Mitochondrial Reversible Changes Determine Diastolic Function Adaptations During Myocardial (Reverse) Remodeling

Supplemental Digital Content is available in the text. Background: Often, pressure overload–induced myocardial remodeling does not undergo complete reverse remodeling after decreasing afterload. Recently, mitochondrial abnormalities and oxidative stress have been successively implicated in the pathogenesis of several chronic pressure overload cardiac diseases. Therefore, we aim to clarify the myocardial energetic dysregulation in (reverse) remodeling, mainly focusing on the mitochondria. Methods: Thirty-five Wistar Han male rats randomly underwent sham or ascending (supravalvular) aortic banding procedure. Echocardiography revealed that banding induced concentric hypertrophy and diastolic dysfunction (early diastolic transmitral flow velocity to peak early-diastolic annular velocity ratio, E/E′: sham, 13.6±2.1, banding, 18.5±4.1, P=0.014) accompanied by increased oxidative stress (dihydroethidium fluorescence: sham, 1.6×108±6.1×107, banding, 2.6×108±4.5×107, P<0.001) and augmented mitochondrial function. After 8 to 9 weeks, half of the banding animals underwent overload relief by an aortic debanding surgery (n=10). Results: Two weeks later, hypertrophy decreased with the decline of oxidative stress (dihydroethidium fluorescence: banding, 2.6×108±4.5×107, debanding, 1.96×108±6.8×107, P<0.001) and diastolic dysfunction improved simultaneously (E/E′: banding, 18.5±4.1, debanding, 15.1±1.8, P=0.029). The reduction of energetic demands imposed by overload relief allowed the mitochondria to reduce its activity and myocardial levels of phosphocreatine, phosphocreatine/ATP, and ATP/ADP to normalize in debanding towards sham values (phosphocreatine: sham, 38.4±7.4, debanding, 35.6±8.7, P=0.71; phosphocreatine/ATP: sham, 1.22±0.23 debanding, 1.11±0.24, P=0.59; ATP/ADP: sham, 6.2±0.9, debanding, 5.6±1.6, P=0.66). Despite the decreased mitochondrial area, complex III and V expression increased in debanding compared with sham or banding. Autophagy and mitophagy-related markers increased in banding and remained higher in debanding rats. Conclusions: During compensatory and maladaptive hypertrophy, mitochondria become more active. However, as the disease progresses, the myocardial energetic demands increase and the myocardium becomes energy deficient. During reverse remodeling, the concomitant attenuation of cardiac hypertrophy and oxidative stress allowed myocardial energetics, left ventricle hypertrophy, and diastolic dysfunction to recover. Autophagy and mitophagy are probably involved in the myocardial adaptation to overload and to unload. We conclude that these mitochondrial reversible changes underlie diastolic function adaptations during myocardial (reverse) remodeling.

[1]  James D. Thomas,et al.  Diastolic Function and Transcatheter Aortic Valve Replacement , 2017, Journal of the American Society of Echocardiography : official publication of the American Society of Echocardiography.

[2]  L. Bellumkonda,et al.  Pathophysiology of heart failure and frailty: a common inflammatory origin? , 2017, Aging cell.

[3]  B. Merkely,et al.  Reverse electrical remodeling following pressure unloading in a rat model of hypertension-induced left ventricular myocardial hypertrophy , 2017, Hypertension Research.

[4]  F. Fernández‐Avilés,et al.  Patients with calcific aortic stenosis exhibit systemic molecular evidence of ischemia, enhanced coagulation, oxidative stress and impaired cholesterol transport. , 2016, International journal of cardiology.

[5]  B. Merkely,et al.  Myocardial reverse remodeling after pressure unloading is associated with maintained cardiac mechanoenergetics in a rat model of left ventricular hypertrophy. , 2016, American journal of physiology. Heart and circulatory physiology.

