Rapid modulation of gut microbiota composition by hypothalamic circuits in mice

Míriam Toledo; Sara Martínez-Martínez; Matthias Van Hul; Berta Laudo; Elena Eyre; Rudy Pelicaen; Anthony Puel; Jordi Altirriba; Alicia G. Gómez-Valadés; Julica Inderhees; Isabel Moreno-Indias; Macarena Pozo; Iñigo Chivite; Maria Milà-Guasch; Roberta Haddad-Tóvolli; Arnaud Obri; Júlia Fos-Domènech; Iasim Tahiri; Sergio R. Llana; Sara Ramírez; Erika Monelli; Markus Schwaninger; Patrice D. Cani; Rubén Nogueiras; Marc Claret

doi:10.1038/s42255-025-01280-3

Rapid modulation of gut microbiota composition by hypothalamic circuits in mice

Míriam Toledo, Sara Martínez-Martínez, Matthias Van Hul, Berta Laudo, Elena Eyre, Rudy Pelicaen, Anthony Puel, Jordi Altirriba, Alicia G. Gómez-Valadés, Julica Inderhees, Isabel Moreno-Indias, Macarena Pozo, Iñigo Chivite, Maria Milà-Guasch, Roberta Haddad-Tóvolli, Arnaud Obri, Júlia Fos-Domènech, Iasim Tahiri, Sergio R. Llana, Sara RamírezErika Monelli, Markus Schwaninger, Patrice D. Cani^*, Rubén Nogueiras^*, Marc Claret^*

^*Corresponding author for this work

Institute of Experimental and Clinical Pharmacology and Toxicology

11 Citations (Scopus)

Abstract

In recent years, the gut microbiota and derived metabolites have emerged as relevant players in modulating several brain functions, including energy balance control^{1, 2–3}. This form of distant communication mirrors that of metabolic hormones (for example, leptin, ghrelin), which convey information about the organism’s energy status by exerting effects on diverse brain regions, including the master homeostatic centre, the hypothalamus⁴. However, whether the hypothalamus is also able to influence gut microbiota composition remains enigmatic. Here we present a study designed to unravel this challenging question. To this aim, we used chemogenetics⁵ (to selectively activate or inhibit hypothalamic pro-opiomelanocortin or agouti-related peptide neurons) or centrally administered leptin or ghrelin to male mice. Subsequently, we conducted microbiota composition analysis throughout the gut using 16S rRNA gene sequencing. Our results showed that these brain interventions significantly changed the gut microbiota in an anatomical and short-term (2–4 h) fashion. Transcriptomic analysis indicated that these changes were associated with the reconfiguration of neuronal and synaptic pathways in the duodenum concomitant with increased sympathetic tone. Interestingly, diet-induced obesity attenuated the brain-mediated changes triggered by leptin in gut microbiota communities and sympathetic activation. Our findings reveal a previously unanticipated brain–gut axis that acutely attunes microbiota composition on fast timescales, with potential implications for meal-to-meal adjustments and systemic energy balance control.

Original language	English
Journal	Nature Metabolism
Volume	7
Issue number	6
Pages (from-to)	1123-1135
Number of pages	13
ISSN	2522-5812
DOIs	https://doi.org/10.1038/s42255-025-01280-3
Publication status	Published - 06.2025

Funding

Funders	Funder number
Ministerio de Ciencia e Innovación
Horizon 2020 Framework Programme
Universitat Internacional de Catalunya
Miguel Servet Type II program
Departament de Recerca i Universitats, Generalitat de Catalunya
European Research Council	810331, 2018 BP00032
European Social Fund Plus	RYC2022-037070-I
H2020 Marie Skłodowska-Curie Actions	801370
Instituto de Salud Carlos III	IHMC22/00039, CP19/00083
Fonds de la Recherche Fondamentale Stratégique-Walloon Excellence in Life Sciences	40007505, WELBIO-CR-2022A-02
European Commission	CPII21/00013
'la Caixa' Foundation	LCF/PR/HR19/52160016, 2021-SGR-01320, ID100010434

