Cardiomyocyte Function Research Articles

Abstract 4122257: Inhibition of Neutrophil Extracellular Traps Prevents Heart Failure by Preserving Mitochondrial Function of Cardiomyocytes in Mice

Background: We have previously demonstrated that neutrophil extracellular traps (NETs) in myocardial tissue are associated with cardiac dysfunction and adverse outcomes in patients with heart failure with reduced ejection fraction. Here, we aimed to elucidate the underlying mechanisms and to clarify whether inhibiting NETs could rescue the cardiac phenotype using ex vivo and in vivo models. Methods and Results: Given that peptidyl arginine deiminase 4 (PAD4) is essential for the formation of NETs, PAD4 knockout mice were used for this study. First, we assessed the mitochondrial function of cardiomyocytes by conducting real-time measurements of the oxygen consumption rate in ex vivo . Extracellular flux analysis revealed that NETs-containing conditioned medium from wild-type neutrophils or purified NET components led to impaired mitochondrial oxygen consumption of adult mouse cardiomyocytes, while these effects were abolished when PAD4 in neutrophils was genetically ablated (Figure 1). In a murine model of pressure overload-induced heart failure, transverse aortic constriction (TAC) operation was performed on wild-type and PAD4 knockout mice. Immunohistological analysis demonstrated that TAC induced the formation of NETs in the myocardium, with the greatest number of NETs occurring at 1 day, persisting into the failing stage at 4 weeks in wild-type mice, while PAD4-deficient hearts displayed no presence of NETs in the heart tissue (Figure 2). Four weeks after TAC, left ventricular ejection fraction was reduced in wild-type mice, whereas PAD4 knockout mice displayed preserved left ventricular ejection fraction (Figure 2). Finally, we investigated the bioenergetics of cardiomyocytes isolated from PAD4 knockout mice after TAC. Maximal mitochondrial oxygen consumption rate in cardiomyocytes isolated from TAC-operated PAD4 knockout mice was significantly higher than in those from TAC-operated wild-type mice (Figure 3). Conclusion: Our data suggest that NETs directly derived impairment of mitochondrial function in cardiomyocytes. Inhibiting NETs represents a potential therapeutic approach for heart failure, preventing mitochondrial dysfunction of cardiomyocytes.

Abstract 4126304: A Cardiac Targeting Peptide Linked to miRNA106a Targets and Suppresses Genes Known to Cause Heart Failure: Reversing Heart Failure at the Source

Background: About one in five adults at age 40 will develop heart failure (HF) during their lifetime. Risk factors for HF (e.g., hypertension, etc.) alter cardiomyocytes structure and function resulting in HF. At the cellular level, these changes consist of mis/over-expression of genes that regulate cardiac identity (e.g., CamK2d, PKC, etc). The current paradigm for treating HF is pharmacological intervention or surgery; however, with few exceptions, the condition worsens with time. We are proposing a paradigm-shift for treating HF from a drug-centric system to a molecular approach that would reverse hypertrophy and adverse remodeling. Methods: A cardiac targeting peptide (CTP) was generated and linked by disulfide bond to miRNA106a, which was then introduced into a HF mouse model to measure its ability to reverse multiple heart failure parameters. CTP-miRNA106a was also introduced into a human cardiac cell line, followed by multiple analyses including Western Blot, qPCR, FACS, immunofluorescence all used to identify mechanism(s) utilized by CTP-miRNA106a to reverse HF characteristics. Results: Bio-distribution studies showed CTP delivered its miRNA106a cargo specifically to the heart within 30 mins, followed by clearance of CTP from the heart to the kidneys and liver by 3-5hrs post systemic drug injection. MiRNA106a persisted in cardiomyocytes until day 7 (latest tested time-point). CTP-miRNA106a reversed Ang2/Iso induced hypertrophy in 90% of the experimental mice ( Fig1 ). We also identified two potential HF intracellular signaling mechanisms (PLCb1/PKC/IP3 and NfkB) targeted by CTP-miRNA106a that could benefit both types of HF, HFrEF and HFpEF. PLCβ1 is a direct target for miRNA106a while the Nfkb pathway is indirectly targeted by decreased Camk2d (an miRNA106a target) signaling to IκBα. NfkB activity is quelled by miRNA106a. Conclusions: Our approach utilizes the function of miRNA106a to downregulate genes involved in cardiac hypertrophy and inflammation through the PLCb1 and CamKIId/Nfkb pathways. Most importantly, using a CTP-miRNA106a, we show delivery of miRNA106a cargo is specific to cardiomyocytes both in vitro and in vivo and that once delivered, many HF parameters including hypertrophy are reversed.