[6]  J. Pierce,et al.  Impaired Myocardial Bioenergetics in HFpEF and the Role of Antioxidants , 2016, The open cardiovascular medicine journal.

[7]  R. Curi,et al.  Housekeeping proteins: How useful are they in skeletal muscle diabetes studies and muscle hypertrophy models? , 2016, Analytical biochemistry.

[8]  W. Staines,et al.  Total protein or high-abundance protein: Which offers the best loading control for Western blotting? , 2016, Analytical biochemistry.

[9]  C. D. dos Remedios,et al.  ADP-stimulated contraction: A predictor of thin-filament activation in cardiac disease , 2015, Proceedings of the National Academy of Sciences.

[10]  J. Keaney,et al.  Pathophysiological role of oxidative stress in systolic and diastolic heart failure and its therapeutic implications. , 2015, European heart journal.

[11]  D. Hausenloy,et al.  Mitochondrial fusion and fission proteins as novel therapeutic targets for treating cardiovascular disease , 2015, European journal of pharmacology.

[12]  C. D. dos Remedios,et al.  Synergistic role of ADP and Ca2+ in diastolic myocardial stiffness , 2015, The Journal of physiology.

[13]  Ç. Erol,et al.  Evaluation of the Role of Oxidative Stress in Degenerative Aortic Stenosis. , 2015, Journal of Heart Valve Disease.

[14]  Jian Wang,et al.  Functions of Autophagy in Pathological Cardiac Hypertrophy , 2015, International journal of biological sciences.

[15]  Joseph A. Hill,et al.  Inhibition of hypertrophy is a good therapeutic strategy in ventricular pressure overload. , 2015, Circulation.

[16]  J. Sadoshima,et al.  Molecular mechanisms of mitochondrial autophagy/mitophagy in the heart. , 2015, Circulation research.

[17]  R. Siegel,et al.  Left ventricular hypertrophy in valvular aortic stenosis: mechanisms and clinical implications. , 2015, The American journal of medicine.

[18]  J. Marín-García,et al.  Mitochondrial oxidative metabolism and uncoupling proteins in the failing heart , 2015, Heart Failure Reviews.

[19]  Takeshi Kimura,et al.  Measurement of Technetium-99m Sestamibi Signals in Rats Administered a Mitochondrial Uncoupler and in a Rat Model of Heart Failure , 2015, PloS one.

[20]  Jianhua Zhang Teaching the basics of autophagy and mitophagy to redox biologists—Mechanisms and experimental approaches , 2015, Redox biology.

[21]  K. Park,et al.  Myocardial Mechanics in a Rat Model with Banding and Debanding of the Ascending Aorta , 2014, Journal of cardiovascular ultrasound.

[22]  P. Pibarot,et al.  Left Ventricular Remodeling in Aortic Stenosis , 2014 .

[23]  T. Doenst,et al.  Mitochondrial reactive oxygen species production and respiratory complex activity in rats with pressure overload‐induced heart failure , 2014, The Journal of physiology.

[24]  A. Zorzano,et al.  Mitochondrial fission is required for cardiomyocyte hypertrophy mediated by a Ca2+-calcineurin signaling pathway , 2014, Journal of Cell Science.

[25]  Ioanna Kougioumtzi,et al.  Right heart failure post left ventricular assist device implantation. , 2014, Journal of thoracic disease.

[26]  W. Paulus,et al.  Myocardial Titin Hypophosphorylation Importantly Contributes to Heart Failure With Preserved Ejection Fraction in a Rat Metabolic Risk Model , 2013, Circulation. Heart failure.

[27]  Torsten Doenst,et al.  Cardiac Metabolism in Heart Failure: Implications Beyond ATP Production , 2013, Circulation research.

[28]  I. Sjaastad,et al.  A mouse model of reverse cardiac remodelling following banding‐debanding of the ascending aorta , 2012, Acta physiologica.

[29]  H. Tsutsui,et al.  Oxidative stress and heart failure. , 2011, American journal of physiology. Heart and circulatory physiology.

