Literature DB >> 30518688

FGF21 underlies a hormetic response to metabolic stress in methylmalonic acidemia.

Irini Manoli1, Justin R Sysol1, Madeline W Epping1, Lina Li1, Cindy Wang1, Jennifer L Sloan1, Alexandra Pass1, Jack Gagné1, Yiouli P Ktena1, Lingli Li2, Niraj S Trivedi3, Bazoumana Ouattara4,5, Patricia M Zerfas6, Victoria Hoffmann6, Mones Abu-Asab7, Maria G Tsokos7, David E Kleiner8, Caterina Garone9, Kristina Cusmano-Ozog10, Gregory M Enns10, Hilary J Vernon11, Hans C Andersson12, Stephanie Grunewald13, Abdel G Elkahloun3, Christiane L Girard4, Jurgen Schnermann2, Salvatore DiMauro9, Eva Andres-Mateos14,15, Luk H Vandenberghe14,15,16,17, Randy J Chandler1, Charles P Venditti1.   

Abstract

Methylmalonic acidemia (MMA), an organic acidemia characterized by metabolic instability and multiorgan complications, is most frequently caused by mutations in methylmalonyl-CoA mutase (MUT). To define the metabolic adaptations in MMA in acute and chronic settings, we studied a mouse model generated by transgenic expression of Mut in the muscle. Mut-/-;TgINS-MCK-Mut mice accurately replicate the hepatorenal mitochondriopathy and growth failure seen in severely affected patients and were used to characterize the response to fasting. The hepatic transcriptome in MMA mice was characterized by the chronic activation of stress-related pathways and an aberrant fasting response when compared with controls. A key metabolic regulator, Fgf21, emerged as a significantly dysregulated transcript in mice and was subsequently studied in a large patient cohort. The concentration of plasma FGF21 in MMA patients correlated with disease subtype, growth indices, and markers of mitochondrial dysfunction but was not affected by renal disease. Restoration of liver Mut activity, by transgenesis and liver-directed gene therapy in mice or liver transplantation in patients, drastically reduced plasma FGF21 and was associated with improved outcomes. Our studies identify mitocellular hormesis as a hepatic adaptation to metabolic stress in MMA and define FGF21 as a highly predictive disease biomarker.

Entities:  

Keywords:  Gene therapy; Genetics; Intermediary metabolism; Metabolism; Mitochondria

Mesh:

Substances:

Year:  2018        PMID: 30518688      PMCID: PMC6328030          DOI: 10.1172/jci.insight.124351

Source DB:  PubMed          Journal:  JCI Insight        ISSN: 2379-3708


  80 in total

1.  Increased fibroblast growth factor 21 in obesity and nonalcoholic fatty liver disease.

Authors:  Jody Dushay; Patricia C Chui; Gosala S Gopalakrishnan; Marta Varela-Rey; Meghan Crawley; Ffolliott M Fisher; Michael K Badman; Maria L Martinez-Chantar; Eleftheria Maratos-Flier
Journal:  Gastroenterology       Date:  2010-05-05       Impact factor: 22.682

2.  Long-term outcome in methylmalonic acidurias is influenced by the underlying defect (mut0, mut-, cblA, cblB).

Authors:  Friederike Hörster; Matthias R Baumgartner; Caroline Viardot; Terttu Suormala; Peter Burgard; Brian Fowler; Georg F Hoffmann; Sven F Garbade; Stefan Kölker; E Regula Baumgartner
Journal:  Pediatr Res       Date:  2007-08       Impact factor: 3.756

Review 3.  Branched-chain amino acids: enzyme and substrate regulation.

Authors:  John T Brosnan; Margaret E Brosnan
Journal:  J Nutr       Date:  2006-01       Impact factor: 4.798

Review 4.  Fatty liver and FGF21 physiology.

Authors:  Eleftheria Maratos-Flier
Journal:  Exp Cell Res       Date:  2017-05-23       Impact factor: 3.905

5.  Hepatocyte-specific deletion of SIRT1 alters fatty acid metabolism and results in hepatic steatosis and inflammation.

