Metabolic Network Analysis Reveals Altered Bile Acid Synthesis and Metabolism in Alzheimer's Disease

The Alzheimer's Disease Metabolomics Consortium

doi:10.1016/j.xcrm.2020.100138

Metabolic Network Analysis Reveals Altered Bile Acid Synthesis and Metabolism in Alzheimer's Disease

The Alzheimer's Disease Metabolomics Consortium

School of Medicine

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

2 Scopus citations

Abstract

Increasing evidence suggests Alzheimer's disease (AD) pathophysiology is influenced by primary and secondary bile acids, the end product of cholesterol metabolism. We analyze 2,114 post-mortem brain transcriptomes and identify genes in the alternative bile acid synthesis pathway to be expressed in the brain. A targeted metabolomic analysis of primary and secondary bile acids measured from post-mortem brain samples of 111 individuals supports these results. Our metabolic network analysis suggests that taurine transport, bile acid synthesis, and cholesterol metabolism differ in AD and cognitively normal individuals. We also identify putative transcription factors regulating metabolic genes and influencing altered metabolism in AD. Intriguingly, some bile acids measured in brain tissue cannot be explained by the presence of enzymes responsible for their synthesis, suggesting that they may originate from the gut microbiome and are transported to the brain. These findings motivate further research into bile acid metabolism in AD to elucidate their possible connection to cognitive decline. Baloni et al. use a systems biology approach to identify alterations in cholesterol and bile acid metabolism in Alzheimer disease (AD). Expression of alternative bile acid and neural cholesterol clearance pathway along with transporters of taurine and bile acids suggest the role of the gut-brain axis in AD.

Original language	English (US)
Article number	100138
Journal	Cell Reports Medicine
Volume	1
Issue number	8
DOIs	https://doi.org/10.1016/j.xcrm.2020.100138
State	Published - Nov 17 2020

Keywords

Alzheimer's disease
bile acids
cholesterol metabolism
genome-scale metabolic models
metabolomics
transcriptional regulatory networks
transcriptomics

ASJC Scopus subject areas

Biochemistry, Genetics and Molecular Biology(all)

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10.1016/j.xcrm.2020.100138

Cite this

@article{fe45ca36fdfa42fe891300d7dada83b5,

title = "Metabolic Network Analysis Reveals Altered Bile Acid Synthesis and Metabolism in Alzheimer's Disease",

abstract = "Increasing evidence suggests Alzheimer's disease (AD) pathophysiology is influenced by primary and secondary bile acids, the end product of cholesterol metabolism. We analyze 2,114 post-mortem brain transcriptomes and identify genes in the alternative bile acid synthesis pathway to be expressed in the brain. A targeted metabolomic analysis of primary and secondary bile acids measured from post-mortem brain samples of 111 individuals supports these results. Our metabolic network analysis suggests that taurine transport, bile acid synthesis, and cholesterol metabolism differ in AD and cognitively normal individuals. We also identify putative transcription factors regulating metabolic genes and influencing altered metabolism in AD. Intriguingly, some bile acids measured in brain tissue cannot be explained by the presence of enzymes responsible for their synthesis, suggesting that they may originate from the gut microbiome and are transported to the brain. These findings motivate further research into bile acid metabolism in AD to elucidate their possible connection to cognitive decline. Baloni et al. use a systems biology approach to identify alterations in cholesterol and bile acid metabolism in Alzheimer disease (AD). Expression of alternative bile acid and neural cholesterol clearance pathway along with transporters of taurine and bile acids suggest the role of the gut-brain axis in AD.",

keywords = "Alzheimer's disease, bile acids, cholesterol metabolism, genome-scale metabolic models, metabolomics, transcriptional regulatory networks, transcriptomics",

