Actinin BioID reveals sarcomere crosstalk with oxidative metabolism through interactions with IGF2BP2.

Actinins are strain-sensing actin cross-linkers that are ubiquitously expressed and harbor mutations in human diseases. We utilize CRISPR, pluripotent stem cells, and BioID to study actinin interactomes in human cardiomyocytes. We identify 324 actinin proximity partners, including those that are dependent on sarcomere assembly. We confirm 19 known interactors and identify a network of RNA-binding proteins, including those with RNA localization functions. In vivo and biochemical interaction studies support that IGF2BP2 localizes electron transport chain transcripts to actinin neighborhoods through interactions between its K homology (KH) domain and actinin\u27s rod domain. We combine alanine scanning mutagenesis and metabolic assays to disrupt and functionally interrogate actinin-IGF2BP2 interactions, which reveal an essential role in metabolic responses to pathological sarcomere activation using a hypertrophic cardiomyopathy model. This study expands our functional knowledge of actinin, uncovers sarcomere interaction partners, and reveals sarcomere crosstalk with IGF2BP2 for metabolic adaptation relevant to human disease

A Contraction Stress Model of Hypertrophic Cardiomyopathy due to Sarcomere Mutations.

Thick-filament sarcomere mutations are a common cause of hypertrophic cardiomyopathy (HCM), a disorder of heart muscle thickening associated with sudden cardiac death and heart failure, with unclear mechanisms. We engineered four isogenic induced pluripotent stem cell (iPSC) models of β-myosin heavy chain and myosin-binding protein C3 mutations, and studied iPSC-derived cardiomyocytes in cardiac microtissue assays that resemble cardiac architecture and biomechanics. All HCM mutations resulted in hypercontractility with prolonged relaxation kinetics in proportion to mutation pathogenicity, but not changes in calcium handling. RNA sequencing and expression studies of HCM models identified p53 activation, oxidative stress, and cytotoxicity induced by metabolic stress that can be reversed by p53 genetic ablation. Our findings implicate hypercontractility as a direct consequence of thick-filament mutations, irrespective of mutation localization, and the p53 pathway as a molecular marker of contraction stress and candidate therapeutic target for HCM patients

Sarcomere function activates a p53-dependent DNA damage response that promotes polyploidization and limits in vivo cell engraftment.

Human cardiac regeneration is limited by low cardiomyocyte replicative rates and progressive polyploidization by unclear mechanisms. To study this process, we engineer a human cardiomyocyte model to track replication and polyploidization using fluorescently tagged cyclin B1 and cardiac troponin T. Using time-lapse imaging, in vitro cardiomyocyte replication patterns recapitulate the progressive mononuclear polyploidization and replicative arrest observed in vivo. Single-cell transcriptomics and chromatin state analyses reveal that polyploidization is preceded by sarcomere assembly, enhanced oxidative metabolism, a DNA damage response, and p53 activation. CRISPR knockout screening reveals p53 as a driver of cell-cycle arrest and polyploidization. Inhibiting sarcomere function, or scavenging ROS, inhibits cell-cycle arrest and polyploidization. Finally, we show that cardiomyocyte engraftment in infarcted rat hearts is enhanced 4-fold by the increased proliferation of troponin-knockout cardiomyocytes. Thus, the sarcomere inhibits cell division through a DNA damage response that can be targeted to improve cardiomyocyte replacement strategies

SARS-CoV-2 Infects Human Engineered Heart Tissues and Models COVID-19 Myocarditis.

There is ongoing debate as to whether cardiac complications of coronavirus disease-2019 (COVID-19) result from myocardial viral infection or are secondary to systemic inflammation and/or thrombosis. We provide evidence that cardiomyocytes are infected in patients with COVID-19 myocarditis and are susceptible to severe acute respiratory syndrome coronavirus 2. We establish an engineered heart tissue model of COVID-19 myocardial pathology, define mechanisms of viral pathogenesis, and demonstrate that cardiomyocyte severe acute respiratory syndrome coronavirus 2 infection results in contractile deficits, cytokine production, sarcomere disassembly, and cell death. These findings implicate direct infection of cardiomyocytes in the pathogenesis of COVID-19 myocardial pathology and provides a model system to study this emerging disease

Coronary sinus pacing for the management of right ventricular and atrial infarction with isolated right ventricular pulsus alternans.

