Literature DB >> 22508027

Multiple phenotypes in Huntington disease mouse neural stem cells.

James J Ritch1, Antonio Valencia, Jonathan Alexander, Ellen Sapp, Leah Gatune, Gavin R Sangrey, Saurabh Sinha, Cally M Scherber, Scott Zeitlin, Ghazaleh Sadri-Vakili, Daniel Irimia, Marian Difiglia, Kimberly B Kegel.   

Abstract

Neural stem (NS) cells are a limitless resource, and thus superior to primary neurons for drug discovery provided they exhibit appropriate disease phenotypes. Here we established NS cells for cellular studies of Huntington's disease (HD). HD is a heritable neurodegenerative disease caused by a mutation resulting in an increased number of glutamines (Q) within a polyglutamine tract in Huntingtin (Htt). NS cells were isolated from embryonic wild-type (Htt(7Q/7Q)) and "knock-in" HD (Htt(140Q/140Q)) mice expressing full-length endogenous normal or mutant Htt. NS cells were also developed from mouse embryonic stem cells that were devoid of Htt (Htt(-/-)), or knock-in cells containing human exon1 with an N-terminal FLAG epitope tag and with 7Q or 140Q inserted into one of the mouse alleles (Htt(F7Q/7Q) and Htt(F140Q/7Q)). Compared to Htt(7Q/7Q) NS cells, HD Htt(140Q/140Q) NS cells showed significantly reduced levels of cholesterol, increased levels of reactive oxygen species (ROS), and impaired motility. The heterozygous Htt(F140Q/7Q) NS cells had increased ROS and decreased motility compared to Htt(F7Q/7Q). These phenotypes of HD NS cells replicate those seen in HD patients or in primary cell or in vivo models of HD. Huntingtin "knock-out" NS cells (Htt(-/-)) also had impaired motility, but in contrast to HD cells had increased cholesterol. In addition, Htt(140Q/140Q) NS cells had higher phospho-AKT/AKT ratios than Htt(7Q/7Q) NS cells in resting conditions and after BDNF stimulation, suggesting mutant htt affects AKT dependent growth factor signaling. Upon differentiation, the Htt(7Q/7Q) and Htt(140Q/140Q) generated numerous Beta(III)-Tubulin- and GABA-positive neurons; however, after 15 days the cellular architecture of the differentiated Htt(140Q/140Q) cultures changed compared to Htt(7Q/7Q) cultures and included a marked increase of GFAP-positive cells. Our findings suggest that NS cells expressing endogenous mutant Htt will be useful for study of mechanisms of HD and drug discovery.
Copyright © 2012 Elsevier Inc. All rights reserved.

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Year:  2012        PMID: 22508027      PMCID: PMC3383872          DOI: 10.1016/j.mcn.2012.03.011

Source DB:  PubMed          Journal:  Mol Cell Neurosci        ISSN: 1044-7431            Impact factor:   4.314


  57 in total

1.  Life without huntingtin: normal differentiation into functional neurons.

Authors:  M Metzler; N Chen; C D Helgason; R K Graham; K Nichol; K McCutcheon; J Nasir; R K Humphries; L A Raymond; M R Hayden
Journal:  J Neurochem       Date:  1999-03       Impact factor: 5.372

Review 2.  The advantages and disadvantages of being polyploid.

Authors:  Luca Comai
Journal:  Nat Rev Genet       Date:  2005-11       Impact factor: 53.242

Review 3.  Consequences of genome duplication.

Authors:  Marie Sémon; Kenneth H Wolfe
Journal:  Curr Opin Genet Dev       Date:  2007-11-19       Impact factor: 5.578

4.  Polyglutamine expansion in huntingtin alters its interaction with phospholipids.

Authors:  Kimberly B Kegel; Ellen Sapp; Jonathan Alexander; Antonio Valencia; Patrick Reeves; Xueyi Li; Nicholas Masso; Lindsay Sobin; Neil Aronin; Marian DiFiglia
Journal:  J Neurochem       Date:  2009-06-29       Impact factor: 5.372

5.  Huntingtin is required for mitotic spindle orientation and mammalian neurogenesis.

Authors:  Juliette D Godin; Kelly Colombo; Maria Molina-Calavita; Guy Keryer; Diana Zala; Bénédicte C Charrin; Paula Dietrich; Marie-Laure Volvert; François Guillemot; Ioannis Dragatsis; Yohanns Bellaiche; Frédéric Saudou; Laurent Nguyen; Sandrine Humbert
Journal:  Neuron       Date:  2010-08-12       Impact factor: 17.173

6.  Characterization of Human Huntington's Disease Cell Model from Induced Pluripotent Stem Cells.

Authors:  Ningzhe Zhang; Mahru C An; Daniel Montoro; Lisa M Ellerby
Journal:  PLoS Curr       Date:  2010-10-28

7.  Human embryonic stem cell models of Huntington disease.

Authors:  Jonathan C Niclis; Alan O Trounson; Mirella Dottori; Andrew M Ellisdon; Stephen P Bottomley; Y Verlinsky; David S Cram
Journal:  Reprod Biomed Online       Date:  2009-07       Impact factor: 3.828

8.  Expanded CAG repeats in the murine Huntington's disease gene increases neuronal differentiation of embryonic and neural stem cells.