author = "{The Alzheimer's Disease Metabolomics Consortium} and Priyanka Baloni and Funk, {Cory C.} and Jingwen Yan and Yurkovich, {James T.} and Alexandra Kueider-Paisley and Kwangsik Nho and Almut Heinken and Wei Jia and Siamak Mahmoudiandehkordi and Gregory Louie and Saykin, {Andrew J.} and Matthias Arnold and Gabi Kastenm{\"u}ller and Griffiths, {William J.} and Ines Thiele and Rima Kaddurah-Daouk and Doraiswamy, {P. Murali} and Colette Blach and Arthur Moseley and Thompson, {J. Will} and Siamak Mahmoudiandehkhordi and Kathleen Welsh-Balmer and Brenda Plassman and Andrew Saykin and Sudeepa Bhattacharyya and Xianlin Han and Rebecca Baillie and Oliver Fiehn and Dinesh Barupal and Peter Meikle and Sarkis Mazmanian and Mitchel Kling and Leslie Shaw and John Trojanowski and Jon Toledo and {van Duijin}, Cornelia and Thomas Hankemier and Nathan Price and Cory Funk and David Wishart and Roberta Brinton and Rui Chang and Lindsay Farrer and Rhoda Au and Wendy Qiu and Peter W{\"u}rtz and Lara Mangravite and Jan Krumsiek and John Newman and Price, {Nathan D.}",

note = "Funding Information: The authors would like to thank the AMP-AD Consortium for funding the project and the AMP-AD Knowledge Portal for sharing the data. The authors would also like to thank members of the Hood-Price group at ISB for their support and help. Funding for the ADMC (Alzheimer{\textquoteright}s Disease Metabolomics Consortium, led by R.K.-D. at Duke University) was provided by National Institute on Aging (NIA) grant no. R01AG046171 , a component of the Accelerated Medicines Partnership for AD (AMP-AD) Target Discovery and Preclinical Validation Project ( https://www.nia.nih.gov/research/dn/amp-ad-target-discovery-and-preclinical-validation-project ) and NIA grant no. RF1 AG0151550 , a component of the M2OVE-AD Consortium (Molecular Mechanisms of the Vascular Etiology of AD–Consortium ( https://www.nia.nih.gov/news/decoding-molecular-ties -between-vascular-disease-and-alzheimers). The Religious Orders and the Rush Memory and Aging studies were supported by NIA grant nos. P30AG10161 , R01AG15819 , R01AG17917 , and U01AG46152 . Additionally, M.A., R.K.-D., and G.K. are supported by NIA grant nos. RF1 AG058942 and R01 AG057452 . M.A. and G.K. are also supported by funding from the Qatar National Research Fund NPRP8-061-3-011 . K.N. is supported by NIA grant nos. NLM R01 LM012535 and NIA R03 AG054936 . A.J.S. is supported by NIH grants, including P30 AG010133 , R01 AG019771 , and R01 CA129769 . W.J.G. is supported by funding from the UK Biotechnology and Biological Sciences Research Council (grant nos. BB/I001735/1 and BB/N015932/1 ) and the Engineering and Physical Sciences Research Council via an Impact Acceleration Account to Swansea University . J.T.Y. is supported by the Institute for Systems Biology{\textquoteright}s Translational Research Fellows Program . Funding Information: The authors would like to thank the AMP-AD Consortium for funding the project and the AMP-AD Knowledge Portal for sharing the data. The authors would also like to thank members of the Hood-Price group at ISB for their support and help. Funding for the ADMC (Alzheimer's Disease Metabolomics Consortium, led by R.K.-D. at Duke University) was provided by National Institute on Aging (NIA) grant no. R01AG046171, a component of the Accelerated Medicines Partnership for AD (AMP-AD) Target Discovery and Preclinical Validation Project (https://www.nia.nih.gov/research/dn/amp-ad-target-discovery-and-preclinical-validation-project) and NIA grant no. RF1 AG0151550, a component of the M2OVE-AD Consortium (Molecular Mechanisms of the Vascular Etiology of AD?Consortium (https://www.nia.nih.gov/news/decoding-molecular-ties-between-vascular-disease-and-alzheimers). The Religious Orders and the Rush Memory and Aging studies were supported by NIA grant nos. P30AG10161, R01AG15819, R01AG17917, andU01AG46152. Additionally, M.A. R.K.-D. and G.K. are supported by NIA grant nos. RF1 AG058942 and R01 AG057452. M.A. and G.K. are also supported by funding from the Qatar National Research Fund NPRP8-061-3-011. K.N. is supported by NIA grant nos. NLM R01 LM012535 and NIA R03 AG054936. A.J.S. is supported by NIH grants, including P30 AG010133, R01 AG019771, and R01 CA129769. W.J.G. is supported by funding from the UK Biotechnology and Biological Sciences Research Council (grant nos. BB/I001735/1 and BB/N015932/1) and the Engineering and Physical Sciences Research Council via an Impact Acceleration Account to Swansea University. J.T.Y. is supported by the Institute for Systems Biology's Translational Research Fellows Program. N.D.P. and R.K.-D. conceived and supervised the study. P.B. reconstructed the brain region-specific metabolic networks; P.B. C.C.F. and J.Y. analyzed the transcriptomics data for post-mortem brain samples downloaded from the AMP-AD knowledge portal; A.K.-P. analyzed the metabolomics data of the brain; I.T. provided the list of metabolites that can cross the BBB; W.J.G. and A.K.-P. provided valuable comments about the BA analysis; W.J. measured the BAs from the post-mortem brain samples; the AMP-AD Consortium and the Alzheimer Disease Metabolomics Consortium collected the transcriptomics and metabolomics data; J.T.Y. and P.B. did the sampling of the metabolic networks; A.H. and I.T. provided the information about the gut microbiome; P.B. C.C.F. J.T.Y. J.Y. A.K.-P. K.N. A.H. S.M. G.L. A.J.S. M.A. G.K. W.J.G. I.T. R.K.-D. and N.D.P. contributed to the writing of this paper. All of the authors reviewed and edited the paper. The authors declare no competing interests. Publisher Copyright: {\textcopyright} 2020 The Authors",

