Diederik W. D. Kuster

Contractile Dysfunction Irrespective of the Mutant Protein in Human Hypertrophic Cardiomyopathy With Normal Systolic Function

Background— Hypertrophic cardiomyopathy (HCM), typically characterized by asymmetrical left ventricular hypertrophy, frequently is caused by mutations in sarcomeric proteins. We studied if changes in sarcomeric properties in HCM depend on the underlying protein mutation. Methods and Results— Comparisons were made between cardiac samples from patients carrying a MYBPC3 mutation (MYBPC3mut; n=17), mutation negative HCM patients without an identified sarcomere mutation (HCMmn; n=11), and nonfailing donors (n=12). All patients had normal systolic function, but impaired diastolic function. Protein expression of myosin binding protein C (cMyBP-C) was significantly lower in MYBPC3mut by 33±5%, and similar in HCMmn compared with donor. cMyBP-C phosphorylation in MYBPC3mut was similar to donor, whereas it was significantly lower in HCMmn. Troponin I phosphorylation was lower in both patient groups compared with donor. Force measurements in single permeabilized cardiomyocytes demonstrated comparable sarcomeric dysfunction in both patient groups characterized by lower maximal force generating capacity in MYBPC3mut and HCMmn, compared with donor (26.4±2.9, 28.0±3.7, and 37.2±2.3 kN/m2, respectively), and higher myofilament Ca2+-sensitivity (EC50=2.5±0.2, 2.4±0.2, and 3.0±0.2 &mgr;mol/L, respectively). The sarcomere length-dependent increase in Ca2+-sensitivity was significantly smaller in both patient groups compared with donor (&Dgr;EC50: 0.46±0.04, 0.37±0.05, and 0.75±0.07 &mgr;mol/L, respectively). Protein kinase A treatment restored myofilament Ca2+-sensitivity and length-dependent activation in both patient groups to donor values. Conclusions— Changes in sarcomere function reflect the clinical HCM phenotype rather than the specific MYBPC3 mutation. Hypocontractile sarcomeres are a common deficit in human HCM with normal systolic left ventricular function and may contribute to HCM disease progression.

Exercise training does not improve cardiac function in compensated or decompensated left ventricular hypertrophy induced by aortic stenosis

There is ample evidence that regular exercise exerts beneficial effects on left ventricular (LV) hypertrophy, remodeling and dysfunction produced by ischemic heart disease or systemic hypertension. In contrast, the effects of exercise on pathological LV hypertrophy and dysfunction produced by LV outflow obstruction have not been studied to date. Consequently, we evaluated the effects of 8 weeks of voluntary wheel running in mice (which mitigates post-infarct LV dysfunction) on LV hypertrophy and dysfunction produced by mild (mTAC) and severe (sTAC) transverse aortic constriction. mTAC produced ~40% LV hypertrophy and increased myocardial expression of hypertrophy marker genes but did not affect LV function, SERCA2a protein levels, apoptosis or capillary density. Exercise had no effect on global LV hypertrophy and function in mTAC but increased interstitial collagen, and ANP expression. sTAC produced ~80% LV hypertrophy and further increased ANP expression and interstitial fibrosis and, in contrast with mTAC, also produced LV dilation, systolic as well as diastolic dysfunction, pulmonary congestion, apoptosis and capillary rarefaction and decreased SERCA2a and ryanodine receptor (RyR) protein levels. LV diastolic dysfunction was likely aggravated by elevated passive isometric force and Ca(2+)-sensitivity of myofilaments. Exercise training failed to mitigate the sTAC-induced LV hypertrophy and capillary rarefaction or the decreases in SERCA2a and RyR. Exercise attenuated the sTAC-induced increase in passive isometric force but did not affect myofilament Ca(2+)-sensitivity and tended to aggravate interstitial fibrosis. In conclusion, exercise had no effect on LV function in compensated and decompensated cardiac hypertrophy produced by LV outflow obstruction, suggesting that the effect of exercise on pathologic LV hypertrophy and dysfunction depends critically on the underlying cause.

