Cardiac muscle disease and therapeutic targets

Hypertrophic cardiomyopathy (HCM) is the most common genetic heart disease. While ∼50% of patients with HCM carry a sarcomere gene mutation (sarcomere mutation-positive, SMP), the genetic background is unknown in the other half of the patients (sarcomere mutation-negative, SMN). Gene mutations are most often present in genes encoding the sarcomere proteins myosin heavy chain, myosin-binding protein C, and troponin T. Studies in cardiac tissue samples from patients with obstructive HCM that were obtained during myectomy surgery showed increased myofilament calcium sensitivity, increased kinetics and tension cost, and a reduction of the super-relaxed state of myosin, which is associated with an energy-conserving status of the crossbridges. The increase in myofilament calcium sensitivity is observed at a low dose of mutant protein, while the magnitude of the increase in calcium sensitivity depends on the specific mutation location. These mutation-mediated myofilament changes may underlie inefficient in vivo cardiac performance in mutation carriers. Reduced cardiac efficiency has been observed before onset of cardiac hypertrophy and at advanced disease stages. In addition, impaired diastolic function is an early disease characteristic of HCM. Our recent proteomics studies revealed increased detyrosination of microtubules, which may be a cause of diastolic dysfunction. Recent treatments that target inefficient cardiac performance, such as myosin inhibitors and metabolic drug therapies, may have the potential to prevent, delay, or even reverse disease in HCM-mutation carriers. Treatment response may depend on the specific gene mutation in SMP individuals and may explain diverse response of HCM patients to therapy. While mutation-mediated cardiomyocyte defects have become clear in past years, more research is warranted to define the cellular pathomechanisms of cardiac dysfunction in SMN patients.

Abstract MP211: NAD Redox Imbalance Exacerbates Diabetic Cardiomyopathy

Diabetes and heart failure are linked to NAD redox imbalance, whose role in diabetic cardiomyopathy has not been directly tested. Streptozotocin-induced diabetes in WT mice for 16 weeks promoted declines in systolic and diastolic function, which associated with lowered cardiac NAD/NADH ratio (NAD redox imbalance). To test the hypothesis that , we employed mouse models with cardiac-specific manipulations of NAD redox states. Cardiac-specific Ndufs4-KO mice (cKO) exhibit lowered cardiac NAD/NADH ratio with normal baseline function, geometry and energetics. Control and cKO mice were challenged with 8-week diabetic stress. Metabolomic analyses of plasma collected after the diabetic stress showed similar hyperglycemia and dyslipidemia stresses in diabetic control and diabetic cKO mice. Chronic diabetic stress promoted systolic and diastolic dysfunctions in control mice, which were further exacerbated in diabetic cKO mice in both male and female cohorts. Collagen levels and transcript analyses of fibrosis and extracellular matrix-dependent pathways showed no change in diabetic cKO hearts, suggesting that cardiomyocyte dysfunction is a likely culprit for the exacerbated dysfunction. Increased protein acetylation, including SOD2-K68Ac, was observed in diabetic cKO hearts. Inhibited antioxidant function by SOD2-K68Ac promoted protein oxidation in diabetic cKO hearts, suggesting oxidative stress as a pathogenic mechanism. We next examined phosphorylation status of myofilament proteins in these diabetic hearts. MyBPC-S282Pi levels are suppressed in failing hearts and remained unchanged in diabetic cKO hearts. TnI-S150Pi increases myofilament calcium sensitivity and prolongs calcium dissociation, while TnI-S23/24Pi imposes the opposite effects. TnI-S150Pi levels were elevated in diabetic cKO hearts, while TnI-S23/24Pi levels unchanged. Therefore, exacerbated diastolic dysfunction in diabetic cKO hearts is due to the selective phosphorylation at TnI-S150. AMPK is activated by energetic stress and phosphorylates TnI-S150. ATP levels decreased, and AMP/ATP ratio increased in diabetic cKO hearts, implicating impaired energetics to promote TnI-S150Pi and dysfunction. Elevation of NAD levels normalized cardiac NAD redox balance in diabetic cKO hearts. Elevated levels of SOD2-K68Ac and TnI-S150Pi, exacerbated systolic and diastolic dysfunction in diabetic cKO hearts were all reversed by elevation of NAD levels. Dysfunction in diabetic control hearts was also ameliorated by elevation of NAD levels. These data collectively conclude that NAD redox imbalance is a positive mediator of the progression of diabetic cardiomyopathy.

