Myosin in autoinhibited off state(s), stabilized by mavacamten, can be recruited via inotropic effectors

Mavacamten is a novel, FDA-approved, small molecule therapeutic designed to regulate cardiac function by selectively but reversibly inhibiting the enzymatic activity of myosin. It shifts myosin towards ordered off states close to the thick filament backbone. It remains unresolved whether mavacamten permanently sequesters these myosin heads in the off state(s) or whether these heads can be recruited in response to physiological stimuli when required to boost cardiac output. We show that cardiac myosins stabilized in these off state(s) by mavacamten are recruitable by Ca2+, increased heart rate, stretch, and β-adrenergic (β-AR) stimulation, all known physiological inotropic effectors. At the molecular level, we show that, in presence of mavacamten, Ca2+ increases myosin ATPase activity by shifting myosin heads from the reserve super-relaxed (SRX) state to the active disordered relaxed (DRX) state. At the myofilament level, both Ca2+ and passive lengthening can shift ordered off myosin heads from positions close to the thick filament backbone to disordered on states closer to the thin filaments in the presence of mavacamten. In isolated rat cardiomyocytes, increased stimulation rates enhanced shortening fraction in mavacamten-treated cells. This observation was confirmed in vivo in telemetered rats, where left-ventricular dP/dtmax, an index of inotropy, increased with heart rate in mavacamten treated animals. Finally, we show that β-AR stimulation in vivo increases left-ventricular function and stroke volume in the setting of mavacamten. Our data demonstrate that the mavacamten-promoted off states of myosin in the thick filament are activable, at least partially, thus leading to preservation of cardiac reserve mechanisms. Significance statement Mavacamten is the first myosin-targeted small molecule inhibitor approved by the FDA to treat obstructive hypertrophic cardiomyopathy by attenuating myocardial hyperdynamic contraction. The recruitment of cardiac contractility is, however, vital to ensure sufficient cardiac output during increased physiological demand. Here we show that major inotropic effectors are at least partially preserved in the setting of mavacamten, resulting in maintenance of cardiac reserve mechanisms. These results not only suggest an alternative mechanistic explanation, beyond mere LV outflow tract obstruction removal, for the clinically observed increase in peak oxygen uptake with exercise in HCM patients receiving mavacamten, but also lay the groundwork for a potential methodology to investigate the sarcomeric basis of chronotropic incompetence in disease states to motivate new therapeutic interventions.

[1]  J. Spudich,et al.  Mavacamten, a precision medicine for hypertrophic cardiomyopathy: From a motor protein to patients. , 2023, Science advances.

[2]  M. Regnier,et al.  Structural OFF/ON transitions of myosin in relaxed porcine myocardium predict calcium-activated force , 2023, Proceedings of the National Academy of Sciences of the United States of America.

[3]  V. Jani,et al.  EMD-57033 Augments the Contractility in Porcine Myocardium by Promoting the Activation of Myosin in Thick Filaments , 2022, International journal of molecular sciences.

[4]  T. Irving,et al.  Cardiac myosin filaments are directly regulated by calcium , 2022, bioRxiv.

[5]  S. Mijailovich,et al.  Effect of Myosin Isoforms on Cardiac Muscle Twitch of Mice, Rats and Humans , 2022, International journal of molecular sciences.

[6]  R. Craig,et al.  Structural basis of the super- and hyper-relaxed states of myosin II , 2021, The Journal of general physiology.

[7]  M. Wheeler,et al.  Abstract 10201: Efficacy of Mavacamten in Patients with Symptomatic Hypertrophic Cardiomyopathy: Sub-Group Analyses by Background Beta-Blocker Use from the EXPLORER-HCM and MAVA-LTE Studies , 2021, Circulation.

[8]  T. Irving,et al.  Myofibril orientation as a metric for characterizing heart disease , 2021, bioRxiv.

[9]  T. Irving,et al.  The Super-Relaxed State and Length Dependent Activation in Porcine Myocardium , 2021, Circulation research.

[10]  Joseph M. Muretta,et al.  Direct detection of the myosin super-relaxed state and interacting-heads motif in solution , 2021, bioRxiv.

