Novel Bacteroides Vulgatus strain protects against gluten-induced break of human celiac gut epithelial homeostasis: a pre-clinical proof-of-concept study

Tina Tran; Stefania Senger; Mariella Baldassarre; Rachel A. Brosnan; Fernanda Cristofori; Marco Crocco; Stefania De Santis; Luca Elli; Christina S. Faherty; Ruggero Francavilla; Isabella Goodchild-Michelman; Victoria A. Kenyon; Maureen M. Leonard; Rosiane S. Lima; Federica Malerba; Monica Montuori; Annalisa Morelli; Lorenzo Norsa; Tiziana Passaro; Pasqua Piemontese; James C. Reed; Naire Sansotta; Francesco Valitutti; Ali R. Zomorrodi; Alessio Fasano; Maria Luisa Forchielli; Adelaide Serretiello; Corrado Vecchi; Gemma Castillejo de Villasante; Giorgia Venutolo; Basilio Malamisura; Angela Calvi; Maria Elena Lionetti; Mariella Baldassarre; Chiara Maria Trovato; Nicoletta Pietropaoli; Michela Perrone; Lidia Celeste Raguseo; Carlo Catassi

doi:10.1038/s41390-023-02960-0

Novel Bacteroides Vulgatus strain protects against gluten-induced break of human celiac gut epithelial homeostasis: a pre-clinical proof-of-concept study

Tina Tran, Stefania Senger, Mariella Baldassarre, Rachel A. Brosnan, Fernanda Cristofori, Marco Crocco, Stefania De Santis, Luca Elli, Christina S. Faherty, Ruggero Francavilla, Isabella Goodchild-Michelman, Victoria A. Kenyon, Maureen M. Leonard, Rosiane S. Lima, Federica Malerba, Monica Montuori, Annalisa Morelli, Lorenzo Norsa, Tiziana Passaro, Pasqua PiemonteseJames C. Reed, Naire Sansotta, Francesco Valitutti, Ali R. Zomorrodi, Alessio Fasano^*, Maria Luisa Forchielli, Adelaide Serretiello, Corrado Vecchi, Gemma Castillejo de Villasante, Giorgia Venutolo, Basilio Malamisura, Angela Calvi, Maria Elena Lionetti, Mariella Baldassarre, Chiara Maria Trovato, Nicoletta Pietropaoli, Michela Perrone, Lidia Celeste Raguseo, Carlo Catassi

^*Corresponding author for this work

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

5 Scopus citations

Abstract

Background and aims: We have identified a decreased abundance of microbial species known to have a potential anti-inflammatory, protective effect in subjects that developed Celiac Disease (CeD) compared to those who did not. We aim to confirm the potential protective role of one of these species, namely Bacteroides vulgatus, and to mechanistically establish the effect of bacterial bioproducts on gluten-dependent changes on human gut epithelial functions. Methods: We identified, isolated, cultivated, and sequenced a unique novel strain (20220303-A2) of B. vulgatus found only in control subjects. Using a human gut organoid system developed from pre-celiac patients, we monitored epithelial phenotype and innate immune cytokines at baseline, after exposure to gliadin, or gliadin plus B. vulgatus cell free supernatant (CFS). Results: Following gliadin exposure, we observed increases in epithelial cell death, epithelial monolayer permeability, and secretion of pro-inflammatory cytokines. These effects were mitigated upon exposure to B. vulgatus 20220303-A2 CFS, which had matched phenotype gene product mutations. These protective effects were mediated by epigenetic reprogramming of the organoids treated with B. vulgatus CFS. Conclusions: We identified a unique strain of B. vulgatus that may exert a beneficial role by protecting CeD epithelium against a gluten-induced break of epithelial tolerance through miRNA reprogramming. Impact: Gut dysbiosis precedes the onset of celiac disease in genetically at-risk infants. This dysbiosis is characterized by the loss of protective bacterial strains in those children who will go on to develop celiac disease. The paper reports the mechanism by which one of these protective strains, B. vulgatus, ameliorates the gluten-induced break of gut epithelial homeostasis by epigenetically re-programming the target intestinal epithelium involving pathways controlling permeability, immune response, and cell turnover.

Original language	English
Pages (from-to)	1254-1264
Number of pages	11
Journal	Pediatric Research
Volume	95
Issue number	5
DOIs	https://doi.org/10.1038/s41390-023-02960-0
State	Published - Apr 2024
Externally published	Yes

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Tran, T., Senger, S., Baldassarre, M., Brosnan, R. A., Cristofori, F., Crocco, M., De Santis, S., Elli, L., Faherty, C. S., Francavilla, R., Goodchild-Michelman, I., Kenyon, V. A., Leonard, M. M., Lima, R. S., Malerba, F., Montuori, M., Morelli, A., Norsa, L., Passaro, T., ... Catassi, C. (2024). Novel Bacteroides Vulgatus strain protects against gluten-induced break of human celiac gut epithelial homeostasis: a pre-clinical proof-of-concept study. Pediatric Research, 95(5), 1254-1264. https://doi.org/10.1038/s41390-023-02960-0