Human-based computational and experimental investigation of disease mechanisms in mutation-specific hypertrophic cardiomyopathy

Funding Acknowledgements Type of funding sources: Public grant(s) – EU funding. Main funding source(s): European Union’s Horizon 2020 research and innovation programme under the Marie Sklodowska-Curie grant agreement 764738. British Heart Foundation Intermediate Basic Science Fellowship (FS/17/22/32644). Background The pathogenic TNNI3R21C/+ variant causes malignant hypertrophic cardiomyopathy (HCM) with high incidence of sudden cardiac death, even in individuals absent of hypertrophy. There is evidence to support a known biophysical defect in the protein, yet the cellular mechanisms that precipitate adverse clinical outcomes remain unclear. Purpose We aim to computationally model and map the TNNI3R21C/+ cellular phenotype observed in induced pluripotent stem cell derived cardiomyocytes (iPSC-CMs) to human disease, thereby explaining the key mechanisms driving HCM in TNNI3R21C/+ variant carriers. Methods Wild-type (WT) and TNNI3R21C/+ iPSC-CMs were characterised by calcium transient analysis and direct sarcomere tracking to assess cellular contraction and relaxation. In-vitro data was used to inform the in-silico modelling of human cardiomyocytes. We constructed an in-silico population of WT adult cardiomyocytes and used it to transform the in-vitro data into corresponding adult phenotypes by means of a novel iPSC-to-adult data mapping. We tested the hypothesis that the abnormal TNNI3R21C/+ phenotype observed in iPSC-CMs would be explained by alterations in calcium affinity of troponin and increased myofilament calcium sensitivity. Results Analysis of in-vitro iPSC-CM data showed that TNNI3R21C/+ cells exhibit increased contractility with slowed relaxation when compared to WT. They also exhibited a faster rise in the calcium transient with a slowed calcium decay in comparison to WT. The in-silico adult TNNI3R21C/+ phenotype from the iPSC-to-adult mapping replicated the abnormalities observed in iPSC-CMs. The WT in-silico population accurately covered the ranges of electromechanical biomarkers providing a representative cohort of physiological variability. The TNNI3R21C/+ calcium phenotype could be recovered by our in-silico mutant models. Simulation results suggest that calcium abnormalities in TNNI3R21C/+ are a direct consequence of abnormal calcium buffering by thin filaments, mediated by increases in calcium affinity of troponin and myofilament calcium sensitivity. The TNNI3R21C/+ phenotype could not be recovered if these two factors were considered in isolation. Corresponding contractility analyses of in-silico models showed that the calcium level changes caused by the TNNI3R21C/+ phenotype are associated with hypercontractility and diastolic dysfunction, well-known hallmarks of HCM, which were also observed in the iPSC-CM model of disease. Conclusions This study showcases human-based computational and experimental methodologies that unearth direct mechanistic explanations of phenotypes driven by the TNNI3R21C/+ HCM variant. We show that the TNNI3R21C/+ HCM-causing mutation exhibits multifactorial remodelling of troponin calcium affinity and myofilament calcium sensitivity. Unearthing mechanistic pathways in mutation-specific HCM will be key to develop effective pharmacological interventions for a wide variety of understudied variants.

Increased myofilament calcium sensitivity is associated with decreased cardiac troponin I phosphorylation in the diabetic rat heart

Background The diabetic heart has impaired systolic and diastolic function independent of other comorbidities. The availability of calcium is altered, but does not fully explain the cardiac dysfunction seen in the diabetic heart. Thus, we explored if myofilament protein regulation of contraction is altered. Methods Calcium sensitivity (pCa50) was measured in Zucker Diabetic Fatty (ZDF) rat hearts at the initial stage of diabetes (12-week-old) and after 8 weeks of uncontrolled hyperglycaemia (20-week-old) and in non-diabetic (nDM) littermates. Skinned cardiomyocytes were connected to a capacitance-gauge transducer and a torque motor to measure force as a function of pCa (-log[Ca2+]). Fluorescent gel stain (ProQ Diamond) was used to measure total protein phosphorylation. Specific phospho-sites on cardiac troponin I (cTnI) and total cTnI O-GlcNAcylation were quantified using immunoblot. Results pCa50 was greater in both 12- and 20-week-old diabetic (DM) rats compared to nDM littermates (p = 0.0005). Total cTnI and cTnI serine 23/24 phosphorylation were lower in DM rats (p = 0.003 & p = 0.01, respectively), but cTnI O-GlcNAc protein expression was not different. pCa50 is greater in DM rats and corresponds with an overall reduction in cTnI phosphorylation. Conclusions These findings indicate that myofilament calcium sensitivity is increased and cTnI phosphorylation is reduced in ZDF DM rats, which suggests an important role for cTnI phosphorylation in the DM heart.