Authors:  Aparna Purushotham; Thaddeus T Schug; Qing Xu; Sailesh Surapureddi; Xiumei Guo; Xiaoling Li
Journal:  Cell Metab       Date:  2009-04       Impact factor: 27.287

6.  A Liver-Bone Endocrine Relay by IGFBP1 Promotes Osteoclastogenesis and Mediates FGF21-Induced Bone Resorption.

Authors:  Xunde Wang; Wei Wei; Jing Y Krzeszinski; Yubao Wang; Yihong Wan
Journal:  Cell Metab       Date:  2015-10-08       Impact factor: 27.287

7.  Primary structure and activity of mouse methylmalonyl-CoA mutase.

Authors:  M F Wilkemeyer; A M Crane; F D Ledley
Journal:  Biochem J       Date:  1990-10-15       Impact factor: 3.857

8.  Novel Mouse Models of Methylmalonic Aciduria Recapitulate Phenotypic Traits with a Genetic Dosage Effect.

Authors:  Patrick Forny; Anke Schumann; Merima Mustedanagic; Déborah Mathis; Marie-Angela Wulf; Nadine Nägele; Claus-Dieter Langhans; Assem Zhakupova; Joerg Heeren; Ludger Scheja; Ralph Fingerhut; Heidi L Peters; Thorsten Hornemann; Beat Thony; Stefan Kölker; Patricie Burda; D Sean Froese; Olivier Devuyst; Matthias R Baumgartner
Journal:  J Biol Chem       Date:  2016-08-12       Impact factor: 5.157

9.  Hepatic SIRT1 attenuates hepatic steatosis and controls energy balance in mice by inducing fibroblast growth factor 21.

Authors:  Yu Li; Kimberly Wong; Amber Giles; Jianwei Jiang; Jong Woo Lee; Andrew C Adams; Alexei Kharitonenkov; Qin Yang; Bin Gao; Leonard Guarente; Mengwei Zang
Journal:  Gastroenterology       Date:  2013-11-01       Impact factor: 22.682

10.  Metabolic phenotype of methylmalonic acidemia in mice and humans: the role of skeletal muscle.

Authors:  Randy J Chandler; Jennifer Sloan; Hong Fu; Matthew Tsai; Sally Stabler; Robert Allen; Klaus H Kaestner; Haig H Kazazian; Charles P Venditti
Journal:  BMC Med Genet       Date:  2007-10-15       Impact factor: 2.103
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  20 in total

Review 1.  Gene Therapy for Methylmalonic Acidemia: Past, Present, and Future.

Authors:  Randy J Chandler; Charles P Venditti
Journal:  Hum Gene Ther       Date:  2019-08-16       Impact factor: 5.695

2.  Guidelines for the diagnosis and management of methylmalonic acidaemia and propionic acidaemia: First revision.

Authors:  Patrick Forny; Friederike Hörster; Diana Ballhausen; Anupam Chakrapani; Kimberly A Chapman; Carlo Dionisi-Vici; Marjorie Dixon; Sarah C Grünert; Stephanie Grunewald; Goknur Haliloglu; Michel Hochuli; Tomas Honzik; Daniela Karall; Diego Martinelli; Femke Molema; Jörn Oliver Sass; Sabine Scholl-Bürgi; Galit Tal; Monique Williams; Martina Huemer; Matthias R Baumgartner
Journal:  J Inherit Metab Dis       Date:  2021-03-09       Impact factor: 4.750

3.  Noninvasive monitoring of chronic kidney disease using pH and perfusion imaging.

Authors:  KowsalyaDevi Pavuluri; Irini Manoli; Alexandra Pass; Yuguo Li; Hilary J Vernon; Charles P Venditti; Michael T McMahon
Journal:  Sci Adv       Date:  2019-08-14       Impact factor: 14.136

4.  Remodeling of whole-body lipid metabolism and a diabetic-like phenotype caused by loss of CDK1 and hepatocyte division.