@article{f89030646c0744abb83880e241f74175,

title = "Novel Bacteroides Vulgatus strain protects against gluten-induced break of human celiac gut epithelial homeostasis: a pre-clinical proof-of-concept study",

abstract = "Background and aims: We have identified a decreased abundance of microbial species known to have a potential anti-inflammatory, protective effect in subjects that developed Celiac Disease (CeD) compared to those who did not. We aim to confirm the potential protective role of one of these species, namely Bacteroides vulgatus, and to mechanistically establish the effect of bacterial bioproducts on gluten-dependent changes on human gut epithelial functions. Methods: We identified, isolated, cultivated, and sequenced a unique novel strain (20220303-A2) of B. vulgatus found only in control subjects. Using a human gut organoid system developed from pre-celiac patients, we monitored epithelial phenotype and innate immune cytokines at baseline, after exposure to gliadin, or gliadin plus B. vulgatus cell free supernatant (CFS). Results: Following gliadin exposure, we observed increases in epithelial cell death, epithelial monolayer permeability, and secretion of pro-inflammatory cytokines. These effects were mitigated upon exposure to B. vulgatus 20220303-A2 CFS, which had matched phenotype gene product mutations. These protective effects were mediated by epigenetic reprogramming of the organoids treated with B. vulgatus CFS. Conclusions: We identified a unique strain of B. vulgatus that may exert a beneficial role by protecting CeD epithelium against a gluten-induced break of epithelial tolerance through miRNA reprogramming. Impact: Gut dysbiosis precedes the onset of celiac disease in genetically at-risk infants. This dysbiosis is characterized by the loss of protective bacterial strains in those children who will go on to develop celiac disease. The paper reports the mechanism by which one of these protective strains, B. vulgatus, ameliorates the gluten-induced break of gut epithelial homeostasis by epigenetically re-programming the target intestinal epithelium involving pathways controlling permeability, immune response, and cell turnover.",

author = "Tina Tran and Stefania Senger and Mariella Baldassarre and Brosnan, {Rachel A.} and Fernanda Cristofori and Marco Crocco and {De Santis}, Stefania and Luca Elli and Faherty, {Christina S.} and Ruggero Francavilla and Isabella Goodchild-Michelman and Kenyon, {Victoria A.} and Leonard, {Maureen M.} and Lima, {Rosiane S.} and Federica Malerba and Monica Montuori and Annalisa Morelli and Lorenzo Norsa and Tiziana Passaro and Pasqua Piemontese and Reed, {James C.} and Naire Sansotta and Francesco Valitutti and Zomorrodi, {Ali R.} and Alessio Fasano and Forchielli, {Maria Luisa} and Adelaide Serretiello and Corrado Vecchi and {de Villasante}, {Gemma Castillejo} and Giorgia Venutolo and Basilio Malamisura and Angela Calvi and Lionetti, {Maria Elena} and Mariella Baldassarre and Trovato, {Chiara Maria} and Nicoletta Pietropaoli and Michela Perrone and Raguseo, {Lidia Celeste} and Carlo Catassi",

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

year = "2024",

month = apr,

doi = "10.1038/s41390-023-02960-0",

language = "English",

volume = "95",

pages = "1254--1264",

journal = "Pediatric Research",

issn = "0031-3998",

number = "5",

}

Tran, T, Senger, S, Baldassarre, M, Brosnan, RA, Cristofori, F, Crocco, M, De Santis, S, Elli, L, Faherty, CS, Francavilla, R, Goodchild-Michelman, I, Kenyon, VA, Leonard, MM, Lima, RS, Malerba, F, Montuori, M, Morelli, A, Norsa, L, Passaro, T, Piemontese, P, Reed, JC, Sansotta, N, Valitutti, F, Zomorrodi, AR, Fasano, A, Forchielli, ML, Serretiello, A, Vecchi, C, de Villasante, GC, Venutolo, G, Malamisura, B, Calvi, A, Lionetti, ME, Baldassarre, M, Trovato, CM, Pietropaoli, N, Perrone, M, Raguseo, LC & Catassi, C 2024, 'Novel Bacteroides Vulgatus strain protects against gluten-induced break of human celiac gut epithelial homeostasis: a pre-clinical proof-of-concept study', Pediatric Research, vol. 95, no. 5, pp. 1254-1264. https://doi.org/10.1038/s41390-023-02960-0

TY - JOUR

T1 - Novel Bacteroides Vulgatus strain protects against gluten-induced break of human celiac gut epithelial homeostasis

T2 - a pre-clinical proof-of-concept study

AU - Tran, Tina

AU - Senger, Stefania

AU - Baldassarre, Mariella

AU - Brosnan, Rachel A.

AU - Cristofori, Fernanda

AU - Crocco, Marco

AU - De Santis, Stefania

AU - Elli, Luca

AU - Faherty, Christina S.

