Literature DB >> 30930170

Metabolic Reprogramming in Astrocytes Distinguishes Region-Specific Neuronal Susceptibility in Huntington Mice.

Aris A Polyzos1, Do Yup Lee1, Rupsa Datta2, Meghan Hauser3, Helen Budworth1, Amy Holt1, Stephanie Mihalik4, Pike Goldschmidt1, Ken Frankel1, Kelly Trego1, Michael J Bennett5, Jerry Vockley4, Ke Xu6, Enrico Gratton2, Cynthia T McMurray7.   

Abstract

The basis for region-specific neuronal toxicity in Huntington disease is unknown. Here, we show that region-specific neuronal vulnerability is a substrate-driven response in astrocytes. Glucose is low in HdhQ(150/150) animals, and astrocytes in each brain region adapt by metabolically reprogramming their mitochondria to use endogenous, non-glycolytic metabolites as an alternative fuel. Each region is characterized by distinct metabolic pools, and astrocytes adapt accordingly. The vulnerable striatum is enriched in fatty acids, and mitochondria reprogram by oxidizing them as an energy source but at the cost of escalating reactive oxygen species (ROS)-induced damage. The cerebellum is replete with amino acids, which are precursors for glucose regeneration through the pentose phosphate shunt or gluconeogenesis pathways. ROS is not elevated, and this region sustains little damage. While mhtt expression imposes disease stress throughout the brain, sensitivity or resistance arises from an adaptive stress response, which is inherently region specific. Metabolic reprogramming may have relevance to other diseases.
Copyright © 2019. Published by Elsevier Inc.

Entities:  

Keywords:  DNA repair; Huntington disease; astrocytes; double-strand break repair; fatty acids; metabolism; mitochondria; neurodegeneration; neurons; reprogramming

Year:  2019        PMID: 30930170      PMCID: PMC6583797          DOI: 10.1016/j.cmet.2019.03.004

Source DB:  PubMed          Journal:  Cell Metab        ISSN: 1550-4131            Impact factor:   27.287


  83 in total

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3.  Cytoscape: a software environment for integrated models of biomolecular interaction networks.

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4.  Assembly of endocytic machinery around individual influenza viruses during viral entry.

Authors:  Michael J Rust; Melike Lakadamyali; Feng Zhang; Xiaowei Zhuang
Journal:  Nat Struct Mol Biol       Date:  2004-05-02       Impact factor: 15.369

5.  Neurological abnormalities in a knock-in mouse model of Huntington's disease.

Authors:  C H Lin; S Tallaksen-Greene; W M Chien; J A Cearley; W S Jackson; A B Crouse; S Ren; X J Li; R L Albin; P J Detloff
Journal:  Hum Mol Genet       Date:  2001-01-15       Impact factor: 6.150

6.  Specific progressive cAMP reduction implicates energy deficit in presymptomatic Huntington's disease knock-in mice.

Authors:  Silvia Gines; Ihn Sik Seong; Elisa Fossale; Elena Ivanova; Flavia Trettel; James F Gusella; Vanessa C Wheeler; Francesca Persichetti; Marcy E MacDonald
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7.  Proton magnetic resonance spectroscopy of cerebrospinal fluid in neurodegenerative disease: indication of glial energy impairment in Huntington chorea, but not Parkinson disease.

Authors:  M Gårseth; U Sonnewald; L R White; M Rød; J A Zwart; O Nygaard; J Aasly
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8.  Heterogeneity in 1H-MRS profiles of presymptomatic and early manifest Huntington's disease.

Authors:  Norman C Reynolds; Robert W Prost; Leighton P Mark
Journal:  Brain Res       Date:  2005-01-07       Impact factor: 3.252

9.  Etomoxir mediates differential metabolic channeling of fatty acid and glycerol precursors into cardiolipin in H9c2 cells.

Authors:  Fred Y Xu; William A Taylor; Jeffrey A Hurd; Grant M Hatch
Journal:  J Lipid Res       Date:  2002-11-04       Impact factor: 5.922

10.  Early mitochondrial calcium defects in Huntington's disease are a direct effect of polyglutamines.

Authors:  Alexander V Panov; Claire-Anne Gutekunst; Blair R Leavitt; Michael R Hayden; James R Burke; Warren J Strittmatter; J Timothy Greenamyre
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  41 in total

1.  Mutant huntingtin does not cross the mitochondrial outer membrane.

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2.  Pleiotropic Mitochondria: The Influence of Mitochondria on Neuronal Development and Disease.

Authors:  Vidhya Rangaraju; Tommy L Lewis; Yusuke Hirabayashi; Matteo Bergami; Elisa Motori; Romain Cartoni; Seok-Kyu Kwon; Julien Courchet
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3.  Mutant huntingtin fails to directly impair brain mitochondria.

