowat, J., Jamieson, C., Kay, E., Zanivan, S., Paul, N. R., Mitchell, C., Nixon, C., Macpherson, I., ... Clarke, C. J. (2025). Metabolic adaptations of micrometastases alter EV production to generate invasive microenvironments. Journal of Cell Biology, 224(8), Article e202405061. https://doi.org/10.1083/jcb.202405061

@article{433e72908f5d494dbc25319774e59f00,

title = "Metabolic adaptations of micrometastases alter EV production to generate invasive microenvironments",

abstract = "Altered cellular metabolism has been associated with the acquisition of invasive phenotypes during metastasis. To study this, we combined a genetically engineered mouse model of mammary carcinoma with syngeneic transplantation and primary tumor resection to generate isogenic cells from primary tumors and their corresponding lung micrometastases. Metabolic analyses indicated that micrometastatic cells increase proline production at the expense of glutathione synthesis, leading to a reduction in total glutathione levels. Micrometastatic cells also have altered sphingomyelin metabolism, leading to increased intracellular levels of specific ceramides. The combination of these metabolic adaptations alters extracellular vesicle (EV) production to render the microenvironment more permissive for invasion. Indeed, micrometastatic cells shut down Rab27-dependent production of EVs and, instead, switch on neutral sphingomyelinase-2 (nSM2)-dependent EV release. EVs released in an nSM2-dependent manner from micrometastatic cells, in turn, influence the ability of fibroblasts to deposit extracellular matrix, which promotes cancer cell invasiveness. These data provide evidence that metabolic rewiring drives invasive processes in metastasis by influencing EV release.",

keywords = "cellular metabolism, mice, tumors, metastasis, metabolic adaptations",

author = "Michalis Gounis and Campos, {America V.} and Engy Shokry and Louise Mitchell and Ruhi Deshmukh and Emmanuel Dornier and Nicholas Rooney and Sandeep Dhayade and Luis Pardo and Madeleine Moore and David Novo and Jenna Mowat and Craig Jamieson and Emily Kay and Sara Zanivan and Paul, {Nikki R.} and Claire Mitchell and Colin Nixon and Iain Macpherson and Saverio Tardito and David Sumpton and Karen Blyth and Norman, {Jim C.} and Clarke, {Cassie J.}",

year = "2025",

month = jun,

day = "9",

doi = "10.1083/jcb.202405061",

language = "English",

volume = "224",

journal = "Journal of Cell Biology",

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Gounis, M, Campos, AV, Shokry, E, Mitchell, L, Deshmukh, R, Dornier, E, Rooney, N, Dhayade, S, Pardo, L, Moore, M, Novo, D, Mowat, J, Jamieson, C, Kay, E, Zanivan, S, Paul, NR, Mitchell, C, Nixon, C, Macpherson, I, Tardito, S, Sumpton, D, Blyth, K, Norman, JC & Clarke, CJ 2025, 'Metabolic adaptations of micrometastases alter EV production to generate invasive microenvironments', Journal of Cell Biology, vol. 224, no. 8, e202405061. https://doi.org/10.1083/jcb.202405061

TY - JOUR

T1 - Metabolic adaptations of micrometastases alter EV production to generate invasive microenvironments

AU - Gounis, Michalis

AU - Campos, America V.

AU - Shokry, Engy

AU - Mitchell, Louise

AU - Deshmukh, Ruhi

AU - Dornier, Emmanuel

AU - Rooney, Nicholas

AU - Dhayade, Sandeep

AU - Pardo, Luis

AU - Moore, Madeleine

AU - Novo, David

AU - Mowat, Jenna

AU - Jamieson, Craig

AU - Kay, Emily

AU - Zanivan, Sara

AU - Paul, Nikki R.

AU - Mitchell, Claire

AU - Nixon, Colin

AU - Macpherson, Iain

AU - Tardito, Saverio

AU - Sumpton, David

AU - Blyth, Karen

AU - Norman, Jim C.

AU - Clarke, Cassie J.

PY - 2025/6/9

Y1 - 2025/6/9

N2 - Altered cellular metabolism has been associated with the acquisition of invasive phenotypes during metastasis. To study this, we combined a genetically engineered mouse model of mammary carcinoma with syngeneic transplantation and primary tumor resection to generate isogenic cells from primary tumors and their corresponding lung micrometastases. Metabolic analyses indicated that micrometastatic cells increase proline production at the expense of glutathione synthesis, leading to a reduction in total glutathione levels. Micrometastatic cells also have altered sphingomyelin metabolism, leading to increased intracellular levels of specific ceramides. The combination of these metabolic adaptations alters extracellular vesicle (EV) production to render the microenvironment more permissive for invasion. Indeed, micrometastatic cells shut down Rab27-dependent production of EVs and, instead, switch on neutral sphingomyelinase-2 (nSM2)-dependent EV release. EVs released in an nSM2-dependent manner from micrometastatic cells, in turn, influence the ability of fibroblasts to deposit extracellular matrix, which promotes cancer cell invasiveness. These data provide evidence that metabolic rewiring drives invasive processes in metastasis by influencing EV release.

AB - Altered cellular metabolism has been associated with the acquisition of invasive phenotypes during metastasis. To study this, we combined a genetically engineered mouse model of mammary carcinoma with syngeneic transplantation and primary tumor resection to generate isogenic cells from primary tumors and their corresponding lung micrometastases. Metabolic analyses indicated that micrometastatic cells increase proline production at the expense of glutathione synthesis, leading to a reduction in total glutathione levels. Micrometastatic cells also have altered sphingomyelin metabolism, leading to increased intracellular levels of specific ceramides. The combination of these metabolic adaptations alters extracellular vesicle (EV) production to render the microenvironment more permissive for invasion. Indeed, micrometastatic cells shut down Rab27-dependent production of EVs and, instead, switch on neutral sphingomyelinase-2 (nSM2)-dependent EV release. EVs released in an nSM2-dependent manner from micrometastatic cells, in turn, influence the ability of fibroblasts to deposit extracellular matrix, which promotes cancer cell invasiveness. These data provide evidence that metabolic rewiring drives invasive processes in metastasis by influencing EV release.

KW - cellular metabolism

KW - mice

KW - tumors

KW - metastasis

KW - metabolic adaptations

U2 - 10.1083/jcb.202405061

DO - 10.1083/jcb.202405061

M3 - Article

SN - 0021-9525

VL - 224

JO - Journal of Cell Biology

JF - Journal of Cell Biology

IS - 8

M1 - e202405061

ER -

Metabolic adaptations of micrometastases alter EV production to generate invasive microenvironments

Abstract

Keywords

UN SDGs

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