Literature DB >> 24888478

Myocyte-mediated arginase expression controls hyperargininemia but not hyperammonemia in arginase-deficient mice.

Chuhong Hu1, Jennifer Kasten1, Hana Park1, Ragini Bhargava1, Denise S Tai1, Wayne W Grody2, Quynh G Nguyen3, Stephen D Hauschka3, Stephen D Cederbaum4, Gerald S Lipshutz5.   

Abstract

Human arginase deficiency is characterized by hyperargininemia and infrequent episodes of hyperammonemia that cause neurological impairment and growth retardation. We previously developed a neonatal mouse adeno-associated viral vector (AAV) rh10-mediated therapeutic approach with arginase expressed by a chicken β-actin promoter that controlled plasma ammonia and arginine, but hepatic arginase declined rapidly. This study tested a codon-optimized arginase cDNA and compared the chicken β-actin promoter to liver- and muscle-specific promoters. ARG1(-/-) mice treated with AAVrh10 carrying the liver-specific promoter also exhibited long-term survival and declining hepatic arginase accompanied by the loss of AAV episomes during subsequent liver growth. Although arginase expression in striated muscle was not expected to counteract hyperammonemia, due to muscle's lack of other urea cycle enzymes, we hypothesized that the postmitotic phenotype in muscle would allow vector genomes to persist, and hence contribute to decreased plasma arginine. As anticipated, ARG1(-/-) neonatal mice treated with AAVrh10 carrying a modified creatine kinase-based muscle-specific promoter did not survive longer than controls; however, their plasma arginine levels remained normal when animals were hyperammonemic. These data imply that plasma arginine can be controlled in arginase deficiency by muscle-specific expression, thus suggesting an alternative approach to utilizing the liver for treating hyperargininemia.

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Year:  2014        PMID: 24888478      PMCID: PMC4428413          DOI: 10.1038/mt.2014.99

Source DB:  PubMed          Journal:  Mol Ther        ISSN: 1525-0016            Impact factor:   11.454


  33 in total

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Authors:  T A Partridge
Journal:  Gene Ther       Date:  2002-06       Impact factor: 5.250

2.  Guanidino compound levels in blood, cerebrospinal fluid, and post-mortem brain material of patients with argininemia.

Authors:  Joshua L Deignan; Peter P De Deyn; Stephen D Cederbaum; Arno Fuchshuber; Bernhard Roth; Wieland Gsell; Bart Marescau
Journal:  Mol Genet Metab       Date:  2010-01-29       Impact factor: 4.797

Review 3.  Comparative properties of arginases.

Authors:  C P Jenkinson; W W Grody; S D Cederbaum
Journal:  Comp Biochem Physiol B Biochem Mol Biol       Date:  1996-05       Impact factor: 2.231

4.  RH10 provides superior transgene expression in mice when compared with natural AAV serotypes for neonatal gene therapy.

Authors:  Chuhong Hu; Ronald W Busuttil; Gerald S Lipshutz
Journal:  J Gene Med       Date:  2010-09       Impact factor: 4.565

Review 5.  Hyperargininemia due to liver arginase deficiency.

Authors:  Eric A Crombez; Stephen D Cederbaum
Journal:  Mol Genet Metab       Date:  2004-12-19       Impact factor: 4.797

Review 6.  The human arginases and arginase deficiency.

Authors:  R Iyer; C P Jenkinson; J G Vockley; R M Kern; W W Grody; S Cederbaum
Journal:  J Inherit Metab Dis       Date:  1998       Impact factor: 4.982

7.  Gene delivery to the juvenile mouse liver using AAV2/8 vectors.

Authors:  Sharon C Cunningham; Allison P Dane; Afroditi Spinoulas; Grant J Logan; Ian E Alexander
Journal:  Mol Ther       Date:  2008-04-15       Impact factor: 11.454

Review 8.  Regulation of nitric oxide synthesis and apoptosis by arginase and arginine recycling.

