Liver X receptor unlinks intestinal regeneration and tumorigenesis

Srustidhar Das; S. Martina Parigi; Xinxin Luo; Jennifer Fransson; Bianca C. Kern; Ali Okhovat; Oscar E. Diaz; Chiara Sorini; Paulo Czarnewski; Anna T. Webb; Rodrigo A. Morales; Sacha Lebon; Gustavo Monasterio; Francisca Castillo; Kumar P. Tripathi; Ning He; Penelope Pelczar; Nicola Schaltenberg; Marjorie De la Fuente; Francisco López-Köstner; Susanne Nylén; Hjalte List Larsen; Raoul Kuiper; Per Antonson; Marcela A. Hermoso; Samuel Huber; Moshe Biton; Sandra Scharaw; Jan Åke Gustafsson; Pekka Katajisto; Eduardo J. Villablanca

doi:10.1038/s41586-024-08247-6

Liver X receptor unlinks intestinal regeneration and tumorigenesis

Srustidhar Das^*
, S. Martina Parigi
, Xinxin Luo
, Jennifer Fransson
, Bianca C. Kern
, Ali Okhovat
, Oscar E. Diaz
, Chiara Sorini
, Paulo Czarnewski
, Anna T. Webb
, Rodrigo A. Morales
, Sacha Lebon
, Gustavo Monasterio
, Francisca Castillo
, Kumar P. Tripathi
, Ning He
, Penelope Pelczar
, Nicola Schaltenberg
, Marjorie De la Fuente
, Francisco López-Köstner

Susanne Nylén, Hjalte List Larsen, Raoul Kuiper, Per Antonson, Marcela A. Hermoso, Samuel Huber, Moshe Biton, Sandra Scharaw, Jan Åke Gustafsson, Pekka Katajisto, Eduardo J. Villablanca^*

^*Autor correspondiente de este trabajo

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

23 Citas (Scopus)

Resumen

Uncontrolled regeneration leads to neoplastic transformation^{1, 2–3}. The intestinal epithelium requires precise regulation during continuous homeostatic and damage-induced tissue renewal to prevent neoplastic transformation, suggesting that pathways unlinking tumour growth from regenerative processes must exist. Here, by mining RNA-sequencing datasets from two intestinal damage models^4,5 and using pharmacological, transcriptomics and genetic tools, we identified liver X receptor (LXR) pathway activation as a tissue adaptation to damage that reciprocally regulates intestinal regeneration and tumorigenesis. Using single-cell RNA sequencing, intestinal organoids, and gain- and loss-of-function experiments, we demonstrate that LXR activation in intestinal epithelial cells induces amphiregulin (Areg), enhancing regenerative responses. This response is coordinated by the LXR-ligand-producing enzyme CYP27A1, which was upregulated in damaged intestinal crypt niches. Deletion of Cyp27a1 impaired intestinal regeneration, which was rescued by exogenous LXR agonists. Notably, in tumour models, Cyp27a1 deficiency led to increased tumour growth, whereas LXR activation elicited anti-tumour responses dependent on adaptive immunity. Consistently, human colorectal cancer specimens exhibited reduced levels of CYP27A1, LXR target genes, and B and CD8 T cell gene signatures. We therefore identify an epithelial adaptation mechanism to damage, whereby LXR functions as a rheostat, promoting tissue repair while limiting tumorigenesis.

Idioma original	Inglés
Páginas (desde-hasta)	1198-1206
Número de páginas	9
Publicación	Nature
Volumen	637
N.º	8048
DOI	https://doi.org/10.1038/s41586-024-08247-6
Estado	Publicada - 30 ene. 2025

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Publisher Copyright:
© The Author(s) 2024.