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Reading Frame Repair of TTN Truncation Variants Restores Titin Quantity and Functions

BACKGROUND: Titin truncation variants (TTNtvs) are the most common inheritable risk factor for dilated cardiomyopathy (DCM), a disease with high morbidity and mortality. The pathogenicity of TTNtvs has been associated with structural localization as A-band variants overlapping myosin heavy chain-binding domains are more pathogenic than I-band variants by incompletely understood mechanisms. Demonstrating why A-band variants are highly pathogenic for DCM could reveal new insights into DCM pathogenesis, titin (TTN) functions, and therapeutic targets. METHODS: We constructed human cardiomyocyte models harboring DCM-associated TTNtvs within A-band and I-band structural domains using induced pluripotent stem cell and CRISPR technologies. We characterized normal TTN isoforms and variant-specific truncation peptides by their expression levels and cardiomyocyte localization using TTN protein gel electrophoresis and immunofluorescence, respectively. Using CRISPR to ablate A-band variant-specific truncation peptides through introduction of a proximal I-band TTNtv, we studied genetic mechanisms in single cardiomyocyte and 3-dimensional, biomimetic cardiac microtissue functional assays. Last, we engineered a full-length TTN protein reporter assay and used next-generation sequencing assays to develop a CRISPR therapeutic for somatic cell genome editing TTNtvs. RESULTS: An A-band TTNtv dose-dependently impaired cardiac microtissue twitch force, reduced full-length TTN levels, and produced abundant TTN truncation peptides. TTN truncation peptides integrated into nascent myofibril-like structures and impaired myofibrillogenesis. CRISPR ablation of TTN truncation peptides using a proximal I-band TTNtv partially restored cardiac microtissue twitch force deficits. Cardiomyocyte genome editing using SpCas9 and a TTNtv-specific guide RNA restored the TTN protein reading frame, which increased full-length TTN protein levels, reduced TTN truncation peptides, and increased sarcomere function in cardiac microtissue assays. CONCLUSIONS: An A-band TTNtv diminished sarcomere function greater than an I-band TTNtv in proportion to estimated DCM pathogenicity. Although both TTNtvs resulted in full-length TTN haploinsufficiency, only the A-band TTNtv produced TTN truncation peptides that impaired myofibrillogenesis and sarcomere function. CRISPR-mediated reading frame repair of the A-band TTNtv restored functional deficits, and could be adapted as a one-and-done genome editing strategy to target ≈30% of DCM-associated TTNtvs

Reading Frame Repair of TTN Truncation Variants Restores Titin Quantity and Functions.

BACKGROUND: Titin truncation variants (TTNtvs) are the most common inheritable risk factor for dilated cardiomyopathy (DCM), a disease with high morbidity and mortality. The pathogenicity of TTNtvs has been associated with structural localization as A-band variants overlapping myosin heavy chain-binding domains are more pathogenic than I-band variants by incompletely understood mechanisms. Demonstrating why A-band variants are highly pathogenic for DCM could reveal new insights into DCM pathogenesis, titin (TTN) functions, and therapeutic targets. METHODS: We constructed human cardiomyocyte models harboring DCM-associated TTNtvs within A-band and I-band structural domains using induced pluripotent stem cell and CRISPR technologies. We characterized normal TTN isoforms and variant-specific truncation peptides by their expression levels and cardiomyocyte localization using TTN protein gel electrophoresis and immunofluorescence, respectively. Using CRISPR to ablate A-band variant-specific truncation peptides through introduction of a proximal I-band TTNtv, we studied genetic mechanisms in single cardiomyocyte and 3-dimensional, biomimetic cardiac microtissue functional assays. Last, we engineered a full-length TTN protein reporter assay and used next-generation sequencing assays to develop a CRISPR therapeutic for somatic cell genome editing TTNtvs. RESULTS: An A-band TTNtv dose-dependently impaired cardiac microtissue twitch force, reduced full-length TTN levels, and produced abundant TTN truncation peptides. TTN truncation peptides integrated into nascent myofibril-like structures and impaired myofibrillogenesis. CRISPR ablation of TTN truncation peptides using a proximal I-band TTNtv partially restored cardiac microtissue twitch force deficits. Cardiomyocyte genome editing using SpCas9 and a TTNtv-specific guide RNA restored the TTN protein reading frame, which increased full-length TTN protein levels, reduced TTN truncation peptides, and increased sarcomere function in cardiac microtissue assays. CONCLUSIONS: An A-band TTNtv diminished sarcomere function greater than an I-band TTNtv in proportion to estimated DCM pathogenicity. Although both TTNtvs resulted in full-length TTN haploinsufficiency, only the A-band TTNtv produced TTN truncation peptides that impaired myofibrillogenesis and sarcomere function. CRISPR-mediated reading frame repair of the A-band TTNtv restored functional deficits, and could be adapted as a one-and-done genome editing strategy to target ≈30% of DCM-associated TTNtvs