AU - Francavilla, Ruggero

AU - Goodchild-Michelman, Isabella

AU - Kenyon, Victoria A.

AU - Leonard, Maureen M.

AU - Lima, Rosiane S.

AU - Malerba, Federica

AU - Montuori, Monica

AU - Morelli, Annalisa

AU - Norsa, Lorenzo

AU - Passaro, Tiziana

AU - Piemontese, Pasqua

AU - Reed, James C.

AU - Sansotta, Naire

AU - Valitutti, Francesco

AU - Zomorrodi, Ali R.

AU - Fasano, Alessio

AU - Forchielli, Maria Luisa

AU - Serretiello, Adelaide

AU - Vecchi, Corrado

AU - de Villasante, Gemma Castillejo

AU - Venutolo, Giorgia

AU - Malamisura, Basilio

AU - Calvi, Angela

AU - Lionetti, Maria Elena

AU - Baldassarre, Mariella

AU - Trovato, Chiara Maria

AU - Pietropaoli, Nicoletta

AU - Perrone, Michela

AU - Raguseo, Lidia Celeste

AU - Catassi, Carlo

PY - 2024/4

Y1 - 2024/4

N2 - Background and aims: We have identified a decreased abundance of microbial species known to have a potential anti-inflammatory, protective effect in subjects that developed Celiac Disease (CeD) compared to those who did not. We aim to confirm the potential protective role of one of these species, namely Bacteroides vulgatus, and to mechanistically establish the effect of bacterial bioproducts on gluten-dependent changes on human gut epithelial functions. Methods: We identified, isolated, cultivated, and sequenced a unique novel strain (20220303-A2) of B. vulgatus found only in control subjects. Using a human gut organoid system developed from pre-celiac patients, we monitored epithelial phenotype and innate immune cytokines at baseline, after exposure to gliadin, or gliadin plus B. vulgatus cell free supernatant (CFS). Results: Following gliadin exposure, we observed increases in epithelial cell death, epithelial monolayer permeability, and secretion of pro-inflammatory cytokines. These effects were mitigated upon exposure to B. vulgatus 20220303-A2 CFS, which had matched phenotype gene product mutations. These protective effects were mediated by epigenetic reprogramming of the organoids treated with B. vulgatus CFS. Conclusions: We identified a unique strain of B. vulgatus that may exert a beneficial role by protecting CeD epithelium against a gluten-induced break of epithelial tolerance through miRNA reprogramming. Impact: Gut dysbiosis precedes the onset of celiac disease in genetically at-risk infants. This dysbiosis is characterized by the loss of protective bacterial strains in those children who will go on to develop celiac disease. The paper reports the mechanism by which one of these protective strains, B. vulgatus, ameliorates the gluten-induced break of gut epithelial homeostasis by epigenetically re-programming the target intestinal epithelium involving pathways controlling permeability, immune response, and cell turnover.

AB - Background and aims: We have identified a decreased abundance of microbial species known to have a potential anti-inflammatory, protective effect in subjects that developed Celiac Disease (CeD) compared to those who did not. We aim to confirm the potential protective role of one of these species, namely Bacteroides vulgatus, and to mechanistically establish the effect of bacterial bioproducts on gluten-dependent changes on human gut epithelial functions. Methods: We identified, isolated, cultivated, and sequenced a unique novel strain (20220303-A2) of B. vulgatus found only in control subjects. Using a human gut organoid system developed from pre-celiac patients, we monitored epithelial phenotype and innate immune cytokines at baseline, after exposure to gliadin, or gliadin plus B. vulgatus cell free supernatant (CFS). Results: Following gliadin exposure, we observed increases in epithelial cell death, epithelial monolayer permeability, and secretion of pro-inflammatory cytokines. These effects were mitigated upon exposure to B. vulgatus 20220303-A2 CFS, which had matched phenotype gene product mutations. These protective effects were mediated by epigenetic reprogramming of the organoids treated with B. vulgatus CFS. Conclusions: We identified a unique strain of B. vulgatus that may exert a beneficial role by protecting CeD epithelium against a gluten-induced break of epithelial tolerance through miRNA reprogramming. Impact: Gut dysbiosis precedes the onset of celiac disease in genetically at-risk infants. This dysbiosis is characterized by the loss of protective bacterial strains in those children who will go on to develop celiac disease. The paper reports the mechanism by which one of these protective strains, B. vulgatus, ameliorates the gluten-induced break of gut epithelial homeostasis by epigenetically re-programming the target intestinal epithelium involving pathways controlling permeability, immune response, and cell turnover.

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U2 - 10.1038/s41390-023-02960-0

DO - 10.1038/s41390-023-02960-0

M3 - Article

C2 - 38177249

AN - SCOPUS:85181460706

SN - 0031-3998

VL - 95

SP - 1254

EP - 1264

JO - Pediatric Research

JF - Pediatric Research

IS - 5

ER -