Helen E. Collins Laboratory

Investigating Mechanisms Underlying Female Cardiovascular Resilience and Health

Cardiomyocyte-Specific BMAL1 Plays Critical Roles in Metabolism, Signaling, and Maintenance of Contractile Function of the Heart


Journal article


M. Young, Rachel A. Brewer, R. A. Peliciari-Garcia, Helen E Collins, Lan He, Tana L. Birky, Bradley W. Peden, E. Thompson, Billy Joe Ammons, M. Bray, J. Chatham, A. Wende, Qinglin Yang, C. Chow, T. Martino, K. Gamble
Journal of biological rhythms, 2014

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APA   Click to copy
Young, M., Brewer, R. A., Peliciari-Garcia, R. A., Collins, H. E., He, L., Birky, T. L., … Gamble, K. (2014). Cardiomyocyte-Specific BMAL1 Plays Critical Roles in Metabolism, Signaling, and Maintenance of Contractile Function of the Heart. Journal of Biological Rhythms.


Chicago/Turabian   Click to copy
Young, M., Rachel A. Brewer, R. A. Peliciari-Garcia, Helen E Collins, Lan He, Tana L. Birky, Bradley W. Peden, et al. “Cardiomyocyte-Specific BMAL1 Plays Critical Roles in Metabolism, Signaling, and Maintenance of Contractile Function of the Heart.” Journal of biological rhythms (2014).


MLA   Click to copy
Young, M., et al. “Cardiomyocyte-Specific BMAL1 Plays Critical Roles in Metabolism, Signaling, and Maintenance of Contractile Function of the Heart.” Journal of Biological Rhythms, 2014.


BibTeX   Click to copy

@article{m2014a,
  title = {Cardiomyocyte-Specific BMAL1 Plays Critical Roles in Metabolism, Signaling, and Maintenance of Contractile Function of the Heart},
  year = {2014},
  journal = {Journal of biological rhythms},
  author = {Young, M. and Brewer, Rachel A. and Peliciari-Garcia, R. A. and Collins, Helen E and He, Lan and Birky, Tana L. and Peden, Bradley W. and Thompson, E. and Ammons, Billy Joe and Bray, M. and Chatham, J. and Wende, A. and Yang, Qinglin and Chow, C. and Martino, T. and Gamble, K.}
}

Abstract

Circadian clocks are cell autonomous, transcriptionally based, molecular mechanisms that confer the selective advantage of anticipation, enabling cells/organs to respond to environmental factors in a temporally appropriate manner. Critical to circadian clock function are 2 transcription factors, CLOCK and BMAL1. The purpose of the present study was to reveal novel physiologic functions of BMAL1 in the heart, as well as to determine the pathologic consequences of chronic disruption of this circadian clock component. To address this goal, we generated cardiomyocyte-specific Bmal1 knockout (CBK) mice. Following validation of the CBK model, combined microarray and in silico analyses were performed, identifying 19 putative direct BMAL1 target genes, which included a number of metabolic (e.g., β-hydroxybutyrate dehydrogenase 1 [Bdh1]) and signaling (e.g., the p85α regulatory subunit of phosphatidylinositol 3-kinase [Pik3r1]) genes. Results from subsequent validation studies were consistent with regulation of Bdh1 and Pik3r1 by BMAL1, with predicted impairments in ketone body metabolism and signaling observed in CBK hearts. Furthermore, CBK hearts exhibited depressed glucose utilization, as well as a differential response to a physiologic metabolic stress (i.e., fasting). Consistent with BMAL1 influencing critical functions in the heart, echocardiographic, gravimetric, histologic, and molecular analyses revealed age-onset development of dilated cardiomyopathy in CBK mice, which was associated with a severe reduction in life span. Collectively, our studies reveal that BMAL1 influences metabolism, signaling, and contractile function of the heart.