UN SDGs

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

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Cite this

Toledo, M., Martínez-Martínez, S., Van Hul, M., Laudo, B., Eyre, E., Pelicaen, R., Puel, A., Altirriba, J., Gómez-Valadés, A. G., Inderhees, J., Moreno-Indias, I., Pozo, M., Chivite, I., Milà-Guasch, M., Haddad-Tóvolli, R., Obri, A., Fos-Domènech, J., Tahiri, I., Llana, S. R., ... Claret, M. (2025). Rapid modulation of gut microbiota composition by hypothalamic circuits in mice. Nature Metabolism, 7(6), 1123-1135. https://doi.org/10.1038/s42255-025-01280-3

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title = "Rapid modulation of gut microbiota composition by hypothalamic circuits in mice",

abstract = "In recent years, the gut microbiota and derived metabolites have emerged as relevant players in modulating several brain functions, including energy balance control1, 2–3. This form of distant communication mirrors that of metabolic hormones (for example, leptin, ghrelin), which convey information about the organism{\textquoteright}s energy status by exerting effects on diverse brain regions, including the master homeostatic centre, the hypothalamus4. However, whether the hypothalamus is also able to influence gut microbiota composition remains enigmatic. Here we present a study designed to unravel this challenging question. To this aim, we used chemogenetics5 (to selectively activate or inhibit hypothalamic pro-opiomelanocortin or agouti-related peptide neurons) or centrally administered leptin or ghrelin to male mice. Subsequently, we conducted microbiota composition analysis throughout the gut using 16S rRNA gene sequencing. Our results showed that these brain interventions significantly changed the gut microbiota in an anatomical and short-term (2–4 h) fashion. Transcriptomic analysis indicated that these changes were associated with the reconfiguration of neuronal and synaptic pathways in the duodenum concomitant with increased sympathetic tone. Interestingly, diet-induced obesity attenuated the brain-mediated changes triggered by leptin in gut microbiota communities and sympathetic activation. Our findings reveal a previously unanticipated brain–gut axis that acutely attunes microbiota composition on fast timescales, with potential implications for meal-to-meal adjustments and systemic energy balance control.",

author = "M{\'i}riam Toledo and Sara Mart{\'i}nez-Mart{\'i}nez and \{Van Hul\}, Matthias and Berta Laudo and Elena Eyre and Rudy Pelicaen and Anthony Puel and Jordi Altirriba and G{\'o}mez-Valad{\'e}s, \{Alicia G.\} and Julica Inderhees and Isabel Moreno-Indias and Macarena Pozo and I{\~n}igo Chivite and Maria Mil{\`a}-Guasch and Roberta Haddad-T{\'o}volli and Arnaud Obri and J{\'u}lia Fos-Dom{\`e}nech and Iasim Tahiri and Llana, \{Sergio R.\} and Sara Ram{\'i}rez and Erika Monelli and Markus Schwaninger and Cani, \{Patrice D.\} and Rub{\'e}n Nogueiras and Marc Claret",

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Toledo, M, Martínez-Martínez, S, Van Hul, M, Laudo, B, Eyre, E, Pelicaen, R, Puel, A, Altirriba, J, Gómez-Valadés, AG, Inderhees, J, Moreno-Indias, I, Pozo, M, Chivite, I, Milà-Guasch, M, Haddad-Tóvolli, R, Obri, A, Fos-Domènech, J, Tahiri, I, Llana, SR, Ramírez, S, Monelli, E, Schwaninger, M, Cani, PD, Nogueiras, R & Claret, M 2025, 'Rapid modulation of gut microbiota composition by hypothalamic circuits in mice', Nature Metabolism, vol. 7, no. 6, pp. 1123-1135. https://doi.org/10.1038/s42255-025-01280-3

TY - JOUR

T1 - Rapid modulation of gut microbiota composition by hypothalamic circuits in mice

AU - Toledo, Míriam

AU - Martínez-Martínez, Sara

AU - Van Hul, Matthias

AU - Laudo, Berta

AU - Eyre, Elena

AU - Pelicaen, Rudy

AU - Puel, Anthony

AU - Altirriba, Jordi

AU - Gómez-Valadés, Alicia G.