Abstract 4139187: Electrophysiological and Mechanical Characterization of Human Ventricular Myocardium from Patients with Primary or Secondary Cardiac Hypertrophy

Left-ventricular hypertrophy (LVH) is an adaptive condition to hemodynamic stress often involving the left ventricle (LV). This pathological condition is associated with clinical complications such as ventricular arrhythmias and diastolic dysfunction, the molecular and cellular mechanisms of which have been poorly investigated in the human heart. We collected myocardial samples from the upper interventricular septum of 132 patients with hypertrophic cardiomyopathy (HCM), 42 patients with aortic stenosis and severe LVH (AoS-LVH) and 12 non-failing non-hypertrophic patients with valve disease (NF-NH), who underwent myectomy operations at our cardiac surgery center. Samples were used to isolate single viable cardiomyocytes from the left ventricle to perform patch-clamp electrophysiological studies and intracellular calcium measurements with fluorescent dyes. Intact trabeculae were also dissected to perform isometric force measurements of electrically-stimulated twitches. Single-cell patch-clamp studies revealed a marked prolongation of action potential duration (APD) in HCM (N=82, mean APD at 90% repolarization=763±252ms at 0.5Hz) and AoS-LVH (N=22, APD90%=579±147ms) samples with respect to NF-NH (N=12, APD90%=447±88ms). In both HCM and AoS-LVH cardiomyocytes, APD prolongation was associated with increased late-Na + current with respect to NF-NH, while L-type Ca 2+ current was enlarged only in HCM samples. Ca 2+ -fluorescence studies revealed markedly slower Ca-transient (CaT) kinetics in myocardial samples from HCM (N=38, mean CaT 50% decay time at 0.5 Hz = 658±179ms) and AoS-LVH patients (N=9, CaT50%= 568±187ms), when compared with NF-NH samples (N=8, CaT50%=283±59ms), paralleled by elevated diastolic [Ca 2+ ]. Twitch force measurements in intact trabeculae revealed prolonged isometric contractions in HCM (N=78, overall twitch duration at 0.5Hz= 730±147ms) and in AoS-LVH patient-samples (N=24, TwD=669±116ms), as compared with NF-NH (N=7, TwD=511±73ms). Force-frequency relationship was flat in pathological samples, while NF-NH trabeculae showed a clear increase in twitch amplitude while increasing pacing rate to 2Hz. Our results suggest that the main features of functional cardiomyocyte remodeling (that is, changes in the expression and/or function of ion-channel and EC-coupling proteins) are qualitatively similar in primary vs. secondary LVH, albeit abnormalities are quantitatively more extensive in HCM samples.

Correction: Huynh et al. Spike Protein Impairs Mitochondrial Function in Human Cardiomyocytes: Mechanisms Underlying Cardiac Injury in COVID-19. Cells 2023, 12, 877

There was an error in the original publication [...]

MicroRNA-24 therapeutic potentials in infarction, stroke, and diabetic complications.

The prevalence of cardiovascular events, stroke, and diabetes worldwide underscores the urgent need for effective and minimally invasive treatments. With nearly 20million annual casualties attributed to cardiovascular diseases and an estimated 463million people living with diabetes in 2022. Identifying promising therapeutic candidates is paramount. MicroRNAs, short nucleic acids involved in regulating gene expression, emerge as potential game-changers. Among these, microRNA-24 (miR-24), a hypoxia-sensitive player in endothelial vessels, has protective roles against diverse vascular complications. Following heart infarction and stroke, elevating miR-24 expression proves beneficial by mitigating oxidative stress, inflammation, and apoptosis while enhancing cell survival. It reduces cardiac fibrosis in heart disease, regulates aberrant angiogenesis in cerebral hemorrhagic strokes, and enhances the functionality of cardiomyocytes and brain neurons. In diabetic conditions, augmenting miR-24 expression mitigates complications. Further, being miR-24 also expressed by the skeletal muscle (i.e., myo-miR) in response to exercise, this miRNA may participate in the complex molecular network that systemically spreads the beneficial effects of physical exercise. This review provides a comprehensive vision of the molecular mechanisms underpinning the miR-24 protective effects, offering new insights into its therapeutic potential and proposing a novel avenue for medical intervention.