Authors:  Masataka Mori
Journal:  J Nutr       Date:  2007-06       Impact factor: 4.798

9.  Short-term correction of arginase deficiency in a neonatal murine model with a helper-dependent adenoviral vector.

Authors:  Chia-Ling Gau; Robin A Rosenblatt; Vincenzo Cerullo; Fides D Lay; Adrienne C Dow; Justin Livesay; Nicola Brunetti-Pierri; Brendan Lee; Stephen D Cederbaum; Wayne W Grody; Gerald S Lipshutz
Journal:  Mol Ther       Date:  2009-04-14       Impact factor: 11.454

10.  Sarcomeric gene expression and contractility in myofibroblasts.

Authors:  D C Mayer; L A Leinwand
Journal:  J Cell Biol       Date:  1997-12-15       Impact factor: 10.539
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  18 in total

1.  Hepatic arginase deficiency fosters dysmyelination during postnatal CNS development.

Authors:  Xiao-Bo Liu; Jillian R Haney; Gloria Cantero; Jenna R Lambert; Marcos Otero-Garcia; Brian Truong; Andrea Gropman; Inma Cobos; Stephen D Cederbaum; Gerald S Lipshutz
Journal:  JCI Insight       Date:  2019-09-05

2.  Human hepatocyte transplantation corrects the inherited metabolic liver disorder arginase deficiency in mice.

Authors:  Stephanie A K Angarita; Brian Truong; Suhail Khoja; Matthew Nitzahn; Abha K Rajbhandari; Irina Zhuravka; Sergio Duarte; Michael G Lin; Alex K Lam; Stephen D Cederbaum; Gerald S Lipshutz
Journal:  Mol Genet Metab       Date:  2018-04-21       Impact factor: 4.797

3.  Rescue of the Functional Alterations of Motor Cortical Circuits in Arginase Deficiency by Neonatal Gene Therapy.

Authors:  Gloria Cantero; Xiao-Bo Liu; Ronald F Mervis; Maria T Lazaro; Stephen D Cederbaum; Peyman Golshani; Gerald S Lipshutz
Journal:  J Neurosci       Date:  2016-06-22       Impact factor: 6.167

Review 4.  Progress and prospects of gene therapy clinical trials for the muscular dystrophies.

Authors:  Niclas E Bengtsson; Jane T Seto; John K Hall; Jeffrey S Chamberlain; Guy L Odom
Journal:  Hum Mol Genet       Date:  2015-10-08       Impact factor: 6.150

5.  Lipid nanoparticle-targeted mRNA therapy as a treatment for the inherited metabolic liver disorder arginase deficiency.

Authors:  Brian Truong; Gabriella Allegri; Xiao-Bo Liu; Kristine E Burke; Xuling Zhu; Stephen D Cederbaum; Johannes Häberle; Paolo G V Martini; Gerald S Lipshutz
Journal:  Proc Natl Acad Sci U S A       Date:  2019-09-09       Impact factor: 11.205

6.  Human recombinant arginase enzyme reduces plasma arginine in mouse models of arginase deficiency.

Authors:  Lindsay C Burrage; Qin Sun; Sarah H Elsea; Ming-Ming Jiang; Sandesh C S Nagamani; Arthur E Frankel; Everett Stone; Susan E Alters; Dale E Johnson; Scott W Rowlinson; George Georgiou; Brendan H Lee
Journal:  Hum Mol Genet       Date:  2015-09-10       Impact factor: 6.150

7.  Augmentation of transgene-encoded protein after neonatal injection of adeno-associated virus improves hepatic copy number without immune responses.

Authors:  Denise S Tai; Chuhong Hu; Elizabeth H Kim; Gerald S Lipshutz
Journal:  Pediatr Res       Date:  2015-06-04       Impact factor: 3.756

8.  Strategies to rescue the consequences of inducible arginase-1 deficiency in mice.

Authors:  Laurel L Ballantyne; Yuan Yan Sin; Tim St Amand; Joshua Si; Steven Goossens; Lieven Haenebalcke; Jody J Haigh; Lianna Kyriakopoulou; Andreas Schulze; Colin D Funk
Journal:  PLoS One       Date:  2015-05-04       Impact factor: 3.240

9.  Minimal ureagenesis is necessary for survival in the murine model of hyperargininemia treated by AAV-based gene therapy.

Authors:  C Hu; D S Tai; H Park; G Cantero; G Cantero-Nieto; E Chan; M Yudkoff; S D Cederbaum; G S Lipshutz
Journal:  Gene Ther       Date:  2014-12-04       Impact factor: 5.250

10.  Liver-specific knockout of arginase-1 leads to a profound phenotype similar to inducible whole body arginase-1 deficiency.

Authors:  Laurel L Ballantyne; Yuan Yan Sin; Osama Y Al-Dirbashi; Xinzhi Li; David J Hurlbut; Colin D Funk
Journal:  Mol Genet Metab Rep       Date:  2016-10-12
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