AU - Inderhees, Julica

AU - Moreno-Indias, Isabel

AU - Pozo, Macarena

AU - Chivite, Iñigo

AU - Milà-Guasch, Maria

AU - Haddad-Tóvolli, Roberta

AU - Obri, Arnaud

AU - Fos-Domènech, Júlia

AU - Tahiri, Iasim

AU - Llana, Sergio R.

AU - Ramírez, Sara

AU - Monelli, Erika

AU - Schwaninger, Markus

AU - Cani, Patrice D.

AU - Nogueiras, Rubén

AU - Claret, Marc

PY - 2025/6

Y1 - 2025/6

N2 - In recent years, the gut microbiota and derived metabolites have emerged as relevant players in modulating several brain functions, including energy balance control1, 2–3. This form of distant communication mirrors that of metabolic hormones (for example, leptin, ghrelin), which convey information about the organism’s energy status by exerting effects on diverse brain regions, including the master homeostatic centre, the hypothalamus4. However, whether the hypothalamus is also able to influence gut microbiota composition remains enigmatic. Here we present a study designed to unravel this challenging question. To this aim, we used chemogenetics5 (to selectively activate or inhibit hypothalamic pro-opiomelanocortin or agouti-related peptide neurons) or centrally administered leptin or ghrelin to male mice. Subsequently, we conducted microbiota composition analysis throughout the gut using 16S rRNA gene sequencing. Our results showed that these brain interventions significantly changed the gut microbiota in an anatomical and short-term (2–4 h) fashion. Transcriptomic analysis indicated that these changes were associated with the reconfiguration of neuronal and synaptic pathways in the duodenum concomitant with increased sympathetic tone. Interestingly, diet-induced obesity attenuated the brain-mediated changes triggered by leptin in gut microbiota communities and sympathetic activation. Our findings reveal a previously unanticipated brain–gut axis that acutely attunes microbiota composition on fast timescales, with potential implications for meal-to-meal adjustments and systemic energy balance control.

AB - In recent years, the gut microbiota and derived metabolites have emerged as relevant players in modulating several brain functions, including energy balance control1, 2–3. This form of distant communication mirrors that of metabolic hormones (for example, leptin, ghrelin), which convey information about the organism’s energy status by exerting effects on diverse brain regions, including the master homeostatic centre, the hypothalamus4. However, whether the hypothalamus is also able to influence gut microbiota composition remains enigmatic. Here we present a study designed to unravel this challenging question. To this aim, we used chemogenetics5 (to selectively activate or inhibit hypothalamic pro-opiomelanocortin or agouti-related peptide neurons) or centrally administered leptin or ghrelin to male mice. Subsequently, we conducted microbiota composition analysis throughout the gut using 16S rRNA gene sequencing. Our results showed that these brain interventions significantly changed the gut microbiota in an anatomical and short-term (2–4 h) fashion. Transcriptomic analysis indicated that these changes were associated with the reconfiguration of neuronal and synaptic pathways in the duodenum concomitant with increased sympathetic tone. Interestingly, diet-induced obesity attenuated the brain-mediated changes triggered by leptin in gut microbiota communities and sympathetic activation. Our findings reveal a previously unanticipated brain–gut axis that acutely attunes microbiota composition on fast timescales, with potential implications for meal-to-meal adjustments and systemic energy balance control.

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Rapid modulation of gut microbiota composition by hypothalamic circuits in mice

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