Authors:  Jin Rong Ow; Matias J Cadez; Gözde Zafer; Juat Chin Foo; Hong Yu Li; Soumita Ghosh; Heike Wollmann; Amaury Cazenave-Gassiot; Chee Bing Ong; Markus R Wenk; Weiping Han; Hyungwon Choi; Philipp Kaldis
Journal:  Elife       Date:  2020-12-21       Impact factor: 8.140

5.  Decrease of disease-related metabolites upon fasting in a hemizygous knock-in mouse model (Mut-ko/ki) of methylmalonic aciduria.

Authors:  Marie Lucienne; Déborah Mathis; Nathan Perkins; Ralph Fingerhut; Matthias R Baumgartner; D Sean Froese
Journal:  JIMD Rep       Date:  2020-11-08

6.  Retrospective evaluation of the Dutch pre-newborn screening cohort for propionic acidemia and isolated methylmalonic acidemia: What to aim, expect, and evaluate from newborn screening?

Authors:  Hanneke A Haijes; Femke Molema; Mirjam Langeveld; Mirian C Janssen; Annet M Bosch; Francjan van Spronsen; Margot F Mulder; Nanda M Verhoeven-Duif; Judith J M Jans; Ans T van der Ploeg; Margreet A Wagenmakers; M Estela Rubio-Gozalbo; Martijn C G J Brouwers; Maaike C de Vries; Janneke G Langendonk; Monique Williams; Peter M van Hasselt
Journal:  J Inherit Metab Dis       Date:  2019-12-22       Impact factor: 4.982

7.  Impaired mitophagy links mitochondrial disease to epithelial stress in methylmalonyl-CoA mutase deficiency.

Authors:  Alessandro Luciani; Anke Schumann; Marine Berquez; Zhiyong Chen; Daniela Nieri; Mario Failli; Huguette Debaix; Beatrice Paola Festa; Natsuko Tokonami; Andrea Raimondi; Alessio Cremonesi; Diego Carrella; Patrick Forny; Stefan Kölker; Francesca Diomedi Camassei; Francisca Diaz; Carlos T Moraes; Diego Di Bernardo; Matthias R Baumgartner; Olivier Devuyst
Journal:  Nat Commun       Date:  2020-02-20       Impact factor: 14.919

8.  1-13C-propionate breath testing as a surrogate endpoint to assess efficacy of liver-directed therapies in methylmalonic acidemia (MMA).

Authors:  Irini Manoli; Alexandra R Pass; Elizabeth A Harrington; Jennifer L Sloan; Jack Gagné; Samantha McCoy; Sarah L Bell; Jacob D Hattenbach; Brooks P Leitner; Courtney J Duckworth; Laura A Fletcher; Thomas M Cassimatis; Carolina I Galarreta; Audrey Thurm; Joseph Snow; Carol Van Ryzin; Susan Ferry; Nicholas Ah Mew; Oleg A Shchelochkov; Kong Y Chen; Charles P Venditti
Journal:  Genet Med       Date:  2021-04-05       Impact factor: 8.822

9.  Liver and/or kidney transplantation in amino and organic acid-related inborn errors of metabolism: An overview on European data.

Authors:  Femke Molema; Diego Martinelli; Friederike Hörster; Stefan Kölker; Trine Tangeraas; Barbara de Koning; Carlo Dionisi-Vici; Monique Williams
Journal:  J Inherit Metab Dis       Date:  2020-10-29       Impact factor: 4.982

10.  Promoterless, Nuclease-Free Genome Editing Confers a Growth Advantage for Corrected Hepatocytes in Mice With Methylmalonic Acidemia.

Authors:  Randy J Chandler; Leah E Venturoni; Jing Liao; Brandon T Hubbard; Jessica L Schneller; Victoria Hoffmann; Susana Gordo; Shengwen Zang; Chih-Wei Ko; Nelson Chau; Kyle Chiang; Mark A Kay; Adi Barzel; Charles P Venditti
Journal:  Hepatology       Date:  2021-05-21       Impact factor: 17.298
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