Literature DB >> 20880512

Strategies for treatment in Alexander disease.

Albee Messing1, Christine M LaPash Daniels, Tracy L Hagemann.   

Abstract

Alexander disease is a rare and generally fatal disorder of the CNS, originally classified among the leukodystrophies because of the prominent myelin deficits found in young patients. The most common form of this disease affects infants, who often have profound mental retardation and a variety of developmental delays, but later onset forms also occur, sometimes with little or no white matter pathology at all. The pathological hallmark of Alexander disease is the inclusion body, known as Rosenthal fiber, within the cell bodies and processes of astrocytes. Recent genetic studies identified heterozygous missense mutations in glial fibrillary acidic protein (GFAP), the major intermediate filament protein in astrocytes, as the cause of nearly all cases of Alexander disease. These studies have transformed our view of this disorder and opened new directions for investigation and clinical practice, particularly with respect to diagnosis. Mechanisms by which expression of mutant forms of glial fibrillary acidic protein (GFAP) lead to the pleiotropic manifestations of disease (afflicting cell types beyond the ones expressing the mutant gene) are slowly coming into focus. Ideas are beginning to emerge that suggest several compelling therapeutic targets for interventions that might slow or arrest the evolution of the disease. This review will outline the rationale for pursuing these strategies, and highlight some of the critical issues that must be addressed in the planning of future clinical trials.
Copyright © 2010 The American Society for Experimental NeuroTherapeutics, Inc. Published by Elsevier Inc. All rights reserved.

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Year:  2010        PMID: 20880512      PMCID: PMC2948554          DOI: 10.1016/j.nurt.2010.05.013

Source DB:  PubMed          Journal:  Neurotherapeutics        ISSN: 1878-7479            Impact factor:   7.620


  86 in total

1.  Targeted deletion in astrocyte intermediate filament (Gfap) alters neuronal physiology.

Authors:  M A McCall; R G Gregg; R R Behringer; M Brenner; C L Delaney; E J Galbreath; C L Zhang; R A Pearce; S Y Chiu; A Messing
Journal:  Proc Natl Acad Sci U S A       Date:  1996-06-25       Impact factor: 11.205

2.  Protection from mitochondrial complex II inhibition in vitro and in vivo by Nrf2-mediated transcription.

Authors:  Marcus J Calkins; Rebekah J Jakel; Delinda A Johnson; Kaimin Chan; Yuet Wai Kan; Jeffrey A Johnson
Journal:  Proc Natl Acad Sci U S A       Date:  2004-12-20       Impact factor: 11.205

Review 3.  GFAP and its role in Alexander disease.

Authors:  Roy A Quinlan; Michael Brenner; James E Goldman; Albee Messing
Journal:  Exp Cell Res       Date:  2007-04-06       Impact factor: 3.905

Review 4.  Intermediate filament proteins.

Authors:  R Quinlan; C Hutchison; B Lane
Journal:  Protein Profile       Date:  1995

5.  Alexander disease: ventricular garlands and abnormalities of the medulla and spinal cord.

Authors:  M S van der Knaap; V Ramesh; R Schiffmann; S Blaser; M Kyllerman; A Gholkar; D W Ellison; J P van der Voorn; S J M van Dooren; C Jakobs; F Barkhof; G S Salomons
Journal:  Neurology       Date:  2006-02-28       Impact factor: 9.910

6.  Regulation of astrocytic glutamate transporter expression by Akt: evidence for a selective transcriptional effect on the GLT-1/EAAT2 subtype.

Authors:  Li-Bin Li; Shuy Vang Toan; Olga Zelenaia; Deborah J Watson; John H Wolfe; Jeffrey D Rothstein; Michael B Robinson
Journal:  J Neurochem       Date:  2006-03-29       Impact factor: 5.372

7.  Oligomers of mutant glial fibrillary acidic protein (GFAP) Inhibit the proteasome system in alexander disease astrocytes, and the small heat shock protein alphaB-crystallin reverses the inhibition.

Authors:  Guomei Tang; Ming D Perng; Sherwin Wilk; Roy Quinlan; James E Goldman
Journal:  J Biol Chem       Date:  2010-01-28       Impact factor: 5.157

8.  Response of a neuronal model of tuberous sclerosis to mammalian target of rapamycin (mTOR) inhibitors: effects on mTORC1 and Akt signaling lead to improved survival and function.

