Obeticholic Acid Modulates Serum Metabolites and Gene Signatures Characteristic of Human NASH and Attenuates Inflammation and Fibrosis Progression in Ldlr‐/‐.Leiden Mice

Obeticholic Acid Modulates Serum Metabolites and Gene Signatures Characteristic of Human NASH and Attenuates Inflammation and Fibrosis Progression in Ldlr‐/‐.Leiden Mice

Concerns have been raised about whether preclinical models sufficiently mimic molecular disease processes observed in nonalcoholic steatohepatitis (NASH) patients, bringing into question their translational value in studies of therapeutic interventions in the process of NASH/fibrosis. We investigate...

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Main Authors: Martine C. Morrison, Lars Verschuren, Kanita Salic, Joanne Verheij, Aswin Menke, Peter Y. Wielinga, Marta Iruarrizaga‐Lejarreta, Laurent Gole, Wei‐Miao Yu, Scott Turner, Martien P.M. Caspers, Ibon Martínez‐Arranz, Elsbet Pieterman, Reinout Stoop, Arianne van Koppen, Anita M. van den Hoek, José M. Mato, Roeland Hanemaaijer, Cristina Alonso, Robert Kleemann
Format: Article
Language:English
Published: Wiley 2018-12-01
Series:Hepatology Communications
Online Access:https://doi.org/10.1002/hep4.1270
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author Martine C. Morrison
Lars Verschuren
Kanita Salic
Joanne Verheij
Aswin Menke
Peter Y. Wielinga
Marta Iruarrizaga‐Lejarreta
Laurent Gole
Wei‐Miao Yu
Scott Turner
Martien P.M. Caspers
Ibon Martínez‐Arranz
Elsbet Pieterman
Reinout Stoop
Arianne van Koppen
Anita M. van den Hoek
José M. Mato
Roeland Hanemaaijer
Cristina Alonso
Robert Kleemann
spellingShingle Martine C. Morrison
Lars Verschuren
Kanita Salic
Joanne Verheij
Aswin Menke
Peter Y. Wielinga
Marta Iruarrizaga‐Lejarreta
Laurent Gole
Wei‐Miao Yu
Scott Turner
Martien P.M. Caspers
Ibon Martínez‐Arranz
Elsbet Pieterman
Reinout Stoop
Arianne van Koppen
Anita M. van den Hoek
José M. Mato
Roeland Hanemaaijer
Cristina Alonso
Robert Kleemann
Obeticholic Acid Modulates Serum Metabolites and Gene Signatures Characteristic of Human NASH and Attenuates Inflammation and Fibrosis Progression in Ldlr‐/‐.Leiden Mice
Hepatology Communications
author_facet Martine C. Morrison
Lars Verschuren
Kanita Salic
Joanne Verheij
Aswin Menke
Peter Y. Wielinga
Marta Iruarrizaga‐Lejarreta
Laurent Gole
Wei‐Miao Yu
Scott Turner
Martien P.M. Caspers
Ibon Martínez‐Arranz
Elsbet Pieterman
Reinout Stoop
Arianne van Koppen
Anita M. van den Hoek
José M. Mato
Roeland Hanemaaijer
Cristina Alonso
Robert Kleemann
author_sort Martine C. Morrison
title Obeticholic Acid Modulates Serum Metabolites and Gene Signatures Characteristic of Human NASH and Attenuates Inflammation and Fibrosis Progression in Ldlr‐/‐.Leiden Mice
title_short Obeticholic Acid Modulates Serum Metabolites and Gene Signatures Characteristic of Human NASH and Attenuates Inflammation and Fibrosis Progression in Ldlr‐/‐.Leiden Mice
title_full Obeticholic Acid Modulates Serum Metabolites and Gene Signatures Characteristic of Human NASH and Attenuates Inflammation and Fibrosis Progression in Ldlr‐/‐.Leiden Mice
title_fullStr Obeticholic Acid Modulates Serum Metabolites and Gene Signatures Characteristic of Human NASH and Attenuates Inflammation and Fibrosis Progression in Ldlr‐/‐.Leiden Mice
title_full_unstemmed Obeticholic Acid Modulates Serum Metabolites and Gene Signatures Characteristic of Human NASH and Attenuates Inflammation and Fibrosis Progression in Ldlr‐/‐.Leiden Mice
title_sort obeticholic acid modulates serum metabolites and gene signatures characteristic of human nash and attenuates inflammation and fibrosis progression in ldlr‐/‐.leiden mice
publisher Wiley
series Hepatology Communications
issn 2471-254X
publishDate 2018-12-01
description Concerns have been raised about whether preclinical models sufficiently mimic molecular disease processes observed in nonalcoholic steatohepatitis (NASH) patients, bringing into question their translational value in studies of therapeutic interventions in the process of NASH/fibrosis. We investigated the representation of molecular disease patterns characteristic for human NASH in high‐fat diet (HFD)‐fed Ldlr‐/‐.Leiden mice and studied the effects of obeticholic acid (OCA) on these disease profiles. Multiplatform serum metabolomic profiles and genome‐wide liver transcriptome from HFD‐fed Ldlr‐/‐.Leiden mice were compared with those of NASH patients. Mice were profiled at the stage of mild (24 weeks HFD) and severe (34 weeks HFD) fibrosis, and after OCA intervention (24‐34 weeks; 10 mg/kg/day). Effects of OCA were analyzed histologically, biochemically, by immunohistochemistry, using deuterated water technology (de novo collagen formation), and by its effect on the human‐based transcriptomics and metabolomics signatures. The transcriptomics and metabolomics profile of Ldlr‐/‐.Leiden mice largely reflected the molecular signature of NASH patients. OCA modulated the expression of these molecular profiles and quenched specific proinflammatory‐profibrotic pathways. OCA attenuated specific facets of cellular inflammation in liver (F4/80‐positive cells) and reduced crown‐like structures in adipose tissue. OCA reduced de novo collagen formation and attenuated further progression of liver fibrosis, but did not reduce fibrosis below the level before intervention. Conclusion: HFD‐fed Ldlr‐/‐.Leiden mice recapitulate molecular transcriptomic and metabolomic profiles of NASH patients, and these signatures are modulated by OCA. Intervention with OCA in developing fibrosis reduces collagen deposition and de novo synthesis but does not resolve already manifest fibrosis in the period studied. These data show that human molecular signatures can be used to evaluate the translational character of preclinical models for NASH.