Effects of anesthetic agents on contractions of the pregnant rat myometrium in vivo and in vitro

Background Several anesthetic agents are used in cesarean sections for both regional and general anesthesia purposes. However, there are no data comparing the in vivo effects of propofol, sevoflurane, and dexmedetomidine on the contraction of the myometrium in pregnant rats. The aim of this study was to investigate the effect of these anesthetic agents on myometrial contraction and elucidate the underlying mechanisms. Methods Contraction force and frequency changes in response to propofol, dexmedetomidine, or sevoflurane were evaluated in vivo and in vitro. To test the effect of arachidonic acid on myometrial contraction enhanced by dexmedetomidine, changes in myometrial contraction with dexmedetomidine after administration of indomethacin were evaluated. The amount of phosphorylated myosin phosphatase target subunit 1 (MYPT1) in the membrane fraction was expressed as a percentage of the total fraction by Western blot analysis. Results This study demonstrated that dexmedetomidine enhances oxytocin-induced contraction in the myometrium of pregnant rats, whereas propofol and sevoflurane attenuate these contractions. The dexmedetomidine-induced enhancement of myometrial contraction force was abolished by the administration of indomethacin. Propofol did not affect oxytocin-induced MYPT1 phosphorylation, whereas sevoflurane attenuated oxytocin-induced MYPT1 phosphorylation. Conclusions Inhibition of myofilament calcium sensitivity may underlie the inhibition of myometrial contraction induced by sevoflurane. Arachidonic acid may play an important role in the enhancement of myometrial contraction induced by dexmedetomidine by increasing myofilament calcium sensitivity. Dexmedetomidine may be used as a sedative agent to promote uterine muscle contraction and suppress bleeding after fetal delivery.

Acute exposure to progesterone attenuates cardiac contraction by modifying myofilament calcium sensitivity in the female mouse heart

Acute application of progesterone attenuates cardiac contraction, although the underlying mechanisms are unclear. We investigated whether progesterone modified contraction in isolated ventricular myocytes and identified the Ca2+ handling mechanisms involved in female C57BL/6 mice (6–9 mo; sodium pentobarbital anesthesia). Cells were field-stimulated (4 Hz; 37°C) and exposed to progesterone (0.001–10.0 μM) or vehicle (35 min). Ca2+ transients (fura-2) and cell shortening were recorded simultaneously. Maximal concentrations of progesterone inhibited peak contraction by 71.4% (IC50 = 160 ± 50 nM; n = 12) and slowed relaxation by 75.4%. By contrast, progesterone had no effect on amplitudes or time courses of underlying Ca2+ transients. Progesterone (1 µM) also abbreviated action potential duration. When the duration of depolarization was controlled by voltage-clamp, progesterone attenuated contraction and slowed relaxation but did not affect Ca2+ currents, Ca2+ transients, sarcoplasmic reticulum (SR) content, or fractional release of SR Ca2+. Actomyosin MgATPase activity was assayed in myofilaments from hearts perfused with progesterone (1 μM) or vehicle (35 min). While maximal responses to Ca2+ were not affected by progesterone, myofilament Ca2+ sensitivity was reduced (EC50 = 0.94 ± 0.01 µM for control, n = 7 vs. 1.13 ± 0.05 μM for progesterone, n = 6; P < 0.05) and progesterone increased phosphorylation of myosin binding protein C. The effects on contraction were inhibited by lonaprisan (progesterone receptor antagonist) and levosimendan (Ca2+ sensitizer). Unlike results in females, progesterone had no effect on contraction or myofilament Ca2+ sensitivity in age-matched male mice. These data indicate that progesterone reduces myofilament Ca2+ sensitivity in female hearts, which may exacerbate manifestations of cardiovascular disease late in pregnancy when progesterone levels are high. NEW & NOTEWORTHY We investigated myocardial effects of acute application of progesterone. In females, but not males, progesterone attenuates and slows cardiomyocyte contraction with no effect on calcium transients. Progesterone also reduces myofilament calcium sensitivity in female hearts. This may adversely affect heart function, especially when serum progesterone levels are high in pregnancy. Listen to this article’s corresponding podcast at https://ajpheart.podbean.com/e/acute-progesterone-modifies-cardiac-contraction/ .