Suya Wang1, Yifei Li1,2, Yang Xu2, Qing Ma1, Zhiqiang Lin1, Michael Schlame3,4, Vassilios J Bezzerides1, Douglas Strathdee5, William T Pu1,6. 1. From the Department of Cardiology, Boston Children's Hospital, MA (S.W., Y.L., Q.M., Z.L., V.J.B., W.T.P.). 2. Department of Pediatrics, West China Second University Hospital, Sichuan University, Chengdu, China (Y.L.). 3. Department of Anesthesiology (Y.X., M.S.). 4. Department of Cell Biology (M.S.), New York University School of Medicine. 5. Transgenic Technology Laboratory, Cancer Research UK Beatson Institute, Glasgow, United Kingdom (D.S.). 6. Harvard Stem Cell Institute, Harvard University, Cambridge, MA (W.T.P.).
Abstract
RATIONALE: Barth syndrome is an X-linked cardiac and skeletal myopathy caused by mutation of the gene Tafazzin (TAZ). Currently, there is no targeted treatment for Barth syndrome. Lack of a proper genetic animal model that recapitulates the features of Barth syndrome has hindered understanding of disease pathogenesis and therapeutic development. OBJECTIVE: We characterized murine germline TAZ knockout mice (TAZ-KO) and cardiomyocyte-specific TAZ knockout mice models and tested the efficacy of adeno-associated virus (AAV)-mediated gene replacement therapy with human TAZ (hTAZ). METHODS AND RESULTS: TAZ-KO caused embryonic and neonatal lethality, impaired growth, dilated cardiomyopathy, and skeletal myopathy. TAZ-KO mice that survived the neonatal period developed progressive, severe cardiac dysfunction, and fibrosis. Cardiomyocyte-specific inactivation of floxed Taz in cardiomyocytes using Myh6-Cre caused progressive dilated cardiomyopathy without fetal or perinatal loss. Using both constitutive and conditional knockout models, we tested the efficacy and durability of Taz replacement by AAV gene therapy. Neonatal AAV-hTAZ rescued neonatal death, cardiac dysfunction, and fibrosis in TAZ-KO mice, and both prevented and reversed established cardiac dysfunction in TAZ-KO and cardiomyocyte-specific TAZ knockout mice models. However, both neonatal and adult therapies required high cardiomyocyte transduction (≈70%) for durable efficacy. CONCLUSIONS: TAZ-KO and cardiomyocyte-specific TAZ knockout mice recapitulate many of the key clinical features of Barth syndrome. AAV-mediated gene replacement is efficacious when a sufficient fraction of cardiomyocytes are transduced.
RATIONALE: Barth syndrome is an X-linked cardiac and skeletal myopathy caused by mutation of the gene Tafazzin (TAZ). Currently, there is no targeted treatment for Barth syndrome. Lack of a proper genetic animal model that recapitulates the features of Barth syndrome has hindered understanding of disease pathogenesis and therapeutic development. OBJECTIVE: We characterized murine germline TAZ knockout mice (TAZ-KO) and cardiomyocyte-specific TAZ knockout mice models and tested the efficacy of adeno-associated virus (AAV)-mediated gene replacement therapy with humanTAZ (hTAZ). METHODS AND RESULTS:TAZ-KO caused embryonic and neonatal lethality, impaired growth, dilated cardiomyopathy, and skeletal myopathy. TAZ-KO mice that survived the neonatal period developed progressive, severe cardiac dysfunction, and fibrosis. Cardiomyocyte-specific inactivation of floxed Taz in cardiomyocytes using Myh6-Cre caused progressive dilated cardiomyopathy without fetal or perinatal loss. Using both constitutive and conditional knockout models, we tested the efficacy and durability of Taz replacement by AAV gene therapy. Neonatal AAV-hTAZ rescued neonatal death, cardiac dysfunction, and fibrosis in TAZ-KO mice, and both prevented and reversed established cardiac dysfunction in TAZ-KO and cardiomyocyte-specific TAZ knockout mice models. However, both neonatal and adult therapies required high cardiomyocyte transduction (≈70%) for durable efficacy. CONCLUSIONS:TAZ-KO and cardiomyocyte-specific TAZ knockout mice recapitulate many of the key clinical features of Barth syndrome. AAV-mediated gene replacement is efficacious when a sufficient fraction of cardiomyocytes are transduced.
Authors: Meghan S Soustek; Darin J Falk; Cathryn S Mah; Matthew J Toth; Michael Schlame; Alfred S Lewin; Barry J Byrne Journal: Hum Gene Ther Date: 2011-05-19 Impact factor: 5.695
Authors: Yang Xu; Morgan Condell; Heide Plesken; Irit Edelman-Novemsky; Jinping Ma; Mindong Ren; Michael Schlame Journal: Proc Natl Acad Sci U S A Date: 2006-07-19 Impact factor: 11.205
Authors: Silveli Suzuki-Hatano; Madhurima Saha; Skylar A Rizzo; Rachael L Witko; Bennett J Gosiker; Manashwi Ramanathan; Meghan S Soustek; Michael D Jones; Peter B Kang; Barry J Byrne; W Todd Cade; Christina A Pacak Journal: Hum Gene Ther Date: 2018-10-03 Impact factor: 5.695
Authors: Aravind Asokan; Julia C Conway; Jana L Phillips; Chengwen Li; Julia Hegge; Rebecca Sinnott; Swati Yadav; Nina DiPrimio; Hyun-Joo Nam; Mavis Agbandje-McKenna; Scott McPhee; Jon Wolff; R Jude Samulski Journal: Nat Biotechnol Date: 2009-12-27 Impact factor: 54.908
Authors: Yang Xu; Hediye Erdjument-Bromage; Colin K L Phoon; Thomas A Neubert; Mindong Ren; Michael Schlame Journal: EMBO J Date: 2021-10-18 Impact factor: 11.598
Authors: Jinxi Wang; Qian Shi; Yihui Wang; Logan W Dawson; Grace Ciampa; Weiyang Zhao; Guangqin Zhang; Biyi Chen; Robert M Weiss; Chad E Grueter; Duane D Hall; Long-Sheng Song Journal: Circ Res Date: 2022-03-23 Impact factor: 23.213
Authors: Micol Falabella; Hilary J Vernon; Michael G Hanna; Steven M Claypool; Robert D S Pitceathly Journal: Trends Endocrinol Metab Date: 2021-02-24 Impact factor: 12.015
Authors: Xujie Liu; Suya Wang; Xiaoling Guo; Yifei Li; Roza Ogurlu; Fujian Lu; Maksymilian Prondzynski; Sofia de la Serna Buzon; Qing Ma; Donghui Zhang; Gang Wang; Justin Cotton; Yuxuan Guo; Ling Xiao; David J Milan; Yang Xu; Michael Schlame; Vassilios J Bezzerides; William T Pu Journal: Circulation Date: 2021-04-01 Impact factor: 29.690