[11]  J. Spertus,et al.  Mavacamten for treatment of symptomatic obstructive hypertrophic cardiomyopathy (EXPLORER-HCM): health status analysis of a randomised, double-blind, placebo-controlled, phase 3 trial , 2021, The Lancet.

[12]  S. Mijailovich,et al.  The effect of variable troponin C mutation thin filament incorporation on cardiac muscle twitch contractions. , 2021, Journal of molecular and cellular cardiology.

[13]  Suman Nag,et al.  To lie or not to lie: Super-relaxing with myosins , 2021, eLife.

[14]  S. Mijailovich,et al.  Multiscale modeling of twitch contractions in cardiac trabeculae , 2021, The Journal of general physiology.

[15]  S. Campbell,et al.  Mavacamten preserved length-dependent contractility and improved diastolic function in human engineered heart tissue. , 2021, American journal of physiology. Heart and circulatory physiology.

[16]  T. Irving,et al.  TWO CLASSES OF MYOSIN INHIBITORS, BLEBBISTATIN AND MAVACAMTEN, STABILIZE β-CARDIAC MYOSIN IN DIFFERENT STRUCTURAL AND FUNCTIONAL STATES , 2020, bioRxiv.

[17]  D - F , 2020, 2020.

[18]  Sampath K Gollapudi,et al.  Synthetic thick filaments: A new avenue for better understanding the myosin super-relaxed state in healthy, diseased, and mavacamten-treated cardiac systems , 2020, The Journal of biological chemistry.

[19]  V. Daggett,et al.  Myosin dynamics during relaxation in mouse soleus muscle and modulation by 2′‐deoxy‐ATP , 2020, The Journal of physiology.

[20]  S. Solomon,et al.  Evaluation of Mavacamten in Symptomatic Patients With Nonobstructive Hypertrophic Cardiomyopathy. , 2020, Journal of the American College of Cardiology.

[21]  K. Campbell,et al.  Effects of mavacamten on Ca2+-sensitivity of contraction as sarcomere length varied in human myocardium , 2020 .

[22]  F. Girolami,et al.  Contemporary Insights Into the Genetics of Hypertrophic Cardiomyopathy: Toward a New Era in Clinical Testing? , 2020, Journal of the American Heart Association.

[23]  B. Levine,et al.  Mechanisms of Chronotropic Incompetence in Heart Failure With Preserved Ejection Fraction , 2020, Circulation. Heart failure.

[24]  J. F. Staples,et al.  Myosin Sequestration Regulates Sarcomere Function, Cardiomyocyte Energetics, and Metabolism, Informing the Pathogenesis of Hypertrophic Cardiomyopathy , 2020, Circulation.

[25]  L. Allen,et al.  Why has positive inotropy failed in chronic heart failure? Lessons from prior inotrope trials , 2019, European journal of heart failure.

[26]  A. Owens,et al.  Mavacamten Treatment for Obstructive Hypertrophic Cardiomyopathy , 2019, Annals of Internal Medicine.

[27]  J. Spudich Three perspectives on the molecular basis of hypercontractility caused by hypertrophic cardiomyopathy mutations , 2019, Pflügers Archiv - European Journal of Physiology.

[28]  T. Irving,et al.  Thick-Filament Extensibility in Intact Skeletal Muscle. , 2018, Biophysical journal.

[29]  T. Irving,et al.  Myosin Head Configurations in Resting and Contracting Murine Skeletal Muscle , 2018, International journal of molecular sciences.

[30]  J. Seidman,et al.  Deciphering the super relaxed state of human β-cardiac myosin and the mode of action of mavacamten from myosin molecules to muscle fibers , 2018, Proceedings of the National Academy of Sciences.

[31]  Joseph M. Muretta,et al.  Mavacamten stabilizes an autoinhibited state of two-headed cardiac myosin , 2018, Proceedings of the National Academy of Sciences.

[32]  E. Braunwald,et al.  Hypertrophic Cardiomyopathy: Genetics, Pathogenesis, Clinical Manifestations, Diagnosis, and Therapy. , 2017, Circulation research.