Klf9 is essential for cardiac mitochondrial homeostasis.

Mitochondrial dynamics and mitophagy are intimately linked physiological processes that are essential for cardiac homeostasis. Here we show that cardiac Krüppel-like factor 9 (Klf9) is dysregulated in human and rodent cardiomyopathy. Both global and cardiac-specific Klf9-deficient mice displayed hypertrophic cardiomyopathy. Klf9 knockout led to mitochondrial disarray and fragmentation, impairing mitochondrial respiratory function in cardiomyocytes. Furthermore, cardiac Klf9 deficiency inhibited mitophagy, thereby causing accumulation of dysfunctional mitochondria and acceleration of heart failure in response to angiotensin II treatment. In contrast, cardiac-specific Klf9 transgene improved cardiac systolic function. Mechanistically, Klf9 knockout decreased the expression of PGC-1α and its target genes involved in mitochondrial energy metabolism. Moreover, Klf9 controlled the expression of Mfn2, thereby regulating mitochondrial dynamics and mitophagy. Finally, adeno-associated virus-mediated Mfn2 rescue in Klf9-CKO hearts improved cardiac mitochondrial and systolic function. Thus, Klf9 integrates cardiac energy metabolism, mitochondrial dynamics and mitophagy. Modulating Klf9 activity may have therapeutic potential in the treatment of heart failure.

Induced pluripotent stem cell-derived cardiomyocyte in vitro models: benchmarking progress and ongoing challenges.

Recent innovations in differentiating cardiomyocytes from human induced pluripotent stem cells (hiPSCs) have unlocked a viable path to creating in vitro cardiac models. Currently, hiPSC-derived cardiomyocytes (hiPSC-CMs) remain immature, leading many in the field to explore approaches to enhance cell and tissue maturation. Here, we systematically analyzed 300 studies using hiPSC-CM models to determine common fabrication, maturation and assessment techniques used to evaluate cardiomyocyte functionality and maturity and compiled the data into an open-access database. Based on this analysis, we present the diversity of, and current trends in, in vitro models and highlight the most common and promising practices for functional assessments. We further analyzed outputs spanning structural maturity, contractile function, electrophysiology and gene expression and note field-wide improvements over time. Finally, we discuss opportunities to collectively pursue the shared goal of hiPSC-CM model development, maturation and assessment that we believe are critical for engineering mature cardiac tissue.

Intracellular delivery of a phospholamban-targeting aptamer using cardiomyocyte-internalizing aptamers

The sarco(endo)plasmic reticulum Ca2+-ATPase 2a (SERCA2a)–phospholamban (PLN) system within the sarcoplasmic reticulum is crucial for regulating intracellular Ca2+ cycling in ventricular cardiomyocytes. Given that impaired Ca2+ cycling is associated with heart failure, modulating SERCA2a activity represents a promising therapeutic strategy. Previously, we engineered an RNA aptamer (Apt30) that binds to PLN, thereby activating SERCA2a by alleviating PLN's inhibitory effect. However, Apt30 alone cannot reach intracellular PLN, necessitating the development of a mechanism for its specific internalization into cardiomyocytes.Using the systematic evolution of ligands by exponential enrichment (SELEX) method, we isolated RNA aptamers capable of internalizing into cardiomyocytes. These aptamers demonstrated sub-micromolar EC50 values for cardiomyocyte internalization and exhibited significantly reduced activity against various non-myocardial cells, highlighting their specificity for cardiomyocytes. Moreover, some of these cardiomyocyte-internalizing aptamers could be linked to Apt30 as a single RNA strand without compromising their internalization efficacy. Supplementing the culture medium with these hybrid aptamers enhanced Ca2+ transients and contractile function in rat cardiomyocytes. These findings provide critical insights for developing novel therapeutics directly acting on PLN in cardiomyocytes, potentially compensating for the disadvantages of conventional methods that involve viral vector-mediated intracellular transduction or alterations in endogenous protein expression.