GSK3β phosphorylates newly identified site in the proline-alanine-rich region of cardiac myosin-binding protein C and alters cross-bridge cycling kinetics in human: short communication.

Rationale: Cardiac myosin–binding protein C (cMyBP-C) regulates cross-bridge cycling kinetics and, thereby, fine-tunes the rate of cardiac muscle contraction and relaxation. Its effects on cardiac kinetics are modified by phosphorylation. Three phosphorylation sites (Ser275, Ser284, and Ser304) have been identified in vivo, all located in the cardiac-specific M-domain of cMyBP-C. However, recent work has shown that up to 4 phosphate groups are present in human cMyBP-C. Objective: To identify and characterize additional phosphorylation sites in human cMyBP-C. Methods and Results: Cardiac MyBP-C was semipurified from human heart tissue. Tandem mass spectrometry analysis identified a novel phosphorylation site on serine 133 in the proline-alanine–rich linker sequence between the C0 and C1 domains of cMyBP-C. Unlike the known sites, Ser133 was not a target of protein kinase A. In silico kinase prediction revealed glycogen synthase kinase 3&bgr; (GSK3&bgr;) as the most likely kinase to phosphorylate Ser133. In vitro incubation of the C0C2 fragment of cMyBP-C with GSK3&bgr; showed phosphorylation on Ser133. In addition, GSK3&bgr; phosphorylated Ser304, although the degree of phosphorylation was less compared with protein kinase A–induced phosphorylation at Ser304. GSK3&bgr; treatment of single membrane–permeabilized human cardiomyocytes significantly enhanced the maximal rate of tension redevelopment. Conclusions: GSK3&bgr; phosphorylates cMyBP-C on a novel site, which is positioned in the proline-alanine–rich region and increases kinetics of force development, suggesting a noncanonical role for GSK3&bgr; at the sarcomere level. Phosphorylation of Ser133 in the linker domain of cMyBP-C may be a novel mechanism to regulate sarcomere kinetics.

‘Integrative Physiology 2.0’: integration of systems biology into physiology and its application to cardiovascular homeostasis

Abstract  Since the completion of the Human Genome Project and the advent of the large scaled unbiased ‘‐omics’ techniques, the field of systems biology has emerged. Systems biology aims to move away from the traditional reductionist molecular approach, which focused on understanding the role of single genes or proteins, towards a more holistic approach by studying networks and interactions between individual components of networks. From a conceptual standpoint, systems biology elicits a ‘back to the future’ experience for any integrative physiologist. However, many of the new techniques and modalities employed by systems biologists yield tremendous potential for integrative physiologists to expand their tool arsenal to (quantitatively) study complex biological processes, such as cardiac remodelling and heart failure, in a truly holistic fashion. We therefore advocate that systems biology should not become/stay a separate discipline with ‘‐omics’ as its playing field, but should be integrated into physiology to create ‘Integrative Physiology 2.0’.

Prostanoids suppress the coronary vasoconstrictor influence of endothelin after myocardial infarction