[30]  G. Tomaselli,et al.  Reciprocal Transcriptional Regulation of Metabolic and Signaling Pathways Correlates With Disease Severity in Heart Failure , 2011, Circulation. Cardiovascular genetics.

[31]  D. Mancini,et al.  Effects of Continuous-Flow Versus Pulsatile-Flow Left Ventricular Assist Devices on Myocardial Unloading and Remodeling , 2011, Circulation. Heart failure.

[32]  J. Pepper,et al.  Enhanced left ventricular mass regression after aortic valve replacement in patients with aortic stenosis is associated with improved long-term survival. , 2011, The Journal of thoracic and cardiovascular surgery.

[33]  T. Prolla,et al.  Mitochondrial Oxidative Stress Mediates Angiotensin II–Induced Cardiac Hypertrophy and G&agr;q Overexpression–Induced Heart Failure , 2011, Circulation research.

[34]  M. Slaughter,et al.  Clinical, molecular, and genomic changes in response to a left ventricular assist device. , 2011, Journal of the American College of Cardiology.

[35]  Fermín Sánchez de Medina,et al.  Reversible Ponceau staining as a loading control alternative to actin in Western blots. , 2010, Analytical biochemistry.

[36]  T. Soga,et al.  Analysis of Metabolic Remodeling in Compensated Left Ventricular Hypertrophy and Heart Failure , 2010, Circulation. Heart failure.

[37]  F. Crea,et al.  Sex-related differences in myocardial remodeling. , 2010, Journal of the American College of Cardiology.

[38]  H. Poyrazoğlu,et al.  Diastolic Function Predicts Outcome After Aortic Valve Replacement in Patients with Chronic Severe Aortic Regurgitation , 2009, Clinical Cardiology.

[39]  D. Burkhoff,et al.  The impact of left ventricular assist device-induced left ventricular unloading on the myocardial renin-angiotensin-aldosterone system: therapeutic consequences? , 2008, European heart journal.

[40]  D. Burkhoff,et al.  Impact of left ventricular assist device (LVAD) support on the cardiac reverse remodeling process. , 2008, Progress in biophysics and molecular biology.

[41]  B. Pamukcu,et al.  Diastolic Dysfunction , 2008 .

[42]  S. Neubauer,et al.  Increased mitochondrial uncoupling proteins, respiratory uncoupling and decreased efficiency in the chronically infarcted rat heart. , 2008, Journal of molecular and cellular cardiology.

[43]  A. Akki,et al.  Compensated cardiac hypertrophy is characterised by a decline in palmitate oxidation , 2008, Molecular and Cellular Biochemistry.

[44]  Min Wu,et al.  Fission and selective fusion govern mitochondrial segregation and elimination by autophagy , 2008, The EMBO journal.

[45]  B. Llamas,et al.  Hypertensive cardiac remodeling in males and females: from the bench to the bedside. , 2007, Hypertension.

[46]  Magdi H Yacoub,et al.  Left ventricular assist device and drug therapy for the reversal of heart failure. , 2006, The New England journal of medicine.

[47]  Robert G. Weiss,et al.  Altered Creatine Kinase Adenosine Triphosphate Kinetics in Failing Hypertrophied Human Myocardium , 2006, Circulation.

[48]  B. Spiegelman,et al.  Transverse aortic constriction leads to accelerated heart failure in mice lacking PPAR-γ coactivator 1α , 2006 .

[49]  William C Stanley,et al.  Myocardial substrate metabolism in the normal and failing heart. , 2005, Physiological reviews.

[50]  S. Rohrbach,et al.  Dysfunction of mitochondrial respiratory chain complex I in human failing myocardium is not due to disturbed mitochondrial gene expression. , 2002, Journal of the American College of Cardiology.