[33]  Yonghong Song,et al.  A small-molecule modulator of cardiac myosin acts on multiple stages of the myosin chemomechanical cycle , 2017, The Journal of Biological Chemistry.

[34]  J. Stelzer,et al.  The contributions of cardiac myosin binding protein C and troponin I phosphorylation to β‐adrenergic enhancement of in vivo cardiac function , 2015, The Journal of physiology.

[35]  G. Piazzesi,et al.  Force generation by skeletal muscle is controlled by mechanosensing in myosin filaments , 2015, Nature.

[36]  J. Kirkwood AVMA Guidelines for the euthanasia of animals , 2013, Animal Welfare.

[37]  W. Catterall Voltage-gated calcium channels. , 2011, Cold Spring Harbor perspectives in biology.

[38]  P. Buttrick,et al.  Analysing force–pCa curves , 2010, Journal of Muscle Research and Cell Motility.

[39]  Kittipong Tachampa,et al.  Myofilament length dependent activation. , 2010, Journal of molecular and cellular cardiology.

[40]  M. Hanna,et al.  Muscle disease , 2009, Practical Neurology.

[41]  A. Mattiazzi,et al.  Pacing staircase phenomenon in the heart: from Bodwitch to the XXI century. , 2004, Heart, lung & circulation.

[42]  T. Irving,et al.  The BioCAT undulator beamline 18ID: a facility for biological non-crystalline diffraction and X-ray absorption spectroscopy at the Advanced Photon Source. , 2004, Journal of synchrotron radiation.

[43]  J. Aronson,et al.  What is a clinical trial? , 2004, British journal of clinical pharmacology.

[44]  B. Kobilka,et al.  Myocyte Adrenoceptor Signaling Pathways , 2003, Science.

[45]  H. Granzier,et al.  Protein Kinase A Phosphorylates Titin’s Cardiac-Specific N2B Domain and Reduces Passive Tension in Rat Cardiac Myocytes , 2002, Circulation research.

[46]  E. Lakatta,et al.  beta2-adrenergic cAMP signaling is uncoupled from phosphorylation of cytoplasmic proteins in canine heart. , 1999, Circulation.

[47]  D. Bushinsky,et al.  Calcium , 1998, The Lancet.

[48]  H E Huxley,et al.  X-ray diffraction measurements of the extensibility of actin and myosin filaments in contracting muscle. , 1994, Biophysical journal.

[49]  M. Burch,et al.  Hypertrophic cardiomyopathy. , 1994, Archives of disease in childhood.

[50]  M. Geeves,et al.  Regulation of the interaction between actin and myosin subfragment 1: evidence for three states of the thin filament. , 1993, Biophysical journal.

[51]  N. Yagi,et al.  Behaviour of myosin projections during the staircase phenomenon of heart muscle , 1978, Nature.

[52]  N. Yagi,et al.  An X‐ray diffraction study of the cross‐circulated canine heart. , 1977, The Journal of physiology.

[53]  R. Solaro,et al.  The purification of cardiac myofibrils with Triton X-100. , 1971, Biochimica et biophysica acta.

[54]  H. Huxley,et al.  ELECTRON MICROSCOPE STUDIES ON THE STRUCTURE OF NATURAL AND SYNTHETIC PROTEIN FILAMENTS FROM STRIATED MUSCLE. , 1963, Journal of molecular biology.

[55]  H. Boom,et al.  Muscle , 2021, Encyclopedia of Evolutionary Psychological Science.

[56]  E. Jones Disease , 2020, Palgrave Studies in Economic History.

[57]  T. Grandin,et al.  AVMA Guidelines for the Euthanasia of Animals: 2013 Edition , 2013 .

[58]  D. Leroith,et al.  Skeletal muscle. , 2005, Advances in experimental medicine and biology.

[59]  J. S. Davis,et al.  Assembly processes in vertebrate skeletal thick filament formation. , 1988, Annual review of biophysics and biophysical chemistry.

[60]  S. Lowey,et al.  Preparation of myosin and its subfragments from rabbit skeletal muscle. , 1982, Methods in enzymology.