Background: Hypertrophic cardiomyopathy (HCM) is caused by pathogenic variants in sarcomere protein genes that evoke hypercontractility, poor relaxation, and increased energy consumption by the heart and increased patient risks for arrhythmias and heart failure. Recent studies show that pathogenic missense variants in myosin, the molecular motor of the sarcomere, are clustered in residues that participate in dynamic conformational states of sarcomere proteins. We hypothesized that these conformations are essential to adapt contractile output for energy conservation and that pathophysiology of HCM results from destabilization of these conformations. Methods: We assayed myosin ATP binding to define the proportion of myosins in the super relaxed state (SRX) conformation or the disordered relaxed state (DRX) conformation in healthy rodent and human hearts, at baseline and in response to reduced hemodynamic demands of hibernation or pathogenic HCM variants. To determine the relationships between myosin conformations, sarcomere function, and cell biology, we assessed contractility, relaxation, and cardiomyocyte morphology and metabolism, with and without an allosteric modulator of myosin ATPase activity. We then tested whether the positions of myosin variants of unknown clinical significance that were identified in patients with HCM, predicted functional consequences and associations with heart failure and arrhythmias. Results: Myosins undergo physiological shifts between the SRX conformation that maximizes energy conservation and the DRX conformation that enables cross-bridge formation with greater ATP consumption. Systemic hemodynamic requirements, pharmacological modulators of myosin, and pathogenic myosin missense mutations influenced the proportions of these conformations. Hibernation increased the proportion of myosins in the SRX conformation, whereas pathogenic variants destabilized these and increased the proportion of myosins in the DRX conformation, which enhanced cardiomyocyte contractility, but impaired relaxation and evoked hypertrophic remodeling with increased energetic stress. Using structural locations to stratify variants of unknown clinical significance, we showed that the variants that destabilized myosin conformations were associated with higher rates of heart failure and arrhythmias in patients with HCM. Conclusions: Myosin conformations establish work-energy equipoise that is essential for life-long cellular homeostasis and heart function. Destabilization of myosin energy-conserving states promotes contractile abnormalities, morphological and metabolic remodeling, and adverse clinical outcomes in patients with HCM. Therapeutic restabilization corrects cellular contractile and metabolic phenotypes and may limit these adverse clinical outcomes in patients with HCM.
Familial dilated cardiomyopathy (DCM) is a leading cause of sudden cardiac death and a major indicator for heart transplant. The disease is frequently caused by mutations of sarcomeric proteins; however, it is not well understood how these molecular mutations lead to alterations in cellular organization and contractility. To address this critical gap in our knowledge, we studied the molecular and cellular consequences of a DCM mutation in troponin-T, ΔK210. We determined the molecular mechanism of ΔK210 and used computational modeling to predict that the mutation should reduce the force per sarcomere. In mutant cardiomyocytes, we found that ΔK210 not only reduces contractility but also causes cellular hypertrophy and impairs cardiomyocytes’ ability to adapt to changes in substrate stiffness (e.g., heart tissue fibrosis that occurs with aging and disease). These results help link the molecular and cellular phenotypes and implicate alterations in mechanosensing as an important factor in the development of DCM.