Post-acute sequelae of SARS-CoV-2 cardiovascular symptoms are associated with trace-level cytokines that affect cardiomyocyte function.

An estimated 65 million people globally suffer from post-acute sequelae of COVID-19 (PASC), with many experiencing cardiovascular symptoms (PASC-CVS) like chest pain and heart palpitations. This study examines the role of chronic inflammation in PASC-CVS, particularly in individuals with symptoms persisting over a year after infection. Blood samples from three groups-recovered individuals, those with prolonged PASC-CVS and SARS-CoV-2-negative individuals-revealed that those with PASC-CVS had a blood signature linked to inflammation. Trace-level pro-inflammatory cytokines were detected in the plasma from donors with PASC-CVS 18 months post infection using nanotechnology. Importantly, these trace-level cytokines affected the function of primary human cardiomyocytes. Plasma proteomics also demonstrated higher levels of complement and coagulation proteins in the plasma from patients with PASC-CVS. This study highlights chronic inflammation's role in the symptoms of PASC-CVS.

SNORD3A: a new possible circulating biomarker of human heart failure

Abstract Background Heart failure (HF) is a complex clinical syndrome and the leading cause of mortality, morbidity and hospitalization in industrialized countries. Human cardiac biopsies are invaluable resources for identifying cardiac signaling pathways, however blood fractions and peripheral blood mononuclear cells (PBMCs) could be used as a source of surrogate biomarkers of signaling pathway activation in human heart failure. Purpose In the present study we aimed to identify novel circulating biomarkers mirroring human myocardial signaling in HF and to study the role played by SNORD3A in cardiomyocyte survival and death. Methods Cardiac left ventricle samples and PBLs from 8 HF patients undergoing heart transplantation and 2 control patients (CTRL) were analyzed by RNA sequencing (RNASeq) to identify transcripts that were regulated in both hearts and PBLs. Five identified transcripts, KCNQOT1, MIAT, SCRN1, MALAT1 and SNORD3A, were then validated by quantitative real-time PCR in PBMCs and in LVs. Next, we analyzed the expression of the Small Nucleolar RNA (snoRNA) SNORD3A in LVs and PBMCs from 8-week-old wild type C57BL/6 mice with pressure overload-induced HF by transverse aortic constriction (TAC). Sham-operated mice (sham) were used as controls. To further investigate the role of SNORD3A in cardiomyocyte function and survival, SNORD3A antisense oligonucleotides (SNOaso) and scramble control sequences (GFPaso) were synthesized and tested in cardiomyoblasts H9C2 cells under normoxic or hypoxic conditions to evaluate SNORD3A transcription levels, cell death and protein synthesis. Results SNORD3A expression was significantly increased in both LVs and PBMCs from HF patients compared to control subjects. Consistent with these results, SNORD3A levels were increased both in PBMCs and LVs from TAC mice compared to sham. In vitro hypoxia significantly increased SNORD3A expression levels in H9C2 cells, compared to normoxia. After SNOaso transfection, SNORD3A transcripts were downregulated, and they were further reduced following 3-hour-hypoxia. Depletion of SNORD3A levels increased cardiomyocyte death and reduced protein synthesis in H9C2 cells. Conclusions Our data suggest that SNORD3A might be involved in the regulation of cardiomyocyte survival in HF and could be useful for diagnostic and prognostic applications in HF.

Calcitonin signalling system regulates function and arhythmogenicity of atrial cardiomyocytes