year = "2020",

month = nov,

day = "17",

doi = "10.1016/j.xcrm.2020.100138",

language = "English (US)",

volume = "1",

journal = "Cell Reports Medicine",

issn = "2666-3791",

publisher = "Cell Press",

number = "8",

}

TY - JOUR

T1 - Metabolic Network Analysis Reveals Altered Bile Acid Synthesis and Metabolism in Alzheimer's Disease

AU - The Alzheimer's Disease Metabolomics Consortium

AU - Baloni, Priyanka

AU - Funk, Cory C.

AU - Yan, Jingwen

AU - Yurkovich, James T.

AU - Kueider-Paisley, Alexandra

AU - Nho, Kwangsik

AU - Heinken, Almut

AU - Jia, Wei

AU - Mahmoudiandehkordi, Siamak

AU - Louie, Gregory

AU - Saykin, Andrew J.

AU - Arnold, Matthias

AU - Kastenmüller, Gabi

AU - Griffiths, William J.

AU - Thiele, Ines

AU - Kaddurah-Daouk, Rima

AU - Doraiswamy, P. Murali

AU - Blach, Colette

AU - Moseley, Arthur

AU - Thompson, J. Will

AU - Mahmoudiandehkhordi, Siamak

AU - Welsh-Balmer, Kathleen

AU - Plassman, Brenda

AU - Saykin, Andrew

AU - Bhattacharyya, Sudeepa

AU - Han, Xianlin

AU - Baillie, Rebecca

AU - Fiehn, Oliver

AU - Barupal, Dinesh

AU - Meikle, Peter

AU - Mazmanian, Sarkis

AU - Kling, Mitchel

AU - Shaw, Leslie

AU - Trojanowski, John

AU - Toledo, Jon

AU - van Duijin, Cornelia

AU - Hankemier, Thomas

AU - Price, Nathan

AU - Funk, Cory

AU - Wishart, David

AU - Brinton, Roberta

AU - Chang, Rui

AU - Farrer, Lindsay

AU - Au, Rhoda

AU - Qiu, Wendy

AU - Würtz, Peter

AU - Mangravite, Lara

AU - Krumsiek, Jan

AU - Newman, John

AU - Price, Nathan D.