[51]  D. Burkhoff,et al.  Comparison of Right and Left Ventricular Responses to Left Ventricular Assist Device Support in Patients With Severe Heart Failure: A Primary Role of Mechanical Unloading Underlying Reverse Remodeling , 2001, Circulation.

[52]  D. Burkhoff,et al.  Time course of reverse remodeling of the left ventricle during support with a left ventricular assist device. , 2001, The Journal of thoracic and cardiovascular surgery.

[53]  A. Nishiyama,et al.  Possible role of uncoupling protein in regulation of myocardial energy metabolism in aortic regurgitation model rats 1 , 2001, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[54]  R. Kerber,et al.  Cardiac hypertrophy is not a required compensatory response to short-term pressure overload. , 2000, Circulation.

[55]  C. Graff,et al.  Mitochondrial medicine – recent advances , 1999, Journal of internal medicine.

[56]  P. Douglas,et al.  Hypertrophic remodeling: gender differences in the early response to left ventricular pressure overload. , 1998, Journal of the American College of Cardiology.

[57]  P. Lockhart,et al.  Functional analysis and intracellular localization of the human menkes protein (MNK) stably expressed from a cDNA construct in Chinese hamster ovary cells (CHO-K1). , 1998, Human molecular genetics.

[58]  B. Lorell,et al.  Failure to maintain a low ADP concentration impairs diastolic function in hypertrophied rat hearts. , 1997, Circulation.

[59]  O. Hess,et al.  Diastolic dysfunction in aortic stenosis. , 1993, Circulation.

[60]  D. Pfeiffer,et al.  Cyclosporin A-sensitive and insensitive mechanisms produce the permeability transition in mitochondria. , 1989, Biochemical and biophysical research communications.

[61]  N. Kamo,et al.  Membrane potential of mitochondria measured with an electrode sensitive to tetraphenyl phosphonium and relationship between proton electrochemical potential and phosphorylation potential in steady state , 1979, The Journal of Membrane Biology.

[62]  C. Hoppel,et al.  Biochemical properties of subsarcolemmal and interfibrillar mitochondria isolated from rat cardiac muscle. , 1977, The Journal of biological chemistry.

[63]  D. Harrison,et al.  The role of ATP in the control of energy metabolism in growing bacteria. , 1968, Journal of General Microbiology.

[64]  K. S. Lee,et al.  Study of Heart Mitochondria and Glycolytic Metabolism in Experimentally Induced Cardiac Failure , 1962, Circulation research.

[65]  Georgios Kararigas,et al.  Mechanistic Pathways of Sex Differences in Cardiovascular Disease. , 2017, Physiological reviews.

[66]  A. Ascensão,et al.  Physical exercise mitigates doxorubicin-induced brain cortex and cerebellum mitochondrial alterations and cellular quality control signaling. , 2016, Mitochondrion.

[67]  A. Ascensão,et al.  Endurance training reverts heart mitochondrial dysfunction, permeability transition and apoptotic signaling in long-term severe hyperglycemia. , 2011, Mitochondrion.

[68]  I. Sjaastad,et al.  Collagen isoform shift during the early phase of reverse left ventricular remodelling after relief of pressure overload. , 2011, European heart journal.

[69]  B. Spiegelman,et al.  Transverse aortic constriction leads to accelerated heart failure in mice lacking PPAR-gamma coactivator 1alpha. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[70]  S. Houser,et al.  Sarcomeric genes involved in reverse remodeling of the heart during left ventricular assist device support. , 2005, The Journal of heart and lung transplantation : the official publication of the International Society for Heart Transplantation.

[71]  Karl H. Van Norman The Biuret Reaction and the Cold Nitric Acid Test in the Recognition of Protein. , 1909 .

[72]  Alan,et al.  Electron Transport in Neurospora Mitochondria , 2022 .

[73]  K. H. Van Norman The Biuret Reaction and the Cold Nitric Acid Test in the Recognition of Protein. , 2022, The Biochemical journal.