ODS de las Naciones Unidas

Este resultado contribuye a los siguientes Objetivos de Desarrollo Sostenible

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Das, S., Parigi, S. M., Luo, X., Fransson, J., Kern, B. C., Okhovat, A., Diaz, O. E., Sorini, C., Czarnewski, P., Webb, A. T., Morales, R. A., Lebon, S., Monasterio, G., Castillo, F., Tripathi, K. P., He, N., Pelczar, P., Schaltenberg, N., De la Fuente, M., ... Villablanca, E. J. (2025). Liver X receptor unlinks intestinal regeneration and tumorigenesis. Nature, 637(8048), 1198-1206. https://doi.org/10.1038/s41586-024-08247-6

@article{d23f45e4630348e8bbadc827938ee5d2,

title = "Liver X receptor unlinks intestinal regeneration and tumorigenesis",

abstract = "Uncontrolled regeneration leads to neoplastic transformation1, 2–3. The intestinal epithelium requires precise regulation during continuous homeostatic and damage-induced tissue renewal to prevent neoplastic transformation, suggesting that pathways unlinking tumour growth from regenerative processes must exist. Here, by mining RNA-sequencing datasets from two intestinal damage models4,5 and using pharmacological, transcriptomics and genetic tools, we identified liver X receptor (LXR) pathway activation as a tissue adaptation to damage that reciprocally regulates intestinal regeneration and tumorigenesis. Using single-cell RNA sequencing, intestinal organoids, and gain- and loss-of-function experiments, we demonstrate that LXR activation in intestinal epithelial cells induces amphiregulin (Areg), enhancing regenerative responses. This response is coordinated by the LXR-ligand-producing enzyme CYP27A1, which was upregulated in damaged intestinal crypt niches. Deletion of Cyp27a1 impaired intestinal regeneration, which was rescued by exogenous LXR agonists. Notably, in tumour models, Cyp27a1 deficiency led to increased tumour growth, whereas LXR activation elicited anti-tumour responses dependent on adaptive immunity. Consistently, human colorectal cancer specimens exhibited reduced levels of CYP27A1, LXR target genes, and B and CD8 T cell gene signatures. We therefore identify an epithelial adaptation mechanism to damage, whereby LXR functions as a rheostat, promoting tissue repair while limiting tumorigenesis.",

author = "Srustidhar Das and Parigi, \{S. Martina\} and Xinxin Luo and Jennifer Fransson and Kern, \{Bianca C.\} and Ali Okhovat and Diaz, \{Oscar E.\} and Chiara Sorini and Paulo Czarnewski and Webb, \{Anna T.\} and Morales, \{Rodrigo A.\} and Sacha Lebon and Gustavo Monasterio and Francisca Castillo and Tripathi, \{Kumar P.\} and Ning He and Penelope Pelczar and Nicola Schaltenberg and \{De la Fuente\}, Marjorie and Francisco L{\'o}pez-K{\"o}stner and Susanne Nyl{\'e}n and Larsen, \{Hjalte List\} and Raoul Kuiper and Per Antonson and Hermoso, \{Marcela A.\} and Samuel Huber and Moshe Biton and Sandra Scharaw and Gustafsson, \{Jan {\AA}ke\} and Pekka Katajisto and Villablanca, \{Eduardo J.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2025",

month = jan,

day = "30",

doi = "10.1038/s41586-024-08247-6",

language = "English",

volume = "637",

pages = "1198--1206",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Research",

number = "8048",

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Das, S, Parigi, SM, Luo, X, Fransson, J, Kern, BC, Okhovat, A, Diaz, OE, Sorini, C, Czarnewski, P, Webb, AT, Morales, RA, Lebon, S, Monasterio, G, Castillo, F, Tripathi, KP, He, N, Pelczar, P, Schaltenberg, N, De la Fuente, M, López-Köstner, F, Nylén, S, Larsen, HL, Kuiper, R, Antonson, P, Hermoso, MA, Huber, S, Biton, M, Scharaw, S, Gustafsson, JÅ, Katajisto, P & Villablanca, EJ 2025, 'Liver X receptor unlinks intestinal regeneration and tumorigenesis', Nature, vol. 637, n.º 8048, pp. 1198-1206. https://doi.org/10.1038/s41586-024-08247-6

TY - JOUR

T1 - Liver X receptor unlinks intestinal regeneration and tumorigenesis

AU - Das, Srustidhar

AU - Parigi, S. Martina

AU - Luo, Xinxin

AU - Fransson, Jennifer

AU - Kern, Bianca C.

AU - Okhovat, Ali

AU - Diaz, Oscar E.

AU - Sorini, Chiara

AU - Czarnewski, Paulo

AU - Webb, Anna T.