N1 - Funding Information: The authors would like to thank the AMP-AD Consortium for funding the project and the AMP-AD Knowledge Portal for sharing the data. The authors would also like to thank members of the Hood-Price group at ISB for their support and help. Funding for the ADMC (Alzheimer’s Disease Metabolomics Consortium, led by R.K.-D. at Duke University) was provided by National Institute on Aging (NIA) grant no. R01AG046171 , a component of the Accelerated Medicines Partnership for AD (AMP-AD) Target Discovery and Preclinical Validation Project ( https://www.nia.nih.gov/research/dn/amp-ad-target-discovery-and-preclinical-validation-project ) and NIA grant no. RF1 AG0151550 , a component of the M2OVE-AD Consortium (Molecular Mechanisms of the Vascular Etiology of AD–Consortium ( https://www.nia.nih.gov/news/decoding-molecular-ties -between-vascular-disease-and-alzheimers). The Religious Orders and the Rush Memory and Aging studies were supported by NIA grant nos. P30AG10161 , R01AG15819 , R01AG17917 , and U01AG46152 . Additionally, M.A., R.K.-D., and G.K. are supported by NIA grant nos. RF1 AG058942 and R01 AG057452 . M.A. and G.K. are also supported by funding from the Qatar National Research Fund NPRP8-061-3-011 . K.N. is supported by NIA grant nos. NLM R01 LM012535 and NIA R03 AG054936 . A.J.S. is supported by NIH grants, including P30 AG010133 , R01 AG019771 , and R01 CA129769 . W.J.G. is supported by funding from the UK Biotechnology and Biological Sciences Research Council (grant nos. BB/I001735/1 and BB/N015932/1 ) and the Engineering and Physical Sciences Research Council via an Impact Acceleration Account to Swansea University . J.T.Y. is supported by the Institute for Systems Biology’s Translational Research Fellows Program . Funding Information: The authors would like to thank the AMP-AD Consortium for funding the project and the AMP-AD Knowledge Portal for sharing the data. The authors would also like to thank members of the Hood-Price group at ISB for their support and help. Funding for the ADMC (Alzheimer's Disease Metabolomics Consortium, led by R.K.-D. at Duke University) was provided by National Institute on Aging (NIA) grant no. R01AG046171, a component of the Accelerated Medicines Partnership for AD (AMP-AD) Target Discovery and Preclinical Validation Project (https://www.nia.nih.gov/research/dn/amp-ad-target-discovery-and-preclinical-validation-project) and NIA grant no. RF1 AG0151550, a component of the M2OVE-AD Consortium (Molecular Mechanisms of the Vascular Etiology of AD?Consortium (https://www.nia.nih.gov/news/decoding-molecular-ties-between-vascular-disease-and-alzheimers). The Religious Orders and the Rush Memory and Aging studies were supported by NIA grant nos. P30AG10161, R01AG15819, R01AG17917, andU01AG46152. Additionally, M.A. R.K.-D. and G.K. are supported by NIA grant nos. RF1 AG058942 and R01 AG057452. M.A. and G.K. are also supported by funding from the Qatar National Research Fund NPRP8-061-3-011. K.N. is supported by NIA grant nos. NLM R01 LM012535 and NIA R03 AG054936. A.J.S. is supported by NIH grants, including P30 AG010133, R01 AG019771, and R01 CA129769. W.J.G. is supported by funding from the UK Biotechnology and Biological Sciences Research Council (grant nos. BB/I001735/1 and BB/N015932/1) and the Engineering and Physical Sciences Research Council via an Impact Acceleration Account to Swansea University. J.T.Y. is supported by the Institute for Systems Biology's Translational Research Fellows Program. N.D.P. and R.K.-D. conceived and supervised the study. P.B. reconstructed the brain region-specific metabolic networks; P.B. C.C.F. and J.Y. analyzed the transcriptomics data for post-mortem brain samples downloaded from the AMP-AD knowledge portal; A.K.-P. analyzed the metabolomics data of the brain; I.T. provided the list of metabolites that can cross the BBB; W.J.G. and A.K.-P. provided valuable comments about the BA analysis; W.J. measured the BAs from the post-mortem brain samples; the AMP-AD Consortium and the Alzheimer Disease Metabolomics Consortium collected the transcriptomics and metabolomics data; J.T.Y. and P.B. did the sampling of the metabolic networks; A.H. and I.T. provided the information about the gut microbiome; P.B. C.C.F. J.T.Y. J.Y. A.K.-P. K.N. A.H. S.M. G.L. A.J.S. M.A. G.K. W.J.G. I.T. R.K.-D. and N.D.P. contributed to the writing of this paper. All of the authors reviewed and edited the paper. The authors declare no competing interests. Publisher Copyright: © 2020 The Authors

