Exercise for Cardiovascular Disease Prevention and Treatment From Molecular to Clinical, Part 1

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Exercise is a potent stimulator that activates numerous downstream cascades at

the molecular and cellular levels. When exercise is sufficiently intensive and sus-

tained, it results in cardiac remodeling. This remodeling increases cardiac func-

tional capacity in both healthy and diseased individuals.

Aerobic exercise capacity is a prognostic marker of heart disease. Clinicians

should promote the benefits of exercise for patients with all levels of cardiac fitness

including those who exercise casually, sedentary individuals and patients with

established cardiovascular disease.

Acknowledgment We would like to thank Dr. Anne Gravelle (University of Ottawa) for the care-
ful review and thoughtful editing of this manuscript.

References

1. Pate RR, Pratt MP, Blair SN et al (1995) Physical activity and public health: a recommenda-
   tion from the Centers for Disease Control and Prevention and the American College of Sports
   Medicine. JAMA 273:402–407


2. Ellison GM, Waring CD, Vicinanza C et  al (2012) Physiological cardiac remodelling in
   response to endurance exercise training: cellular and molecular mechanisms. Heart 98:5–10


3. Gielen S, Schuler G, Adams V (2010) Cardiovascular effects of exercise training molecular
   mechanisms. Circulation 122:1221–1238


4. Gyöngyösi M, Winkler J, Ramos I (2017) Myocardial fibrosis. Biomedical research from
   bench to bedside. Eur J Heart Fail 19:177–191


5. Rai V, Sharma P, Agrawal S et al (2017) Relevance of mouse models of cardiac fibrosis and
   hypertrophy in cardiac research. Mol Cell Biochem 424(1-2):123–145


6. Weber KT, Sun Y, Bhattacharya SK et al (2013) Myofibroblast mediated mechanisms of patho-
   logical remodelling of the heart. Nat Rev Cardiol 10:15–26


7. Wynn TA, Ramalingam TR (2012) Mechanisms of fibrosis: therapeutic translation for fibrotic
   disease. Nat Med 18:1028–1040


8. Lajiness JD, Conway SJ (2014) Origin, development, and differentiation of cardiac fibroblasts.
   J Mol Cell Cardiol 70:2–8


9. Krenning G, Zeisberg EM, Kalluri R (2010) The origin of fibroblasts and mechanism of car-
   diac fibrosis. J Cell Physiol 225(3):631–637


10. Zeisberg EM, Kalluri R (2010) Origins of cardiac fibroblasts. Circ Res 107(11):1304–1312


11. Kong P, Christia P, Frangogiannis N (2014) The pathogenesis of cardiac fibrosis. Cell Mol Life
    Sci 71:549–574


12. Li AH, Liu PP, Villarreal FJ et al (2014) Dynamic changes in myocardial matrix and relevance
    to disease: translational perspectives. Circ Res 114:916–927


13. Heymans S, González A, Pizard A et al (2015) Searching for new mechanisms of myocardial
    fibrosis with diagnostic and/or therapeutic potential. Eur J Heart Fail 17:764–771


14. Watson CJ, Phelan D, Collier P et al (2014) Extracellular matrix sub-types and mechanical
    stretch impact human cardiac fibroblast responses to transforming growth factor beta. Connect
    Tissue Res 55:248–256


15. Segura A, Frazier OH, Buja LM (2014) Fibrosis and heart failure. Heart Fail Rev 19:173–185


16. Olivey H, Mundell N, Austin A et  al (2006) Transforming growth factor-beta stimulates
    epithelial- mesenchymal transformation in the proepicardium. Dev Dyn 235(1):50–59


17. Kakkar R (2010) Lee RT (2010) Intramyocardial fibroblast myocyte communication. Circ Res
    106(1):47–57

J. Kyselovič and J.J. Leddy