Authors:  Lynsey Meikle; Kristen Pollizzi; Anna Egnor; Ioannis Kramvis; Heidi Lane; Mustafa Sahin; David J Kwiatkowski
Journal:  J Neurosci       Date:  2008-05-21       Impact factor: 6.167

9.  Lithium induces autophagy by inhibiting inositol monophosphatase.

Authors:  Sovan Sarkar; R Andres Floto; Zdenek Berger; Sara Imarisio; Axelle Cordenier; Matthieu Pasco; Lynnette J Cook; David C Rubinsztein
Journal:  J Cell Biol       Date:  2005-09-26       Impact factor: 10.539

10.  A rational mechanism for combination treatment of Huntington's disease using lithium and rapamycin.

Authors:  Sovan Sarkar; Gauri Krishna; Sara Imarisio; Shinji Saiki; Cahir J O'Kane; David C Rubinsztein
Journal:  Hum Mol Genet       Date:  2007-10-06       Impact factor: 6.150
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  22 in total

Review 1.  Alexander's disease: reassessment of a neonatal form.

Authors:  Navneet Singh; Catherine Bixby; Denzil Etienne; R Shane Tubbs; Marios Loukas
Journal:  Childs Nerv Syst       Date:  2012-08-14       Impact factor: 1.475

2.  Juvenile alexander disease: a case report.

Authors:  Halit Ozkaya; Abdullah Baris Akcan; Gokhan Aydemir; Mustafa Kul; Secil Aydinoz; Ferhan Karademir; Selami Suleymanoglu
Journal:  Eurasian J Med       Date:  2012-04

3.  Astrogliopathology in neurological, neurodevelopmental and psychiatric disorders.

Authors:  Alexei Verkhratsky; Vladimir Parpura
Journal:  Neurobiol Dis       Date:  2015-04-03       Impact factor: 5.996

Review 4.  Glial fibrillary acidic protein: from intermediate filament assembly and gliosis to neurobiomarker.

Authors:  Zhihui Yang; Kevin K W Wang
Journal:  Trends Neurosci       Date:  2015-05-11       Impact factor: 13.837

5.  Protein changes in immunodepleted cerebrospinal fluid from a transgenic mouse model of Alexander disease detected using mass spectrometry.

Authors:  Robert Cunningham; Paige Jany; Albee Messing; Lingjun Li
Journal:  J Proteome Res       Date:  2013-01-11       Impact factor: 4.466

6.  Antisense suppression of glial fibrillary acidic protein as a treatment for Alexander disease.

Authors:  Tracy L Hagemann; Berit Powers; Curt Mazur; Aneeza Kim; Steven Wheeler; Gene Hung; Eric Swayze; Albee Messing
Journal:  Ann Neurol       Date:  2018-01-14       Impact factor: 10.422

7.  Glial fibrillary acidic protein exhibits altered turnover kinetics in a mouse model of Alexander disease.

Authors:  Laura R Moody; Gregory A Barrett-Wilt; Michael R Sussman; Albee Messing
Journal:  J Biol Chem       Date:  2017-02-21       Impact factor: 5.157

8.  Alexander disease.

Authors:  Albee Messing; Michael Brenner; Mel B Feany; Maiken Nedergaard; James E Goldman
Journal:  J Neurosci       Date:  2012-04-11       Impact factor: 6.167

9.  GFAP Mutations in Astrocytes Impair Oligodendrocyte Progenitor Proliferation and Myelination in an hiPSC Model of Alexander Disease.

Authors:  Li Li; E Tian; Xianwei Chen; Jianfei Chao; Jeremy Klein; Qiuhao Qu; Guihua Sun; Guoqiang Sun; Yanzhou Huang; Charles D Warden; Peng Ye; Lizhao Feng; Xinqiang Li; Qi Cui; Abdullah Sultan; Panagiotis Douvaras; Valentina Fossati; Neville E Sanjana; Arthur D Riggs; Yanhong Shi
Journal:  Cell Stem Cell       Date:  2018-08-02       Impact factor: 24.633

10.  GFAP expression as an indicator of disease severity in mouse models of Alexander disease.

Authors:  Paige L Jany; Tracy L Hagemann; Albee Messing
Journal:  ASN Neuro       Date:  2013       Impact factor: 4.146
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