PY - 2020/11/17

Y1 - 2020/11/17

N2 - Increasing evidence suggests Alzheimer's disease (AD) pathophysiology is influenced by primary and secondary bile acids, the end product of cholesterol metabolism. We analyze 2,114 post-mortem brain transcriptomes and identify genes in the alternative bile acid synthesis pathway to be expressed in the brain. A targeted metabolomic analysis of primary and secondary bile acids measured from post-mortem brain samples of 111 individuals supports these results. Our metabolic network analysis suggests that taurine transport, bile acid synthesis, and cholesterol metabolism differ in AD and cognitively normal individuals. We also identify putative transcription factors regulating metabolic genes and influencing altered metabolism in AD. Intriguingly, some bile acids measured in brain tissue cannot be explained by the presence of enzymes responsible for their synthesis, suggesting that they may originate from the gut microbiome and are transported to the brain. These findings motivate further research into bile acid metabolism in AD to elucidate their possible connection to cognitive decline. Baloni et al. use a systems biology approach to identify alterations in cholesterol and bile acid metabolism in Alzheimer disease (AD). Expression of alternative bile acid and neural cholesterol clearance pathway along with transporters of taurine and bile acids suggest the role of the gut-brain axis in AD.

AB - Increasing evidence suggests Alzheimer's disease (AD) pathophysiology is influenced by primary and secondary bile acids, the end product of cholesterol metabolism. We analyze 2,114 post-mortem brain transcriptomes and identify genes in the alternative bile acid synthesis pathway to be expressed in the brain. A targeted metabolomic analysis of primary and secondary bile acids measured from post-mortem brain samples of 111 individuals supports these results. Our metabolic network analysis suggests that taurine transport, bile acid synthesis, and cholesterol metabolism differ in AD and cognitively normal individuals. We also identify putative transcription factors regulating metabolic genes and influencing altered metabolism in AD. Intriguingly, some bile acids measured in brain tissue cannot be explained by the presence of enzymes responsible for their synthesis, suggesting that they may originate from the gut microbiome and are transported to the brain. These findings motivate further research into bile acid metabolism in AD to elucidate their possible connection to cognitive decline. Baloni et al. use a systems biology approach to identify alterations in cholesterol and bile acid metabolism in Alzheimer disease (AD). Expression of alternative bile acid and neural cholesterol clearance pathway along with transporters of taurine and bile acids suggest the role of the gut-brain axis in AD.

KW - Alzheimer's disease

KW - bile acids

KW - cholesterol metabolism

KW - genome-scale metabolic models

KW - metabolomics

KW - transcriptional regulatory networks

KW - transcriptomics

UR - http://www.scopus.com/inward/record.url?scp=85097135825&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85097135825&partnerID=8YFLogxK

U2 - 10.1016/j.xcrm.2020.100138

DO - 10.1016/j.xcrm.2020.100138

M3 - Article

C2 - 33294859

AN - SCOPUS:85097135825

SN - 2666-3791

VL - 1

JO - Cell Reports Medicine

JF - Cell Reports Medicine

IS - 8

M1 - 100138

ER -

Metabolic Network Analysis Reveals Altered Bile Acid Synthesis and Metabolism in Alzheimer's Disease

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