Authors:  James Hamilton; Tatiana Brustovetsky; Nickolay Brustovetsky
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4.  Determining the Bioenergetic Capacity for Fatty Acid Oxidation in the Mammalian Nervous System.

Authors:  Cory J White; Jieun Lee; Joseph Choi; Tiffany Chu; Susanna Scafidi; Michael J Wolfgang
Journal:  Mol Cell Biol       Date:  2020-04-28       Impact factor: 4.272

5.  Energy Metabolism and Mitochondrial Superoxide Anion Production in Pre-symptomatic Striatal Neurons Derived from Human-Induced Pluripotent Stem Cells Expressing Mutant Huntingtin.

Authors:  James Hamilton; Tatiana Brustovetsky; Akshayalakshmi Sridhar; Yanling Pan; Theodore R Cummins; Jason S Meyer; Nickolay Brustovetsky
Journal:  Mol Neurobiol       Date:  2019-08-21       Impact factor: 5.590

6.  Mitochondria-Endoplasmic Reticulum Contacts in Reactive Astrocytes Promote Vascular Remodeling.

Authors:  Jana Gӧbel; Esther Engelhardt; Patric Pelzer; Vignesh Sakthivelu; Hannah M Jahn; Milica Jevtic; Kat Folz-Donahue; Christian Kukat; Astrid Schauss; Christian K Frese; Patrick Giavalisco; Alexander Ghanem; Karl-Klaus Conzelmann; Elisa Motori; Matteo Bergami
Journal:  Cell Metab       Date:  2020-03-26       Impact factor: 27.287

7.  Lactobacillus and Pediococcus ameliorate progression of non-alcoholic fatty liver disease through modulation of the gut microbiome.

Authors:  Na Young Lee; Sang Jun Yoon; Dae Hee Han; Haripriya Gupta; Gi Soo Youn; Min Jea Shin; Young Lim Ham; Min Jung Kwak; Byung Yong Kim; Jeong Seok Yu; Do Yup Lee; Tae-Sik Park; Si-Hyun Park; Byoung Kook Kim; Hyun Chae Joung; In Suk Choi; Ji Taek Hong; Dong Joon Kim; Sang Hak Han; Ki Tae Suk
Journal:  Gut Microbes       Date:  2020-01-22

Review 8.  Reactive astrocyte nomenclature, definitions, and future directions.

Authors:  András Lakatos; James P O'Callaghan; Gabor C Petzold; Alberto Serrano-Pozo; Christian Steinhäuser; Andrea Volterra; Giorgio Carmignoto; Carole Escartin; Elena Galea; Amit Agarwal; Nicola J Allen; Alfonso Araque; Luis Barbeito; Ari Barzilai; Dwight E Bergles; Gilles Bonvento; Arthur M Butt; Wei-Ting Chen; Martine Cohen-Salmon; Colm Cunningham; Benjamin Deneen; Bart De Strooper; Blanca Díaz-Castro; Cinthia Farina; Marc Freeman; Vittorio Gallo; James E Goldman; Steven A Goldman; Magdalena Götz; Antonia Gutiérrez; Philip G Haydon; Dieter H Heiland; Elly M Hol; Matthew G Holt; Masamitsu Iino; Ksenia V Kastanenka; Helmut Kettenmann; Baljit S Khakh; Schuichi Koizumi; C Justin Lee; Shane A Liddelow; Brian A MacVicar; Pierre Magistretti; Albee Messing; Anusha Mishra; Anna V Molofsky; Keith K Murai; Christopher M Norris; Seiji Okada; Stéphane H R Oliet; João F Oliveira; Aude Panatier; Vladimir Parpura; Marcela Pekna; Milos Pekny; Luc Pellerin; Gertrudis Perea; Beatriz G Pérez-Nievas; Frank W Pfrieger; Kira E Poskanzer; Francisco J Quintana; Richard M Ransohoff; Miriam Riquelme-Perez; Stefanie Robel; Christine R Rose; Jeffrey D Rothstein; Nathalie Rouach; David H Rowitch; Alexey Semyanov; Swetlana Sirko; Harald Sontheimer; Raymond A Swanson; Javier Vitorica; Ina-Beate Wanner; Levi B Wood; Jiaqian Wu; Binhai Zheng; Eduardo R Zimmer; Robert Zorec; Michael V Sofroniew; Alexei Verkhratsky
Journal:  Nat Neurosci       Date:  2021-02-15       Impact factor: 24.884

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Journal:  Int J Mol Sci       Date:  2021-03-24       Impact factor: 5.923

Review 10.  Metabolic Reprogramming: Strategy for Ischemic Stroke Treatment by Ischemic Preconditioning.

Authors:  Jing Liang; Rongrong Han; Bing Zhou
Journal:  Biology (Basel)       Date:  2021-05-11
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