27Familial dilated cardiomyopathy (DCM) is a leading cause of sudden cardiac death and a 28 major indicator for heart transplant. The disease is frequently caused by mutations of 29 sarcomeric proteins; however, it is not well understood how these molecular mutations 30 lead to alterations in cellular organization and contractility. To address this critical gap in 31 our knowledge, we studied the molecular and cellular consequences of a DCM mutation 32 in troponin-T, DK210. We determined the molecular mechanism of DK210 and used 33 computational modeling to predict that the mutation should reduce the force per 34 sarcomere. In mutant cardiomyocytes, we found that DK210 not only reduces contractility, 35 but also causes cellular hypertrophy and impairs cardiomyocytes' ability to adapt to 36 changes in substrate stiffness (e.g., heart tissue fibrosis that occurs with aging and 37 disease). These results link the molecular and cellular phenotypes and implicate 38 alterations in mechanosensing as an important factor in the development of DCM. 39Results 100 DK210 decreases calcium sensitivity in an in vitro motility assay 101We set out to decipher the molecular mechanism of the DK210 mutation in vitro. 102The molecular effects of cardiomyopathy mutations depend on the myosin isoform (7-9, 103 35-37) and therefore, we used porcine cardiac ventricular myosin (38). Porcine ventricular 104 cardiac myosin (MYH7) is 97% identical to human, while murine cardiac myosin (MYH6) 105 is only 92% identical. Porcine cardiac myosin has very similar biophysical properties to 106 human cardiac myosin, including the kinetics of the ATPase cycle, step size, and 107 sensitivity to load (38-41), making it an ideal myosin for biophysical studies. 108Given the role of troponin-T in thin filament regulation, we first determined whether 109 the DK210 mutation affects calcium-based regulation of myosin binding to thin filaments 110 using an in vitro motility assay (42). Reconstituted thin filaments, consisting of porcine 111 cardiac actin and recombinantly expressed human troponin and tropomyosin, were added 112 to a flow cell coated with porcine cardiac myosin in the presence of ATP. The speed of 113 filament translocation was measured as a function of added calcium. As has been 114 reported previously, the speed of regulated thin filament translocation increased 115 sigmoidally with increasing Ca 2+ concentration (43), ( Figure 1B). Data were fit with the Hill 116 equation to obtain the pCa50 (i.e., the concentration of calcium necessary for half-117 maximal activation). Consistent with previous studies using mouse cardiac, rabbit cardiac, 118 and rabbit skeletal muscle fibers (31, 33, 44), DK210 shows a right-shifted curve (pCa50 119 = 5.7 ± 0.1) compared to the WT (pCa50 = 6.1 ± 0.1; p < 0.0001), meaning more calcium 120 is needed for the same level of activation. This suggests that the mutant could show 121 impaired force production during a calcium transient. 122 7 123 Molecular mechanism of DK210-induced changes in thin filament regulat...
The structural and functional maturation of human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) is essential for pharmaceutical testing, disease modeling, and ultimately therapeutic use. Multicellular 3D-tissue platforms have improved the functional maturation of hiPSC-CMs, but probing cardiac contractile properties in a 3D environment remains challenging, especially at depth and in live tissues. Using small-angle X-ray scattering (SAXS) imaging, we show that hiPSC-CMs matured and examined in a 3D environment exhibit a periodic spatial arrangement of the myofilament lattice, which has not been previously detected in hiPSC-CMs. The contractile force is found to correlate with both the scattering intensity (R2 = 0.44) and lattice spacing (R2 = 0.46). The scattering intensity also correlates with lattice spacing (R2 = 0.81), suggestive of lower noise in our structural measurement than in the functional measurement. Notably, we observed decreased myofilament ordering in tissues with a myofilament mutation known to lead to hypertrophic cardiomyopathy (HCM). Our results highlight the progress of human cardiac tissue engineering and enable unprecedented study of structural maturation in hiPSC-CMs.
Background - To assess the genetic architecture of hypertrophic cardiomyopathy (HCM) in patients of predominantly Chinese ancestry. Methods - We sequenced HCM disease genes in Singaporean patients (n=224) and Singaporean controls (n=3,634), compared findings with additional populations and Caucasian HCM cohorts (n=6,179) and performed in vitro functional studies. Results - Singaporean HCM patients had significantly fewer confidently interpreted HCM disease variants (Pathogenic (P)/Likely Pathogenic (LP):18%, p<0.0001) but an excess of variants of unknown significance (exVUS: 24%, p<0.0001), as compared to Caucasians (P/LP: 31%, exVUS: 7%). Two missense variants in thin filament encoding genes were commonly seen in Singaporean HCM ( TNNI3 :p.R79C, disease allele frequency (AF)=0.018; TNNT2 :p.R286H, disease AF=0.022) and are enriched in Singaporean HCM when compared with Asian controls ( TNNI3 :p.R79C, Singaporean controls AF=0.0055, p=0.0057, gnomAD-East Asian (gnomAD-EA) AF=0.0062, p=0.0086; TNNT2 :p.R286H, Singaporean controls AF=0.0017, p<0.0001, gnomAD-EA AF=0.0009, p<0.0001). Both these variants have conflicting annotations in ClinVar and are of low penetrance ( TNNI3 :p.R79C, 0.7%; TNNT2 :p.R286H, 2.7%) but are predicted to be deleterious by computational tools. In population controls, TNNI3 :p.R79C carriers had significantly thicker left ventricular walls compared to non-carriers while its etiological fraction is limited (0.70, 95% CI: 0.35-0.86) and thus TNNI3 :p.R79C is considered a VUS. Mutant TNNT2 :p.R286H iPSC-CMs show hypercontractility, increased metabolic requirements and cellular hypertrophy and the etiological fraction (0.93, 95% CI: 0.83-0.97) support the likely pathogenicity of TNNT2 :p.R286H. Conclusions - As compared to Caucasians, Chinese HCM patients commonly have low penetrance risk alleles in TNNT2 or TNNI3 but exhibit few clinically actionable HCM variants overall. This highlights the need for greater study of HCM genetics in non-Caucasian populations.