Abstract Background Atrial fibrillation (AF) poses a significant therapeutic challenge due to myocardial remodelling, involving both structural and electrical alterations. Recent investigations have shed light on the role of atrial cardiomyocytes (CMs) in secreting Calcitonin (CT), a factor crucial for maintaining atrial tissue integrity. Dysregulated CT secretion in AF showed to contribute to fibrotic tissue production by atrial fibroblasts, exacerbating arrhythmogenesis [1]. However, the direct impact of CT on CM function and arrhythmogenicity remains unclear, driving the objectives of our study. Methods/Results Serum samples from 20 cardiac surgery patients revealed a noteworthy association between higher pre-operative CT levels and a significant ~2.8-fold reduction in the incidence of post-operative AF (poAF). Using freshly isolated atrial guinea pig CMs, confirmed (by qPCR and immunofluorescence) that CMs express CT-receptor (CTR) to enable CT actions in the cell. Functional studies found that CT administration inhibits spontaneous calcium (Ca2+)-release events induced by pacing and decreases the Ca2+ transients amplitude (at 2 Hz; IonOptix μstep system) in fura2-loaded CMs (n=22 cells) in a concentration-dependent manner. Atrial iPSC-CMs transduced with global RGECO sensor (Genetically encoded Ca2+ indicator) and treated with 15 pM CT showed a reduction in the beat rate when paced at 2Hz, and a significantly increased the time to 50% baseline. Evaluation of the expression and phosphorylation of selected Ca2+ handling proteins, which may potentially account for the observed changes in Ca2+ transients, showed no differences in total or phospho-(ser2808) ryanodine receptor, and SERCA2α in response to CT but an increase in phospho-(Ser16) Phospholamban. Conclusion Our findings highlight the effects of CT on atrial CM function. Maintaining physiological CT levels offer a promising approach for managing AF clinically, potentially through the use of already in clinical use CT-analogues.

Deletion of nephrocystin 4 exacerbates cardiac function and survival rate in a mouse model of cardio-renal syndrome

Abstract Background Cardiorenal syndrome (CRS), characterized by cardiac and renal dysfunction, is an increasing health problem associated with high mortality rate. Nephrocystin 4 (NPHP4) gene is the major cause of end-stage renal disease in children. We have reported NPHP4 single nucleotide polymorphism is the genetic risk for CRS and subsequent cardiovascular events in general population. However, the functional role of Nphp4 in the development of CRS has never been examined yet. Methods and Results We generated systemic Nphp4 knockout (KO) mice deleting exon 3 to 8 using CRISPR-Cas9 system. RNA sequence analysis of heart and kidney tissues demonstrated that gene-sets related to mitochondrial function were significantly downregulated in Nphp4 KO mice compared to their wild-type (WT) littermates. Nphp4 KO mice showed less cardiac hypertrophy, however, exacerbated cardiac function and survival compared to WT mice in a CRS model induced by thoracic transverse aortic constriction. Nphp4 located in endosome and cell membrane in H9C2 cardiomyocytes. Immunoprecipitation confirmed protein interaction between Nphp4 and HECT-type E3 ligase Itch. Furthermore, we found that Itch targeted Lats2 and insulin-like growth factor-1 receptor in cardiomyocytes. Knockdown of Nphp4 activated Hippo signaling and worsened mitochondrial function in H9C2 cardiomyocytes through the inhibition of Itch-dependent Lats2 degradation. Knockdown of Nphp4 inhibited insulin-like growth factor-1 signaling through the disturbance of Itch-mediated endosome function. Conclusions Deletion of Nphp4 impaired compensatory cardiac hypertrophy and exacerbated cardiac function and survival in a mouse CRS model through mitochondrial dysfunction. Nphp4 mediated Hippo signaling and insulin-like growth factor-1 signaling through the interaction with Itch. NPHP4 could be the novel therapeutic target in CRS.figure1figure2

Loss of IDH1 and IDH2 in macrophages induces pathological phenotypes in cardiomyocytes