Authors:  Matthew T Lorincz; Virginia A Zawistowski
Journal:  Mol Cell Neurosci       Date:  2008-06-19       Impact factor: 4.314

9.  Expression of expanded polyglutamine targets profilin for degradation and alters actin dynamics.

Authors:  Barrington G Burnett; Jaime Andrews; Srikanth Ranganathan; Kenneth H Fischbeck; Nicholas A Di Prospero
Journal:  Neurobiol Dis       Date:  2008-03-06       Impact factor: 5.996

10.  Huntingtin is a cytoplasmic protein associated with vesicles in human and rat brain neurons.

Authors:  M DiFiglia; E Sapp; K Chase; C Schwarz; A Meloni; C Young; E Martin; J P Vonsattel; R Carraway; S A Reeves
Journal:  Neuron       Date:  1995-05       Impact factor: 17.173
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  27 in total

1.  Loss of caveolin-1 expression in knock-in mouse model of Huntington's disease suppresses pathophysiology in vivo.

Authors:  Eugenia Trushina; Christie A Canaria; Do-Yup Lee; Cynthia T McMurray
Journal:  Hum Mol Genet       Date:  2013-09-10       Impact factor: 6.150

Review 2.  The emerging role of the first 17 amino acids of huntingtin in Huntington's disease.

Authors:  James R Arndt; Maxmore Chaibva; Justin Legleiter
Journal:  Biomol Concepts       Date:  2015-03

3.  Probing the Huntingtin 1-17 membrane anchor on a phospholipid bilayer by using all-atom simulations.

Authors:  Sébastien Côté; Vincent Binette; Evgeniy S Salnikov; Burkhard Bechinger; Normand Mousseau
Journal:  Biophys J       Date:  2015-03-10       Impact factor: 4.033

4.  Free-Energy Landscape of the Amino-Terminal Fragment of Huntingtin in Aqueous Solution.

Authors:  Vincent Binette; Sébastien Côté; Normand Mousseau
Journal:  Biophys J       Date:  2016-03-08       Impact factor: 4.033

5.  Cholesterol Modifies Huntingtin Binding to, Disruption of, and Aggregation on Lipid Membranes.

Authors:  Xiang Gao; Warren A Campbell; Maxmore Chaibva; Pranav Jain; Ashley E Leslie; Shelli L Frey; Justin Legleiter
Journal:  Biochemistry       Date:  2015-12-22       Impact factor: 3.162

6.  Acetylation within the First 17 Residues of Huntingtin Exon 1 Alters Aggregation and Lipid Binding.

Authors:  Maxmore Chaibva; Sudi Jawahery; Albert W Pilkington; James R Arndt; Olivia Sarver; Stephen Valentine; Silvina Matysiak; Justin Legleiter
Journal:  Biophys J       Date:  2016-07-26       Impact factor: 4.033

7.  Experimental models for identifying modifiers of polyglutamine-induced aggregation and neurodegeneration.

Authors:  Barbara Calamini; Donald C Lo; Linda S Kaltenbach
Journal:  Neurotherapeutics       Date:  2013-07       Impact factor: 7.620

8.  Adult neural progenitor cells from Huntington's disease mouse brain exhibit increased proliferation and migration due to enhanced calcium and ROS signals.

Authors:  Wenjuan Xie; Jiu-Qiang Wang; Qiao-Chu Wang; Yun Wang; Sheng Yao; Tie-Shan Tang
Journal:  Cell Prolif       Date:  2015-08-13       Impact factor: 6.831

Review 9.  Cell-Autonomous and Non-cell-Autonomous Pathogenic Mechanisms in Huntington's Disease: Insights from In Vitro and In Vivo Models.

Authors:  Jordi Creus-Muncunill; Michelle E Ehrlich
Journal:  Neurotherapeutics       Date:  2019-10       Impact factor: 7.620

10.  Pitfalls in the detection of cholesterol in Huntington's disease models.

Authors:  Manuela Marullo; Marta Valenza; Valerio Leoni; Claudio Caccia; Chiara Scarlatti; Agnese De Mario; Chiara Zuccato; Stefano Di Donato; Ernesto Carafoli; Elena Cattaneo
Journal:  PLoS Curr       Date:  2012-10-11
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