Myocardial infarction (MI) is associated with endothelial dysfunction resulting in an imbalance in endothelium-derived vasodilators and vasoconstrictors. We have previously shown that despite increased endothelin (ET) plasma levels, the coronary vasoconstrictor effect of endogenous ET is abolished after MI. In normal swine, nitric oxide (NO) and prostanoids modulate the vasoconstrictor effect of ET. In light of the interaction among NO, prostanoids, and ET combined with endothelial dysfunction present after MI, we investigated this interaction in control of coronary vasomotor tone in the remote noninfarcted myocardium after MI. Studies were performed in chronically instrumented swine (18 normal swine; 13 swine with MI) at rest and during treadmill exercise. Furthermore, endothelial nitric oxide synthase (eNOS) and cyclooxygenase protein levels were measured in the anterior (noninfarcted) wall of six normal and six swine with MI. eNOS inhibition with N(ω)-nitro-L-arginine (L-NNA) and cyclooxygenase inhibition with indomethacin each resulted in coronary vasoconstriction at rest and during exercise, as evidenced by a decrease in coronary venous oxygen levels. The effect of l-NNA was slightly decreased in swine with MI, although eNOS expression was not altered. Conversely, in accordance with the unaltered expression of cyclooxygenase-1 after MI, the effect of indomethacin was similar in normal and MI swine. L-NNA enhanced the vasodilator effect of the ET(A/B) receptor blocker tezosentan but exclusively during exercise in both normal and MI swine. Interestingly, this effect of L-NNA was blunted in MI compared with normal swine. In contrast, whereas indomethacin increased the vasodilator effect of tezosentan only during exercise in normal swine, indomethacin unmasked a coronary vasodilator effect of tezosentan in MI swine both at rest and during exercise. In conclusion, the present study shows that endothelial control of the coronary vasculature is altered in post-MI remodeled myocardium. Thus the overall vasodilator influences of NO as well as its inhibition of the vasoconstrictor influence of ET on the coronary resistance vessels were reduced after MI. In contrast, while the overall prostanoid vasodilator influence was maintained, its inhibition of ET vasoconstrictor influences was enhanced in post-MI remote myocardium.

Synergistic role of ADP and Ca2+ in diastolic myocardial stiffness

Diastolic dysfunction in heart failure patients is evident from stiffening of the passive properties of the ventricular wall. Increased actomyosin interactions may significantly limit diastolic capacity, however, direct evidence is absent. From experiments at the cellular and whole organ level, in humans and rats, we show that actomyosin‐related force development contributes significantly to high diastolic stiffness in environments where high ADP and increased diastolic [Ca2+] are present, such as the failing myocardium. Our basal study provides a mechanical mechanism which may partly underlie diastolic dysfunction.

ADP-stimulated contraction: A predictor of thin-filament activation in cardiac disease

Significance Diastolic dysfunction is characteristic of patients with cardiomyopathy. Evidence indicates that diseased hearts show basal sarcomeric activation capable of impairing diastolic performance. By activating human cardiomyopathy muscle in ADP-containing solutions without Ca2+, we showed that actin–myosin blockade is disrupted. This may be caused by the presence of mutations and/or the reduced phosphorylation of myofilament proteins. Our mechanistic study supports the novel idea that protein kinase A-target phosphorylation and myosin-binding protein C regulate the OFF–ON transition of the thin filaments. ADP increased myofilament force and stiffness in the presence of Ca2+ in cardiomyopathy samples, suggesting this condition limits muscle relaxation through increased actin–myosin interactions. We conclude that ADP-stimulated contraction can be used to reveal conformational changes in the three-state model of thin-filament activation. Diastolic dysfunction is general to all idiopathic dilated (IDCM) and hypertrophic cardiomyopathy (HCM) patients. Relaxation deficits may result from increased actin–myosin formation during diastole due to altered tropomyosin position, which blocks myosin binding to actin in the absence of Ca2+. We investigated whether ADP-stimulated force development (without Ca2+) can be used to reveal changes in actin–myosin blockade in human cardiomyopathy cardiomyocytes. Cardiac samples from HCM patients, harboring thick-filament (MYH7mut, MYBPC3mut) and thin-filament (TNNT2mut, TNNI3mut) mutations, and IDCM were compared with sarcomere mutation-negative HCM (HCMsmn) and nonfailing donors. Myofilament ADP sensitivity was higher in IDCM and HCM compared with donors, whereas it was lower for MYBPC3. Increased ADP sensitivity in IDCM, HCMsmn, and MYH7mut was caused by low phosphorylation of myofilament proteins, as it was normalized to donors by protein kinase A (PKA) treatment. Troponin exchange experiments in a TNNT2mut sample corrected the abnormal actin–myosin blockade. In MYBPC3trunc samples, ADP sensitivity highly correlated with cardiac myosin-binding protein-C (cMyBP-C) protein level. Incubation of cardiomyocytes with cMyBP-C antibody against the actin-binding N-terminal region reduced ADP sensitivity, indicative of cMyBP-C’s role in actin–myosin regulation. In the presence of Ca2+, ADP increased myofilament force development and sarcomere stiffness. Enhanced sarcomere stiffness in sarcomere mutation-positive HCM samples was irrespective of the phosphorylation background. In conclusion, ADP-stimulated contraction can be used as a tool to study how protein phosphorylation and mutant proteins alter accessibility of myosin binding on actin. In the presence of Ca2+, pathologic [ADP] and low PKA-phosphorylation, high actin–myosin formation could contribute to the impaired myocardial relaxation observed in cardiomyopathies.