Abstract Introduction The clonal expansion of hematopoietic stem cells can be induced by a variety of age-related somatic mutations, a phenomenon known as "clonal hematopoiesis of indeterminate potential" (CHIP). CHIP is associated with an increased incidence and poor outcomes in patients with cardiovascular disease. The mechanisms underlying the crosstalk between CHIP cells and cardiac tissue are yet to be elucidated. Rare mutations in the metabolism-regulating isocitrate dehydrogenases encoding genes IDH1 and IDH2 have been identified as AML-like and cardiovascular high-risk CHIP-driving mutations in patient cohorts. However, the potential paracrine effects of these mutations in immune cells on cardiac tissue are unknown. Therefore, we assessed the impact of IDH1 and IDH2 mutations on the paracrine activities of macrophages. Methods and Results To gain first insights into the functional consequences of the IDH mutations, we used the AlphaMissense algorithm, which predicts the impact of mutations on protein function. IDH1 and IDH2 mutations identified in our patient cohorts were predicted to induce pathological alterations of protein function with a score >0.99. Therefore, we assessed the effects of silencing of the two genes in primary human CD14+ M0 macrophages on the paracrine activity on neonatal rat cardiomyocytes. Transfection with siRNA pools targeting IDH1 and IDH2 to mimic CHIP-driving conditions reduced mRNA abundance by 78% and 73%, respectively (both p<0.05). To assess the impact of IDH-silencing on cardiovascular cells, cardiomyocytes were treated with the supernatant of the macrophages. Interestingly, supernatants of IDH1 silenced macrophages significantly increased apoptosis of cardiomyocytes (8.6-fold increased expression of cleaved caspase-3; p<0.05) and reduced beating frequency. In addition, supernatants of IDH1 silenced macrophages induced a 1.5-fold increase in cardiomyocyte hypertrophy (p<0.01), whereas silencing of IDH2 showed no effect on cardiomyocyte hypertrophy and apoptosis. However, supernatants of both IDH1 and IDH2 silenced macrophages resulted in significantly increased numbers of bi- and multinucleated cardiomyocytes. Conclusion: Loss of isocitrate dehydrogenases in human macrophages affects cardiomyocyte functions in a paracrine fashion. Particularly silencing of IDH1 in macrophages introduced cardiomyocyte hypertrophy, apoptosis, and bi- and multinucleation, and reduced contractile function. Ongoing studies will address how IDH1 and IDH2 silencing-induced alterations in macrophages control their paracrine activity on cardiomyocytes.

APEX1 Knockdown Alleviates Inflammation and Fibrosis in Myocardial Infarction Through Promoting ZCCHC9 Expression and Blocking the p38 MAPK Signaling.

It was reported that serum apurinic/apyrimidinic endodeoxyribonuclease 1 (APEX1) level was higher in acute myocardial infarction (AMI) patients than in angina. This study aimed to investigate the role and mechanism of APEX1 in AMI progression. The mRNA and protein levels of APEX1 and zinc finger CCHC domain containing 9 (ZCCHC9) in blood specimens of AMI patients and normal controls were determined by RT-qPCR and Western blot assays, respectively. H9c2 cardiomyocytes were treated with angiotensin II (Ang II) to induce cardiomyocyte injury and then transfected with small interfering RNA against APEX1 (si-APEX1) or overexpression plasmids of ZCCHC9 (pcDNA-ZCCHC9). The cell viability, apoptosis, inflammatory cytokine levels, and fibrosis-associated protein expression in H9c2 cells were evaluated. ZCCHC9 promoter methylation were detected with methylation-specific PCR (MSP) assay. Then, rescue experiments were performed to explore whether APEX1 mediated cardiomyocyte functions by regulating ZCCHC9 expression. Furthermore, we explored whether the APEX1/ZCCHC9 axis regulated cardiomyocyte injury in AMI via the p38 MAPK signaling pathway. Additionally, an AMI rat model was established using the left anterior descending artery (LAD) ligation method and multipoint intramyocardial injection (5 points, 2 µL/point) of lentivirus (1 × 109 TU/mL) carrying scramble or si-APEX1 was conducted before modeling. The rats were euthanized four weeks after AMI modeling, and blood samples and myocardial tissues were harvested. The infarct area, cell apoptosis, inflammation, and fibrosis in myocardial tissues were detected. APEX1 was upregulated and ZCCHC9 was downregulated in blood samples of AMI patients compared with normal controls. APEX1 knockdown or ZCCHC9 overexpression attenuated Ang II-induced viability reduction, apoptosis, inflammation, and fibrosis in cardiomyocytes. APEX1 inhibited ZCCHC9 expression by promoting DNA methyltransferase 1 (DNMT1)-mediated ZCCHC9 promoter methylation. ZCCHC9 knockdown abolished the protective effects of APEX1 knockdown on Ang II-induced cardiomyocyte injury. APEX1 knockdown inhibited the p38 MAPK signal signaling, and anisomycin reversed the effect of APEX1 knockdown on cardiomyocyte functions. Additionally, APEX1 knockdown alleviated apoptosis, inflammation, and fibrosis in myocardial tissues of AMI rats. APEX1 knockdown attenuated Ang II-induced apoptosis, inflammation, and fibrosis in cardiomyocytes although promoting ZCCHC9 expression and inhibiting the p38 MAPK signaling pathway, thus relieving myocardial infarction, inflammation, and fibrosis in AMI rats.