url https://doi.org/10.1002/hep4.1270
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spelling doaj-b7dbea0375ad493383bf24d4d1bb040c2020-11-25T01:10:32ZengWileyHepatology Communications2471-254X2018-12-012121513153210.1002/hep4.1270Obeticholic Acid Modulates Serum Metabolites and Gene Signatures Characteristic of Human NASH and Attenuates Inflammation and Fibrosis Progression in Ldlr‐/‐.Leiden MiceMartine C. Morrison0Lars Verschuren1Kanita Salic2Joanne Verheij3Aswin Menke4Peter Y. Wielinga5Marta Iruarrizaga‐Lejarreta6Laurent Gole7Wei‐Miao Yu8Scott Turner9Martien P.M. Caspers10Ibon Martínez‐Arranz11Elsbet Pieterman12Reinout Stoop13Arianne van Koppen14Anita M. van den Hoek15José M. Mato16Roeland Hanemaaijer17Cristina Alonso18Robert Kleemann19Department of Metabolic Health Research Netherlands Organization for Applied Scientific Research Leiden The NetherlandsDepartment of Microbiology and Systems Biology Netherlands Organisation for Applied Scientific Research Zeist The NetherlandsDepartment of Metabolic Health Research Netherlands Organization for Applied Scientific Research Leiden The NetherlandsDepartment of Pathology Amsterdam Medical Center Amsterdam The NetherlandsDepartment of Pathology Triskelion B.V. Zeist The NetherlandsDepartment of Metabolic Health Research Netherlands Organization for Applied Scientific Research Leiden The NetherlandsOWL Metabolomics Derio SpainComputational BioImage Analysis Unit, Agency of Science, Technology and Research (A*STAR), Institute of Molecular and Cell Biology SingaporeComputational BioImage Analysis Unit, Agency of Science, Technology and Research (A*STAR), Institute of Molecular and Cell Biology SingaporeKinemed Inc. Emeryville CADepartment of Microbiology and Systems Biology Netherlands Organisation for Applied Scientific Research Zeist The NetherlandsOWL Metabolomics Derio SpainDepartment of Metabolic Health Research Netherlands Organization for Applied Scientific Research Leiden The NetherlandsDepartment of Metabolic Health Research Netherlands Organization for Applied Scientific Research Leiden The NetherlandsDepartment of Metabolic Health Research Netherlands Organization for Applied Scientific Research Leiden The NetherlandsDepartment of Metabolic Health Research Netherlands Organization for Applied Scientific Research Leiden The NetherlandsCIC bioGUNE, CIBERehd Derio SpainDepartment of Metabolic Health Research Netherlands Organization for Applied Scientific Research Leiden The NetherlandsOWL Metabolomics Derio SpainDepartment of Metabolic Health Research Netherlands Organization for Applied Scientific Research Leiden The NetherlandsConcerns have been raised about whether preclinical models sufficiently mimic molecular disease processes observed in nonalcoholic steatohepatitis (NASH) patients, bringing into question their translational value in studies of therapeutic interventions in the process of NASH/fibrosis. We investigated the representation of molecular disease patterns characteristic for human NASH in high‐fat diet (HFD)‐fed Ldlr‐/‐.Leiden mice and studied the effects of obeticholic acid (OCA) on these disease profiles. Multiplatform serum metabolomic profiles and genome‐wide liver transcriptome from HFD‐fed Ldlr‐/‐.Leiden mice were compared with those of NASH patients. Mice were profiled at the stage of mild (24 weeks HFD) and severe (34 weeks HFD) fibrosis, and after OCA intervention (24‐34 weeks; 10 mg/kg/day). Effects of OCA were analyzed histologically, biochemically, by immunohistochemistry, using deuterated water technology (de novo collagen formation), and by its effect on the human‐based transcriptomics and metabolomics signatures. The transcriptomics and metabolomics profile of Ldlr‐/‐.Leiden mice largely reflected the molecular signature of NASH patients. OCA modulated the expression of these molecular profiles and quenched specific proinflammatory‐profibrotic pathways. OCA attenuated specific facets of cellular inflammation in liver (F4/80‐positive cells) and reduced crown‐like structures in adipose tissue. OCA reduced de novo collagen formation and attenuated further progression of liver fibrosis, but did not reduce fibrosis below the level before intervention. Conclusion: HFD‐fed Ldlr‐/‐.Leiden mice recapitulate molecular transcriptomic and metabolomic profiles of NASH patients, and these signatures are modulated by OCA. Intervention with OCA in developing fibrosis reduces collagen deposition and de novo synthesis but does not resolve already manifest fibrosis in the period studied. These data show that human molecular signatures can be used to evaluate the translational character of preclinical models for NASH.https://doi.org/10.1002/hep4.1270

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