Synergistic role of ADP and Ca(2+) in diastolic myocardial stiffness.

Diastolic dysfunction in heart failure patients is evident from stiffening of the passive properties of the ventricular wall. Increased actomyosin interactions may significantly limit diastolic capacity, however, direct evidence is absent. From experiments at the cellular and whole organ level, in humans and rats, we show that actomyosin‐related force development contributes significantly to high diastolic stiffness in environments where high ADP and increased diastolic [Ca2+] are present, such as the failing myocardium. Our basal study provides a mechanical mechanism which may partly underlie diastolic dysfunction.

Gene reprogramming in exercise-induced cardiac hypertrophy in swine: A transcriptional genomics approach

Cardiac hypertrophy of the left ventricle (LV) in response to dynamic exercise-training (EX) is a beneficial adaptation to increased workload, and is thought to result from genetic reprogramming. We aimed to determine which transcription factors (TFs) are involved in this genetic reprogramming of the LV in swine induced by exercise-training. Swine underwent 3-6 weeks of dynamic EX, resulting in a 16% increase of LV weight/body weight ratio compared to sedentary animals (P=0.03). Hemodynamic analysis showed an increased stroke volume index (stroke volume/body weight +35%; P=0.02). Microarray-analysis of LV tissue identified 339 upregulated and 408 downregulated genes (false discovery rate<0.05). Of the human homologues of the differentially expressed genes, promoter regions were searched for TF consensus binding sites (TFBSs). For upregulated and downregulated genes, 17 and 24 TFBSs were overrepresented by >1.5-fold (P<0.01), respectively. In DNA-binding assays, using LV nuclear protein extracts and protein/DNA array, signal intensity changes >2-fold were observed for 23 TF-specific DNA probes. Matching results in TFBS and protein/DNA array analyses were obtained for transcription factors YY1 (Yin Yang 1), PAX6 (paired box 6) and GR (glucocorticoid receptor). Notably, PAX6 and GR show lower signals in TFBS and protein/DNA array analyses upon exercise-training, whereas we previously showed higher signals for these factors in the remodeled LV of swine post-myocardial infarction (MI). In conclusion, we have identified transcription factors that may drive the genetic reprogramming underlying exercise-training induced LV hypertrophy in swine. PAX6 and GR are among the transcription factors that are oppositely regulated in LV hypertrophy after exercise-training and MI. These proteins may be at the base of the differences between pathological and physiological hypertrophy.

Sex-dependent pathophysiological mechanisms in hypertrophic cardiomyopathy: Implications for rhythm disorders

Differences in cardiac physiology are seen between men and women in terms of health and disease. Sex differences start to develop at puberty and are maintained during aging. The prevalence of almost all cardiovascular diseases is found to be higher in men than in women, and disease progression tends to be more rapid in male than in female patients. In cohorts of patients with hypertrophic cardiomyopathy (HCM), the most common autosomal inherited cardiac disease, men are overrepresented, suggesting increased penetrance of HCM-causing mutations in male patients. Cardiac remodeling in patients with HCM is higher in men than in women, the same is seen in HCM animal models. Patients with HCM are at increased risk of sudden cardiac death (SCD) and developing rhythm disorders. There seems to be no sex effect on the risk of SCD or arrhythmias in patients with HCM; however, animal studies suggest that certain mutations predispose men to SCD.