AU - Morales, Rodrigo A.

AU - Lebon, Sacha

AU - Monasterio, Gustavo

AU - Castillo, Francisca

AU - Tripathi, Kumar P.

AU - He, Ning

AU - Pelczar, Penelope

AU - Schaltenberg, Nicola

AU - De la Fuente, Marjorie

AU - López-Köstner, Francisco

AU - Nylén, Susanne

AU - Larsen, Hjalte List

AU - Kuiper, Raoul

AU - Antonson, Per

AU - Hermoso, Marcela A.

AU - Huber, Samuel

AU - Biton, Moshe

AU - Scharaw, Sandra

AU - Gustafsson, Jan Åke

AU - Katajisto, Pekka

AU - Villablanca, Eduardo J.

PY - 2025/1/30

Y1 - 2025/1/30

N2 - Uncontrolled regeneration leads to neoplastic transformation1, 2–3. The intestinal epithelium requires precise regulation during continuous homeostatic and damage-induced tissue renewal to prevent neoplastic transformation, suggesting that pathways unlinking tumour growth from regenerative processes must exist. Here, by mining RNA-sequencing datasets from two intestinal damage models4,5 and using pharmacological, transcriptomics and genetic tools, we identified liver X receptor (LXR) pathway activation as a tissue adaptation to damage that reciprocally regulates intestinal regeneration and tumorigenesis. Using single-cell RNA sequencing, intestinal organoids, and gain- and loss-of-function experiments, we demonstrate that LXR activation in intestinal epithelial cells induces amphiregulin (Areg), enhancing regenerative responses. This response is coordinated by the LXR-ligand-producing enzyme CYP27A1, which was upregulated in damaged intestinal crypt niches. Deletion of Cyp27a1 impaired intestinal regeneration, which was rescued by exogenous LXR agonists. Notably, in tumour models, Cyp27a1 deficiency led to increased tumour growth, whereas LXR activation elicited anti-tumour responses dependent on adaptive immunity. Consistently, human colorectal cancer specimens exhibited reduced levels of CYP27A1, LXR target genes, and B and CD8 T cell gene signatures. We therefore identify an epithelial adaptation mechanism to damage, whereby LXR functions as a rheostat, promoting tissue repair while limiting tumorigenesis.

AB - Uncontrolled regeneration leads to neoplastic transformation1, 2–3. The intestinal epithelium requires precise regulation during continuous homeostatic and damage-induced tissue renewal to prevent neoplastic transformation, suggesting that pathways unlinking tumour growth from regenerative processes must exist. Here, by mining RNA-sequencing datasets from two intestinal damage models4,5 and using pharmacological, transcriptomics and genetic tools, we identified liver X receptor (LXR) pathway activation as a tissue adaptation to damage that reciprocally regulates intestinal regeneration and tumorigenesis. Using single-cell RNA sequencing, intestinal organoids, and gain- and loss-of-function experiments, we demonstrate that LXR activation in intestinal epithelial cells induces amphiregulin (Areg), enhancing regenerative responses. This response is coordinated by the LXR-ligand-producing enzyme CYP27A1, which was upregulated in damaged intestinal crypt niches. Deletion of Cyp27a1 impaired intestinal regeneration, which was rescued by exogenous LXR agonists. Notably, in tumour models, Cyp27a1 deficiency led to increased tumour growth, whereas LXR activation elicited anti-tumour responses dependent on adaptive immunity. Consistently, human colorectal cancer specimens exhibited reduced levels of CYP27A1, LXR target genes, and B and CD8 T cell gene signatures. We therefore identify an epithelial adaptation mechanism to damage, whereby LXR functions as a rheostat, promoting tissue repair while limiting tumorigenesis.

UR - https://www.scopus.com/pages/publications/85209738764

U2 - 10.1038/s41586-024-08247-6

DO - 10.1038/s41586-024-08247-6

M3 - Article

C2 - 39567700

AN - SCOPUS:85209738764

SN - 0028-0836

VL - 637

SP - 1198

EP - 1206

JO - Nature

JF - Nature

IS - 8048

ER -

Liver X receptor unlinks intestinal regeneration and tumorigenesis

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