Hydrogel microsphere stem cell encapsulation enhances cardiomyocyte differentiation and functionality in scalable suspension system

A reliable suspension-based platform for scaling engineered cardiac tissue (ECT) production from human induced pluripotent stem cells (hiPSCs) is crucial for regenerative therapies. Here, we compared the production and functionality of ECTs formed using our scaffold-based, engineered tissue microsphere differentiation approach with those formed using the prevalent scaffold-free aggregate platform. We utilized a microfluidic system for the rapid (1 million cells/min), high density (30, 40, 60 million cells/ml) encapsulation of hiPSCs within PEG-fibrinogen hydrogel microspheres. HiPSC-laden microspheres and aggregates underwent suspension-based cardiac differentiation in chemically defined media. In comparison to aggregates, microspheres maintained consistent size and shape initially, over time, and within and between batches. Initial size and shape coefficients of variation for microspheres were eight and three times lower, respectively, compared to aggregates. On day 10, microsphere cardiomyocyte (CM) content was 27 % higher and the number of CMs per initial hiPSC was 250 % higher than in aggregates. Contraction and relaxation velocities of microspheres were four and nine times higher than those of aggregates, respectively. Microsphere contractile functionality also improved with culture time, whereas aggregate functionality remained unchanged. Additionally, microspheres displayed improved β-adrenergic signaling responsiveness and uniform calcium transient propagation. Transcriptomic analysis revealed that while both microspheres and aggregates demonstrated similar gene regulation patterns associated with cardiomyocyte differentiation, heart development, cardiac muscle contraction, and sarcomere organization, the microspheres exhibited more pronounced transcriptional changes over time. Taken together, these results highlight the capability of the microsphere platform for scaling up biomanufacturing of ECTs in a suspension-based culture platform.

High-intensity interval training improves cardiomyocyte contractile function and myofilament sensitivity to intracellular Ca2+ in obese rats.

High-intensity interval training (HIIT) has shown significant results in addressing adiposity and risk factors associated with obesity. However, there are no studies that investigate the effects of HIIT on contractility and intracellular Ca2+ handling. The purpose of this study was to explore the impact of HIIT on cardiomyocyte contractile function and intracellular Ca2+ handling in rats in which obesity was induced by a saturated high-fat diet (HFD). Male Wistar rats were initially randomized into a standard diet and a HFD group. The experimental protocol spanned 23weeks, comprising the induction and maintenance of obesity (15weeks) followed by HIIT treatment (8weeks). Performance was assessed using the maximum oxygen consumption test ( ). Evaluation encompassed cardiac, adipose and skeletal muscle histology, as well as contractility and intracellular Ca2+ handling. HIIT resulted in a reduction in visceral area, an increase in , and an augmentation of gastrocnemius fibre diameter in obese subjects. Additionally, HIIT led to a decrease in collagen fraction, an increase in percentage shortening, and a reduction in systolic Ca2+/percentage shortening and systolic Ca2+/maximum shortening rates. HIIT induces physiological cardiac remodelling, enhancing the contractile function of cardiomyocytes and improving myofilament sensitivity to Ca2+ in the context of obesity. This approach not only enhances cardiorespiratory and physical performance but also reduces visceral area and prevents interstitial fibrosis.

Recording and Interpretation of Active Calcium Transients in Induced Pluripotent Stem Cell-Derived Cardiomyocytes.

Calcium plays a pivotal role in the excitation-contraction coupling process in cardiomyocytes, a critical multi-parametric event leading to rhythmic contraction. Over the past few decades, calcium signaling in cardiomyocytes has been extensively studied in cardiovascular sciences. However, a standard methodology is needed not only to trace the calcium within cells but also to remove signal processing biases and to accurately interpret the features of calcium transient signals in relation to cardiomyocyte electrophysiology. This article outlines the use of genetically encoded calcium indicator (GCaMP) human-induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) to record calcium transients. These cells express a green fluorescent signal when calcium binds to intracellular calmodulin, a key regulator of calcium signaling. The extraction and processing of calcium transient waveforms are performed using ImageJ and MATLAB software. Key features of these waveforms are then identified and categorized based on their physiological relevance to cardiomyocyte function. Additionally, this work includes a Support Protocol for the successful replating of cardiomyocytes onto non-traditional culture platforms, such as metallic sensors and polymer-based substrates, to facilitate data multiplexing. The three Basic Protocols outlined here provide a comprehensive approach for maintaining, expanding, and differentiating the GCaMP hiPSCs, video recording of calcium transients, and the subsequent signal extraction, preprocessing, analysis, and data visualization. © 2024 The Author(s). Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Maintenance, expansion, and differentiation of genetically encoded calcium indicator hiPSCs Support Protocol: Replating GCaMP hiPSC-CMs for stimulation and multielectrode array studies Basic Protocol 2: Video recording from calcium transients of GCaMP hiPSC-CMs Basic Protocol 3: Signal extraction, preprocessing, analysis, and data visualization.