Familial hypertrophic cardiomyopathy (HCM), a leading cause of sudden cardiac death, is primarily caused by mutations in sarcomeric proteins. The pathogenesis of HCM is complex, with functional changes that span scales, from molecules to tissues. This makes it challenging to deconvolve the biophysical molecular defect that drives the disease pathogenesis from downstream changes in cellular function. In this study, we examine an HCM mutation in troponin T, R92Q, for which several models explaining its effects in disease have been put forward. We demonstrate that the primary molecular insult driving disease pathogenesis is mutation-induced alterations in tropomyosin positioning, which causes increased molecular and cellular force generation during calcium-based activation. Computational modeling shows that the increased cellular force is consistent with the molecular mechanism. These changes in cellular contractility cause downstream alterations in gene expression, calcium handling, and electrophysiology. Taken together, our results demonstrate that molecularly driven changes in mechanical tension drive the early disease pathogenesis of familial HCM, leading to activation of adaptive mechanobiological signaling pathways.
Progressive loss of cardiac systolic function in arrhythmogenic cardiomyopathy (ACM) has recently gained attention as an important clinical consideration in managing the disease. However, the mechanisms leading to reduction in cardiac contractility are poorly defined. Here, we use CRISPR gene editing to generate human induced pluripotent stem cells (iPSCs) that harbor plakophilin-2 truncating variants (PKP2tv), the most prevalent ACM-linked mutations. The PKP2tv iPSC-derived cardiomyocytes are shown to have aberrant action potentials and reduced systolic function in cardiac microtissues, recapitulating both the electrical and mechanical pathologies reported in ACM. By combining cell micropatterning with traction force microscopy and live imaging, we found that PKP2tvs impair cardiac tissue contractility by destabilizing cell-cell junctions and in turn disrupting sarcomere stability and organization. These findings highlight the interplay between cell-cell adhesions and sarcomeres required for stabilizing cardiomyocyte structure and function and suggest fundamental pathogenic mechanisms that may be shared among different types of cardiomyopathies.
Background: Heterozygous truncating variants in the sarcomere protein titin (TTN) are the most common genetic cause of heart failure, a major cause of morbidity and mortality. This causality indicates that even two-fold changes in the amount of TTN can profoundly disturb cardiac physiology. Although a critical role of TTN in sarcomere formation and cardiomyocyte contractility is well established, the mechanisms regulating transcription of the TTN gene remain poorly understood. Methods: We performed bioinformatics analysis to identify a putative transcriptional enhancer of TTN . Next, we created biallelic deletion of the enhancer in human induced pluripotent stem cell derived cardiomyocytes and performed enhancer reporter assays both in vitro and in vivo to demonstrate necessity and sufficiency of the enhancer in TTN gene expression, respectively. Furthermore, we performed massive parallel reporter assay to define critical transcriptional factors of the TTN enhancer activity and analyzed whole genome sequencing (WGS) data of human patients with unexplained dilated cardiomyopathy (DCM). Results: We identified an intron mediated enhancer that promotes cardiac-specific TTN expression. Global deletion of this element downregulated TTN expression in cardiomyocytes and impaired sarcomere development, while transgenic expression promoted cardiac expression in mice. Using mutational scanning we defined key transcription factor binding sites, including NKX2-5 and MEF2 motifs that promote TTN expression in cardiomyocytes. Consistent with these functions, analyses of WGS data in 69 patients with unexplained DCM revealed one rare variant that disrupted the conserved MEF2 transcriptional factor binding motif. Conclusions: Discovery of a TTN enhancer advances our understanding of cardiomyocyte development, provides an opportunity to modulate TTN transcriptional activity, and ultimately develop therapeutic strategies to treat dilated cardiomyopathy caused by TTN haploinsufficiency.
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