Robert Romano scite author profile

SummaryThick-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.

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

Romano

Ghahremani

Zimmerman

et al. 2022

Circulation

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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, 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. Finally, we engineered a full-length TTN protein reporter assay and utilized 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 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. While 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.

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

et al. 2021

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Development of a Cardiac Sarcomere Functional Genomics Platform to Enable Scalable Interrogation of Human TNNT2 Variants

et al. 2020

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Background: Pathogenic TNNT2 variants are a cause of hypertrophic (HCM) and dilated (DCM) cardiomyopathies, which promote heart failure by incompletely understood mechanisms. Additionally, the precise functional significance for 87% of TNNT2 variants remains undetermined partially due to a lack of functional genomics studies. The knowledge of which and how TNNT2 variants cause HCM and DCM could improve heart failure risk determination, treatment efficacy, and therapeutic discovery, as well as provide new insights into cardiomyopathy pathogenesis. Methods: We created a toolkit of human induced pluripotent stem cell (hiPSC) models and functional assays using CRISPR/Cas9 to study TNNT2 variant pathogenicity and pathophysiology. Using hiPSC-derived cardiomyocytes (hiPSC-CMs) in cardiac microtissue and single cell assays, we functionally interrogated 51 TNNT2 variants, including 30 pathogenic/likely pathogenic variants and 21 variants of unknown significance (VUS). We utilized RNA-sequencing to determine the transcriptomic consequences of pathogenic TNNT2 variants, and adapted CRISPR/Cas9 to engineer a transcriptional reporter assay to assist prediction of TNNT2 variant pathogenicity. We also studied variant-specific pathophysiology using a thin filament-directed calcium reporter to monitor changes in myofilament calcium affinity. Results: HCM-associated TNNT2 variants caused increased cardiac microtissue contraction, while DCM-associated variants decreased contraction. TNNT2 variant-dependent changes in sarcomere contractile function induced graded regulation of 101 gene transcripts, including MAPK signaling targets, HOPX , and NPPB . We distinguished pathogenic TNNT2 variants from wildtype controls using a sarcomere functional reporter engineered by inserting tdTomato into the endogenous NPPB locus. Based on a combination of NPPB reporter activity and cardiac microtissue contraction, our study provides experimental support for the reclassification of 2 pathogenic/likely pathogenic variants and 2 VUSs. Conclusions: Our study found that HCM-associated TNNT2 variants increased cardiac microtissue contraction, while DCM-associated variants cause decreased contraction, both of which paralleled changes in myofilament calcium affinity. Transcriptomic changes, including NPPB levels, directly correlated with sarcomere function and can be utilized to predict TNNT2 variant pathogenicity.

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Robert Romano

A Contraction Stress Model of Hypertrophic Cardiomyopathy due to Sarcomere Mutations

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

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

Development of a Cardiac Sarcomere Functional Genomics Platform to Enable Scalable Interrogation of Human TNNT2 Variants

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