Human induced pluripotent stem cell-derived cardiomyocytes to study inflammation-induced aberrant calcium transient.

Heart failure with preserved ejection fraction (HFpEF) is commonly found in persons living with HIV (PLWH) even when antiretroviral therapy suppresses HIV viremia. However, studying this condition has been challenging because an appropriate animal model is not available. In this article, we studied calcium transient in human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) in culture to simulate the cardiomyocyte relaxation defect noted in PLWH and HFpEF and assess whether various drugs have an effect. We show that treatment of hiPSC-CMs with inflammatory cytokines (such as interferon-γ or TNF-α) impairs their Ca2+ uptake into sarcoplasmic reticulum and that SGLT2 inhibitors, clinically proven as effective for HFpEF, reverse this effect. Additionally, treatment with mitochondrial antioxidants (like mito-Tempo) and certain antiretrovirals resulted in the reversal of the effects of these cytokines on calcium transient. Finally, incubation of hiPSC-CMs with serum from HIV patients with and without diastolic dysfunction did not alter their Ca2+-decay time, indicating that the exposure to the serum of these patients is not sufficient to induce the decrease in Ca2+ uptake in vitro. Together, our results indicate that hiPSC-CMs can be used as a model to study molecular mechanisms of inflammation-mediated abnormal cardiomyocyte relaxation and screen for potential new interventions.

Spaceflight-induced contractile and mitochondrial dysfunction in an automated heart-on-a-chip platform

With current plans for manned missions to Mars and beyond, the need to better understand, prevent, and counteract the harmful effects of long-duration spaceflight on the body is becoming increasingly important. In this study, an automated heart-on-a-chip platform was flown to the International Space Station on a 1-mo mission during which contractile cardiac function was monitored in real-time. Upon return to Earth, engineered human heart tissues (EHTs) were further analyzed with ultrastructural imaging and RNA sequencing to investigate the impact of prolonged microgravity on cardiomyocyte function and health. Spaceflight EHTs exhibited significantly reduced twitch forces, increased incidences of arrhythmias, and increased signs of sarcomere disruption and mitochondrial damage. Transcriptomic analyses showed an up-regulation of genes and pathways associated with metabolic disorders, heart failure, oxidative stress, and inflammation, while genes related to contractility and calcium signaling showed significant down-regulation. Finally, in silico modeling revealed a potential link between oxidative stress and mitochondrial dysfunction that corresponded with RNA sequencing results. This represents an in vitro model to faithfully reproduce the adverse effects of spaceflight on three-dimensional (3D)-engineered heart tissue.

PRDM16 determines specification of ventricular cardiomyocytes by suppressing alternative cell fates.

PRDM16 is a transcription factor with histone methyltransferase activity expressed at the earliest stages of cardiac development. Pathogenic mutations in humans lead to cardiomyopathy, conduction abnormalities, and heart failure. PRDM16 is specifically expressed in ventricular but not atrial cardiomyocytes, and its expression declines postnatally. Because in other tissues PRDM16 is best known for its role in binary cell fate decisions, we hypothesized a similar decision-making function in cardiomyocytes. Here, we demonstrated that cardiomyocyte-specific deletion of Prdm16 during cardiac development results in contractile dysfunction and abnormal electrophysiology of the postnatal heart, resulting in premature death. By combined RNA+ATAC single-cell sequencing, we found that PRDM16 favors ventricular working cardiomyocyte identity, by opposing the activity of master regulators of ventricular conduction and atrial fate. Myocardial loss of PRDM16 during development resulted in hyperplasia of the (distal) ventricular conduction system. Hence, PRDM16 plays an indispensable role during cardiac development by driving ventricular working cardiomyocyte identity.