RATIONALE: Cardiomyocytes cultured in a mechanically active 3-dimensional configuration can be used for studies that correlate contractile performance to cellular physiology. Current engineered cardiac tissue (ECT) models use cells derived from either rat or chick hearts. Development of a murine ECT would provide access to many existing models of cardiac disease and open the possibility of performing targeted genetic manipulation with the ability to directly assess contractile and molecular variables. OBJECTIVE: To generate, characterize, and validate mouse ECT with a physiologically relevant model of hypertrophic cardiomyopathy. METHODS AND RESULTS: We generated mechanically integrated ECT using isolated neonatal mouse cardiac cells derived from both wild-type and myosin-binding protein C (cMyBP-C)-null mouse hearts. The murine ECTs produced consistent contractile forces that followed the Frank-Starling law and accepted physiological pacing. cMyBP-C-null ECTs showed characteristic acceleration of contraction kinetics. Adenovirus-mediated expression of human cMyBP-C in murine cMyBP-C-null ECT restored contractile properties to levels indistinguishable from those of wild-type ECT. Importantly, the cardiomyocytes used to construct the cMyBP-C(-/-) ECT had yet to undergo the significant hypertrophic remodeling that occurs in vivo. Thus, this murine ECT model reveals a contractile phenotype that is specific to the genetic mutation rather than to secondary remodeling events. CONCLUSIONS: Data presented here show mouse ECT to be an efficient and cost-effective platform to study the primary effects of genetic manipulation on cardiac contractile function. This model provides a previously unavailable tool to study specific sarcomeric protein mutations in an intact mammalian muscle system.
RATIONALE: Cardiomyocytes cultured in a mechanically active 3-dimensional configuration can be used for studies that correlate contractile performance to cellular physiology. Current engineered cardiac tissue (ECT) models use cells derived from either rat or chick hearts. Development of a murine ECT would provide access to many existing models of cardiac disease and open the possibility of performing targeted genetic manipulation with the ability to directly assess contractile and molecular variables. OBJECTIVE: To generate, characterize, and validate mouse ECT with a physiologically relevant model of hypertrophic cardiomyopathy. METHODS AND RESULTS: We generated mechanically integrated ECT using isolated neonatal mouse cardiac cells derived from both wild-type and myosin-binding protein C (cMyBP-C)-null mouse hearts. The murine ECTs produced consistent contractile forces that followed the Frank-Starling law and accepted physiological pacing. cMyBP-C-null ECTs showed characteristic acceleration of contraction kinetics. Adenovirus-mediated expression of human cMyBP-C in murine cMyBP-C-null ECT restored contractile properties to levels indistinguishable from those of wild-type ECT. Importantly, the cardiomyocytes used to construct the cMyBP-C(-/-) ECT had yet to undergo the significant hypertrophic remodeling that occurs in vivo. Thus, this murine ECT model reveals a contractile phenotype that is specific to the genetic mutation rather than to secondary remodeling events. CONCLUSIONS: Data presented here show mouse ECT to be an efficient and cost-effective platform to study the primary effects of genetic manipulation on cardiac contractile function. This model provides a previously unavailable tool to study specific sarcomeric protein mutations in an intact mammalian muscle system.
Authors: R L Carrier; M Papadaki; M Rupnick; F J Schoen; N Bursac; R Langer; L E Freed; G Vunjak-Novakovic Journal: Biotechnol Bioeng Date: 1999-09-05 Impact factor: 4.530
Authors: Milica Radisic; Hyoungshin Park; Helen Shing; Thomas Consi; Frederick J Schoen; Robert Langer; Lisa E Freed; Gordana Vunjak-Novakovic Journal: Proc Natl Acad Sci U S A Date: 2004-12-16 Impact factor: 11.205
Authors: Hiroshi Naito; Ivan Melnychenko; Michael Didié; Karin Schneiderbanger; Pia Schubert; Stephan Rosenkranz; Thomas Eschenhagen; Wolfram-Hubertus Zimmermann Journal: Circulation Date: 2006-07-04 Impact factor: 29.690
Authors: T Eschenhagen; C Fink; U Remmers; H Scholz; J Wattchow; J Weil; W Zimmermann; H H Dohmen; H Schäfer; N Bishopric; T Wakatsuki; E L Elson Journal: FASEB J Date: 1997-07 Impact factor: 5.191
Authors: Veniamin Y Sidorov; Philip C Samson; Tatiana N Sidorova; Jeffrey M Davidson; Chee C Lim; John P Wikswo Journal: Acta Biomater Date: 2016-11-04 Impact factor: 8.947
Authors: Dan F Smelter; Willem J de Lange; Wenxuan Cai; Ying Ge; J Carter Ralphe Journal: Am J Physiol Heart Circ Physiol Date: 2018-02-16 Impact factor: 4.733
Authors: Wenxuan Cai; Jianhua Zhang; Willem J de Lange; Zachery R Gregorich; Hannah Karp; Emily T Farrell; Stanford D Mitchell; Trisha Tucholski; Ziqing Lin; Mitch Biermann; Sean J McIlwain; J Carter Ralphe; Timothy J Kamp; Ying Ge Journal: Circ Res Date: 2019-10-01 Impact factor: 17.367
Authors: J Notbohm; B N Napiwocki; W J deLange; A Stempien; A Saraswathibhatla; R J Craven; M R Salick; J C Ralphe; W C Crone Journal: Exp Mech Date: 2019-01-29 Impact factor: 2.808
Authors: Kunil K Raval; Ran Tao; Brent E White; Willem J De Lange; Chad H Koonce; Junying Yu; Priya S Kishnani; James A Thomson; Deane F Mosher; John C Ralphe; Timothy J Kamp Journal: J Biol Chem Date: 2014-12-08 Impact factor: 5.157